/* Optimize by combining instructions for GNU compiler. Copyright (C) 1987-2015 Free Software Foundation, Inc. This file is part of GCC. GCC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GCC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GCC; see the file COPYING3. If not see . */ /* This module is essentially the "combiner" phase of the U. of Arizona Portable Optimizer, but redone to work on our list-structured representation for RTL instead of their string representation. The LOG_LINKS of each insn identify the most recent assignment to each REG used in the insn. It is a list of previous insns, each of which contains a SET for a REG that is used in this insn and not used or set in between. LOG_LINKs never cross basic blocks. They were set up by the preceding pass (lifetime analysis). We try to combine each pair of insns joined by a logical link. We also try to combine triplets of insns A, B and C when C has a link back to B and B has a link back to A. Likewise for a small number of quadruplets of insns A, B, C and D for which there's high likelihood of success. LOG_LINKS does not have links for use of the CC0. They don't need to, because the insn that sets the CC0 is always immediately before the insn that tests it. So we always regard a branch insn as having a logical link to the preceding insn. The same is true for an insn explicitly using CC0. We check (with use_crosses_set_p) to avoid combining in such a way as to move a computation to a place where its value would be different. Combination is done by mathematically substituting the previous insn(s) values for the regs they set into the expressions in the later insns that refer to these regs. If the result is a valid insn for our target machine, according to the machine description, we install it, delete the earlier insns, and update the data flow information (LOG_LINKS and REG_NOTES) for what we did. There are a few exceptions where the dataflow information isn't completely updated (however this is only a local issue since it is regenerated before the next pass that uses it): - reg_live_length is not updated - reg_n_refs is not adjusted in the rare case when a register is no longer required in a computation - there are extremely rare cases (see distribute_notes) when a REG_DEAD note is lost - a LOG_LINKS entry that refers to an insn with multiple SETs may be removed because there is no way to know which register it was linking To simplify substitution, we combine only when the earlier insn(s) consist of only a single assignment. To simplify updating afterward, we never combine when a subroutine call appears in the middle. Since we do not represent assignments to CC0 explicitly except when that is all an insn does, there is no LOG_LINKS entry in an insn that uses the condition code for the insn that set the condition code. Fortunately, these two insns must be consecutive. Therefore, every JUMP_INSN is taken to have an implicit logical link to the preceding insn. This is not quite right, since non-jumps can also use the condition code; but in practice such insns would not combine anyway. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "backend.h" #include "target.h" #include "rtl.h" #include "tree.h" #include "predict.h" #include "df.h" #include "tm_p.h" #include "optabs.h" #include "regs.h" #include "emit-rtl.h" #include "recog.h" #include "cgraph.h" #include "stor-layout.h" #include "cfgrtl.h" #include "cfgcleanup.h" /* Include expr.h after insn-config.h so we get HAVE_conditional_move. */ #include "explow.h" #include "insn-attr.h" #include "rtlhooks-def.h" #include "params.h" #include "tree-pass.h" #include "valtrack.h" #include "rtl-iter.h" #include "print-rtl.h" #ifndef LOAD_EXTEND_OP #define LOAD_EXTEND_OP(M) UNKNOWN #endif /* Number of attempts to combine instructions in this function. */ static int combine_attempts; /* Number of attempts that got as far as substitution in this function. */ static int combine_merges; /* Number of instructions combined with added SETs in this function. */ static int combine_extras; /* Number of instructions combined in this function. */ static int combine_successes; /* Totals over entire compilation. */ static int total_attempts, total_merges, total_extras, total_successes; /* combine_instructions may try to replace the right hand side of the second instruction with the value of an associated REG_EQUAL note before throwing it at try_combine. That is problematic when there is a REG_DEAD note for a register used in the old right hand side and can cause distribute_notes to do wrong things. This is the second instruction if it has been so modified, null otherwise. */ static rtx_insn *i2mod; /* When I2MOD is nonnull, this is a copy of the old right hand side. */ static rtx i2mod_old_rhs; /* When I2MOD is nonnull, this is a copy of the new right hand side. */ static rtx i2mod_new_rhs; struct reg_stat_type { /* Record last point of death of (hard or pseudo) register n. */ rtx_insn *last_death; /* Record last point of modification of (hard or pseudo) register n. */ rtx_insn *last_set; /* The next group of fields allows the recording of the last value assigned to (hard or pseudo) register n. We use this information to see if an operation being processed is redundant given a prior operation performed on the register. For example, an `and' with a constant is redundant if all the zero bits are already known to be turned off. We use an approach similar to that used by cse, but change it in the following ways: (1) We do not want to reinitialize at each label. (2) It is useful, but not critical, to know the actual value assigned to a register. Often just its form is helpful. Therefore, we maintain the following fields: last_set_value the last value assigned last_set_label records the value of label_tick when the register was assigned last_set_table_tick records the value of label_tick when a value using the register is assigned last_set_invalid set to nonzero when it is not valid to use the value of this register in some register's value To understand the usage of these tables, it is important to understand the distinction between the value in last_set_value being valid and the register being validly contained in some other expression in the table. (The next two parameters are out of date). reg_stat[i].last_set_value is valid if it is nonzero, and either reg_n_sets[i] is 1 or reg_stat[i].last_set_label == label_tick. Register I may validly appear in any expression returned for the value of another register if reg_n_sets[i] is 1. It may also appear in the value for register J if reg_stat[j].last_set_invalid is zero, or reg_stat[i].last_set_label < reg_stat[j].last_set_label. If an expression is found in the table containing a register which may not validly appear in an expression, the register is replaced by something that won't match, (clobber (const_int 0)). */ /* Record last value assigned to (hard or pseudo) register n. */ rtx last_set_value; /* Record the value of label_tick when an expression involving register n is placed in last_set_value. */ int last_set_table_tick; /* Record the value of label_tick when the value for register n is placed in last_set_value. */ int last_set_label; /* These fields are maintained in parallel with last_set_value and are used to store the mode in which the register was last set, the bits that were known to be zero when it was last set, and the number of sign bits copies it was known to have when it was last set. */ unsigned HOST_WIDE_INT last_set_nonzero_bits; char last_set_sign_bit_copies; ENUM_BITFIELD(machine_mode) last_set_mode : 8; /* Set nonzero if references to register n in expressions should not be used. last_set_invalid is set nonzero when this register is being assigned to and last_set_table_tick == label_tick. */ char last_set_invalid; /* Some registers that are set more than once and used in more than one basic block are nevertheless always set in similar ways. For example, a QImode register may be loaded from memory in two places on a machine where byte loads zero extend. We record in the following fields if a register has some leading bits that are always equal to the sign bit, and what we know about the nonzero bits of a register, specifically which bits are known to be zero. If an entry is zero, it means that we don't know anything special. */ unsigned char sign_bit_copies; unsigned HOST_WIDE_INT nonzero_bits; /* Record the value of the label_tick when the last truncation happened. The field truncated_to_mode is only valid if truncation_label == label_tick. */ int truncation_label; /* Record the last truncation seen for this register. If truncation is not a nop to this mode we might be able to save an explicit truncation if we know that value already contains a truncated value. */ ENUM_BITFIELD(machine_mode) truncated_to_mode : 8; }; static vec reg_stat; /* One plus the highest pseudo for which we track REG_N_SETS. regstat_init_n_sets_and_refs allocates the array for REG_N_SETS just once, but during combine_split_insns new pseudos can be created. As we don't have updated DF information in that case, it is hard to initialize the array after growing. The combiner only cares about REG_N_SETS (regno) == 1, so instead of growing the arrays, just assume all newly created pseudos during combine might be set multiple times. */ static unsigned int reg_n_sets_max; /* Record the luid of the last insn that invalidated memory (anything that writes memory, and subroutine calls, but not pushes). */ static int mem_last_set; /* Record the luid of the last CALL_INSN so we can tell whether a potential combination crosses any calls. */ static int last_call_luid; /* When `subst' is called, this is the insn that is being modified (by combining in a previous insn). The PATTERN of this insn is still the old pattern partially modified and it should not be looked at, but this may be used to examine the successors of the insn to judge whether a simplification is valid. */ static rtx_insn *subst_insn; /* This is the lowest LUID that `subst' is currently dealing with. get_last_value will not return a value if the register was set at or after this LUID. If not for this mechanism, we could get confused if I2 or I1 in try_combine were an insn that used the old value of a register to obtain a new value. In that case, we might erroneously get the new value of the register when we wanted the old one. */ static int subst_low_luid; /* This contains any hard registers that are used in newpat; reg_dead_at_p must consider all these registers to be always live. */ static HARD_REG_SET newpat_used_regs; /* This is an insn to which a LOG_LINKS entry has been added. If this insn is the earlier than I2 or I3, combine should rescan starting at that location. */ static rtx_insn *added_links_insn; /* Basic block in which we are performing combines. */ static basic_block this_basic_block; static bool optimize_this_for_speed_p; /* Length of the currently allocated uid_insn_cost array. */ static int max_uid_known; /* The following array records the insn_rtx_cost for every insn in the instruction stream. */ static int *uid_insn_cost; /* The following array records the LOG_LINKS for every insn in the instruction stream as struct insn_link pointers. */ struct insn_link { rtx_insn *insn; unsigned int regno; struct insn_link *next; }; static struct insn_link **uid_log_links; #define INSN_COST(INSN) (uid_insn_cost[INSN_UID (INSN)]) #define LOG_LINKS(INSN) (uid_log_links[INSN_UID (INSN)]) #define FOR_EACH_LOG_LINK(L, INSN) \ for ((L) = LOG_LINKS (INSN); (L); (L) = (L)->next) /* Links for LOG_LINKS are allocated from this obstack. */ static struct obstack insn_link_obstack; /* Allocate a link. */ static inline struct insn_link * alloc_insn_link (rtx_insn *insn, unsigned int regno, struct insn_link *next) { struct insn_link *l = (struct insn_link *) obstack_alloc (&insn_link_obstack, sizeof (struct insn_link)); l->insn = insn; l->regno = regno; l->next = next; return l; } /* Incremented for each basic block. */ static int label_tick; /* Reset to label_tick for each extended basic block in scanning order. */ static int label_tick_ebb_start; /* Mode used to compute significance in reg_stat[].nonzero_bits. It is the largest integer mode that can fit in HOST_BITS_PER_WIDE_INT. */ static machine_mode nonzero_bits_mode; /* Nonzero when reg_stat[].nonzero_bits and reg_stat[].sign_bit_copies can be safely used. It is zero while computing them and after combine has completed. This former test prevents propagating values based on previously set values, which can be incorrect if a variable is modified in a loop. */ static int nonzero_sign_valid; /* Record one modification to rtl structure to be undone by storing old_contents into *where. */ enum undo_kind { UNDO_RTX, UNDO_INT, UNDO_MODE, UNDO_LINKS }; struct undo { struct undo *next; enum undo_kind kind; union { rtx r; int i; machine_mode m; struct insn_link *l; } old_contents; union { rtx *r; int *i; struct insn_link **l; } where; }; /* Record a bunch of changes to be undone, up to MAX_UNDO of them. num_undo says how many are currently recorded. other_insn is nonzero if we have modified some other insn in the process of working on subst_insn. It must be verified too. */ struct undobuf { struct undo *undos; struct undo *frees; rtx_insn *other_insn; }; static struct undobuf undobuf; /* Number of times the pseudo being substituted for was found and replaced. */ static int n_occurrences; static rtx reg_nonzero_bits_for_combine (const_rtx, machine_mode, const_rtx, machine_mode, unsigned HOST_WIDE_INT, unsigned HOST_WIDE_INT *); static rtx reg_num_sign_bit_copies_for_combine (const_rtx, machine_mode, const_rtx, machine_mode, unsigned int, unsigned int *); static void do_SUBST (rtx *, rtx); static void do_SUBST_INT (int *, int); static void init_reg_last (void); static void setup_incoming_promotions (rtx_insn *); static void set_nonzero_bits_and_sign_copies (rtx, const_rtx, void *); static int cant_combine_insn_p (rtx_insn *); static int can_combine_p (rtx_insn *, rtx_insn *, rtx_insn *, rtx_insn *, rtx_insn *, rtx_insn *, rtx *, rtx *); static int combinable_i3pat (rtx_insn *, rtx *, rtx, rtx, rtx, int, int, rtx *); static int contains_muldiv (rtx); static rtx_insn *try_combine (rtx_insn *, rtx_insn *, rtx_insn *, rtx_insn *, int *, rtx_insn *); static void undo_all (void); static void undo_commit (void); static rtx *find_split_point (rtx *, rtx_insn *, bool); static rtx subst (rtx, rtx, rtx, int, int, int); static rtx combine_simplify_rtx (rtx, machine_mode, int, int); static rtx simplify_if_then_else (rtx); static rtx simplify_set (rtx); static rtx simplify_logical (rtx); static rtx expand_compound_operation (rtx); static const_rtx expand_field_assignment (const_rtx); static rtx make_extraction (machine_mode, rtx, HOST_WIDE_INT, rtx, unsigned HOST_WIDE_INT, int, int, int); static rtx extract_left_shift (rtx, int); static int get_pos_from_mask (unsigned HOST_WIDE_INT, unsigned HOST_WIDE_INT *); static rtx canon_reg_for_combine (rtx, rtx); static rtx force_to_mode (rtx, machine_mode, unsigned HOST_WIDE_INT, int); static rtx if_then_else_cond (rtx, rtx *, rtx *); static rtx known_cond (rtx, enum rtx_code, rtx, rtx); static int rtx_equal_for_field_assignment_p (rtx, rtx, bool = false); static rtx make_field_assignment (rtx); static rtx apply_distributive_law (rtx); static rtx distribute_and_simplify_rtx (rtx, int); static rtx simplify_and_const_int_1 (machine_mode, rtx, unsigned HOST_WIDE_INT); static rtx simplify_and_const_int (rtx, machine_mode, rtx, unsigned HOST_WIDE_INT); static int merge_outer_ops (enum rtx_code *, HOST_WIDE_INT *, enum rtx_code, HOST_WIDE_INT, machine_mode, int *); static rtx simplify_shift_const_1 (enum rtx_code, machine_mode, rtx, int); static rtx simplify_shift_const (rtx, enum rtx_code, machine_mode, rtx, int); static int recog_for_combine (rtx *, rtx_insn *, rtx *); static rtx gen_lowpart_for_combine (machine_mode, rtx); static enum rtx_code simplify_compare_const (enum rtx_code, machine_mode, rtx, rtx *); static enum rtx_code simplify_comparison (enum rtx_code, rtx *, rtx *); static void update_table_tick (rtx); static void record_value_for_reg (rtx, rtx_insn *, rtx); static void check_promoted_subreg (rtx_insn *, rtx); static void record_dead_and_set_regs_1 (rtx, const_rtx, void *); static void record_dead_and_set_regs (rtx_insn *); static int get_last_value_validate (rtx *, rtx_insn *, int, int); static rtx get_last_value (const_rtx); static int use_crosses_set_p (const_rtx, int); static void reg_dead_at_p_1 (rtx, const_rtx, void *); static int reg_dead_at_p (rtx, rtx_insn *); static void move_deaths (rtx, rtx, int, rtx_insn *, rtx *); static int reg_bitfield_target_p (rtx, rtx); static void distribute_notes (rtx, rtx_insn *, rtx_insn *, rtx_insn *, rtx, rtx, rtx); static void distribute_links (struct insn_link *); static void mark_used_regs_combine (rtx); static void record_promoted_value (rtx_insn *, rtx); static bool unmentioned_reg_p (rtx, rtx); static void record_truncated_values (rtx *, void *); static bool reg_truncated_to_mode (machine_mode, const_rtx); static rtx gen_lowpart_or_truncate (machine_mode, rtx); /* It is not safe to use ordinary gen_lowpart in combine. See comments in gen_lowpart_for_combine. */ #undef RTL_HOOKS_GEN_LOWPART #define RTL_HOOKS_GEN_LOWPART gen_lowpart_for_combine /* Our implementation of gen_lowpart never emits a new pseudo. */ #undef RTL_HOOKS_GEN_LOWPART_NO_EMIT #define RTL_HOOKS_GEN_LOWPART_NO_EMIT gen_lowpart_for_combine #undef RTL_HOOKS_REG_NONZERO_REG_BITS #define RTL_HOOKS_REG_NONZERO_REG_BITS reg_nonzero_bits_for_combine #undef RTL_HOOKS_REG_NUM_SIGN_BIT_COPIES #define RTL_HOOKS_REG_NUM_SIGN_BIT_COPIES reg_num_sign_bit_copies_for_combine #undef RTL_HOOKS_REG_TRUNCATED_TO_MODE #define RTL_HOOKS_REG_TRUNCATED_TO_MODE reg_truncated_to_mode static const struct rtl_hooks combine_rtl_hooks = RTL_HOOKS_INITIALIZER; /* Convenience wrapper for the canonicalize_comparison target hook. Target hooks cannot use enum rtx_code. */ static inline void target_canonicalize_comparison (enum rtx_code *code, rtx *op0, rtx *op1, bool op0_preserve_value) { int code_int = (int)*code; targetm.canonicalize_comparison (&code_int, op0, op1, op0_preserve_value); *code = (enum rtx_code)code_int; } /* Try to split PATTERN found in INSN. This returns NULL_RTX if PATTERN can not be split. Otherwise, it returns an insn sequence. This is a wrapper around split_insns which ensures that the reg_stat vector is made larger if the splitter creates a new register. */ static rtx_insn * combine_split_insns (rtx pattern, rtx_insn *insn) { rtx_insn *ret; unsigned int nregs; ret = split_insns (pattern, insn); nregs = max_reg_num (); if (nregs > reg_stat.length ()) reg_stat.safe_grow_cleared (nregs); return ret; } /* This is used by find_single_use to locate an rtx in LOC that contains exactly one use of DEST, which is typically either a REG or CC0. It returns a pointer to the innermost rtx expression containing DEST. Appearances of DEST that are being used to totally replace it are not counted. */ static rtx * find_single_use_1 (rtx dest, rtx *loc) { rtx x = *loc; enum rtx_code code = GET_CODE (x); rtx *result = NULL; rtx *this_result; int i; const char *fmt; switch (code) { case CONST: case LABEL_REF: case SYMBOL_REF: CASE_CONST_ANY: case CLOBBER: return 0; case SET: /* If the destination is anything other than CC0, PC, a REG or a SUBREG of a REG that occupies all of the REG, the insn uses DEST if it is mentioned in the destination or the source. Otherwise, we need just check the source. */ if (GET_CODE (SET_DEST (x)) != CC0 && GET_CODE (SET_DEST (x)) != PC && !REG_P (SET_DEST (x)) && ! (GET_CODE (SET_DEST (x)) == SUBREG && REG_P (SUBREG_REG (SET_DEST (x))) && (((GET_MODE_SIZE (GET_MODE (SUBREG_REG (SET_DEST (x)))) + (UNITS_PER_WORD - 1)) / UNITS_PER_WORD) == ((GET_MODE_SIZE (GET_MODE (SET_DEST (x))) + (UNITS_PER_WORD - 1)) / UNITS_PER_WORD)))) break; return find_single_use_1 (dest, &SET_SRC (x)); case MEM: case SUBREG: return find_single_use_1 (dest, &XEXP (x, 0)); default: break; } /* If it wasn't one of the common cases above, check each expression and vector of this code. Look for a unique usage of DEST. */ fmt = GET_RTX_FORMAT (code); for (i = GET_RTX_LENGTH (code) - 1; i >= 0; i--) { if (fmt[i] == 'e') { if (dest == XEXP (x, i) || (REG_P (dest) && REG_P (XEXP (x, i)) && REGNO (dest) == REGNO (XEXP (x, i)))) this_result = loc; else this_result = find_single_use_1 (dest, &XEXP (x, i)); if (result == NULL) result = this_result; else if (this_result) /* Duplicate usage. */ return NULL; } else if (fmt[i] == 'E') { int j; for (j = XVECLEN (x, i) - 1; j >= 0; j--) { if (XVECEXP (x, i, j) == dest || (REG_P (dest) && REG_P (XVECEXP (x, i, j)) && REGNO (XVECEXP (x, i, j)) == REGNO (dest))) this_result = loc; else this_result = find_single_use_1 (dest, &XVECEXP (x, i, j)); if (result == NULL) result = this_result; else if (this_result) return NULL; } } } return result; } /* See if DEST, produced in INSN, is used only a single time in the sequel. If so, return a pointer to the innermost rtx expression in which it is used. If PLOC is nonzero, *PLOC is set to the insn containing the single use. If DEST is cc0_rtx, we look only at the next insn. In that case, we don't care about REG_DEAD notes or LOG_LINKS. Otherwise, we find the single use by finding an insn that has a LOG_LINKS pointing at INSN and has a REG_DEAD note for DEST. If DEST is only referenced once in that insn, we know that it must be the first and last insn referencing DEST. */ static rtx * find_single_use (rtx dest, rtx_insn *insn, rtx_insn **ploc) { basic_block bb; rtx_insn *next; rtx *result; struct insn_link *link; if (dest == cc0_rtx) { next = NEXT_INSN (insn); if (next == 0 || (!NONJUMP_INSN_P (next) && !JUMP_P (next))) return 0; result = find_single_use_1 (dest, &PATTERN (next)); if (result && ploc) *ploc = next; return result; } if (!REG_P (dest)) return 0; bb = BLOCK_FOR_INSN (insn); for (next = NEXT_INSN (insn); next && BLOCK_FOR_INSN (next) == bb; next = NEXT_INSN (next)) if (INSN_P (next) && dead_or_set_p (next, dest)) { FOR_EACH_LOG_LINK (link, next) if (link->insn == insn && link->regno == REGNO (dest)) break; if (link) { result = find_single_use_1 (dest, &PATTERN (next)); if (ploc) *ploc = next; return result; } } return 0; } /* Substitute NEWVAL, an rtx expression, into INTO, a place in some insn. The substitution can be undone by undo_all. If INTO is already set to NEWVAL, do not record this change. Because computing NEWVAL might also call SUBST, we have to compute it before we put anything into the undo table. */ static void do_SUBST (rtx *into, rtx newval) { struct undo *buf; rtx oldval = *into; if (oldval == newval) return; /* We'd like to catch as many invalid transformations here as possible. Unfortunately, there are way too many mode changes that are perfectly valid, so we'd waste too much effort for little gain doing the checks here. Focus on catching invalid transformations involving integer constants. */ if (GET_MODE_CLASS (GET_MODE (oldval)) == MODE_INT && CONST_INT_P (newval)) { /* Sanity check that we're replacing oldval with a CONST_INT that is a valid sign-extension for the original mode. */ gcc_assert (INTVAL (newval) == trunc_int_for_mode (INTVAL (newval), GET_MODE (oldval))); /* Replacing the operand of a SUBREG or a ZERO_EXTEND with a CONST_INT is not valid, because after the replacement, the original mode would be gone. Unfortunately, we can't tell when do_SUBST is called to replace the operand thereof, so we perform this test on oldval instead, checking whether an invalid replacement took place before we got here. */ gcc_assert (!(GET_CODE (oldval) == SUBREG && CONST_INT_P (SUBREG_REG (oldval)))); gcc_assert (!(GET_CODE (oldval) == ZERO_EXTEND && CONST_INT_P (XEXP (oldval, 0)))); } if (undobuf.frees) buf = undobuf.frees, undobuf.frees = buf->next; else buf = XNEW (struct undo); buf->kind = UNDO_RTX; buf->where.r = into; buf->old_contents.r = oldval; *into = newval; buf->next = undobuf.undos, undobuf.undos = buf; } #define SUBST(INTO, NEWVAL) do_SUBST (&(INTO), (NEWVAL)) /* Similar to SUBST, but NEWVAL is an int expression. Note that substitution for the value of a HOST_WIDE_INT value (including CONST_INT) is not safe. */ static void do_SUBST_INT (int *into, int newval) { struct undo *buf; int oldval = *into; if (oldval == newval) return; if (undobuf.frees) buf = undobuf.frees, undobuf.frees = buf->next; else buf = XNEW (struct undo); buf->kind = UNDO_INT; buf->where.i = into; buf->old_contents.i = oldval; *into = newval; buf->next = undobuf.undos, undobuf.undos = buf; } #define SUBST_INT(INTO, NEWVAL) do_SUBST_INT (&(INTO), (NEWVAL)) /* Similar to SUBST, but just substitute the mode. This is used when changing the mode of a pseudo-register, so that any other references to the entry in the regno_reg_rtx array will change as well. */ static void do_SUBST_MODE (rtx *into, machine_mode newval) { struct undo *buf; machine_mode oldval = GET_MODE (*into); if (oldval == newval) return; if (undobuf.frees) buf = undobuf.frees, undobuf.frees = buf->next; else buf = XNEW (struct undo); buf->kind = UNDO_MODE; buf->where.r = into; buf->old_contents.m = oldval; adjust_reg_mode (*into, newval); buf->next = undobuf.undos, undobuf.undos = buf; } #define SUBST_MODE(INTO, NEWVAL) do_SUBST_MODE (&(INTO), (NEWVAL)) /* Similar to SUBST, but NEWVAL is a LOG_LINKS expression. */ static void do_SUBST_LINK (struct insn_link **into, struct insn_link *newval) { struct undo *buf; struct insn_link * oldval = *into; if (oldval == newval) return; if (undobuf.frees) buf = undobuf.frees, undobuf.frees = buf->next; else buf = XNEW (struct undo); buf->kind = UNDO_LINKS; buf->where.l = into; buf->old_contents.l = oldval; *into = newval; buf->next = undobuf.undos, undobuf.undos = buf; } #define SUBST_LINK(oldval, newval) do_SUBST_LINK (&oldval, newval) /* Subroutine of try_combine. Determine whether the replacement patterns NEWPAT, NEWI2PAT and NEWOTHERPAT are cheaper according to insn_rtx_cost than the original sequence I0, I1, I2, I3 and undobuf.other_insn. Note that I0, I1 and/or NEWI2PAT may be NULL_RTX. Similarly, NEWOTHERPAT and undobuf.other_insn may also both be NULL_RTX. Return false if the cost of all the instructions can be estimated and the replacements are more expensive than the original sequence. */ static bool combine_validate_cost (rtx_insn *i0, rtx_insn *i1, rtx_insn *i2, rtx_insn *i3, rtx newpat, rtx newi2pat, rtx newotherpat) { int i0_cost, i1_cost, i2_cost, i3_cost; int new_i2_cost, new_i3_cost; int old_cost, new_cost; /* Lookup the original insn_rtx_costs. */ i2_cost = INSN_COST (i2); i3_cost = INSN_COST (i3); if (i1) { i1_cost = INSN_COST (i1); if (i0) { i0_cost = INSN_COST (i0); old_cost = (i0_cost > 0 && i1_cost > 0 && i2_cost > 0 && i3_cost > 0 ? i0_cost + i1_cost + i2_cost + i3_cost : 0); } else { old_cost = (i1_cost > 0 && i2_cost > 0 && i3_cost > 0 ? i1_cost + i2_cost + i3_cost : 0); i0_cost = 0; } } else { old_cost = (i2_cost > 0 && i3_cost > 0) ? i2_cost + i3_cost : 0; i1_cost = i0_cost = 0; } /* If we have split a PARALLEL I2 to I1,I2, we have counted its cost twice; correct that. */ if (old_cost && i1 && INSN_UID (i1) == INSN_UID (i2)) old_cost -= i1_cost; /* Calculate the replacement insn_rtx_costs. */ new_i3_cost = insn_rtx_cost (newpat, optimize_this_for_speed_p); if (newi2pat) { new_i2_cost = insn_rtx_cost (newi2pat, optimize_this_for_speed_p); new_cost = (new_i2_cost > 0 && new_i3_cost > 0) ? new_i2_cost + new_i3_cost : 0; } else { new_cost = new_i3_cost; new_i2_cost = 0; } if (undobuf.other_insn) { int old_other_cost, new_other_cost; old_other_cost = INSN_COST (undobuf.other_insn); new_other_cost = insn_rtx_cost (newotherpat, optimize_this_for_speed_p); if (old_other_cost > 0 && new_other_cost > 0) { old_cost += old_other_cost; new_cost += new_other_cost; } else old_cost = 0; } /* Disallow this combination if both new_cost and old_cost are greater than zero, and new_cost is greater than old cost. */ int reject = old_cost > 0 && new_cost > old_cost; if (dump_file) { fprintf (dump_file, "%s combination of insns ", reject ? "rejecting" : "allowing"); if (i0) fprintf (dump_file, "%d, ", INSN_UID (i0)); if (i1 && INSN_UID (i1) != INSN_UID (i2)) fprintf (dump_file, "%d, ", INSN_UID (i1)); fprintf (dump_file, "%d and %d\n", INSN_UID (i2), INSN_UID (i3)); fprintf (dump_file, "original costs "); if (i0) fprintf (dump_file, "%d + ", i0_cost); if (i1 && INSN_UID (i1) != INSN_UID (i2)) fprintf (dump_file, "%d + ", i1_cost); fprintf (dump_file, "%d + %d = %d\n", i2_cost, i3_cost, old_cost); if (newi2pat) fprintf (dump_file, "replacement costs %d + %d = %d\n", new_i2_cost, new_i3_cost, new_cost); else fprintf (dump_file, "replacement cost %d\n", new_cost); } if (reject) return false; /* Update the uid_insn_cost array with the replacement costs. */ INSN_COST (i2) = new_i2_cost; INSN_COST (i3) = new_i3_cost; if (i1) { INSN_COST (i1) = 0; if (i0) INSN_COST (i0) = 0; } return true; } /* Delete any insns that copy a register to itself. */ static void delete_noop_moves (void) { rtx_insn *insn, *next; basic_block bb; FOR_EACH_BB_FN (bb, cfun) { for (insn = BB_HEAD (bb); insn != NEXT_INSN (BB_END (bb)); insn = next) { next = NEXT_INSN (insn); if (INSN_P (insn) && noop_move_p (insn)) { if (dump_file) fprintf (dump_file, "deleting noop move %d\n", INSN_UID (insn)); delete_insn_and_edges (insn); } } } } /* Return false if we do not want to (or cannot) combine DEF. */ static bool can_combine_def_p (df_ref def) { /* Do not consider if it is pre/post modification in MEM. */ if (DF_REF_FLAGS (def) & DF_REF_PRE_POST_MODIFY) return false; unsigned int regno = DF_REF_REGNO (def); /* Do not combine frame pointer adjustments. */ if ((regno == FRAME_POINTER_REGNUM && (!reload_completed || frame_pointer_needed)) || (!HARD_FRAME_POINTER_IS_FRAME_POINTER && regno == HARD_FRAME_POINTER_REGNUM && (!reload_completed || frame_pointer_needed)) || (FRAME_POINTER_REGNUM != ARG_POINTER_REGNUM && regno == ARG_POINTER_REGNUM && fixed_regs[regno])) return false; return true; } /* Return false if we do not want to (or cannot) combine USE. */ static bool can_combine_use_p (df_ref use) { /* Do not consider the usage of the stack pointer by function call. */ if (DF_REF_FLAGS (use) & DF_REF_CALL_STACK_USAGE) return false; return true; } /* Fill in log links field for all insns. */ static void create_log_links (void) { basic_block bb; rtx_insn **next_use; rtx_insn *insn; df_ref def, use; next_use = XCNEWVEC (rtx_insn *, max_reg_num ()); /* Pass through each block from the end, recording the uses of each register and establishing log links when def is encountered. Note that we do not clear next_use array in order to save time, so we have to test whether the use is in the same basic block as def. There are a few cases below when we do not consider the definition or usage -- these are taken from original flow.c did. Don't ask me why it is done this way; I don't know and if it works, I don't want to know. */ FOR_EACH_BB_FN (bb, cfun) { FOR_BB_INSNS_REVERSE (bb, insn) { if (!NONDEBUG_INSN_P (insn)) continue; /* Log links are created only once. */ gcc_assert (!LOG_LINKS (insn)); FOR_EACH_INSN_DEF (def, insn) { unsigned int regno = DF_REF_REGNO (def); rtx_insn *use_insn; if (!next_use[regno]) continue; if (!can_combine_def_p (def)) continue; use_insn = next_use[regno]; next_use[regno] = NULL; if (BLOCK_FOR_INSN (use_insn) != bb) continue; /* flow.c claimed: We don't build a LOG_LINK for hard registers contained in ASM_OPERANDs. If these registers get replaced, we might wind up changing the semantics of the insn, even if reload can make what appear to be valid assignments later. */ if (regno < FIRST_PSEUDO_REGISTER && asm_noperands (PATTERN (use_insn)) >= 0) continue; /* Don't add duplicate links between instructions. */ struct insn_link *links; FOR_EACH_LOG_LINK (links, use_insn) if (insn == links->insn && regno == links->regno) break; if (!links) LOG_LINKS (use_insn) = alloc_insn_link (insn, regno, LOG_LINKS (use_insn)); } FOR_EACH_INSN_USE (use, insn) if (can_combine_use_p (use)) next_use[DF_REF_REGNO (use)] = insn; } } free (next_use); } /* Walk the LOG_LINKS of insn B to see if we find a reference to A. Return true if we found a LOG_LINK that proves that A feeds B. This only works if there are no instructions between A and B which could have a link depending on A, since in that case we would not record a link for B. We also check the implicit dependency created by a cc0 setter/user pair. */ static bool insn_a_feeds_b (rtx_insn *a, rtx_insn *b) { struct insn_link *links; FOR_EACH_LOG_LINK (links, b) if (links->insn == a) return true; if (HAVE_cc0 && sets_cc0_p (a)) return true; return false; } /* Main entry point for combiner. F is the first insn of the function. NREGS is the first unused pseudo-reg number. Return nonzero if the combiner has turned an indirect jump instruction into a direct jump. */ static int combine_instructions (rtx_insn *f, unsigned int nregs) { rtx_insn *insn, *next; rtx_insn *prev; struct insn_link *links, *nextlinks; rtx_insn *first; basic_block last_bb; int new_direct_jump_p = 0; for (first = f; first && !INSN_P (first); ) first = NEXT_INSN (first); if (!first) return 0; combine_attempts = 0; combine_merges = 0; combine_extras = 0; combine_successes = 0; rtl_hooks = combine_rtl_hooks; reg_stat.safe_grow_cleared (nregs); init_recog_no_volatile (); /* Allocate array for insn info. */ max_uid_known = get_max_uid (); uid_log_links = XCNEWVEC (struct insn_link *, max_uid_known + 1); uid_insn_cost = XCNEWVEC (int, max_uid_known + 1); gcc_obstack_init (&insn_link_obstack); nonzero_bits_mode = mode_for_size (HOST_BITS_PER_WIDE_INT, MODE_INT, 0); /* Don't use reg_stat[].nonzero_bits when computing it. This can cause problems when, for example, we have j <<= 1 in a loop. */ nonzero_sign_valid = 0; label_tick = label_tick_ebb_start = 1; /* Scan all SETs and see if we can deduce anything about what bits are known to be zero for some registers and how many copies of the sign bit are known to exist for those registers. Also set any known values so that we can use it while searching for what bits are known to be set. */ setup_incoming_promotions (first); /* Allow the entry block and the first block to fall into the same EBB. Conceptually the incoming promotions are assigned to the entry block. */ last_bb = ENTRY_BLOCK_PTR_FOR_FN (cfun); create_log_links (); FOR_EACH_BB_FN (this_basic_block, cfun) { optimize_this_for_speed_p = optimize_bb_for_speed_p (this_basic_block); last_call_luid = 0; mem_last_set = -1; label_tick++; if (!single_pred_p (this_basic_block) || single_pred (this_basic_block) != last_bb) label_tick_ebb_start = label_tick; last_bb = this_basic_block; FOR_BB_INSNS (this_basic_block, insn) if (INSN_P (insn) && BLOCK_FOR_INSN (insn)) { rtx links; subst_low_luid = DF_INSN_LUID (insn); subst_insn = insn; note_stores (PATTERN (insn), set_nonzero_bits_and_sign_copies, insn); record_dead_and_set_regs (insn); if (AUTO_INC_DEC) for (links = REG_NOTES (insn); links; links = XEXP (links, 1)) if (REG_NOTE_KIND (links) == REG_INC) set_nonzero_bits_and_sign_copies (XEXP (links, 0), NULL_RTX, insn); /* Record the current insn_rtx_cost of this instruction. */ if (NONJUMP_INSN_P (insn)) INSN_COST (insn) = insn_rtx_cost (PATTERN (insn), optimize_this_for_speed_p); if (dump_file) fprintf (dump_file, "insn_cost %d: %d\n", INSN_UID (insn), INSN_COST (insn)); } } nonzero_sign_valid = 1; /* Now scan all the insns in forward order. */ label_tick = label_tick_ebb_start = 1; init_reg_last (); setup_incoming_promotions (first); last_bb = ENTRY_BLOCK_PTR_FOR_FN (cfun); int max_combine = PARAM_VALUE (PARAM_MAX_COMBINE_INSNS); FOR_EACH_BB_FN (this_basic_block, cfun) { rtx_insn *last_combined_insn = NULL; optimize_this_for_speed_p = optimize_bb_for_speed_p (this_basic_block); last_call_luid = 0; mem_last_set = -1; label_tick++; if (!single_pred_p (this_basic_block) || single_pred (this_basic_block) != last_bb) label_tick_ebb_start = label_tick; last_bb = this_basic_block; rtl_profile_for_bb (this_basic_block); for (insn = BB_HEAD (this_basic_block); insn != NEXT_INSN (BB_END (this_basic_block)); insn = next ? next : NEXT_INSN (insn)) { next = 0; if (!NONDEBUG_INSN_P (insn)) continue; while (last_combined_insn && last_combined_insn->deleted ()) last_combined_insn = PREV_INSN (last_combined_insn); if (last_combined_insn == NULL_RTX || BARRIER_P (last_combined_insn) || BLOCK_FOR_INSN (last_combined_insn) != this_basic_block || DF_INSN_LUID (last_combined_insn) <= DF_INSN_LUID (insn)) last_combined_insn = insn; /* See if we know about function return values before this insn based upon SUBREG flags. */ check_promoted_subreg (insn, PATTERN (insn)); /* See if we can find hardregs and subreg of pseudos in narrower modes. This could help turning TRUNCATEs into SUBREGs. */ note_uses (&PATTERN (insn), record_truncated_values, NULL); /* Try this insn with each insn it links back to. */ FOR_EACH_LOG_LINK (links, insn) if ((next = try_combine (insn, links->insn, NULL, NULL, &new_direct_jump_p, last_combined_insn)) != 0) { statistics_counter_event (cfun, "two-insn combine", 1); goto retry; } /* Try each sequence of three linked insns ending with this one. */ if (max_combine >= 3) FOR_EACH_LOG_LINK (links, insn) { rtx_insn *link = links->insn; /* If the linked insn has been replaced by a note, then there is no point in pursuing this chain any further. */ if (NOTE_P (link)) continue; FOR_EACH_LOG_LINK (nextlinks, link) if ((next = try_combine (insn, link, nextlinks->insn, NULL, &new_direct_jump_p, last_combined_insn)) != 0) { statistics_counter_event (cfun, "three-insn combine", 1); goto retry; } } /* Try to combine a jump insn that uses CC0 with a preceding insn that sets CC0, and maybe with its logical predecessor as well. This is how we make decrement-and-branch insns. We need this special code because data flow connections via CC0 do not get entered in LOG_LINKS. */ if (HAVE_cc0 && JUMP_P (insn) && (prev = prev_nonnote_insn (insn)) != 0 && NONJUMP_INSN_P (prev) && sets_cc0_p (PATTERN (prev))) { if ((next = try_combine (insn, prev, NULL, NULL, &new_direct_jump_p, last_combined_insn)) != 0) goto retry; FOR_EACH_LOG_LINK (nextlinks, prev) if ((next = try_combine (insn, prev, nextlinks->insn, NULL, &new_direct_jump_p, last_combined_insn)) != 0) goto retry; } /* Do the same for an insn that explicitly references CC0. */ if (HAVE_cc0 && NONJUMP_INSN_P (insn) && (prev = prev_nonnote_insn (insn)) != 0 && NONJUMP_INSN_P (prev) && sets_cc0_p (PATTERN (prev)) && GET_CODE (PATTERN (insn)) == SET && reg_mentioned_p (cc0_rtx, SET_SRC (PATTERN (insn)))) { if ((next = try_combine (insn, prev, NULL, NULL, &new_direct_jump_p, last_combined_insn)) != 0) goto retry; FOR_EACH_LOG_LINK (nextlinks, prev) if ((next = try_combine (insn, prev, nextlinks->insn, NULL, &new_direct_jump_p, last_combined_insn)) != 0) goto retry; } /* Finally, see if any of the insns that this insn links to explicitly references CC0. If so, try this insn, that insn, and its predecessor if it sets CC0. */ if (HAVE_cc0) { FOR_EACH_LOG_LINK (links, insn) if (NONJUMP_INSN_P (links->insn) && GET_CODE (PATTERN (links->insn)) == SET && reg_mentioned_p (cc0_rtx, SET_SRC (PATTERN (links->insn))) && (prev = prev_nonnote_insn (links->insn)) != 0 && NONJUMP_INSN_P (prev) && sets_cc0_p (PATTERN (prev)) && (next = try_combine (insn, links->insn, prev, NULL, &new_direct_jump_p, last_combined_insn)) != 0) goto retry; } /* Try combining an insn with two different insns whose results it uses. */ if (max_combine >= 3) FOR_EACH_LOG_LINK (links, insn) for (nextlinks = links->next; nextlinks; nextlinks = nextlinks->next) if ((next = try_combine (insn, links->insn, nextlinks->insn, NULL, &new_direct_jump_p, last_combined_insn)) != 0) { statistics_counter_event (cfun, "three-insn combine", 1); goto retry; } /* Try four-instruction combinations. */ if (max_combine >= 4) FOR_EACH_LOG_LINK (links, insn) { struct insn_link *next1; rtx_insn *link = links->insn; /* If the linked insn has been replaced by a note, then there is no point in pursuing this chain any further. */ if (NOTE_P (link)) continue; FOR_EACH_LOG_LINK (next1, link) { rtx_insn *link1 = next1->insn; if (NOTE_P (link1)) continue; /* I0 -> I1 -> I2 -> I3. */ FOR_EACH_LOG_LINK (nextlinks, link1) if ((next = try_combine (insn, link, link1, nextlinks->insn, &new_direct_jump_p, last_combined_insn)) != 0) { statistics_counter_event (cfun, "four-insn combine", 1); goto retry; } /* I0, I1 -> I2, I2 -> I3. */ for (nextlinks = next1->next; nextlinks; nextlinks = nextlinks->next) if ((next = try_combine (insn, link, link1, nextlinks->insn, &new_direct_jump_p, last_combined_insn)) != 0) { statistics_counter_event (cfun, "four-insn combine", 1); goto retry; } } for (next1 = links->next; next1; next1 = next1->next) { rtx_insn *link1 = next1->insn; if (NOTE_P (link1)) continue; /* I0 -> I2; I1, I2 -> I3. */ FOR_EACH_LOG_LINK (nextlinks, link) if ((next = try_combine (insn, link, link1, nextlinks->insn, &new_direct_jump_p, last_combined_insn)) != 0) { statistics_counter_event (cfun, "four-insn combine", 1); goto retry; } /* I0 -> I1; I1, I2 -> I3. */ FOR_EACH_LOG_LINK (nextlinks, link1) if ((next = try_combine (insn, link, link1, nextlinks->insn, &new_direct_jump_p, last_combined_insn)) != 0) { statistics_counter_event (cfun, "four-insn combine", 1); goto retry; } } } /* Try this insn with each REG_EQUAL note it links back to. */ FOR_EACH_LOG_LINK (links, insn) { rtx set, note; rtx_insn *temp = links->insn; if ((set = single_set (temp)) != 0 && (note = find_reg_equal_equiv_note (temp)) != 0 && (note = XEXP (note, 0), GET_CODE (note)) != EXPR_LIST /* Avoid using a register that may already been marked dead by an earlier instruction. */ && ! unmentioned_reg_p (note, SET_SRC (set)) && (GET_MODE (note) == VOIDmode ? SCALAR_INT_MODE_P (GET_MODE (SET_DEST (set))) : GET_MODE (SET_DEST (set)) == GET_MODE (note))) { /* Temporarily replace the set's source with the contents of the REG_EQUAL note. The insn will be deleted or recognized by try_combine. */ rtx orig = SET_SRC (set); SET_SRC (set) = note; i2mod = temp; i2mod_old_rhs = copy_rtx (orig); i2mod_new_rhs = copy_rtx (note); next = try_combine (insn, i2mod, NULL, NULL, &new_direct_jump_p, last_combined_insn); i2mod = NULL; if (next) { statistics_counter_event (cfun, "insn-with-note combine", 1); goto retry; } SET_SRC (set) = orig; } } if (!NOTE_P (insn)) record_dead_and_set_regs (insn); retry: ; } } default_rtl_profile (); clear_bb_flags (); new_direct_jump_p |= purge_all_dead_edges (); delete_noop_moves (); /* Clean up. */ obstack_free (&insn_link_obstack, NULL); free (uid_log_links); free (uid_insn_cost); reg_stat.release (); { struct undo *undo, *next; for (undo = undobuf.frees; undo; undo = next) { next = undo->next; free (undo); } undobuf.frees = 0; } total_attempts += combine_attempts; total_merges += combine_merges; total_extras += combine_extras; total_successes += combine_successes; nonzero_sign_valid = 0; rtl_hooks = general_rtl_hooks; /* Make recognizer allow volatile MEMs again. */ init_recog (); return new_direct_jump_p; } /* Wipe the last_xxx fields of reg_stat in preparation for another pass. */ static void init_reg_last (void) { unsigned int i; reg_stat_type *p; FOR_EACH_VEC_ELT (reg_stat, i, p) memset (p, 0, offsetof (reg_stat_type, sign_bit_copies)); } /* Set up any promoted values for incoming argument registers. */ static void setup_incoming_promotions (rtx_insn *first) { tree arg; bool strictly_local = false; for (arg = DECL_ARGUMENTS (current_function_decl); arg; arg = DECL_CHAIN (arg)) { rtx x, reg = DECL_INCOMING_RTL (arg); int uns1, uns3; machine_mode mode1, mode2, mode3, mode4; /* Only continue if the incoming argument is in a register. */ if (!REG_P (reg)) continue; /* Determine, if possible, whether all call sites of the current function lie within the current compilation unit. (This does take into account the exporting of a function via taking its address, and so forth.) */ strictly_local = cgraph_node::local_info (current_function_decl)->local; /* The mode and signedness of the argument before any promotions happen (equal to the mode of the pseudo holding it at that stage). */ mode1 = TYPE_MODE (TREE_TYPE (arg)); uns1 = TYPE_UNSIGNED (TREE_TYPE (arg)); /* The mode and signedness of the argument after any source language and TARGET_PROMOTE_PROTOTYPES-driven promotions. */ mode2 = TYPE_MODE (DECL_ARG_TYPE (arg)); uns3 = TYPE_UNSIGNED (DECL_ARG_TYPE (arg)); /* The mode and signedness of the argument as it is actually passed, see assign_parm_setup_reg in function.c. */ mode3 = promote_function_mode (TREE_TYPE (arg), mode1, &uns3, TREE_TYPE (cfun->decl), 0); /* The mode of the register in which the argument is being passed. */ mode4 = GET_MODE (reg); /* Eliminate sign extensions in the callee when: (a) A mode promotion has occurred; */ if (mode1 == mode3) continue; /* (b) The mode of the register is the same as the mode of the argument as it is passed; */ if (mode3 != mode4) continue; /* (c) There's no language level extension; */ if (mode1 == mode2) ; /* (c.1) All callers are from the current compilation unit. If that's the case we don't have to rely on an ABI, we only have to know what we're generating right now, and we know that we will do the mode1 to mode2 promotion with the given sign. */ else if (!strictly_local) continue; /* (c.2) The combination of the two promotions is useful. This is true when the signs match, or if the first promotion is unsigned. In the later case, (sign_extend (zero_extend x)) is the same as (zero_extend (zero_extend x)), so make sure to force UNS3 true. */ else if (uns1) uns3 = true; else if (uns3) continue; /* Record that the value was promoted from mode1 to mode3, so that any sign extension at the head of the current function may be eliminated. */ x = gen_rtx_CLOBBER (mode1, const0_rtx); x = gen_rtx_fmt_e ((uns3 ? ZERO_EXTEND : SIGN_EXTEND), mode3, x); record_value_for_reg (reg, first, x); } } /* If MODE has a precision lower than PREC and SRC is a non-negative constant that would appear negative in MODE, sign-extend SRC for use in nonzero_bits because some machines (maybe most) will actually do the sign-extension and this is the conservative approach. ??? For 2.5, try to tighten up the MD files in this regard instead of this kludge. */ static rtx sign_extend_short_imm (rtx src, machine_mode mode, unsigned int prec) { if (GET_MODE_PRECISION (mode) < prec && CONST_INT_P (src) && INTVAL (src) > 0 && val_signbit_known_set_p (mode, INTVAL (src))) src = GEN_INT (INTVAL (src) | ~GET_MODE_MASK (mode)); return src; } /* Update RSP for pseudo-register X from INSN's REG_EQUAL note (if one exists) and SET. */ static void update_rsp_from_reg_equal (reg_stat_type *rsp, rtx_insn *insn, const_rtx set, rtx x) { rtx reg_equal_note = insn ? find_reg_equal_equiv_note (insn) : NULL_RTX; unsigned HOST_WIDE_INT bits = 0; rtx reg_equal = NULL, src = SET_SRC (set); unsigned int num = 0; if (reg_equal_note) reg_equal = XEXP (reg_equal_note, 0); if (SHORT_IMMEDIATES_SIGN_EXTEND) { src = sign_extend_short_imm (src, GET_MODE (x), BITS_PER_WORD); if (reg_equal) reg_equal = sign_extend_short_imm (reg_equal, GET_MODE (x), BITS_PER_WORD); } /* Don't call nonzero_bits if it cannot change anything. */ if (rsp->nonzero_bits != ~(unsigned HOST_WIDE_INT) 0) { bits = nonzero_bits (src, nonzero_bits_mode); if (reg_equal && bits) bits &= nonzero_bits (reg_equal, nonzero_bits_mode); rsp->nonzero_bits |= bits; } /* Don't call num_sign_bit_copies if it cannot change anything. */ if (rsp->sign_bit_copies != 1) { num = num_sign_bit_copies (SET_SRC (set), GET_MODE (x)); if (reg_equal && num != GET_MODE_PRECISION (GET_MODE (x))) { unsigned int numeq = num_sign_bit_copies (reg_equal, GET_MODE (x)); if (num == 0 || numeq > num) num = numeq; } if (rsp->sign_bit_copies == 0 || num < rsp->sign_bit_copies) rsp->sign_bit_copies = num; } } /* Called via note_stores. If X is a pseudo that is narrower than HOST_BITS_PER_WIDE_INT and is being set, record what bits are known zero. If we are setting only a portion of X and we can't figure out what portion, assume all bits will be used since we don't know what will be happening. Similarly, set how many bits of X are known to be copies of the sign bit at all locations in the function. This is the smallest number implied by any set of X. */ static void set_nonzero_bits_and_sign_copies (rtx x, const_rtx set, void *data) { rtx_insn *insn = (rtx_insn *) data; if (REG_P (x) && REGNO (x) >= FIRST_PSEUDO_REGISTER /* If this register is undefined at the start of the file, we can't say what its contents were. */ && ! REGNO_REG_SET_P (DF_LR_IN (ENTRY_BLOCK_PTR_FOR_FN (cfun)->next_bb), REGNO (x)) && HWI_COMPUTABLE_MODE_P (GET_MODE (x))) { reg_stat_type *rsp = ®_stat[REGNO (x)]; if (set == 0 || GET_CODE (set) == CLOBBER) { rsp->nonzero_bits = GET_MODE_MASK (GET_MODE (x)); rsp->sign_bit_copies = 1; return; } /* If this register is being initialized using itself, and the register is uninitialized in this basic block, and there are no LOG_LINKS which set the register, then part of the register is uninitialized. In that case we can't assume anything about the number of nonzero bits. ??? We could do better if we checked this in reg_{nonzero_bits,num_sign_bit_copies}_for_combine. Then we could avoid making assumptions about the insn which initially sets the register, while still using the information in other insns. We would have to be careful to check every insn involved in the combination. */ if (insn && reg_referenced_p (x, PATTERN (insn)) && !REGNO_REG_SET_P (DF_LR_IN (BLOCK_FOR_INSN (insn)), REGNO (x))) { struct insn_link *link; FOR_EACH_LOG_LINK (link, insn) if (dead_or_set_p (link->insn, x)) break; if (!link) { rsp->nonzero_bits = GET_MODE_MASK (GET_MODE (x)); rsp->sign_bit_copies = 1; return; } } /* If this is a complex assignment, see if we can convert it into a simple assignment. */ set = expand_field_assignment (set); /* If this is a simple assignment, or we have a paradoxical SUBREG, set what we know about X. */ if (SET_DEST (set) == x || (paradoxical_subreg_p (SET_DEST (set)) && SUBREG_REG (SET_DEST (set)) == x)) update_rsp_from_reg_equal (rsp, insn, set, x); else { rsp->nonzero_bits = GET_MODE_MASK (GET_MODE (x)); rsp->sign_bit_copies = 1; } } } /* See if INSN can be combined into I3. PRED, PRED2, SUCC and SUCC2 are optionally insns that were previously combined into I3 or that will be combined into the merger of INSN and I3. The order is PRED, PRED2, INSN, SUCC, SUCC2, I3. Return 0 if the combination is not allowed for any reason. If the combination is allowed, *PDEST will be set to the single destination of INSN and *PSRC to the single source, and this function will return 1. */ static int can_combine_p (rtx_insn *insn, rtx_insn *i3, rtx_insn *pred ATTRIBUTE_UNUSED, rtx_insn *pred2 ATTRIBUTE_UNUSED, rtx_insn *succ, rtx_insn *succ2, rtx *pdest, rtx *psrc) { int i; const_rtx set = 0; rtx src, dest; rtx_insn *p; rtx link; bool all_adjacent = true; int (*is_volatile_p) (const_rtx); if (succ) { if (succ2) { if (next_active_insn (succ2) != i3) all_adjacent = false; if (next_active_insn (succ) != succ2) all_adjacent = false; } else if (next_active_insn (succ) != i3) all_adjacent = false; if (next_active_insn (insn) != succ) all_adjacent = false; } else if (next_active_insn (insn) != i3) all_adjacent = false; /* Can combine only if previous insn is a SET of a REG, a SUBREG or CC0. or a PARALLEL consisting of such a SET and CLOBBERs. If INSN has CLOBBER parallel parts, ignore them for our processing. By definition, these happen during the execution of the insn. When it is merged with another insn, all bets are off. If they are, in fact, needed and aren't also supplied in I3, they may be added by recog_for_combine. Otherwise, it won't match. We can also ignore a SET whose SET_DEST is mentioned in a REG_UNUSED note. Get the source and destination of INSN. If more than one, can't combine. */ if (GET_CODE (PATTERN (insn)) == SET) set = PATTERN (insn); else if (GET_CODE (PATTERN (insn)) == PARALLEL && GET_CODE (XVECEXP (PATTERN (insn), 0, 0)) == SET) { for (i = 0; i < XVECLEN (PATTERN (insn), 0); i++) { rtx elt = XVECEXP (PATTERN (insn), 0, i); switch (GET_CODE (elt)) { /* This is important to combine floating point insns for the SH4 port. */ case USE: /* Combining an isolated USE doesn't make sense. We depend here on combinable_i3pat to reject them. */ /* The code below this loop only verifies that the inputs of the SET in INSN do not change. We call reg_set_between_p to verify that the REG in the USE does not change between I3 and INSN. If the USE in INSN was for a pseudo register, the matching insn pattern will likely match any register; combining this with any other USE would only be safe if we knew that the used registers have identical values, or if there was something to tell them apart, e.g. different modes. For now, we forgo such complicated tests and simply disallow combining of USES of pseudo registers with any other USE. */ if (REG_P (XEXP (elt, 0)) && GET_CODE (PATTERN (i3)) == PARALLEL) { rtx i3pat = PATTERN (i3); int i = XVECLEN (i3pat, 0) - 1; unsigned int regno = REGNO (XEXP (elt, 0)); do { rtx i3elt = XVECEXP (i3pat, 0, i); if (GET_CODE (i3elt) == USE && REG_P (XEXP (i3elt, 0)) && (REGNO (XEXP (i3elt, 0)) == regno ? reg_set_between_p (XEXP (elt, 0), PREV_INSN (insn), i3) : regno >= FIRST_PSEUDO_REGISTER)) return 0; } while (--i >= 0); } break; /* We can ignore CLOBBERs. */ case CLOBBER: break; case SET: /* Ignore SETs whose result isn't used but not those that have side-effects. */ if (find_reg_note (insn, REG_UNUSED, SET_DEST (elt)) && insn_nothrow_p (insn) && !side_effects_p (elt)) break; /* If we have already found a SET, this is a second one and so we cannot combine with this insn. */ if (set) return 0; set = elt; break; default: /* Anything else means we can't combine. */ return 0; } } if (set == 0 /* If SET_SRC is an ASM_OPERANDS we can't throw away these CLOBBERs, so don't do anything with it. */ || GET_CODE (SET_SRC (set)) == ASM_OPERANDS) return 0; } else return 0; if (set == 0) return 0; /* The simplification in expand_field_assignment may call back to get_last_value, so set safe guard here. */ subst_low_luid = DF_INSN_LUID (insn); set = expand_field_assignment (set); src = SET_SRC (set), dest = SET_DEST (set); /* Do not eliminate user-specified register if it is in an asm input because we may break the register asm usage defined in GCC manual if allow to do so. Be aware that this may cover more cases than we expect but this should be harmless. */ if (REG_P (dest) && REG_USERVAR_P (dest) && HARD_REGISTER_P (dest) && extract_asm_operands (PATTERN (i3))) return 0; /* Don't eliminate a store in the stack pointer. */ if (dest == stack_pointer_rtx /* Don't combine with an insn that sets a register to itself if it has a REG_EQUAL note. This may be part of a LIBCALL sequence. */ || (rtx_equal_p (src, dest) && find_reg_note (insn, REG_EQUAL, NULL_RTX)) /* Can't merge an ASM_OPERANDS. */ || GET_CODE (src) == ASM_OPERANDS /* Can't merge a function call. */ || GET_CODE (src) == CALL /* Don't eliminate a function call argument. */ || (CALL_P (i3) && (find_reg_fusage (i3, USE, dest) || (REG_P (dest) && REGNO (dest) < FIRST_PSEUDO_REGISTER && global_regs[REGNO (dest)]))) /* Don't substitute into an incremented register. */ || FIND_REG_INC_NOTE (i3, dest) || (succ && FIND_REG_INC_NOTE (succ, dest)) || (succ2 && FIND_REG_INC_NOTE (succ2, dest)) /* Don't substitute into a non-local goto, this confuses CFG. */ || (JUMP_P (i3) && find_reg_note (i3, REG_NON_LOCAL_GOTO, NULL_RTX)) /* Make sure that DEST is not used after SUCC but before I3. */ || (!all_adjacent && ((succ2 && (reg_used_between_p (dest, succ2, i3) || reg_used_between_p (dest, succ, succ2))) || (!succ2 && succ && reg_used_between_p (dest, succ, i3)))) /* Make sure that the value that is to be substituted for the register does not use any registers whose values alter in between. However, If the insns are adjacent, a use can't cross a set even though we think it might (this can happen for a sequence of insns each setting the same destination; last_set of that register might point to a NOTE). If INSN has a REG_EQUIV note, the register is always equivalent to the memory so the substitution is valid even if there are intervening stores. Also, don't move a volatile asm or UNSPEC_VOLATILE across any other insns. */ || (! all_adjacent && (((!MEM_P (src) || ! find_reg_note (insn, REG_EQUIV, src)) && use_crosses_set_p (src, DF_INSN_LUID (insn))) || (GET_CODE (src) == ASM_OPERANDS && MEM_VOLATILE_P (src)) || GET_CODE (src) == UNSPEC_VOLATILE)) /* Don't combine across a CALL_INSN, because that would possibly change whether the life span of some REGs crosses calls or not, and it is a pain to update that information. Exception: if source is a constant, moving it later can't hurt. Accept that as a special case. */ || (DF_INSN_LUID (insn) < last_call_luid && ! CONSTANT_P (src))) return 0; /* DEST must either be a REG or CC0. */ if (REG_P (dest)) { /* If register alignment is being enforced for multi-word items in all cases except for parameters, it is possible to have a register copy insn referencing a hard register that is not allowed to contain the mode being copied and which would not be valid as an operand of most insns. Eliminate this problem by not combining with such an insn. Also, on some machines we don't want to extend the life of a hard register. */ if (REG_P (src) && ((REGNO (dest) < FIRST_PSEUDO_REGISTER && ! HARD_REGNO_MODE_OK (REGNO (dest), GET_MODE (dest))) /* Don't extend the life of a hard register unless it is user variable (if we have few registers) or it can't fit into the desired register (meaning something special is going on). Also avoid substituting a return register into I3, because reload can't handle a conflict with constraints of other inputs. */ || (REGNO (src) < FIRST_PSEUDO_REGISTER && ! HARD_REGNO_MODE_OK (REGNO (src), GET_MODE (src))))) return 0; } else if (GET_CODE (dest) != CC0) return 0; if (GET_CODE (PATTERN (i3)) == PARALLEL) for (i = XVECLEN (PATTERN (i3), 0) - 1; i >= 0; i--) if (GET_CODE (XVECEXP (PATTERN (i3), 0, i)) == CLOBBER) { rtx reg = XEXP (XVECEXP (PATTERN (i3), 0, i), 0); /* If the clobber represents an earlyclobber operand, we must not substitute an expression containing the clobbered register. As we do not analyze the constraint strings here, we have to make the conservative assumption. However, if the register is a fixed hard reg, the clobber cannot represent any operand; we leave it up to the machine description to either accept or reject use-and-clobber patterns. */ if (!REG_P (reg) || REGNO (reg) >= FIRST_PSEUDO_REGISTER || !fixed_regs[REGNO (reg)]) if (reg_overlap_mentioned_p (reg, src)) return 0; } /* If INSN contains anything volatile, or is an `asm' (whether volatile or not), reject, unless nothing volatile comes between it and I3 */ if (GET_CODE (src) == ASM_OPERANDS || volatile_refs_p (src)) { /* Make sure neither succ nor succ2 contains a volatile reference. */ if (succ2 != 0 && volatile_refs_p (PATTERN (succ2))) return 0; if (succ != 0 && volatile_refs_p (PATTERN (succ))) return 0; /* We'll check insns between INSN and I3 below. */ } /* If INSN is an asm, and DEST is a hard register, reject, since it has to be an explicit register variable, and was chosen for a reason. */ if (GET_CODE (src) == ASM_OPERANDS && REG_P (dest) && REGNO (dest) < FIRST_PSEUDO_REGISTER) return 0; /* If INSN contains volatile references (specifically volatile MEMs), we cannot combine across any other volatile references. Even if INSN doesn't contain volatile references, any intervening volatile insn might affect machine state. */ is_volatile_p = volatile_refs_p (PATTERN (insn)) ? volatile_refs_p : volatile_insn_p; for (p = NEXT_INSN (insn); p != i3; p = NEXT_INSN (p)) if (INSN_P (p) && p != succ && p != succ2 && is_volatile_p (PATTERN (p))) return 0; /* If INSN contains an autoincrement or autodecrement, make sure that register is not used between there and I3, and not already used in I3 either. Neither must it be used in PRED or SUCC, if they exist. Also insist that I3 not be a jump; if it were one and the incremented register were spilled, we would lose. */ if (AUTO_INC_DEC) for (link = REG_NOTES (insn); link; link = XEXP (link, 1)) if (REG_NOTE_KIND (link) == REG_INC && (JUMP_P (i3) || reg_used_between_p (XEXP (link, 0), insn, i3) || (pred != NULL_RTX && reg_overlap_mentioned_p (XEXP (link, 0), PATTERN (pred))) || (pred2 != NULL_RTX && reg_overlap_mentioned_p (XEXP (link, 0), PATTERN (pred2))) || (succ != NULL_RTX && reg_overlap_mentioned_p (XEXP (link, 0), PATTERN (succ))) || (succ2 != NULL_RTX && reg_overlap_mentioned_p (XEXP (link, 0), PATTERN (succ2))) || reg_overlap_mentioned_p (XEXP (link, 0), PATTERN (i3)))) return 0; /* Don't combine an insn that follows a CC0-setting insn. An insn that uses CC0 must not be separated from the one that sets it. We do, however, allow I2 to follow a CC0-setting insn if that insn is passed as I1; in that case it will be deleted also. We also allow combining in this case if all the insns are adjacent because that would leave the two CC0 insns adjacent as well. It would be more logical to test whether CC0 occurs inside I1 or I2, but that would be much slower, and this ought to be equivalent. */ if (HAVE_cc0) { p = prev_nonnote_insn (insn); if (p && p != pred && NONJUMP_INSN_P (p) && sets_cc0_p (PATTERN (p)) && ! all_adjacent) return 0; } /* If we get here, we have passed all the tests and the combination is to be allowed. */ *pdest = dest; *psrc = src; return 1; } /* LOC is the location within I3 that contains its pattern or the component of a PARALLEL of the pattern. We validate that it is valid for combining. One problem is if I3 modifies its output, as opposed to replacing it entirely, we can't allow the output to contain I2DEST, I1DEST or I0DEST as doing so would produce an insn that is not equivalent to the original insns. Consider: (set (reg:DI 101) (reg:DI 100)) (set (subreg:SI (reg:DI 101) 0) ) This is NOT equivalent to: (parallel [(set (subreg:SI (reg:DI 100) 0) ) (set (reg:DI 101) (reg:DI 100))]) Not only does this modify 100 (in which case it might still be valid if 100 were dead in I2), it sets 101 to the ORIGINAL value of 100. We can also run into a problem if I2 sets a register that I1 uses and I1 gets directly substituted into I3 (not via I2). In that case, we would be getting the wrong value of I2DEST into I3, so we must reject the combination. This case occurs when I2 and I1 both feed into I3, rather than when I1 feeds into I2, which feeds into I3. If I1_NOT_IN_SRC is nonzero, it means that finding I1 in the source of a SET must prevent combination from occurring. The same situation can occur for I0, in which case I0_NOT_IN_SRC is set. Before doing the above check, we first try to expand a field assignment into a set of logical operations. If PI3_DEST_KILLED is nonzero, it is a pointer to a location in which we place a register that is both set and used within I3. If more than one such register is detected, we fail. Return 1 if the combination is valid, zero otherwise. */ static int combinable_i3pat (rtx_insn *i3, rtx *loc, rtx i2dest, rtx i1dest, rtx i0dest, int i1_not_in_src, int i0_not_in_src, rtx *pi3dest_killed) { rtx x = *loc; if (GET_CODE (x) == SET) { rtx set = x ; rtx dest = SET_DEST (set); rtx src = SET_SRC (set); rtx inner_dest = dest; rtx subdest; while (GET_CODE (inner_dest) == STRICT_LOW_PART || GET_CODE (inner_dest) == SUBREG || GET_CODE (inner_dest) == ZERO_EXTRACT) inner_dest = XEXP (inner_dest, 0); /* Check for the case where I3 modifies its output, as discussed above. We don't want to prevent pseudos from being combined into the address of a MEM, so only prevent the combination if i1 or i2 set the same MEM. */ if ((inner_dest != dest && (!MEM_P (inner_dest) || rtx_equal_p (i2dest, inner_dest) || (i1dest && rtx_equal_p (i1dest, inner_dest)) || (i0dest && rtx_equal_p (i0dest, inner_dest))) && (reg_overlap_mentioned_p (i2dest, inner_dest) || (i1dest && reg_overlap_mentioned_p (i1dest, inner_dest)) || (i0dest && reg_overlap_mentioned_p (i0dest, inner_dest)))) /* This is the same test done in can_combine_p except we can't test all_adjacent; we don't have to, since this instruction will stay in place, thus we are not considering increasing the lifetime of INNER_DEST. Also, if this insn sets a function argument, combining it with something that might need a spill could clobber a previous function argument; the all_adjacent test in can_combine_p also checks this; here, we do a more specific test for this case. */ || (REG_P (inner_dest) && REGNO (inner_dest) < FIRST_PSEUDO_REGISTER && (! HARD_REGNO_MODE_OK (REGNO (inner_dest), GET_MODE (inner_dest)))) || (i1_not_in_src && reg_overlap_mentioned_p (i1dest, src)) || (i0_not_in_src && reg_overlap_mentioned_p (i0dest, src))) return 0; /* If DEST is used in I3, it is being killed in this insn, so record that for later. We have to consider paradoxical subregs here, since they kill the whole register, but we ignore partial subregs, STRICT_LOW_PART, etc. Never add REG_DEAD notes for the FRAME_POINTER_REGNUM or the STACK_POINTER_REGNUM, since these are always considered to be live. Similarly for ARG_POINTER_REGNUM if it is fixed. */ subdest = dest; if (GET_CODE (subdest) == SUBREG && (GET_MODE_SIZE (GET_MODE (subdest)) >= GET_MODE_SIZE (GET_MODE (SUBREG_REG (subdest))))) subdest = SUBREG_REG (subdest); if (pi3dest_killed && REG_P (subdest) && reg_referenced_p (subdest, PATTERN (i3)) && REGNO (subdest) != FRAME_POINTER_REGNUM && (HARD_FRAME_POINTER_IS_FRAME_POINTER || REGNO (subdest) != HARD_FRAME_POINTER_REGNUM) && (FRAME_POINTER_REGNUM == ARG_POINTER_REGNUM || (REGNO (subdest) != ARG_POINTER_REGNUM || ! fixed_regs [REGNO (subdest)])) && REGNO (subdest) != STACK_POINTER_REGNUM) { if (*pi3dest_killed) return 0; *pi3dest_killed = subdest; } } else if (GET_CODE (x) == PARALLEL) { int i; for (i = 0; i < XVECLEN (x, 0); i++) if (! combinable_i3pat (i3, &XVECEXP (x, 0, i), i2dest, i1dest, i0dest, i1_not_in_src, i0_not_in_src, pi3dest_killed)) return 0; } return 1; } /* Return 1 if X is an arithmetic expression that contains a multiplication and division. We don't count multiplications by powers of two here. */ static int contains_muldiv (rtx x) { switch (GET_CODE (x)) { case MOD: case DIV: case UMOD: case UDIV: return 1; case MULT: return ! (CONST_INT_P (XEXP (x, 1)) && exact_log2 (UINTVAL (XEXP (x, 1))) >= 0); default: if (BINARY_P (x)) return contains_muldiv (XEXP (x, 0)) || contains_muldiv (XEXP (x, 1)); if (UNARY_P (x)) return contains_muldiv (XEXP (x, 0)); return 0; } } /* Determine whether INSN can be used in a combination. Return nonzero if not. This is used in try_combine to detect early some cases where we can't perform combinations. */ static int cant_combine_insn_p (rtx_insn *insn) { rtx set; rtx src, dest; /* If this isn't really an insn, we can't do anything. This can occur when flow deletes an insn that it has merged into an auto-increment address. */ if (! INSN_P (insn)) return 1; /* Never combine loads and stores involving hard regs that are likely to be spilled. The register allocator can usually handle such reg-reg moves by tying. If we allow the combiner to make substitutions of likely-spilled regs, reload might die. As an exception, we allow combinations involving fixed regs; these are not available to the register allocator so there's no risk involved. */ set = single_set (insn); if (! set) return 0; src = SET_SRC (set); dest = SET_DEST (set); if (GET_CODE (src) == SUBREG) src = SUBREG_REG (src); if (GET_CODE (dest) == SUBREG) dest = SUBREG_REG (dest); if (REG_P (src) && REG_P (dest) && ((HARD_REGISTER_P (src) && ! TEST_HARD_REG_BIT (fixed_reg_set, REGNO (src)) && targetm.class_likely_spilled_p (REGNO_REG_CLASS (REGNO (src)))) || (HARD_REGISTER_P (dest) && ! TEST_HARD_REG_BIT (fixed_reg_set, REGNO (dest)) && targetm.class_likely_spilled_p (REGNO_REG_CLASS (REGNO (dest)))))) return 1; return 0; } struct likely_spilled_retval_info { unsigned regno, nregs; unsigned mask; }; /* Called via note_stores by likely_spilled_retval_p. Remove from info->mask hard registers that are known to be written to / clobbered in full. */ static void likely_spilled_retval_1 (rtx x, const_rtx set, void *data) { struct likely_spilled_retval_info *const info = (struct likely_spilled_retval_info *) data; unsigned regno, nregs; unsigned new_mask; if (!REG_P (XEXP (set, 0))) return; regno = REGNO (x); if (regno >= info->regno + info->nregs) return; nregs = REG_NREGS (x); if (regno + nregs <= info->regno) return; new_mask = (2U << (nregs - 1)) - 1; if (regno < info->regno) new_mask >>= info->regno - regno; else new_mask <<= regno - info->regno; info->mask &= ~new_mask; } /* Return nonzero iff part of the return value is live during INSN, and it is likely spilled. This can happen when more than one insn is needed to copy the return value, e.g. when we consider to combine into the second copy insn for a complex value. */ static int likely_spilled_retval_p (rtx_insn *insn) { rtx_insn *use = BB_END (this_basic_block); rtx reg; rtx_insn *p; unsigned regno, nregs; /* We assume here that no machine mode needs more than 32 hard registers when the value overlaps with a register for which TARGET_FUNCTION_VALUE_REGNO_P is true. */ unsigned mask; struct likely_spilled_retval_info info; if (!NONJUMP_INSN_P (use) || GET_CODE (PATTERN (use)) != USE || insn == use) return 0; reg = XEXP (PATTERN (use), 0); if (!REG_P (reg) || !targetm.calls.function_value_regno_p (REGNO (reg))) return 0; regno = REGNO (reg); nregs = REG_NREGS (reg); if (nregs == 1) return 0; mask = (2U << (nregs - 1)) - 1; /* Disregard parts of the return value that are set later. */ info.regno = regno; info.nregs = nregs; info.mask = mask; for (p = PREV_INSN (use); info.mask && p != insn; p = PREV_INSN (p)) if (INSN_P (p)) note_stores (PATTERN (p), likely_spilled_retval_1, &info); mask = info.mask; /* Check if any of the (probably) live return value registers is likely spilled. */ nregs --; do { if ((mask & 1 << nregs) && targetm.class_likely_spilled_p (REGNO_REG_CLASS (regno + nregs))) return 1; } while (nregs--); return 0; } /* Adjust INSN after we made a change to its destination. Changing the destination can invalidate notes that say something about the results of the insn and a LOG_LINK pointing to the insn. */ static void adjust_for_new_dest (rtx_insn *insn) { /* For notes, be conservative and simply remove them. */ remove_reg_equal_equiv_notes (insn); /* The new insn will have a destination that was previously the destination of an insn just above it. Call distribute_links to make a LOG_LINK from the next use of that destination. */ rtx set = single_set (insn); gcc_assert (set); rtx reg = SET_DEST (set); while (GET_CODE (reg) == ZERO_EXTRACT || GET_CODE (reg) == STRICT_LOW_PART || GET_CODE (reg) == SUBREG) reg = XEXP (reg, 0); gcc_assert (REG_P (reg)); distribute_links (alloc_insn_link (insn, REGNO (reg), NULL)); df_insn_rescan (insn); } /* Return TRUE if combine can reuse reg X in mode MODE. ADDED_SETS is nonzero if the original set is still required. */ static bool can_change_dest_mode (rtx x, int added_sets, machine_mode mode) { unsigned int regno; if (!REG_P (x)) return false; regno = REGNO (x); /* Allow hard registers if the new mode is legal, and occupies no more registers than the old mode. */ if (regno < FIRST_PSEUDO_REGISTER) return (HARD_REGNO_MODE_OK (regno, mode) && REG_NREGS (x) >= hard_regno_nregs[regno][mode]); /* Or a pseudo that is only used once. */ return (regno < reg_n_sets_max && REG_N_SETS (regno) == 1 && !added_sets && !REG_USERVAR_P (x)); } /* Check whether X, the destination of a set, refers to part of the register specified by REG. */ static bool reg_subword_p (rtx x, rtx reg) { /* Check that reg is an integer mode register. */ if (!REG_P (reg) || GET_MODE_CLASS (GET_MODE (reg)) != MODE_INT) return false; if (GET_CODE (x) == STRICT_LOW_PART || GET_CODE (x) == ZERO_EXTRACT) x = XEXP (x, 0); return GET_CODE (x) == SUBREG && SUBREG_REG (x) == reg && GET_MODE_CLASS (GET_MODE (x)) == MODE_INT; } /* Delete the unconditional jump INSN and adjust the CFG correspondingly. Note that the INSN should be deleted *after* removing dead edges, so that the kept edge is the fallthrough edge for a (set (pc) (pc)) but not for a (set (pc) (label_ref FOO)). */ static void update_cfg_for_uncondjump (rtx_insn *insn) { basic_block bb = BLOCK_FOR_INSN (insn); gcc_assert (BB_END (bb) == insn); purge_dead_edges (bb); delete_insn (insn); if (EDGE_COUNT (bb->succs) == 1) { rtx_insn *insn; single_succ_edge (bb)->flags |= EDGE_FALLTHRU; /* Remove barriers from the footer if there are any. */ for (insn = BB_FOOTER (bb); insn; insn = NEXT_INSN (insn)) if (BARRIER_P (insn)) { if (PREV_INSN (insn)) SET_NEXT_INSN (PREV_INSN (insn)) = NEXT_INSN (insn); else BB_FOOTER (bb) = NEXT_INSN (insn); if (NEXT_INSN (insn)) SET_PREV_INSN (NEXT_INSN (insn)) = PREV_INSN (insn); } else if (LABEL_P (insn)) break; } } /* Return whether PAT is a PARALLEL of exactly N register SETs followed by an arbitrary number of CLOBBERs. */ static bool is_parallel_of_n_reg_sets (rtx pat, int n) { if (GET_CODE (pat) != PARALLEL) return false; int len = XVECLEN (pat, 0); if (len < n) return false; int i; for (i = 0; i < n; i++) if (GET_CODE (XVECEXP (pat, 0, i)) != SET || !REG_P (SET_DEST (XVECEXP (pat, 0, i)))) return false; for ( ; i < len; i++) if (GET_CODE (XVECEXP (pat, 0, i)) != CLOBBER || XEXP (XVECEXP (pat, 0, i), 0) == const0_rtx) return false; return true; } /* Return whether INSN, a PARALLEL of N register SETs (and maybe some CLOBBERs), can be split into individual SETs in that order, without changing semantics. */ static bool can_split_parallel_of_n_reg_sets (rtx_insn *insn, int n) { if (!insn_nothrow_p (insn)) return false; rtx pat = PATTERN (insn); int i, j; for (i = 0; i < n; i++) { if (side_effects_p (SET_SRC (XVECEXP (pat, 0, i)))) return false; rtx reg = SET_DEST (XVECEXP (pat, 0, i)); for (j = i + 1; j < n; j++) if (reg_referenced_p (reg, XVECEXP (pat, 0, j))) return false; } return true; } /* Try to combine the insns I0, I1 and I2 into I3. Here I0, I1 and I2 appear earlier than I3. I0 and I1 can be zero; then we combine just I2 into I3, or I1 and I2 into I3. If we are combining more than two insns and the resulting insn is not recognized, try splitting it into two insns. If that happens, I2 and I3 are retained and I1/I0 are pseudo-deleted by turning them into a NOTE. Otherwise, I0, I1 and I2 are pseudo-deleted. Return 0 if the combination does not work. Then nothing is changed. If we did the combination, return the insn at which combine should resume scanning. Set NEW_DIRECT_JUMP_P to a nonzero value if try_combine creates a new direct jump instruction. LAST_COMBINED_INSN is either I3, or some insn after I3 that has been I3 passed to an earlier try_combine within the same basic block. */ static rtx_insn * try_combine (rtx_insn *i3, rtx_insn *i2, rtx_insn *i1, rtx_insn *i0, int *new_direct_jump_p, rtx_insn *last_combined_insn) { /* New patterns for I3 and I2, respectively. */ rtx newpat, newi2pat = 0; rtvec newpat_vec_with_clobbers = 0; int substed_i2 = 0, substed_i1 = 0, substed_i0 = 0; /* Indicates need to preserve SET in I0, I1 or I2 in I3 if it is not dead. */ int added_sets_0, added_sets_1, added_sets_2; /* Total number of SETs to put into I3. */ int total_sets; /* Nonzero if I2's or I1's body now appears in I3. */ int i2_is_used = 0, i1_is_used = 0; /* INSN_CODEs for new I3, new I2, and user of condition code. */ int insn_code_number, i2_code_number = 0, other_code_number = 0; /* Contains I3 if the destination of I3 is used in its source, which means that the old life of I3 is being killed. If that usage is placed into I2 and not in I3, a REG_DEAD note must be made. */ rtx i3dest_killed = 0; /* SET_DEST and SET_SRC of I2, I1 and I0. */ rtx i2dest = 0, i2src = 0, i1dest = 0, i1src = 0, i0dest = 0, i0src = 0; /* Copy of SET_SRC of I1 and I0, if needed. */ rtx i1src_copy = 0, i0src_copy = 0, i0src_copy2 = 0; /* Set if I2DEST was reused as a scratch register. */ bool i2scratch = false; /* The PATTERNs of I0, I1, and I2, or a copy of them in certain cases. */ rtx i0pat = 0, i1pat = 0, i2pat = 0; /* Indicates if I2DEST or I1DEST is in I2SRC or I1_SRC. */ int i2dest_in_i2src = 0, i1dest_in_i1src = 0, i2dest_in_i1src = 0; int i0dest_in_i0src = 0, i1dest_in_i0src = 0, i2dest_in_i0src = 0; int i2dest_killed = 0, i1dest_killed = 0, i0dest_killed = 0; int i1_feeds_i2_n = 0, i0_feeds_i2_n = 0, i0_feeds_i1_n = 0; /* Notes that must be added to REG_NOTES in I3 and I2. */ rtx new_i3_notes, new_i2_notes; /* Notes that we substituted I3 into I2 instead of the normal case. */ int i3_subst_into_i2 = 0; /* Notes that I1, I2 or I3 is a MULT operation. */ int have_mult = 0; int swap_i2i3 = 0; int changed_i3_dest = 0; int maxreg; rtx_insn *temp_insn; rtx temp_expr; struct insn_link *link; rtx other_pat = 0; rtx new_other_notes; int i; /* Immediately return if any of I0,I1,I2 are the same insn (I3 can never be). */ if (i1 == i2 || i0 == i2 || (i0 && i0 == i1)) return 0; /* Only try four-insn combinations when there's high likelihood of success. Look for simple insns, such as loads of constants or binary operations involving a constant. */ if (i0) { int i; int ngood = 0; int nshift = 0; rtx set0, set3; if (!flag_expensive_optimizations) return 0; for (i = 0; i < 4; i++) { rtx_insn *insn = i == 0 ? i0 : i == 1 ? i1 : i == 2 ? i2 : i3; rtx set = single_set (insn); rtx src; if (!set) continue; src = SET_SRC (set); if (CONSTANT_P (src)) { ngood += 2; break; } else if (BINARY_P (src) && CONSTANT_P (XEXP (src, 1))) ngood++; else if (GET_CODE (src) == ASHIFT || GET_CODE (src) == ASHIFTRT || GET_CODE (src) == LSHIFTRT) nshift++; } /* If I0 loads a memory and I3 sets the same memory, then I1 and I2 are likely manipulating its value. Ideally we'll be able to combine all four insns into a bitfield insertion of some kind. Note the source in I0 might be inside a sign/zero extension and the memory modes in I0 and I3 might be different. So extract the address from the destination of I3 and search for it in the source of I0. In the event that there's a match but the source/dest do not actually refer to the same memory, the worst that happens is we try some combinations that we wouldn't have otherwise. */ if ((set0 = single_set (i0)) /* Ensure the source of SET0 is a MEM, possibly buried inside an extension. */ && (GET_CODE (SET_SRC (set0)) == MEM || ((GET_CODE (SET_SRC (set0)) == ZERO_EXTEND || GET_CODE (SET_SRC (set0)) == SIGN_EXTEND) && GET_CODE (XEXP (SET_SRC (set0), 0)) == MEM)) && (set3 = single_set (i3)) /* Ensure the destination of SET3 is a MEM. */ && GET_CODE (SET_DEST (set3)) == MEM /* Would it be better to extract the base address for the MEM in SET3 and look for that? I don't have cases where it matters but I could envision such cases. */ && rtx_referenced_p (XEXP (SET_DEST (set3), 0), SET_SRC (set0))) ngood += 2; if (ngood < 2 && nshift < 2) return 0; } /* Exit early if one of the insns involved can't be used for combinations. */ if (CALL_P (i2) || (i1 && CALL_P (i1)) || (i0 && CALL_P (i0)) || cant_combine_insn_p (i3) || cant_combine_insn_p (i2) || (i1 && cant_combine_insn_p (i1)) || (i0 && cant_combine_insn_p (i0)) || likely_spilled_retval_p (i3)) return 0; combine_attempts++; undobuf.other_insn = 0; /* Reset the hard register usage information. */ CLEAR_HARD_REG_SET (newpat_used_regs); if (dump_file && (dump_flags & TDF_DETAILS)) { if (i0) fprintf (dump_file, "\nTrying %d, %d, %d -> %d:\n", INSN_UID (i0), INSN_UID (i1), INSN_UID (i2), INSN_UID (i3)); else if (i1) fprintf (dump_file, "\nTrying %d, %d -> %d:\n", INSN_UID (i1), INSN_UID (i2), INSN_UID (i3)); else fprintf (dump_file, "\nTrying %d -> %d:\n", INSN_UID (i2), INSN_UID (i3)); } /* If multiple insns feed into one of I2 or I3, they can be in any order. To simplify the code below, reorder them in sequence. */ if (i0 && DF_INSN_LUID (i0) > DF_INSN_LUID (i2)) std::swap (i0, i2); if (i0 && DF_INSN_LUID (i0) > DF_INSN_LUID (i1)) std::swap (i0, i1); if (i1 && DF_INSN_LUID (i1) > DF_INSN_LUID (i2)) std::swap (i1, i2); added_links_insn = 0; /* First check for one important special case that the code below will not handle. Namely, the case where I1 is zero, I2 is a PARALLEL and I3 is a SET whose SET_SRC is a SET_DEST in I2. In that case, we may be able to replace that destination with the destination of I3. This occurs in the common code where we compute both a quotient and remainder into a structure, in which case we want to do the computation directly into the structure to avoid register-register copies. Note that this case handles both multiple sets in I2 and also cases where I2 has a number of CLOBBERs inside the PARALLEL. We make very conservative checks below and only try to handle the most common cases of this. For example, we only handle the case where I2 and I3 are adjacent to avoid making difficult register usage tests. */ if (i1 == 0 && NONJUMP_INSN_P (i3) && GET_CODE (PATTERN (i3)) == SET && REG_P (SET_SRC (PATTERN (i3))) && REGNO (SET_SRC (PATTERN (i3))) >= FIRST_PSEUDO_REGISTER && find_reg_note (i3, REG_DEAD, SET_SRC (PATTERN (i3))) && GET_CODE (PATTERN (i2)) == PARALLEL && ! side_effects_p (SET_DEST (PATTERN (i3))) /* If the dest of I3 is a ZERO_EXTRACT or STRICT_LOW_PART, the code below would need to check what is inside (and reg_overlap_mentioned_p doesn't support those codes anyway). Don't allow those destinations; the resulting insn isn't likely to be recognized anyway. */ && GET_CODE (SET_DEST (PATTERN (i3))) != ZERO_EXTRACT && GET_CODE (SET_DEST (PATTERN (i3))) != STRICT_LOW_PART && ! reg_overlap_mentioned_p (SET_SRC (PATTERN (i3)), SET_DEST (PATTERN (i3))) && next_active_insn (i2) == i3) { rtx p2 = PATTERN (i2); /* Make sure that the destination of I3, which we are going to substitute into one output of I2, is not used within another output of I2. We must avoid making this: (parallel [(set (mem (reg 69)) ...) (set (reg 69) ...)]) which is not well-defined as to order of actions. (Besides, reload can't handle output reloads for this.) The problem can also happen if the dest of I3 is a memory ref, if another dest in I2 is an indirect memory ref. */ for (i = 0; i < XVECLEN (p2, 0); i++) if ((GET_CODE (XVECEXP (p2, 0, i)) == SET || GET_CODE (XVECEXP (p2, 0, i)) == CLOBBER) && reg_overlap_mentioned_p (SET_DEST (PATTERN (i3)), SET_DEST (XVECEXP (p2, 0, i)))) break; /* Make sure this PARALLEL is not an asm. We do not allow combining that usually (see can_combine_p), so do not here either. */ for (i = 0; i < XVECLEN (p2, 0); i++) if (GET_CODE (XVECEXP (p2, 0, i)) == SET && GET_CODE (SET_SRC (XVECEXP (p2, 0, i))) == ASM_OPERANDS) break; if (i == XVECLEN (p2, 0)) for (i = 0; i < XVECLEN (p2, 0); i++) if (GET_CODE (XVECEXP (p2, 0, i)) == SET && SET_DEST (XVECEXP (p2, 0, i)) == SET_SRC (PATTERN (i3))) { combine_merges++; subst_insn = i3; subst_low_luid = DF_INSN_LUID (i2); added_sets_2 = added_sets_1 = added_sets_0 = 0; i2src = SET_SRC (XVECEXP (p2, 0, i)); i2dest = SET_DEST (XVECEXP (p2, 0, i)); i2dest_killed = dead_or_set_p (i2, i2dest); /* Replace the dest in I2 with our dest and make the resulting insn the new pattern for I3. Then skip to where we validate the pattern. Everything was set up above. */ SUBST (SET_DEST (XVECEXP (p2, 0, i)), SET_DEST (PATTERN (i3))); newpat = p2; i3_subst_into_i2 = 1; goto validate_replacement; } } /* If I2 is setting a pseudo to a constant and I3 is setting some sub-part of it to another constant, merge them by making a new constant. */ if (i1 == 0 && (temp_expr = single_set (i2)) != 0 && CONST_SCALAR_INT_P (SET_SRC (temp_expr)) && GET_CODE (PATTERN (i3)) == SET && CONST_SCALAR_INT_P (SET_SRC (PATTERN (i3))) && reg_subword_p (SET_DEST (PATTERN (i3)), SET_DEST (temp_expr))) { rtx dest = SET_DEST (PATTERN (i3)); int offset = -1; int width = 0; if (GET_CODE (dest) == ZERO_EXTRACT) { if (CONST_INT_P (XEXP (dest, 1)) && CONST_INT_P (XEXP (dest, 2))) { width = INTVAL (XEXP (dest, 1)); offset = INTVAL (XEXP (dest, 2)); dest = XEXP (dest, 0); if (BITS_BIG_ENDIAN) offset = GET_MODE_PRECISION (GET_MODE (dest)) - width - offset; } } else { if (GET_CODE (dest) == STRICT_LOW_PART) dest = XEXP (dest, 0); width = GET_MODE_PRECISION (GET_MODE (dest)); offset = 0; } if (offset >= 0) { /* If this is the low part, we're done. */ if (subreg_lowpart_p (dest)) ; /* Handle the case where inner is twice the size of outer. */ else if (GET_MODE_PRECISION (GET_MODE (SET_DEST (temp_expr))) == 2 * GET_MODE_PRECISION (GET_MODE (dest))) offset += GET_MODE_PRECISION (GET_MODE (dest)); /* Otherwise give up for now. */ else offset = -1; } if (offset >= 0) { rtx inner = SET_SRC (PATTERN (i3)); rtx outer = SET_SRC (temp_expr); wide_int o = wi::insert (std::make_pair (outer, GET_MODE (SET_DEST (temp_expr))), std::make_pair (inner, GET_MODE (dest)), offset, width); combine_merges++; subst_insn = i3; subst_low_luid = DF_INSN_LUID (i2); added_sets_2 = added_sets_1 = added_sets_0 = 0; i2dest = SET_DEST (temp_expr); i2dest_killed = dead_or_set_p (i2, i2dest); /* Replace the source in I2 with the new constant and make the resulting insn the new pattern for I3. Then skip to where we validate the pattern. Everything was set up above. */ SUBST (SET_SRC (temp_expr), immed_wide_int_const (o, GET_MODE (SET_DEST (temp_expr)))); newpat = PATTERN (i2); /* The dest of I3 has been replaced with the dest of I2. */ changed_i3_dest = 1; goto validate_replacement; } } /* If we have no I1 and I2 looks like: (parallel [(set (reg:CC X) (compare:CC OP (const_int 0))) (set Y OP)]) make up a dummy I1 that is (set Y OP) and change I2 to be (set (reg:CC X) (compare:CC Y (const_int 0))) (We can ignore any trailing CLOBBERs.) This undoes a previous combination and allows us to match a branch-and- decrement insn. */ if (!HAVE_cc0 && i1 == 0 && is_parallel_of_n_reg_sets (PATTERN (i2), 2) && (GET_MODE_CLASS (GET_MODE (SET_DEST (XVECEXP (PATTERN (i2), 0, 0)))) == MODE_CC) && GET_CODE (SET_SRC (XVECEXP (PATTERN (i2), 0, 0))) == COMPARE && XEXP (SET_SRC (XVECEXP (PATTERN (i2), 0, 0)), 1) == const0_rtx && rtx_equal_p (XEXP (SET_SRC (XVECEXP (PATTERN (i2), 0, 0)), 0), SET_SRC (XVECEXP (PATTERN (i2), 0, 1))) && !reg_used_between_p (SET_DEST (XVECEXP (PATTERN (i2), 0, 0)), i2, i3) && !reg_used_between_p (SET_DEST (XVECEXP (PATTERN (i2), 0, 1)), i2, i3)) { /* We make I1 with the same INSN_UID as I2. This gives it the same DF_INSN_LUID for value tracking. Our fake I1 will never appear in the insn stream so giving it the same INSN_UID as I2 will not cause a problem. */ i1 = gen_rtx_INSN (VOIDmode, NULL, i2, BLOCK_FOR_INSN (i2), XVECEXP (PATTERN (i2), 0, 1), INSN_LOCATION (i2), -1, NULL_RTX); INSN_UID (i1) = INSN_UID (i2); SUBST (PATTERN (i2), XVECEXP (PATTERN (i2), 0, 0)); SUBST (XEXP (SET_SRC (PATTERN (i2)), 0), SET_DEST (PATTERN (i1))); unsigned int regno = REGNO (SET_DEST (PATTERN (i1))); SUBST_LINK (LOG_LINKS (i2), alloc_insn_link (i1, regno, LOG_LINKS (i2))); } /* If I2 is a PARALLEL of two SETs of REGs (and perhaps some CLOBBERs), make those two SETs separate I1 and I2 insns, and make an I0 that is the original I1. */ if (!HAVE_cc0 && i0 == 0 && is_parallel_of_n_reg_sets (PATTERN (i2), 2) && can_split_parallel_of_n_reg_sets (i2, 2) && !reg_used_between_p (SET_DEST (XVECEXP (PATTERN (i2), 0, 0)), i2, i3) && !reg_used_between_p (SET_DEST (XVECEXP (PATTERN (i2), 0, 1)), i2, i3)) { /* If there is no I1, there is no I0 either. */ i0 = i1; /* We make I1 with the same INSN_UID as I2. This gives it the same DF_INSN_LUID for value tracking. Our fake I1 will never appear in the insn stream so giving it the same INSN_UID as I2 will not cause a problem. */ i1 = gen_rtx_INSN (VOIDmode, NULL, i2, BLOCK_FOR_INSN (i2), XVECEXP (PATTERN (i2), 0, 0), INSN_LOCATION (i2), -1, NULL_RTX); INSN_UID (i1) = INSN_UID (i2); SUBST (PATTERN (i2), XVECEXP (PATTERN (i2), 0, 1)); } /* Verify that I2 and I1 are valid for combining. */ if (! can_combine_p (i2, i3, i0, i1, NULL, NULL, &i2dest, &i2src) || (i1 && ! can_combine_p (i1, i3, i0, NULL, i2, NULL, &i1dest, &i1src)) || (i0 && ! can_combine_p (i0, i3, NULL, NULL, i1, i2, &i0dest, &i0src))) { undo_all (); return 0; } /* Record whether I2DEST is used in I2SRC and similarly for the other cases. Knowing this will help in register status updating below. */ i2dest_in_i2src = reg_overlap_mentioned_p (i2dest, i2src); i1dest_in_i1src = i1 && reg_overlap_mentioned_p (i1dest, i1src); i2dest_in_i1src = i1 && reg_overlap_mentioned_p (i2dest, i1src); i0dest_in_i0src = i0 && reg_overlap_mentioned_p (i0dest, i0src); i1dest_in_i0src = i0 && reg_overlap_mentioned_p (i1dest, i0src); i2dest_in_i0src = i0 && reg_overlap_mentioned_p (i2dest, i0src); i2dest_killed = dead_or_set_p (i2, i2dest); i1dest_killed = i1 && dead_or_set_p (i1, i1dest); i0dest_killed = i0 && dead_or_set_p (i0, i0dest); /* For the earlier insns, determine which of the subsequent ones they feed. */ i1_feeds_i2_n = i1 && insn_a_feeds_b (i1, i2); i0_feeds_i1_n = i0 && insn_a_feeds_b (i0, i1); i0_feeds_i2_n = (i0 && (!i0_feeds_i1_n ? insn_a_feeds_b (i0, i2) : (!reg_overlap_mentioned_p (i1dest, i0dest) && reg_overlap_mentioned_p (i0dest, i2src)))); /* Ensure that I3's pattern can be the destination of combines. */ if (! combinable_i3pat (i3, &PATTERN (i3), i2dest, i1dest, i0dest, i1 && i2dest_in_i1src && !i1_feeds_i2_n, i0 && ((i2dest_in_i0src && !i0_feeds_i2_n) || (i1dest_in_i0src && !i0_feeds_i1_n)), &i3dest_killed)) { undo_all (); return 0; } /* See if any of the insns is a MULT operation. Unless one is, we will reject a combination that is, since it must be slower. Be conservative here. */ if (GET_CODE (i2src) == MULT || (i1 != 0 && GET_CODE (i1src) == MULT) || (i0 != 0 && GET_CODE (i0src) == MULT) || (GET_CODE (PATTERN (i3)) == SET && GET_CODE (SET_SRC (PATTERN (i3))) == MULT)) have_mult = 1; /* If I3 has an inc, then give up if I1 or I2 uses the reg that is inc'd. We used to do this EXCEPT in one case: I3 has a post-inc in an output operand. However, that exception can give rise to insns like mov r3,(r3)+ which is a famous insn on the PDP-11 where the value of r3 used as the source was model-dependent. Avoid this sort of thing. */ #if 0 if (!(GET_CODE (PATTERN (i3)) == SET && REG_P (SET_SRC (PATTERN (i3))) && MEM_P (SET_DEST (PATTERN (i3))) && (GET_CODE (XEXP (SET_DEST (PATTERN (i3)), 0)) == POST_INC || GET_CODE (XEXP (SET_DEST (PATTERN (i3)), 0)) == POST_DEC))) /* It's not the exception. */ #endif if (AUTO_INC_DEC) { rtx link; for (link = REG_NOTES (i3); link; link = XEXP (link, 1)) if (REG_NOTE_KIND (link) == REG_INC && (reg_overlap_mentioned_p (XEXP (link, 0), PATTERN (i2)) || (i1 != 0 && reg_overlap_mentioned_p (XEXP (link, 0), PATTERN (i1))))) { undo_all (); return 0; } } /* See if the SETs in I1 or I2 need to be kept around in the merged instruction: whenever the value set there is still needed past I3. For the SET in I2, this is easy: we see if I2DEST dies or is set in I3. For the SET in I1, we have two cases: if I1 and I2 independently feed into I3, the set in I1 needs to be kept around unless I1DEST dies or is set in I3. Otherwise (if I1 feeds I2 which feeds I3), the set in I1 needs to be kept around unless I1DEST dies or is set in either I2 or I3. The same considerations apply to I0. */ added_sets_2 = !dead_or_set_p (i3, i2dest); if (i1) added_sets_1 = !(dead_or_set_p (i3, i1dest) || (i1_feeds_i2_n && dead_or_set_p (i2, i1dest))); else added_sets_1 = 0; if (i0) added_sets_0 = !(dead_or_set_p (i3, i0dest) || (i0_feeds_i1_n && dead_or_set_p (i1, i0dest)) || ((i0_feeds_i2_n || (i0_feeds_i1_n && i1_feeds_i2_n)) && dead_or_set_p (i2, i0dest))); else added_sets_0 = 0; /* We are about to copy insns for the case where they need to be kept around. Check that they can be copied in the merged instruction. */ if (targetm.cannot_copy_insn_p && ((added_sets_2 && targetm.cannot_copy_insn_p (i2)) || (i1 && added_sets_1 && targetm.cannot_copy_insn_p (i1)) || (i0 && added_sets_0 && targetm.cannot_copy_insn_p (i0)))) { undo_all (); return 0; } /* If the set in I2 needs to be kept around, we must make a copy of PATTERN (I2), so that when we substitute I1SRC for I1DEST in PATTERN (I2), we are only substituting for the original I1DEST, not into an already-substituted copy. This also prevents making self-referential rtx. If I2 is a PARALLEL, we just need the piece that assigns I2SRC to I2DEST. */ if (added_sets_2) { if (GET_CODE (PATTERN (i2)) == PARALLEL) i2pat = gen_rtx_SET (i2dest, copy_rtx (i2src)); else i2pat = copy_rtx (PATTERN (i2)); } if (added_sets_1) { if (GET_CODE (PATTERN (i1)) == PARALLEL) i1pat = gen_rtx_SET (i1dest, copy_rtx (i1src)); else i1pat = copy_rtx (PATTERN (i1)); } if (added_sets_0) { if (GET_CODE (PATTERN (i0)) == PARALLEL) i0pat = gen_rtx_SET (i0dest, copy_rtx (i0src)); else i0pat = copy_rtx (PATTERN (i0)); } combine_merges++; /* Substitute in the latest insn for the regs set by the earlier ones. */ maxreg = max_reg_num (); subst_insn = i3; /* Many machines that don't use CC0 have insns that can both perform an arithmetic operation and set the condition code. These operations will be represented as a PARALLEL with the first element of the vector being a COMPARE of an arithmetic operation with the constant zero. The second element of the vector will set some pseudo to the result of the same arithmetic operation. If we simplify the COMPARE, we won't match such a pattern and so will generate an extra insn. Here we test for this case, where both the comparison and the operation result are needed, and make the PARALLEL by just replacing I2DEST in I3SRC with I2SRC. Later we will make the PARALLEL that contains I2. */ if (!HAVE_cc0 && i1 == 0 && added_sets_2 && GET_CODE (PATTERN (i3)) == SET && GET_CODE (SET_SRC (PATTERN (i3))) == COMPARE && CONST_INT_P (XEXP (SET_SRC (PATTERN (i3)), 1)) && rtx_equal_p (XEXP (SET_SRC (PATTERN (i3)), 0), i2dest)) { rtx newpat_dest; rtx *cc_use_loc = NULL; rtx_insn *cc_use_insn = NULL; rtx op0 = i2src, op1 = XEXP (SET_SRC (PATTERN (i3)), 1); machine_mode compare_mode, orig_compare_mode; enum rtx_code compare_code = UNKNOWN, orig_compare_code = UNKNOWN; newpat = PATTERN (i3); newpat_dest = SET_DEST (newpat); compare_mode = orig_compare_mode = GET_MODE (newpat_dest); if (undobuf.other_insn == 0 && (cc_use_loc = find_single_use (SET_DEST (newpat), i3, &cc_use_insn))) { compare_code = orig_compare_code = GET_CODE (*cc_use_loc); compare_code = simplify_compare_const (compare_code, GET_MODE (i2dest), op0, &op1); target_canonicalize_comparison (&compare_code, &op0, &op1, 1); } /* Do the rest only if op1 is const0_rtx, which may be the result of simplification. */ if (op1 == const0_rtx) { /* If a single use of the CC is found, prepare to modify it when SELECT_CC_MODE returns a new CC-class mode, or when the above simplify_compare_const() returned a new comparison operator. undobuf.other_insn is assigned the CC use insn when modifying it. */ if (cc_use_loc) { #ifdef SELECT_CC_MODE machine_mode new_mode = SELECT_CC_MODE (compare_code, op0, op1); if (new_mode != orig_compare_mode && can_change_dest_mode (SET_DEST (newpat), added_sets_2, new_mode)) { unsigned int regno = REGNO (newpat_dest); compare_mode = new_mode; if (regno < FIRST_PSEUDO_REGISTER) newpat_dest = gen_rtx_REG (compare_mode, regno); else { SUBST_MODE (regno_reg_rtx[regno], compare_mode); newpat_dest = regno_reg_rtx[regno]; } } #endif /* Cases for modifying the CC-using comparison. */ if (compare_code != orig_compare_code /* ??? Do we need to verify the zero rtx? */ && XEXP (*cc_use_loc, 1) == const0_rtx) { /* Replace cc_use_loc with entire new RTX. */ SUBST (*cc_use_loc, gen_rtx_fmt_ee (compare_code, compare_mode, newpat_dest, const0_rtx)); undobuf.other_insn = cc_use_insn; } else if (compare_mode != orig_compare_mode) { /* Just replace the CC reg with a new mode. */ SUBST (XEXP (*cc_use_loc, 0), newpat_dest); undobuf.other_insn = cc_use_insn; } } /* Now we modify the current newpat: First, SET_DEST(newpat) is updated if the CC mode has been altered. For targets without SELECT_CC_MODE, this should be optimized away. */ if (compare_mode != orig_compare_mode) SUBST (SET_DEST (newpat), newpat_dest); /* This is always done to propagate i2src into newpat. */ SUBST (SET_SRC (newpat), gen_rtx_COMPARE (compare_mode, op0, op1)); /* Create new version of i2pat if needed; the below PARALLEL creation needs this to work correctly. */ if (! rtx_equal_p (i2src, op0)) i2pat = gen_rtx_SET (i2dest, op0); i2_is_used = 1; } } if (i2_is_used == 0) { /* It is possible that the source of I2 or I1 may be performing an unneeded operation, such as a ZERO_EXTEND of something that is known to have the high part zero. Handle that case by letting subst look at the inner insns. Another way to do this would be to have a function that tries to simplify a single insn instead of merging two or more insns. We don't do this because of the potential of infinite loops and because of the potential extra memory required. However, doing it the way we are is a bit of a kludge and doesn't catch all cases. But only do this if -fexpensive-optimizations since it slows things down and doesn't usually win. This is not done in the COMPARE case above because the unmodified I2PAT is used in the PARALLEL and so a pattern with a modified I2SRC would not match. */ if (flag_expensive_optimizations) { /* Pass pc_rtx so no substitutions are done, just simplifications. */ if (i1) { subst_low_luid = DF_INSN_LUID (i1); i1src = subst (i1src, pc_rtx, pc_rtx, 0, 0, 0); } subst_low_luid = DF_INSN_LUID (i2); i2src = subst (i2src, pc_rtx, pc_rtx, 0, 0, 0); } n_occurrences = 0; /* `subst' counts here */ subst_low_luid = DF_INSN_LUID (i2); /* If I1 feeds into I2 and I1DEST is in I1SRC, we need to make a unique copy of I2SRC each time we substitute it, in order to avoid creating self-referential RTL when we will be substituting I1SRC for I1DEST later. Likewise if I0 feeds into I2, either directly or indirectly through I1, and I0DEST is in I0SRC. */ newpat = subst (PATTERN (i3), i2dest, i2src, 0, 0, (i1_feeds_i2_n && i1dest_in_i1src) || ((i0_feeds_i2_n || (i0_feeds_i1_n && i1_feeds_i2_n)) && i0dest_in_i0src)); substed_i2 = 1; /* Record whether I2's body now appears within I3's body. */ i2_is_used = n_occurrences; } /* If we already got a failure, don't try to do more. Otherwise, try to substitute I1 if we have it. */ if (i1 && GET_CODE (newpat) != CLOBBER) { /* Check that an autoincrement side-effect on I1 has not been lost. This happens if I1DEST is mentioned in I2 and dies there, and has disappeared from the new pattern. */ if ((FIND_REG_INC_NOTE (i1, NULL_RTX) != 0 && i1_feeds_i2_n && dead_or_set_p (i2, i1dest) && !reg_overlap_mentioned_p (i1dest, newpat)) /* Before we can do this substitution, we must redo the test done above (see detailed comments there) that ensures I1DEST isn't mentioned in any SETs in NEWPAT that are field assignments. */ || !combinable_i3pat (NULL, &newpat, i1dest, NULL_RTX, NULL_RTX, 0, 0, 0)) { undo_all (); return 0; } n_occurrences = 0; subst_low_luid = DF_INSN_LUID (i1); /* If the following substitution will modify I1SRC, make a copy of it for the case where it is substituted for I1DEST in I2PAT later. */ if (added_sets_2 && i1_feeds_i2_n) i1src_copy = copy_rtx (i1src); /* If I0 feeds into I1 and I0DEST is in I0SRC, we need to make a unique copy of I1SRC each time we substitute it, in order to avoid creating self-referential RTL when we will be substituting I0SRC for I0DEST later. */ newpat = subst (newpat, i1dest, i1src, 0, 0, i0_feeds_i1_n && i0dest_in_i0src); substed_i1 = 1; /* Record whether I1's body now appears within I3's body. */ i1_is_used = n_occurrences; } /* Likewise for I0 if we have it. */ if (i0 && GET_CODE (newpat) != CLOBBER) { if ((FIND_REG_INC_NOTE (i0, NULL_RTX) != 0 && ((i0_feeds_i2_n && dead_or_set_p (i2, i0dest)) || (i0_feeds_i1_n && dead_or_set_p (i1, i0dest))) && !reg_overlap_mentioned_p (i0dest, newpat)) || !combinable_i3pat (NULL, &newpat, i0dest, NULL_RTX, NULL_RTX, 0, 0, 0)) { undo_all (); return 0; } /* If the following substitution will modify I0SRC, make a copy of it for the case where it is substituted for I0DEST in I1PAT later. */ if (added_sets_1 && i0_feeds_i1_n) i0src_copy = copy_rtx (i0src); /* And a copy for I0DEST in I2PAT substitution. */ if (added_sets_2 && ((i0_feeds_i1_n && i1_feeds_i2_n) || (i0_feeds_i2_n))) i0src_copy2 = copy_rtx (i0src); n_occurrences = 0; subst_low_luid = DF_INSN_LUID (i0); newpat = subst (newpat, i0dest, i0src, 0, 0, 0); substed_i0 = 1; } /* Fail if an autoincrement side-effect has been duplicated. Be careful to count all the ways that I2SRC and I1SRC can be used. */ if ((FIND_REG_INC_NOTE (i2, NULL_RTX) != 0 && i2_is_used + added_sets_2 > 1) || (i1 != 0 && FIND_REG_INC_NOTE (i1, NULL_RTX) != 0 && (i1_is_used + added_sets_1 + (added_sets_2 && i1_feeds_i2_n) > 1)) || (i0 != 0 && FIND_REG_INC_NOTE (i0, NULL_RTX) != 0 && (n_occurrences + added_sets_0 + (added_sets_1 && i0_feeds_i1_n) + (added_sets_2 && i0_feeds_i2_n) > 1)) /* Fail if we tried to make a new register. */ || max_reg_num () != maxreg /* Fail if we couldn't do something and have a CLOBBER. */ || GET_CODE (newpat) == CLOBBER /* Fail if this new pattern is a MULT and we didn't have one before at the outer level. */ || (GET_CODE (newpat) == SET && GET_CODE (SET_SRC (newpat)) == MULT && ! have_mult)) { undo_all (); return 0; } /* If the actions of the earlier insns must be kept in addition to substituting them into the latest one, we must make a new PARALLEL for the latest insn to hold additional the SETs. */ if (added_sets_0 || added_sets_1 || added_sets_2) { int extra_sets = added_sets_0 + added_sets_1 + added_sets_2; combine_extras++; if (GET_CODE (newpat) == PARALLEL) { rtvec old = XVEC (newpat, 0); total_sets = XVECLEN (newpat, 0) + extra_sets; newpat = gen_rtx_PARALLEL (VOIDmode, rtvec_alloc (total_sets)); memcpy (XVEC (newpat, 0)->elem, &old->elem[0], sizeof (old->elem[0]) * old->num_elem); } else { rtx old = newpat; total_sets = 1 + extra_sets; newpat = gen_rtx_PARALLEL (VOIDmode, rtvec_alloc (total_sets)); XVECEXP (newpat, 0, 0) = old; } if (added_sets_0) XVECEXP (newpat, 0, --total_sets) = i0pat; if (added_sets_1) { rtx t = i1pat; if (i0_feeds_i1_n) t = subst (t, i0dest, i0src_copy ? i0src_copy : i0src, 0, 0, 0); XVECEXP (newpat, 0, --total_sets) = t; } if (added_sets_2) { rtx t = i2pat; if (i1_feeds_i2_n) t = subst (t, i1dest, i1src_copy ? i1src_copy : i1src, 0, 0, i0_feeds_i1_n && i0dest_in_i0src); if ((i0_feeds_i1_n && i1_feeds_i2_n) || i0_feeds_i2_n) t = subst (t, i0dest, i0src_copy2 ? i0src_copy2 : i0src, 0, 0, 0); XVECEXP (newpat, 0, --total_sets) = t; } } validate_replacement: /* Note which hard regs this insn has as inputs. */ mark_used_regs_combine (newpat); /* If recog_for_combine fails, it strips existing clobbers. If we'll consider splitting this pattern, we might need these clobbers. */ if (i1 && GET_CODE (newpat) == PARALLEL && GET_CODE (XVECEXP (newpat, 0, XVECLEN (newpat, 0) - 1)) == CLOBBER) { int len = XVECLEN (newpat, 0); newpat_vec_with_clobbers = rtvec_alloc (len); for (i = 0; i < len; i++) RTVEC_ELT (newpat_vec_with_clobbers, i) = XVECEXP (newpat, 0, i); } /* We have recognized nothing yet. */ insn_code_number = -1; /* See if this is a PARALLEL of two SETs where one SET's destination is a register that is unused and this isn't marked as an instruction that might trap in an EH region. In that case, we just need the other SET. We prefer this over the PARALLEL. This can occur when simplifying a divmod insn. We *must* test for this case here because the code below that splits two independent SETs doesn't handle this case correctly when it updates the register status. It's pointless doing this if we originally had two sets, one from i3, and one from i2. Combining then splitting the parallel results in the original i2 again plus an invalid insn (which we delete). The net effect is only to move instructions around, which makes debug info less accurate. */ if (!(added_sets_2 && i1 == 0) && is_parallel_of_n_reg_sets (newpat, 2) && asm_noperands (newpat) < 0) { rtx set0 = XVECEXP (newpat, 0, 0); rtx set1 = XVECEXP (newpat, 0, 1); rtx oldpat = newpat; if (((REG_P (SET_DEST (set1)) && find_reg_note (i3, REG_UNUSED, SET_DEST (set1))) || (GET_CODE (SET_DEST (set1)) == SUBREG && find_reg_note (i3, REG_UNUSED, SUBREG_REG (SET_DEST (set1))))) && insn_nothrow_p (i3) && !side_effects_p (SET_SRC (set1))) { newpat = set0; insn_code_number = recog_for_combine (&newpat, i3, &new_i3_notes); } else if (((REG_P (SET_DEST (set0)) && find_reg_note (i3, REG_UNUSED, SET_DEST (set0))) || (GET_CODE (SET_DEST (set0)) == SUBREG && find_reg_note (i3, REG_UNUSED, SUBREG_REG (SET_DEST (set0))))) && insn_nothrow_p (i3) && !side_effects_p (SET_SRC (set0))) { newpat = set1; insn_code_number = recog_for_combine (&newpat, i3, &new_i3_notes); if (insn_code_number >= 0) changed_i3_dest = 1; } if (insn_code_number < 0) newpat = oldpat; } /* Is the result of combination a valid instruction? */ if (insn_code_number < 0) insn_code_number = recog_for_combine (&newpat, i3, &new_i3_notes); /* If we were combining three insns and the result is a simple SET with no ASM_OPERANDS that wasn't recognized, try to split it into two insns. There are two ways to do this. It can be split using a machine-specific method (like when you have an addition of a large constant) or by combine in the function find_split_point. */ if (i1 && insn_code_number < 0 && GET_CODE (newpat) == SET && asm_noperands (newpat) < 0) { rtx parallel, *split; rtx_insn *m_split_insn; /* See if the MD file can split NEWPAT. If it can't, see if letting it use I2DEST as a scratch register will help. In the latter case, convert I2DEST to the mode of the source of NEWPAT if we can. */ m_split_insn = combine_split_insns (newpat, i3); /* We can only use I2DEST as a scratch reg if it doesn't overlap any inputs of NEWPAT. */ /* ??? If I2DEST is not safe, and I1DEST exists, then it would be possible to try that as a scratch reg. This would require adding more code to make it work though. */ if (m_split_insn == 0 && ! reg_overlap_mentioned_p (i2dest, newpat)) { machine_mode new_mode = GET_MODE (SET_DEST (newpat)); /* First try to split using the original register as a scratch register. */ parallel = gen_rtx_PARALLEL (VOIDmode, gen_rtvec (2, newpat, gen_rtx_CLOBBER (VOIDmode, i2dest))); m_split_insn = combine_split_insns (parallel, i3); /* If that didn't work, try changing the mode of I2DEST if we can. */ if (m_split_insn == 0 && new_mode != GET_MODE (i2dest) && new_mode != VOIDmode && can_change_dest_mode (i2dest, added_sets_2, new_mode)) { machine_mode old_mode = GET_MODE (i2dest); rtx ni2dest; if (REGNO (i2dest) < FIRST_PSEUDO_REGISTER) ni2dest = gen_rtx_REG (new_mode, REGNO (i2dest)); else { SUBST_MODE (regno_reg_rtx[REGNO (i2dest)], new_mode); ni2dest = regno_reg_rtx[REGNO (i2dest)]; } parallel = (gen_rtx_PARALLEL (VOIDmode, gen_rtvec (2, newpat, gen_rtx_CLOBBER (VOIDmode, ni2dest)))); m_split_insn = combine_split_insns (parallel, i3); if (m_split_insn == 0 && REGNO (i2dest) >= FIRST_PSEUDO_REGISTER) { struct undo *buf; adjust_reg_mode (regno_reg_rtx[REGNO (i2dest)], old_mode); buf = undobuf.undos; undobuf.undos = buf->next; buf->next = undobuf.frees; undobuf.frees = buf; } } i2scratch = m_split_insn != 0; } /* If recog_for_combine has discarded clobbers, try to use them again for the split. */ if (m_split_insn == 0 && newpat_vec_with_clobbers) { parallel = gen_rtx_PARALLEL (VOIDmode, newpat_vec_with_clobbers); m_split_insn = combine_split_insns (parallel, i3); } if (m_split_insn && NEXT_INSN (m_split_insn) == NULL_RTX) { rtx m_split_pat = PATTERN (m_split_insn); insn_code_number = recog_for_combine (&m_split_pat, i3, &new_i3_notes); if (insn_code_number >= 0) newpat = m_split_pat; } else if (m_split_insn && NEXT_INSN (NEXT_INSN (m_split_insn)) == NULL_RTX && (next_nonnote_nondebug_insn (i2) == i3 || ! use_crosses_set_p (PATTERN (m_split_insn), DF_INSN_LUID (i2)))) { rtx i2set, i3set; rtx newi3pat = PATTERN (NEXT_INSN (m_split_insn)); newi2pat = PATTERN (m_split_insn); i3set = single_set (NEXT_INSN (m_split_insn)); i2set = single_set (m_split_insn); i2_code_number = recog_for_combine (&newi2pat, i2, &new_i2_notes); /* If I2 or I3 has multiple SETs, we won't know how to track register status, so don't use these insns. If I2's destination is used between I2 and I3, we also can't use these insns. */ if (i2_code_number >= 0 && i2set && i3set && (next_nonnote_nondebug_insn (i2) == i3 || ! reg_used_between_p (SET_DEST (i2set), i2, i3))) insn_code_number = recog_for_combine (&newi3pat, i3, &new_i3_notes); if (insn_code_number >= 0) newpat = newi3pat; /* It is possible that both insns now set the destination of I3. If so, we must show an extra use of it. */ if (insn_code_number >= 0) { rtx new_i3_dest = SET_DEST (i3set); rtx new_i2_dest = SET_DEST (i2set); while (GET_CODE (new_i3_dest) == ZERO_EXTRACT || GET_CODE (new_i3_dest) == STRICT_LOW_PART || GET_CODE (new_i3_dest) == SUBREG) new_i3_dest = XEXP (new_i3_dest, 0); while (GET_CODE (new_i2_dest) == ZERO_EXTRACT || GET_CODE (new_i2_dest) == STRICT_LOW_PART || GET_CODE (new_i2_dest) == SUBREG) new_i2_dest = XEXP (new_i2_dest, 0); if (REG_P (new_i3_dest) && REG_P (new_i2_dest) && REGNO (new_i3_dest) == REGNO (new_i2_dest) && REGNO (new_i2_dest) < reg_n_sets_max) INC_REG_N_SETS (REGNO (new_i2_dest), 1); } } /* If we can split it and use I2DEST, go ahead and see if that helps things be recognized. Verify that none of the registers are set between I2 and I3. */ if (insn_code_number < 0 && (split = find_split_point (&newpat, i3, false)) != 0 && (!HAVE_cc0 || REG_P (i2dest)) /* We need I2DEST in the proper mode. If it is a hard register or the only use of a pseudo, we can change its mode. Make sure we don't change a hard register to have a mode that isn't valid for it, or change the number of registers. */ && (GET_MODE (*split) == GET_MODE (i2dest) || GET_MODE (*split) == VOIDmode || can_change_dest_mode (i2dest, added_sets_2, GET_MODE (*split))) && (next_nonnote_nondebug_insn (i2) == i3 || ! use_crosses_set_p (*split, DF_INSN_LUID (i2))) /* We can't overwrite I2DEST if its value is still used by NEWPAT. */ && ! reg_referenced_p (i2dest, newpat)) { rtx newdest = i2dest; enum rtx_code split_code = GET_CODE (*split); machine_mode split_mode = GET_MODE (*split); bool subst_done = false; newi2pat = NULL_RTX; i2scratch = true; /* *SPLIT may be part of I2SRC, so make sure we have the original expression around for later debug processing. We should not need I2SRC any more in other cases. */ if (MAY_HAVE_DEBUG_INSNS) i2src = copy_rtx (i2src); else i2src = NULL; /* Get NEWDEST as a register in the proper mode. We have already validated that we can do this. */ if (GET_MODE (i2dest) != split_mode && split_mode != VOIDmode) { if (REGNO (i2dest) < FIRST_PSEUDO_REGISTER) newdest = gen_rtx_REG (split_mode, REGNO (i2dest)); else { SUBST_MODE (regno_reg_rtx[REGNO (i2dest)], split_mode); newdest = regno_reg_rtx[REGNO (i2dest)]; } } /* If *SPLIT is a (mult FOO (const_int pow2)), convert it to an ASHIFT. This can occur if it was inside a PLUS and hence appeared to be a memory address. This is a kludge. */ if (split_code == MULT && CONST_INT_P (XEXP (*split, 1)) && INTVAL (XEXP (*split, 1)) > 0 && (i = exact_log2 (UINTVAL (XEXP (*split, 1)))) >= 0) { SUBST (*split, gen_rtx_ASHIFT (split_mode, XEXP (*split, 0), GEN_INT (i))); /* Update split_code because we may not have a multiply anymore. */ split_code = GET_CODE (*split); } /* Similarly for (plus (mult FOO (const_int pow2))). */ if (split_code == PLUS && GET_CODE (XEXP (*split, 0)) == MULT && CONST_INT_P (XEXP (XEXP (*split, 0), 1)) && INTVAL (XEXP (XEXP (*split, 0), 1)) > 0 && (i = exact_log2 (UINTVAL (XEXP (XEXP (*split, 0), 1)))) >= 0) { rtx nsplit = XEXP (*split, 0); SUBST (XEXP (*split, 0), gen_rtx_ASHIFT (GET_MODE (nsplit), XEXP (nsplit, 0), GEN_INT (i))); /* Update split_code because we may not have a multiply anymore. */ split_code = GET_CODE (*split); } #ifdef INSN_SCHEDULING /* If *SPLIT is a paradoxical SUBREG, when we split it, it should be written as a ZERO_EXTEND. */ if (split_code == SUBREG && MEM_P (SUBREG_REG (*split))) { /* Or as a SIGN_EXTEND if LOAD_EXTEND_OP says that that's what it really is. */ if (LOAD_EXTEND_OP (GET_MODE (SUBREG_REG (*split))) == SIGN_EXTEND) SUBST (*split, gen_rtx_SIGN_EXTEND (split_mode, SUBREG_REG (*split))); else SUBST (*split, gen_rtx_ZERO_EXTEND (split_mode, SUBREG_REG (*split))); } #endif /* Attempt to split binary operators using arithmetic identities. */ if (BINARY_P (SET_SRC (newpat)) && split_mode == GET_MODE (SET_SRC (newpat)) && ! side_effects_p (SET_SRC (newpat))) { rtx setsrc = SET_SRC (newpat); machine_mode mode = GET_MODE (setsrc); enum rtx_code code = GET_CODE (setsrc); rtx src_op0 = XEXP (setsrc, 0); rtx src_op1 = XEXP (setsrc, 1); /* Split "X = Y op Y" as "Z = Y; X = Z op Z". */ if (rtx_equal_p (src_op0, src_op1)) { newi2pat = gen_rtx_SET (newdest, src_op0); SUBST (XEXP (setsrc, 0), newdest); SUBST (XEXP (setsrc, 1), newdest); subst_done = true; } /* Split "((P op Q) op R) op S" where op is PLUS or MULT. */ else if ((code == PLUS || code == MULT) && GET_CODE (src_op0) == code && GET_CODE (XEXP (src_op0, 0)) == code && (INTEGRAL_MODE_P (mode) || (FLOAT_MODE_P (mode) && flag_unsafe_math_optimizations))) { rtx p = XEXP (XEXP (src_op0, 0), 0); rtx q = XEXP (XEXP (src_op0, 0), 1); rtx r = XEXP (src_op0, 1); rtx s = src_op1; /* Split both "((X op Y) op X) op Y" and "((X op Y) op Y) op X" as "T op T" where T is "X op Y". */ if ((rtx_equal_p (p,r) && rtx_equal_p (q,s)) || (rtx_equal_p (p,s) && rtx_equal_p (q,r))) { newi2pat = gen_rtx_SET (newdest, XEXP (src_op0, 0)); SUBST (XEXP (setsrc, 0), newdest); SUBST (XEXP (setsrc, 1), newdest); subst_done = true; } /* Split "((X op X) op Y) op Y)" as "T op T" where T is "X op Y". */ else if (rtx_equal_p (p,q) && rtx_equal_p (r,s)) { rtx tmp = simplify_gen_binary (code, mode, p, r); newi2pat = gen_rtx_SET (newdest, tmp); SUBST (XEXP (setsrc, 0), newdest); SUBST (XEXP (setsrc, 1), newdest); subst_done = true; } } } if (!subst_done) { newi2pat = gen_rtx_SET (newdest, *split); SUBST (*split, newdest); } i2_code_number = recog_for_combine (&newi2pat, i2, &new_i2_notes); /* recog_for_combine might have added CLOBBERs to newi2pat. Make sure NEWPAT does not depend on the clobbered regs. */ if (GET_CODE (newi2pat) == PARALLEL) for (i = XVECLEN (newi2pat, 0) - 1; i >= 0; i--) if (GET_CODE (XVECEXP (newi2pat, 0, i)) == CLOBBER) { rtx reg = XEXP (XVECEXP (newi2pat, 0, i), 0); if (reg_overlap_mentioned_p (reg, newpat)) { undo_all (); return 0; } } /* If the split point was a MULT and we didn't have one before, don't use one now. */ if (i2_code_number >= 0 && ! (split_code == MULT && ! have_mult)) insn_code_number = recog_for_combine (&newpat, i3, &new_i3_notes); } } /* Check for a case where we loaded from memory in a narrow mode and then sign extended it, but we need both registers. In that case, we have a PARALLEL with both loads from the same memory location. We can split this into a load from memory followed by a register-register copy. This saves at least one insn, more if register allocation can eliminate the copy. We cannot do this if the destination of the first assignment is a condition code register or cc0. We eliminate this case by making sure the SET_DEST and SET_SRC have the same mode. We cannot do this if the destination of the second assignment is a register that we have already assumed is zero-extended. Similarly for a SUBREG of such a register. */ else if (i1 && insn_code_number < 0 && asm_noperands (newpat) < 0 && GET_CODE (newpat) == PARALLEL && XVECLEN (newpat, 0) == 2 && GET_CODE (XVECEXP (newpat, 0, 0)) == SET && GET_CODE (SET_SRC (XVECEXP (newpat, 0, 0))) == SIGN_EXTEND && (GET_MODE (SET_DEST (XVECEXP (newpat, 0, 0))) == GET_MODE (SET_SRC (XVECEXP (newpat, 0, 0)))) && GET_CODE (XVECEXP (newpat, 0, 1)) == SET && rtx_equal_p (SET_SRC (XVECEXP (newpat, 0, 1)), XEXP (SET_SRC (XVECEXP (newpat, 0, 0)), 0)) && ! use_crosses_set_p (SET_SRC (XVECEXP (newpat, 0, 1)), DF_INSN_LUID (i2)) && GET_CODE (SET_DEST (XVECEXP (newpat, 0, 1))) != ZERO_EXTRACT && GET_CODE (SET_DEST (XVECEXP (newpat, 0, 1))) != STRICT_LOW_PART && ! (temp_expr = SET_DEST (XVECEXP (newpat, 0, 1)), (REG_P (temp_expr) && reg_stat[REGNO (temp_expr)].nonzero_bits != 0 && GET_MODE_PRECISION (GET_MODE (temp_expr)) < BITS_PER_WORD && GET_MODE_PRECISION (GET_MODE (temp_expr)) < HOST_BITS_PER_INT && (reg_stat[REGNO (temp_expr)].nonzero_bits != GET_MODE_MASK (word_mode)))) && ! (GET_CODE (SET_DEST (XVECEXP (newpat, 0, 1))) == SUBREG && (temp_expr = SUBREG_REG (SET_DEST (XVECEXP (newpat, 0, 1))), (REG_P (temp_expr) && reg_stat[REGNO (temp_expr)].nonzero_bits != 0 && GET_MODE_PRECISION (GET_MODE (temp_expr)) < BITS_PER_WORD && GET_MODE_PRECISION (GET_MODE (temp_expr)) < HOST_BITS_PER_INT && (reg_stat[REGNO (temp_expr)].nonzero_bits != GET_MODE_MASK (word_mode))))) && ! reg_overlap_mentioned_p (SET_DEST (XVECEXP (newpat, 0, 1)), SET_SRC (XVECEXP (newpat, 0, 1))) && ! find_reg_note (i3, REG_UNUSED, SET_DEST (XVECEXP (newpat, 0, 0)))) { rtx ni2dest; newi2pat = XVECEXP (newpat, 0, 0); ni2dest = SET_DEST (XVECEXP (newpat, 0, 0)); newpat = XVECEXP (newpat, 0, 1); SUBST (SET_SRC (newpat), gen_lowpart (GET_MODE (SET_SRC (newpat)), ni2dest)); i2_code_number = recog_for_combine (&newi2pat, i2, &new_i2_notes); if (i2_code_number >= 0) insn_code_number = recog_for_combine (&newpat, i3, &new_i3_notes); if (insn_code_number >= 0) swap_i2i3 = 1; } /* Similarly, check for a case where we have a PARALLEL of two independent SETs but we started with three insns. In this case, we can do the sets as two separate insns. This case occurs when some SET allows two other insns to combine, but the destination of that SET is still live. Also do this if we started with two insns and (at least) one of the resulting sets is a noop; this noop will be deleted later. */ else if (insn_code_number < 0 && asm_noperands (newpat) < 0 && GET_CODE (newpat) == PARALLEL && XVECLEN (newpat, 0) == 2 && GET_CODE (XVECEXP (newpat, 0, 0)) == SET && GET_CODE (XVECEXP (newpat, 0, 1)) == SET && (i1 || set_noop_p (XVECEXP (newpat, 0, 0)) || set_noop_p (XVECEXP (newpat, 0, 1))) && GET_CODE (SET_DEST (XVECEXP (newpat, 0, 0))) != ZERO_EXTRACT && GET_CODE (SET_DEST (XVECEXP (newpat, 0, 0))) != STRICT_LOW_PART && GET_CODE (SET_DEST (XVECEXP (newpat, 0, 1))) != ZERO_EXTRACT && GET_CODE (SET_DEST (XVECEXP (newpat, 0, 1))) != STRICT_LOW_PART && ! reg_referenced_p (SET_DEST (XVECEXP (newpat, 0, 1)), XVECEXP (newpat, 0, 0)) && ! reg_referenced_p (SET_DEST (XVECEXP (newpat, 0, 0)), XVECEXP (newpat, 0, 1)) && ! (contains_muldiv (SET_SRC (XVECEXP (newpat, 0, 0))) && contains_muldiv (SET_SRC (XVECEXP (newpat, 0, 1))))) { rtx set0 = XVECEXP (newpat, 0, 0); rtx set1 = XVECEXP (newpat, 0, 1); /* Normally, it doesn't matter which of the two is done first, but the one that references cc0 can't be the second, and one which uses any regs/memory set in between i2 and i3 can't be first. The PARALLEL might also have been pre-existing in i3, so we need to make sure that we won't wrongly hoist a SET to i2 that would conflict with a death note present in there. */ if (!use_crosses_set_p (SET_SRC (set1), DF_INSN_LUID (i2)) && !(REG_P (SET_DEST (set1)) && find_reg_note (i2, REG_DEAD, SET_DEST (set1))) && !(GET_CODE (SET_DEST (set1)) == SUBREG && find_reg_note (i2, REG_DEAD, SUBREG_REG (SET_DEST (set1)))) && (!HAVE_cc0 || !reg_referenced_p (cc0_rtx, set0)) /* If I3 is a jump, ensure that set0 is a jump so that we do not create invalid RTL. */ && (!JUMP_P (i3) || SET_DEST (set0) == pc_rtx) ) { newi2pat = set1; newpat = set0; } else if (!use_crosses_set_p (SET_SRC (set0), DF_INSN_LUID (i2)) && !(REG_P (SET_DEST (set0)) && find_reg_note (i2, REG_DEAD, SET_DEST (set0))) && !(GET_CODE (SET_DEST (set0)) == SUBREG && find_reg_note (i2, REG_DEAD, SUBREG_REG (SET_DEST (set0)))) && (!HAVE_cc0 || !reg_referenced_p (cc0_rtx, set1)) /* If I3 is a jump, ensure that set1 is a jump so that we do not create invalid RTL. */ && (!JUMP_P (i3) || SET_DEST (set1) == pc_rtx) ) { newi2pat = set0; newpat = set1; } else { undo_all (); return 0; } i2_code_number = recog_for_combine (&newi2pat, i2, &new_i2_notes); if (i2_code_number >= 0) { /* recog_for_combine might have added CLOBBERs to newi2pat. Make sure NEWPAT does not depend on the clobbered regs. */ if (GET_CODE (newi2pat) == PARALLEL) { for (i = XVECLEN (newi2pat, 0) - 1; i >= 0; i--) if (GET_CODE (XVECEXP (newi2pat, 0, i)) == CLOBBER) { rtx reg = XEXP (XVECEXP (newi2pat, 0, i), 0); if (reg_overlap_mentioned_p (reg, newpat)) { undo_all (); return 0; } } } insn_code_number = recog_for_combine (&newpat, i3, &new_i3_notes); } } /* If it still isn't recognized, fail and change things back the way they were. */ if ((insn_code_number < 0 /* Is the result a reasonable ASM_OPERANDS? */ && (! check_asm_operands (newpat) || added_sets_1 || added_sets_2))) { undo_all (); return 0; } /* If we had to change another insn, make sure it is valid also. */ if (undobuf.other_insn) { CLEAR_HARD_REG_SET (newpat_used_regs); other_pat = PATTERN (undobuf.other_insn); other_code_number = recog_for_combine (&other_pat, undobuf.other_insn, &new_other_notes); if (other_code_number < 0 && ! check_asm_operands (other_pat)) { undo_all (); return 0; } } /* If I2 is the CC0 setter and I3 is the CC0 user then check whether they are adjacent to each other or not. */ if (HAVE_cc0) { rtx_insn *p = prev_nonnote_insn (i3); if (p && p != i2 && NONJUMP_INSN_P (p) && newi2pat && sets_cc0_p (newi2pat)) { undo_all (); return 0; } } /* Only allow this combination if insn_rtx_costs reports that the replacement instructions are cheaper than the originals. */ if (!combine_validate_cost (i0, i1, i2, i3, newpat, newi2pat, other_pat)) { undo_all (); return 0; } if (MAY_HAVE_DEBUG_INSNS) { struct undo *undo; for (undo = undobuf.undos; undo; undo = undo->next) if (undo->kind == UNDO_MODE) { rtx reg = *undo->where.r; machine_mode new_mode = GET_MODE (reg); machine_mode old_mode = undo->old_contents.m; /* Temporarily revert mode back. */ adjust_reg_mode (reg, old_mode); if (reg == i2dest && i2scratch) { /* If we used i2dest as a scratch register with a different mode, substitute it for the original i2src while its original mode is temporarily restored, and then clear i2scratch so that we don't do it again later. */ propagate_for_debug (i2, last_combined_insn, reg, i2src, this_basic_block); i2scratch = false; /* Put back the new mode. */ adjust_reg_mode (reg, new_mode); } else { rtx tempreg = gen_raw_REG (old_mode, REGNO (reg)); rtx_insn *first, *last; if (reg == i2dest) { first = i2; last = last_combined_insn; } else { first = i3; last = undobuf.other_insn; gcc_assert (last); if (DF_INSN_LUID (last) < DF_INSN_LUID (last_combined_insn)) last = last_combined_insn; } /* We're dealing with a reg that changed mode but not meaning, so we want to turn it into a subreg for the new mode. However, because of REG sharing and because its mode had already changed, we have to do it in two steps. First, replace any debug uses of reg, with its original mode temporarily restored, with this copy we have created; then, replace the copy with the SUBREG of the original shared reg, once again changed to the new mode. */ propagate_for_debug (first, last, reg, tempreg, this_basic_block); adjust_reg_mode (reg, new_mode); propagate_for_debug (first, last, tempreg, lowpart_subreg (old_mode, reg, new_mode), this_basic_block); } } } /* If we will be able to accept this, we have made a change to the destination of I3. This requires us to do a few adjustments. */ if (changed_i3_dest) { PATTERN (i3) = newpat; adjust_for_new_dest (i3); } /* We now know that we can do this combination. Merge the insns and update the status of registers and LOG_LINKS. */ if (undobuf.other_insn) { rtx note, next; PATTERN (undobuf.other_insn) = other_pat; /* If any of the notes in OTHER_INSN were REG_DEAD or REG_UNUSED, ensure that they are still valid. Then add any non-duplicate notes added by recog_for_combine. */ for (note = REG_NOTES (undobuf.other_insn); note; note = next) { next = XEXP (note, 1); if ((REG_NOTE_KIND (note) == REG_DEAD && !reg_referenced_p (XEXP (note, 0), PATTERN (undobuf.other_insn))) ||(REG_NOTE_KIND (note) == REG_UNUSED && !reg_set_p (XEXP (note, 0), PATTERN (undobuf.other_insn)))) remove_note (undobuf.other_insn, note); } distribute_notes (new_other_notes, undobuf.other_insn, undobuf.other_insn, NULL, NULL_RTX, NULL_RTX, NULL_RTX); } if (swap_i2i3) { rtx_insn *insn; struct insn_link *link; rtx ni2dest; /* I3 now uses what used to be its destination and which is now I2's destination. This requires us to do a few adjustments. */ PATTERN (i3) = newpat; adjust_for_new_dest (i3); /* We need a LOG_LINK from I3 to I2. But we used to have one, so we still will. However, some later insn might be using I2's dest and have a LOG_LINK pointing at I3. We must remove this link. The simplest way to remove the link is to point it at I1, which we know will be a NOTE. */ /* newi2pat is usually a SET here; however, recog_for_combine might have added some clobbers. */ if (GET_CODE (newi2pat) == PARALLEL) ni2dest = SET_DEST (XVECEXP (newi2pat, 0, 0)); else ni2dest = SET_DEST (newi2pat); for (insn = NEXT_INSN (i3); insn && (this_basic_block->next_bb == EXIT_BLOCK_PTR_FOR_FN (cfun) || insn != BB_HEAD (this_basic_block->next_bb)); insn = NEXT_INSN (insn)) { if (INSN_P (insn) && reg_referenced_p (ni2dest, PATTERN (insn))) { FOR_EACH_LOG_LINK (link, insn) if (link->insn == i3) link->insn = i1; break; } } } { rtx i3notes, i2notes, i1notes = 0, i0notes = 0; struct insn_link *i3links, *i2links, *i1links = 0, *i0links = 0; rtx midnotes = 0; int from_luid; /* Compute which registers we expect to eliminate. newi2pat may be setting either i3dest or i2dest, so we must check it. */ rtx elim_i2 = ((newi2pat && reg_set_p (i2dest, newi2pat)) || i2dest_in_i2src || i2dest_in_i1src || i2dest_in_i0src || !i2dest_killed ? 0 : i2dest); /* For i1, we need to compute both local elimination and global elimination information with respect to newi2pat because i1dest may be the same as i3dest, in which case newi2pat may be setting i1dest. Global information is used when distributing REG_DEAD note for i2 and i3, in which case it does matter if newi2pat sets i1dest or not. Local information is used when distributing REG_DEAD note for i1, in which case it doesn't matter if newi2pat sets i1dest or not. See PR62151, if we have four insns combination: i0: r0 <- i0src i1: r1 <- i1src (using r0) REG_DEAD (r0) i2: r0 <- i2src (using r1) i3: r3 <- i3src (using r0) ix: using r0 From i1's point of view, r0 is eliminated, no matter if it is set by newi2pat or not. In other words, REG_DEAD info for r0 in i1 should be discarded. Note local information only affects cases in forms like "I1->I2->I3", "I0->I1->I2->I3" or "I0&I1->I2, I2->I3". For other cases like "I0->I1, I1&I2->I3" or "I1&I2->I3", newi2pat won't set i1dest or i0dest anyway. */ rtx local_elim_i1 = (i1 == 0 || i1dest_in_i1src || i1dest_in_i0src || !i1dest_killed ? 0 : i1dest); rtx elim_i1 = (local_elim_i1 == 0 || (newi2pat && reg_set_p (i1dest, newi2pat)) ? 0 : i1dest); /* Same case as i1. */ rtx local_elim_i0 = (i0 == 0 || i0dest_in_i0src || !i0dest_killed ? 0 : i0dest); rtx elim_i0 = (local_elim_i0 == 0 || (newi2pat && reg_set_p (i0dest, newi2pat)) ? 0 : i0dest); /* Get the old REG_NOTES and LOG_LINKS from all our insns and clear them. */ i3notes = REG_NOTES (i3), i3links = LOG_LINKS (i3); i2notes = REG_NOTES (i2), i2links = LOG_LINKS (i2); if (i1) i1notes = REG_NOTES (i1), i1links = LOG_LINKS (i1); if (i0) i0notes = REG_NOTES (i0), i0links = LOG_LINKS (i0); /* Ensure that we do not have something that should not be shared but occurs multiple times in the new insns. Check this by first resetting all the `used' flags and then copying anything is shared. */ reset_used_flags (i3notes); reset_used_flags (i2notes); reset_used_flags (i1notes); reset_used_flags (i0notes); reset_used_flags (newpat); reset_used_flags (newi2pat); if (undobuf.other_insn) reset_used_flags (PATTERN (undobuf.other_insn)); i3notes = copy_rtx_if_shared (i3notes); i2notes = copy_rtx_if_shared (i2notes); i1notes = copy_rtx_if_shared (i1notes); i0notes = copy_rtx_if_shared (i0notes); newpat = copy_rtx_if_shared (newpat); newi2pat = copy_rtx_if_shared (newi2pat); if (undobuf.other_insn) reset_used_flags (PATTERN (undobuf.other_insn)); INSN_CODE (i3) = insn_code_number; PATTERN (i3) = newpat; if (CALL_P (i3) && CALL_INSN_FUNCTION_USAGE (i3)) { rtx call_usage = CALL_INSN_FUNCTION_USAGE (i3); reset_used_flags (call_usage); call_usage = copy_rtx (call_usage); if (substed_i2) { /* I2SRC must still be meaningful at this point. Some splitting operations can invalidate I2SRC, but those operations do not apply to calls. */ gcc_assert (i2src); replace_rtx (call_usage, i2dest, i2src); } if (substed_i1) replace_rtx (call_usage, i1dest, i1src); if (substed_i0) replace_rtx (call_usage, i0dest, i0src); CALL_INSN_FUNCTION_USAGE (i3) = call_usage; } if (undobuf.other_insn) INSN_CODE (undobuf.other_insn) = other_code_number; /* We had one special case above where I2 had more than one set and we replaced a destination of one of those sets with the destination of I3. In that case, we have to update LOG_LINKS of insns later in this basic block. Note that this (expensive) case is rare. Also, in this case, we must pretend that all REG_NOTEs for I2 actually came from I3, so that REG_UNUSED notes from I2 will be properly handled. */ if (i3_subst_into_i2) { for (i = 0; i < XVECLEN (PATTERN (i2), 0); i++) if ((GET_CODE (XVECEXP (PATTERN (i2), 0, i)) == SET || GET_CODE (XVECEXP (PATTERN (i2), 0, i)) == CLOBBER) && REG_P (SET_DEST (XVECEXP (PATTERN (i2), 0, i))) && SET_DEST (XVECEXP (PATTERN (i2), 0, i)) != i2dest && ! find_reg_note (i2, REG_UNUSED, SET_DEST (XVECEXP (PATTERN (i2), 0, i)))) for (temp_insn = NEXT_INSN (i2); temp_insn && (this_basic_block->next_bb == EXIT_BLOCK_PTR_FOR_FN (cfun) || BB_HEAD (this_basic_block) != temp_insn); temp_insn = NEXT_INSN (temp_insn)) if (temp_insn != i3 && INSN_P (temp_insn)) FOR_EACH_LOG_LINK (link, temp_insn) if (link->insn == i2) link->insn = i3; if (i3notes) { rtx link = i3notes; while (XEXP (link, 1)) link = XEXP (link, 1); XEXP (link, 1) = i2notes; } else i3notes = i2notes; i2notes = 0; } LOG_LINKS (i3) = NULL; REG_NOTES (i3) = 0; LOG_LINKS (i2) = NULL; REG_NOTES (i2) = 0; if (newi2pat) { if (MAY_HAVE_DEBUG_INSNS && i2scratch) propagate_for_debug (i2, last_combined_insn, i2dest, i2src, this_basic_block); INSN_CODE (i2) = i2_code_number; PATTERN (i2) = newi2pat; } else { if (MAY_HAVE_DEBUG_INSNS && i2src) propagate_for_debug (i2, last_combined_insn, i2dest, i2src, this_basic_block); SET_INSN_DELETED (i2); } if (i1) { LOG_LINKS (i1) = NULL; REG_NOTES (i1) = 0; if (MAY_HAVE_DEBUG_INSNS) propagate_for_debug (i1, last_combined_insn, i1dest, i1src, this_basic_block); SET_INSN_DELETED (i1); } if (i0) { LOG_LINKS (i0) = NULL; REG_NOTES (i0) = 0; if (MAY_HAVE_DEBUG_INSNS) propagate_for_debug (i0, last_combined_insn, i0dest, i0src, this_basic_block); SET_INSN_DELETED (i0); } /* Get death notes for everything that is now used in either I3 or I2 and used to die in a previous insn. If we built two new patterns, move from I1 to I2 then I2 to I3 so that we get the proper movement on registers that I2 modifies. */ if (i0) from_luid = DF_INSN_LUID (i0); else if (i1) from_luid = DF_INSN_LUID (i1); else from_luid = DF_INSN_LUID (i2); if (newi2pat) move_deaths (newi2pat, NULL_RTX, from_luid, i2, &midnotes); move_deaths (newpat, newi2pat, from_luid, i3, &midnotes); /* Distribute all the LOG_LINKS and REG_NOTES from I1, I2, and I3. */ if (i3notes) distribute_notes (i3notes, i3, i3, newi2pat ? i2 : NULL, elim_i2, elim_i1, elim_i0); if (i2notes) distribute_notes (i2notes, i2, i3, newi2pat ? i2 : NULL, elim_i2, elim_i1, elim_i0); if (i1notes) distribute_notes (i1notes, i1, i3, newi2pat ? i2 : NULL, elim_i2, local_elim_i1, local_elim_i0); if (i0notes) distribute_notes (i0notes, i0, i3, newi2pat ? i2 : NULL, elim_i2, elim_i1, local_elim_i0); if (midnotes) distribute_notes (midnotes, NULL, i3, newi2pat ? i2 : NULL, elim_i2, elim_i1, elim_i0); /* Distribute any notes added to I2 or I3 by recog_for_combine. We know these are REG_UNUSED and want them to go to the desired insn, so we always pass it as i3. */ if (newi2pat && new_i2_notes) distribute_notes (new_i2_notes, i2, i2, NULL, NULL_RTX, NULL_RTX, NULL_RTX); if (new_i3_notes) distribute_notes (new_i3_notes, i3, i3, NULL, NULL_RTX, NULL_RTX, NULL_RTX); /* If I3DEST was used in I3SRC, it really died in I3. We may need to put a REG_DEAD note for it somewhere. If NEWI2PAT exists and sets I3DEST, the death must be somewhere before I2, not I3. If we passed I3 in that case, it might delete I2. Similarly for I2 and I1. Show an additional death due to the REG_DEAD note we make here. If we discard it in distribute_notes, we will decrement it again. */ if (i3dest_killed) { rtx new_note = alloc_reg_note (REG_DEAD, i3dest_killed, NULL_RTX); if (newi2pat && reg_set_p (i3dest_killed, newi2pat)) distribute_notes (new_note, NULL, i2, NULL, elim_i2, elim_i1, elim_i0); else distribute_notes (new_note, NULL, i3, newi2pat ? i2 : NULL, elim_i2, elim_i1, elim_i0); } if (i2dest_in_i2src) { rtx new_note = alloc_reg_note (REG_DEAD, i2dest, NULL_RTX); if (newi2pat && reg_set_p (i2dest, newi2pat)) distribute_notes (new_note, NULL, i2, NULL, NULL_RTX, NULL_RTX, NULL_RTX); else distribute_notes (new_note, NULL, i3, newi2pat ? i2 : NULL, NULL_RTX, NULL_RTX, NULL_RTX); } if (i1dest_in_i1src) { rtx new_note = alloc_reg_note (REG_DEAD, i1dest, NULL_RTX); if (newi2pat && reg_set_p (i1dest, newi2pat)) distribute_notes (new_note, NULL, i2, NULL, NULL_RTX, NULL_RTX, NULL_RTX); else distribute_notes (new_note, NULL, i3, newi2pat ? i2 : NULL, NULL_RTX, NULL_RTX, NULL_RTX); } if (i0dest_in_i0src) { rtx new_note = alloc_reg_note (REG_DEAD, i0dest, NULL_RTX); if (newi2pat && reg_set_p (i0dest, newi2pat)) distribute_notes (new_note, NULL, i2, NULL, NULL_RTX, NULL_RTX, NULL_RTX); else distribute_notes (new_note, NULL, i3, newi2pat ? i2 : NULL, NULL_RTX, NULL_RTX, NULL_RTX); } distribute_links (i3links); distribute_links (i2links); distribute_links (i1links); distribute_links (i0links); if (REG_P (i2dest)) { struct insn_link *link; rtx_insn *i2_insn = 0; rtx i2_val = 0, set; /* The insn that used to set this register doesn't exist, and this life of the register may not exist either. See if one of I3's links points to an insn that sets I2DEST. If it does, that is now the last known value for I2DEST. If we don't update this and I2 set the register to a value that depended on its old contents, we will get confused. If this insn is used, thing will be set correctly in combine_instructions. */ FOR_EACH_LOG_LINK (link, i3) if ((set = single_set (link->insn)) != 0 && rtx_equal_p (i2dest, SET_DEST (set))) i2_insn = link->insn, i2_val = SET_SRC (set); record_value_for_reg (i2dest, i2_insn, i2_val); /* If the reg formerly set in I2 died only once and that was in I3, zero its use count so it won't make `reload' do any work. */ if (! added_sets_2 && (newi2pat == 0 || ! reg_mentioned_p (i2dest, newi2pat)) && ! i2dest_in_i2src && REGNO (i2dest) < reg_n_sets_max) INC_REG_N_SETS (REGNO (i2dest), -1); } if (i1 && REG_P (i1dest)) { struct insn_link *link; rtx_insn *i1_insn = 0; rtx i1_val = 0, set; FOR_EACH_LOG_LINK (link, i3) if ((set = single_set (link->insn)) != 0 && rtx_equal_p (i1dest, SET_DEST (set))) i1_insn = link->insn, i1_val = SET_SRC (set); record_value_for_reg (i1dest, i1_insn, i1_val); if (! added_sets_1 && ! i1dest_in_i1src && REGNO (i1dest) < reg_n_sets_max) INC_REG_N_SETS (REGNO (i1dest), -1); } if (i0 && REG_P (i0dest)) { struct insn_link *link; rtx_insn *i0_insn = 0; rtx i0_val = 0, set; FOR_EACH_LOG_LINK (link, i3) if ((set = single_set (link->insn)) != 0 && rtx_equal_p (i0dest, SET_DEST (set))) i0_insn = link->insn, i0_val = SET_SRC (set); record_value_for_reg (i0dest, i0_insn, i0_val); if (! added_sets_0 && ! i0dest_in_i0src && REGNO (i0dest) < reg_n_sets_max) INC_REG_N_SETS (REGNO (i0dest), -1); } /* Update reg_stat[].nonzero_bits et al for any changes that may have been made to this insn. The order is important, because newi2pat can affect nonzero_bits of newpat. */ if (newi2pat) note_stores (newi2pat, set_nonzero_bits_and_sign_copies, NULL); note_stores (newpat, set_nonzero_bits_and_sign_copies, NULL); } if (undobuf.other_insn != NULL_RTX) { if (dump_file) { fprintf (dump_file, "modifying other_insn "); dump_insn_slim (dump_file, undobuf.other_insn); } df_insn_rescan (undobuf.other_insn); } if (i0 && !(NOTE_P (i0) && (NOTE_KIND (i0) == NOTE_INSN_DELETED))) { if (dump_file) { fprintf (dump_file, "modifying insn i0 "); dump_insn_slim (dump_file, i0); } df_insn_rescan (i0); } if (i1 && !(NOTE_P (i1) && (NOTE_KIND (i1) == NOTE_INSN_DELETED))) { if (dump_file) { fprintf (dump_file, "modifying insn i1 "); dump_insn_slim (dump_file, i1); } df_insn_rescan (i1); } if (i2 && !(NOTE_P (i2) && (NOTE_KIND (i2) == NOTE_INSN_DELETED))) { if (dump_file) { fprintf (dump_file, "modifying insn i2 "); dump_insn_slim (dump_file, i2); } df_insn_rescan (i2); } if (i3 && !(NOTE_P (i3) && (NOTE_KIND (i3) == NOTE_INSN_DELETED))) { if (dump_file) { fprintf (dump_file, "modifying insn i3 "); dump_insn_slim (dump_file, i3); } df_insn_rescan (i3); } /* Set new_direct_jump_p if a new return or simple jump instruction has been created. Adjust the CFG accordingly. */ if (returnjump_p (i3) || any_uncondjump_p (i3)) { *new_direct_jump_p = 1; mark_jump_label (PATTERN (i3), i3, 0); update_cfg_for_uncondjump (i3); } if (undobuf.other_insn != NULL_RTX && (returnjump_p (undobuf.other_insn) || any_uncondjump_p (undobuf.other_insn))) { *new_direct_jump_p = 1; update_cfg_for_uncondjump (undobuf.other_insn); } /* A noop might also need cleaning up of CFG, if it comes from the simplification of a jump. */ if (JUMP_P (i3) && GET_CODE (newpat) == SET && SET_SRC (newpat) == pc_rtx && SET_DEST (newpat) == pc_rtx) { *new_direct_jump_p = 1; update_cfg_for_uncondjump (i3); } if (undobuf.other_insn != NULL_RTX && JUMP_P (undobuf.other_insn) && GET_CODE (PATTERN (undobuf.other_insn)) == SET && SET_SRC (PATTERN (undobuf.other_insn)) == pc_rtx && SET_DEST (PATTERN (undobuf.other_insn)) == pc_rtx) { *new_direct_jump_p = 1; update_cfg_for_uncondjump (undobuf.other_insn); } combine_successes++; undo_commit (); if (added_links_insn && (newi2pat == 0 || DF_INSN_LUID (added_links_insn) < DF_INSN_LUID (i2)) && DF_INSN_LUID (added_links_insn) < DF_INSN_LUID (i3)) return added_links_insn; else return newi2pat ? i2 : i3; } /* Get a marker for undoing to the current state. */ static void * get_undo_marker (void) { return undobuf.undos; } /* Undo the modifications up to the marker. */ static void undo_to_marker (void *marker) { struct undo *undo, *next; for (undo = undobuf.undos; undo != marker; undo = next) { gcc_assert (undo); next = undo->next; switch (undo->kind) { case UNDO_RTX: *undo->where.r = undo->old_contents.r; break; case UNDO_INT: *undo->where.i = undo->old_contents.i; break; case UNDO_MODE: adjust_reg_mode (*undo->where.r, undo->old_contents.m); break; case UNDO_LINKS: *undo->where.l = undo->old_contents.l; break; default: gcc_unreachable (); } undo->next = undobuf.frees; undobuf.frees = undo; } undobuf.undos = (struct undo *) marker; } /* Undo all the modifications recorded in undobuf. */ static void undo_all (void) { undo_to_marker (0); } /* We've committed to accepting the changes we made. Move all of the undos to the free list. */ static void undo_commit (void) { struct undo *undo, *next; for (undo = undobuf.undos; undo; undo = next) { next = undo->next; undo->next = undobuf.frees; undobuf.frees = undo; } undobuf.undos = 0; } /* Find the innermost point within the rtx at LOC, possibly LOC itself, where we have an arithmetic expression and return that point. LOC will be inside INSN. try_combine will call this function to see if an insn can be split into two insns. */ static rtx * find_split_point (rtx *loc, rtx_insn *insn, bool set_src) { rtx x = *loc; enum rtx_code code = GET_CODE (x); rtx *split; unsigned HOST_WIDE_INT len = 0; HOST_WIDE_INT pos = 0; int unsignedp = 0; rtx inner = NULL_RTX; /* First special-case some codes. */ switch (code) { case SUBREG: #ifdef INSN_SCHEDULING /* If we are making a paradoxical SUBREG invalid, it becomes a split point. */ if (MEM_P (SUBREG_REG (x))) return loc; #endif return find_split_point (&SUBREG_REG (x), insn, false); case MEM: /* If we have (mem (const ..)) or (mem (symbol_ref ...)), split it using LO_SUM and HIGH. */ if (HAVE_lo_sum && (GET_CODE (XEXP (x, 0)) == CONST || GET_CODE (XEXP (x, 0)) == SYMBOL_REF)) { machine_mode address_mode = get_address_mode (x); SUBST (XEXP (x, 0), gen_rtx_LO_SUM (address_mode, gen_rtx_HIGH (address_mode, XEXP (x, 0)), XEXP (x, 0))); return &XEXP (XEXP (x, 0), 0); } /* If we have a PLUS whose second operand is a constant and the address is not valid, perhaps will can split it up using the machine-specific way to split large constants. We use the first pseudo-reg (one of the virtual regs) as a placeholder; it will not remain in the result. */ if (GET_CODE (XEXP (x, 0)) == PLUS && CONST_INT_P (XEXP (XEXP (x, 0), 1)) && ! memory_address_addr_space_p (GET_MODE (x), XEXP (x, 0), MEM_ADDR_SPACE (x))) { rtx reg = regno_reg_rtx[FIRST_PSEUDO_REGISTER]; rtx_insn *seq = combine_split_insns (gen_rtx_SET (reg, XEXP (x, 0)), subst_insn); /* This should have produced two insns, each of which sets our placeholder. If the source of the second is a valid address, we can make put both sources together and make a split point in the middle. */ if (seq && NEXT_INSN (seq) != NULL_RTX && NEXT_INSN (NEXT_INSN (seq)) == NULL_RTX && NONJUMP_INSN_P (seq) && GET_CODE (PATTERN (seq)) == SET && SET_DEST (PATTERN (seq)) == reg && ! reg_mentioned_p (reg, SET_SRC (PATTERN (seq))) && NONJUMP_INSN_P (NEXT_INSN (seq)) && GET_CODE (PATTERN (NEXT_INSN (seq))) == SET && SET_DEST (PATTERN (NEXT_INSN (seq))) == reg && memory_address_addr_space_p (GET_MODE (x), SET_SRC (PATTERN (NEXT_INSN (seq))), MEM_ADDR_SPACE (x))) { rtx src1 = SET_SRC (PATTERN (seq)); rtx src2 = SET_SRC (PATTERN (NEXT_INSN (seq))); /* Replace the placeholder in SRC2 with SRC1. If we can find where in SRC2 it was placed, that can become our split point and we can replace this address with SRC2. Just try two obvious places. */ src2 = replace_rtx (src2, reg, src1); split = 0; if (XEXP (src2, 0) == src1) split = &XEXP (src2, 0); else if (GET_RTX_FORMAT (GET_CODE (XEXP (src2, 0)))[0] == 'e' && XEXP (XEXP (src2, 0), 0) == src1) split = &XEXP (XEXP (src2, 0), 0); if (split) { SUBST (XEXP (x, 0), src2); return split; } } /* If that didn't work, perhaps the first operand is complex and needs to be computed separately, so make a split point there. This will occur on machines that just support REG + CONST and have a constant moved through some previous computation. */ else if (!OBJECT_P (XEXP (XEXP (x, 0), 0)) && ! (GET_CODE (XEXP (XEXP (x, 0), 0)) == SUBREG && OBJECT_P (SUBREG_REG (XEXP (XEXP (x, 0), 0))))) return &XEXP (XEXP (x, 0), 0); } /* If we have a PLUS whose first operand is complex, try computing it separately by making a split there. */ if (GET_CODE (XEXP (x, 0)) == PLUS && ! memory_address_addr_space_p (GET_MODE (x), XEXP (x, 0), MEM_ADDR_SPACE (x)) && ! OBJECT_P (XEXP (XEXP (x, 0), 0)) && ! (GET_CODE (XEXP (XEXP (x, 0), 0)) == SUBREG && OBJECT_P (SUBREG_REG (XEXP (XEXP (x, 0), 0))))) return &XEXP (XEXP (x, 0), 0); break; case SET: /* If SET_DEST is CC0 and SET_SRC is not an operand, a COMPARE, or a ZERO_EXTRACT, the most likely reason why this doesn't match is that we need to put the operand into a register. So split at that point. */ if (SET_DEST (x) == cc0_rtx && GET_CODE (SET_SRC (x)) != COMPARE && GET_CODE (SET_SRC (x)) != ZERO_EXTRACT && !OBJECT_P (SET_SRC (x)) && ! (GET_CODE (SET_SRC (x)) == SUBREG && OBJECT_P (SUBREG_REG (SET_SRC (x))))) return &SET_SRC (x); /* See if we can split SET_SRC as it stands. */ split = find_split_point (&SET_SRC (x), insn, true); if (split && split != &SET_SRC (x)) return split; /* See if we can split SET_DEST as it stands. */ split = find_split_point (&SET_DEST (x), insn, false); if (split && split != &SET_DEST (x)) return split; /* See if this is a bitfield assignment with everything constant. If so, this is an IOR of an AND, so split it into that. */ if (GET_CODE (SET_DEST (x)) == ZERO_EXTRACT && HWI_COMPUTABLE_MODE_P (GET_MODE (XEXP (SET_DEST (x), 0))) && CONST_INT_P (XEXP (SET_DEST (x), 1)) && CONST_INT_P (XEXP (SET_DEST (x), 2)) && CONST_INT_P (SET_SRC (x)) && ((INTVAL (XEXP (SET_DEST (x), 1)) + INTVAL (XEXP (SET_DEST (x), 2))) <= GET_MODE_PRECISION (GET_MODE (XEXP (SET_DEST (x), 0)))) && ! side_effects_p (XEXP (SET_DEST (x), 0))) { HOST_WIDE_INT pos = INTVAL (XEXP (SET_DEST (x), 2)); unsigned HOST_WIDE_INT len = INTVAL (XEXP (SET_DEST (x), 1)); unsigned HOST_WIDE_INT src = INTVAL (SET_SRC (x)); rtx dest = XEXP (SET_DEST (x), 0); machine_mode mode = GET_MODE (dest); unsigned HOST_WIDE_INT mask = ((unsigned HOST_WIDE_INT) 1 << len) - 1; rtx or_mask; if (BITS_BIG_ENDIAN) pos = GET_MODE_PRECISION (mode) - len - pos; or_mask = gen_int_mode (src << pos, mode); if (src == mask) SUBST (SET_SRC (x), simplify_gen_binary (IOR, mode, dest, or_mask)); else { rtx negmask = gen_int_mode (~(mask << pos), mode); SUBST (SET_SRC (x), simplify_gen_binary (IOR, mode, simplify_gen_binary (AND, mode, dest, negmask), or_mask)); } SUBST (SET_DEST (x), dest); split = find_split_point (&SET_SRC (x), insn, true); if (split && split != &SET_SRC (x)) return split; } /* Otherwise, see if this is an operation that we can split into two. If so, try to split that. */ code = GET_CODE (SET_SRC (x)); switch (code) { case AND: /* If we are AND'ing with a large constant that is only a single bit and the result is only being used in a context where we need to know if it is zero or nonzero, replace it with a bit extraction. This will avoid the large constant, which might have taken more than one insn to make. If the constant were not a valid argument to the AND but took only one insn to make, this is no worse, but if it took more than one insn, it will be better. */ if (CONST_INT_P (XEXP (SET_SRC (x), 1)) && REG_P (XEXP (SET_SRC (x), 0)) && (pos = exact_log2 (UINTVAL (XEXP (SET_SRC (x), 1)))) >= 7 && REG_P (SET_DEST (x)) && (split = find_single_use (SET_DEST (x), insn, NULL)) != 0 && (GET_CODE (*split) == EQ || GET_CODE (*split) == NE) && XEXP (*split, 0) == SET_DEST (x) && XEXP (*split, 1) == const0_rtx) { rtx extraction = make_extraction (GET_MODE (SET_DEST (x)), XEXP (SET_SRC (x), 0), pos, NULL_RTX, 1, 1, 0, 0); if (extraction != 0) { SUBST (SET_SRC (x), extraction); return find_split_point (loc, insn, false); } } break; case NE: /* If STORE_FLAG_VALUE is -1, this is (NE X 0) and only one bit of X is known to be on, this can be converted into a NEG of a shift. */ if (STORE_FLAG_VALUE == -1 && XEXP (SET_SRC (x), 1) == const0_rtx && GET_MODE (SET_SRC (x)) == GET_MODE (XEXP (SET_SRC (x), 0)) && 1 <= (pos = exact_log2 (nonzero_bits (XEXP (SET_SRC (x), 0), GET_MODE (XEXP (SET_SRC (x), 0)))))) { machine_mode mode = GET_MODE (XEXP (SET_SRC (x), 0)); SUBST (SET_SRC (x), gen_rtx_NEG (mode, gen_rtx_LSHIFTRT (mode, XEXP (SET_SRC (x), 0), GEN_INT (pos)))); split = find_split_point (&SET_SRC (x), insn, true); if (split && split != &SET_SRC (x)) return split; } break; case SIGN_EXTEND: inner = XEXP (SET_SRC (x), 0); /* We can't optimize if either mode is a partial integer mode as we don't know how many bits are significant in those modes. */ if (GET_MODE_CLASS (GET_MODE (inner)) == MODE_PARTIAL_INT || GET_MODE_CLASS (GET_MODE (SET_SRC (x))) == MODE_PARTIAL_INT) break; pos = 0; len = GET_MODE_PRECISION (GET_MODE (inner)); unsignedp = 0; break; case SIGN_EXTRACT: case ZERO_EXTRACT: if (CONST_INT_P (XEXP (SET_SRC (x), 1)) && CONST_INT_P (XEXP (SET_SRC (x), 2))) { inner = XEXP (SET_SRC (x), 0); len = INTVAL (XEXP (SET_SRC (x), 1)); pos = INTVAL (XEXP (SET_SRC (x), 2)); if (BITS_BIG_ENDIAN) pos = GET_MODE_PRECISION (GET_MODE (inner)) - len - pos; unsignedp = (code == ZERO_EXTRACT); } break; default: break; } if (len && pos >= 0 && pos + len <= GET_MODE_PRECISION (GET_MODE (inner))) { machine_mode mode = GET_MODE (SET_SRC (x)); /* For unsigned, we have a choice of a shift followed by an AND or two shifts. Use two shifts for field sizes where the constant might be too large. We assume here that we can always at least get 8-bit constants in an AND insn, which is true for every current RISC. */ if (unsignedp && len <= 8) { unsigned HOST_WIDE_INT mask = ((unsigned HOST_WIDE_INT) 1 << len) - 1; SUBST (SET_SRC (x), gen_rtx_AND (mode, gen_rtx_LSHIFTRT (mode, gen_lowpart (mode, inner), GEN_INT (pos)), gen_int_mode (mask, mode))); split = find_split_point (&SET_SRC (x), insn, true); if (split && split != &SET_SRC (x)) return split; } else { SUBST (SET_SRC (x), gen_rtx_fmt_ee (unsignedp ? LSHIFTRT : ASHIFTRT, mode, gen_rtx_ASHIFT (mode, gen_lowpart (mode, inner), GEN_INT (GET_MODE_PRECISION (mode) - len - pos)), GEN_INT (GET_MODE_PRECISION (mode) - len))); split = find_split_point (&SET_SRC (x), insn, true); if (split && split != &SET_SRC (x)) return split; } } /* See if this is a simple operation with a constant as the second operand. It might be that this constant is out of range and hence could be used as a split point. */ if (BINARY_P (SET_SRC (x)) && CONSTANT_P (XEXP (SET_SRC (x), 1)) && (OBJECT_P (XEXP (SET_SRC (x), 0)) || (GET_CODE (XEXP (SET_SRC (x), 0)) == SUBREG && OBJECT_P (SUBREG_REG (XEXP (SET_SRC (x), 0)))))) return &XEXP (SET_SRC (x), 1); /* Finally, see if this is a simple operation with its first operand not in a register. The operation might require this operand in a register, so return it as a split point. We can always do this because if the first operand were another operation, we would have already found it as a split point. */ if ((BINARY_P (SET_SRC (x)) || UNARY_P (SET_SRC (x))) && ! register_operand (XEXP (SET_SRC (x), 0), VOIDmode)) return &XEXP (SET_SRC (x), 0); return 0; case AND: case IOR: /* We write NOR as (and (not A) (not B)), but if we don't have a NOR, it is better to write this as (not (ior A B)) so we can split it. Similarly for IOR. */ if (GET_CODE (XEXP (x, 0)) == NOT && GET_CODE (XEXP (x, 1)) == NOT) { SUBST (*loc, gen_rtx_NOT (GET_MODE (x), gen_rtx_fmt_ee (code == IOR ? AND : IOR, GET_MODE (x), XEXP (XEXP (x, 0), 0), XEXP (XEXP (x, 1), 0)))); return find_split_point (loc, insn, set_src); } /* Many RISC machines have a large set of logical insns. If the second operand is a NOT, put it first so we will try to split the other operand first. */ if (GET_CODE (XEXP (x, 1)) == NOT) { rtx tem = XEXP (x, 0); SUBST (XEXP (x, 0), XEXP (x, 1)); SUBST (XEXP (x, 1), tem); } break; case PLUS: case MINUS: /* Canonicalization can produce (minus A (mult B C)), where C is a constant. It may be better to try splitting (plus (mult B -C) A) instead if this isn't a multiply by a power of two. */ if (set_src && code == MINUS && GET_CODE (XEXP (x, 1)) == MULT && GET_CODE (XEXP (XEXP (x, 1), 1)) == CONST_INT && exact_log2 (INTVAL (XEXP (XEXP (x, 1), 1))) < 0) { machine_mode mode = GET_MODE (x); unsigned HOST_WIDE_INT this_int = INTVAL (XEXP (XEXP (x, 1), 1)); HOST_WIDE_INT other_int = trunc_int_for_mode (-this_int, mode); SUBST (*loc, gen_rtx_PLUS (mode, gen_rtx_MULT (mode, XEXP (XEXP (x, 1), 0), gen_int_mode (other_int, mode)), XEXP (x, 0))); return find_split_point (loc, insn, set_src); } /* Split at a multiply-accumulate instruction. However if this is the SET_SRC, we likely do not have such an instruction and it's worthless to try this split. */ if (!set_src && (GET_CODE (XEXP (x, 0)) == MULT || (GET_CODE (XEXP (x, 0)) == ASHIFT && GET_CODE (XEXP (XEXP (x, 0), 1)) == CONST_INT))) return loc; default: break; } /* Otherwise, select our actions depending on our rtx class. */ switch (GET_RTX_CLASS (code)) { case RTX_BITFIELD_OPS: /* This is ZERO_EXTRACT and SIGN_EXTRACT. */ case RTX_TERNARY: split = find_split_point (&XEXP (x, 2), insn, false); if (split) return split; /* ... fall through ... */ case RTX_BIN_ARITH: case RTX_COMM_ARITH: case RTX_COMPARE: case RTX_COMM_COMPARE: split = find_split_point (&XEXP (x, 1), insn, false); if (split) return split; /* ... fall through ... */ case RTX_UNARY: /* Some machines have (and (shift ...) ...) insns. If X is not an AND, but XEXP (X, 0) is, use it as our split point. */ if (GET_CODE (x) != AND && GET_CODE (XEXP (x, 0)) == AND) return &XEXP (x, 0); split = find_split_point (&XEXP (x, 0), insn, false); if (split) return split; return loc; default: /* Otherwise, we don't have a split point. */ return 0; } } /* Throughout X, replace FROM with TO, and return the result. The result is TO if X is FROM; otherwise the result is X, but its contents may have been modified. If they were modified, a record was made in undobuf so that undo_all will (among other things) return X to its original state. If the number of changes necessary is too much to record to undo, the excess changes are not made, so the result is invalid. The changes already made can still be undone. undobuf.num_undo is incremented for such changes, so by testing that the caller can tell whether the result is valid. `n_occurrences' is incremented each time FROM is replaced. IN_DEST is nonzero if we are processing the SET_DEST of a SET. IN_COND is nonzero if we are at the top level of a condition. UNIQUE_COPY is nonzero if each substitution must be unique. We do this by copying if `n_occurrences' is nonzero. */ static rtx subst (rtx x, rtx from, rtx to, int in_dest, int in_cond, int unique_copy) { enum rtx_code code = GET_CODE (x); machine_mode op0_mode = VOIDmode; const char *fmt; int len, i; rtx new_rtx; /* Two expressions are equal if they are identical copies of a shared RTX or if they are both registers with the same register number and mode. */ #define COMBINE_RTX_EQUAL_P(X,Y) \ ((X) == (Y) \ || (REG_P (X) && REG_P (Y) \ && REGNO (X) == REGNO (Y) && GET_MODE (X) == GET_MODE (Y))) /* Do not substitute into clobbers of regs -- this will never result in valid RTL. */ if (GET_CODE (x) == CLOBBER && REG_P (XEXP (x, 0))) return x; if (! in_dest && COMBINE_RTX_EQUAL_P (x, from)) { n_occurrences++; return (unique_copy && n_occurrences > 1 ? copy_rtx (to) : to); } /* If X and FROM are the same register but different modes, they will not have been seen as equal above. However, the log links code will make a LOG_LINKS entry for that case. If we do nothing, we will try to rerecognize our original insn and, when it succeeds, we will delete the feeding insn, which is incorrect. So force this insn not to match in this (rare) case. */ if (! in_dest && code == REG && REG_P (from) && reg_overlap_mentioned_p (x, from)) return gen_rtx_CLOBBER (GET_MODE (x), const0_rtx); /* If this is an object, we are done unless it is a MEM or LO_SUM, both of which may contain things that can be combined. */ if (code != MEM && code != LO_SUM && OBJECT_P (x)) return x; /* It is possible to have a subexpression appear twice in the insn. Suppose that FROM is a register that appears within TO. Then, after that subexpression has been scanned once by `subst', the second time it is scanned, TO may be found. If we were to scan TO here, we would find FROM within it and create a self-referent rtl structure which is completely wrong. */ if (COMBINE_RTX_EQUAL_P (x, to)) return to; /* Parallel asm_operands need special attention because all of the inputs are shared across the arms. Furthermore, unsharing the rtl results in recognition failures. Failure to handle this case specially can result in circular rtl. Solve this by doing a normal pass across the first entry of the parallel, and only processing the SET_DESTs of the subsequent entries. Ug. */ if (code == PARALLEL && GET_CODE (XVECEXP (x, 0, 0)) == SET && GET_CODE (SET_SRC (XVECEXP (x, 0, 0))) == ASM_OPERANDS) { new_rtx = subst (XVECEXP (x, 0, 0), from, to, 0, 0, unique_copy); /* If this substitution failed, this whole thing fails. */ if (GET_CODE (new_rtx) == CLOBBER && XEXP (new_rtx, 0) == const0_rtx) return new_rtx; SUBST (XVECEXP (x, 0, 0), new_rtx); for (i = XVECLEN (x, 0) - 1; i >= 1; i--) { rtx dest = SET_DEST (XVECEXP (x, 0, i)); if (!REG_P (dest) && GET_CODE (dest) != CC0 && GET_CODE (dest) != PC) { new_rtx = subst (dest, from, to, 0, 0, unique_copy); /* If this substitution failed, this whole thing fails. */ if (GET_CODE (new_rtx) == CLOBBER && XEXP (new_rtx, 0) == const0_rtx) return new_rtx; SUBST (SET_DEST (XVECEXP (x, 0, i)), new_rtx); } } } else { len = GET_RTX_LENGTH (code); fmt = GET_RTX_FORMAT (code); /* We don't need to process a SET_DEST that is a register, CC0, or PC, so set up to skip this common case. All other cases where we want to suppress replacing something inside a SET_SRC are handled via the IN_DEST operand. */ if (code == SET && (REG_P (SET_DEST (x)) || GET_CODE (SET_DEST (x)) == CC0 || GET_CODE (SET_DEST (x)) == PC)) fmt = "ie"; /* Trying to simplify the operands of a widening MULT is not likely to create RTL matching a machine insn. */ if (code == MULT && (GET_CODE (XEXP (x, 0)) == ZERO_EXTEND || GET_CODE (XEXP (x, 0)) == SIGN_EXTEND) && (GET_CODE (XEXP (x, 1)) == ZERO_EXTEND || GET_CODE (XEXP (x, 1)) == SIGN_EXTEND) && REG_P (XEXP (XEXP (x, 0), 0)) && REG_P (XEXP (XEXP (x, 1), 0)) && from == to) return x; /* Get the mode of operand 0 in case X is now a SIGN_EXTEND of a constant. */ if (fmt[0] == 'e') op0_mode = GET_MODE (XEXP (x, 0)); for (i = 0; i < len; i++) { if (fmt[i] == 'E') { int j; for (j = XVECLEN (x, i) - 1; j >= 0; j--) { if (COMBINE_RTX_EQUAL_P (XVECEXP (x, i, j), from)) { new_rtx = (unique_copy && n_occurrences ? copy_rtx (to) : to); n_occurrences++; } else { new_rtx = subst (XVECEXP (x, i, j), from, to, 0, 0, unique_copy); /* If this substitution failed, this whole thing fails. */ if (GET_CODE (new_rtx) == CLOBBER && XEXP (new_rtx, 0) == const0_rtx) return new_rtx; } SUBST (XVECEXP (x, i, j), new_rtx); } } else if (fmt[i] == 'e') { /* If this is a register being set, ignore it. */ new_rtx = XEXP (x, i); if (in_dest && i == 0 && (((code == SUBREG || code == ZERO_EXTRACT) && REG_P (new_rtx)) || code == STRICT_LOW_PART)) ; else if (COMBINE_RTX_EQUAL_P (XEXP (x, i), from)) { /* In general, don't install a subreg involving two modes not tieable. It can worsen register allocation, and can even make invalid reload insns, since the reg inside may need to be copied from in the outside mode, and that may be invalid if it is an fp reg copied in integer mode. We allow two exceptions to this: It is valid if it is inside another SUBREG and the mode of that SUBREG and the mode of the inside of TO is tieable and it is valid if X is a SET that copies FROM to CC0. */ if (GET_CODE (to) == SUBREG && ! MODES_TIEABLE_P (GET_MODE (to), GET_MODE (SUBREG_REG (to))) && ! (code == SUBREG && MODES_TIEABLE_P (GET_MODE (x), GET_MODE (SUBREG_REG (to)))) && (!HAVE_cc0 || (! (code == SET && i == 1 && XEXP (x, 0) == cc0_rtx)))) return gen_rtx_CLOBBER (VOIDmode, const0_rtx); if (code == SUBREG && REG_P (to) && REGNO (to) < FIRST_PSEUDO_REGISTER && simplify_subreg_regno (REGNO (to), GET_MODE (to), SUBREG_BYTE (x), GET_MODE (x)) < 0) return gen_rtx_CLOBBER (VOIDmode, const0_rtx); new_rtx = (unique_copy && n_occurrences ? copy_rtx (to) : to); n_occurrences++; } else /* If we are in a SET_DEST, suppress most cases unless we have gone inside a MEM, in which case we want to simplify the address. We assume here that things that are actually part of the destination have their inner parts in the first expression. This is true for SUBREG, STRICT_LOW_PART, and ZERO_EXTRACT, which are the only things aside from REG and MEM that should appear in a SET_DEST. */ new_rtx = subst (XEXP (x, i), from, to, (((in_dest && (code == SUBREG || code == STRICT_LOW_PART || code == ZERO_EXTRACT)) || code == SET) && i == 0), code == IF_THEN_ELSE && i == 0, unique_copy); /* If we found that we will have to reject this combination, indicate that by returning the CLOBBER ourselves, rather than an expression containing it. This will speed things up as well as prevent accidents where two CLOBBERs are considered to be equal, thus producing an incorrect simplification. */ if (GET_CODE (new_rtx) == CLOBBER && XEXP (new_rtx, 0) == const0_rtx) return new_rtx; if (GET_CODE (x) == SUBREG && CONST_SCALAR_INT_P (new_rtx)) { machine_mode mode = GET_MODE (x); x = simplify_subreg (GET_MODE (x), new_rtx, GET_MODE (SUBREG_REG (x)), SUBREG_BYTE (x)); if (! x) x = gen_rtx_CLOBBER (mode, const0_rtx); } else if (CONST_SCALAR_INT_P (new_rtx) && GET_CODE (x) == ZERO_EXTEND) { x = simplify_unary_operation (ZERO_EXTEND, GET_MODE (x), new_rtx, GET_MODE (XEXP (x, 0))); gcc_assert (x); } else SUBST (XEXP (x, i), new_rtx); } } } /* Check if we are loading something from the constant pool via float extension; in this case we would undo compress_float_constant optimization and degenerate constant load to an immediate value. */ if (GET_CODE (x) == FLOAT_EXTEND && MEM_P (XEXP (x, 0)) && MEM_READONLY_P (XEXP (x, 0))) { rtx tmp = avoid_constant_pool_reference (x); if (x != tmp) return x; } /* Try to simplify X. If the simplification changed the code, it is likely that further simplification will help, so loop, but limit the number of repetitions that will be performed. */ for (i = 0; i < 4; i++) { /* If X is sufficiently simple, don't bother trying to do anything with it. */ if (code != CONST_INT && code != REG && code != CLOBBER) x = combine_simplify_rtx (x, op0_mode, in_dest, in_cond); if (GET_CODE (x) == code) break; code = GET_CODE (x); /* We no longer know the original mode of operand 0 since we have changed the form of X) */ op0_mode = VOIDmode; } return x; } /* Simplify X, a piece of RTL. We just operate on the expression at the outer level; call `subst' to simplify recursively. Return the new expression. OP0_MODE is the original mode of XEXP (x, 0). IN_DEST is nonzero if we are inside a SET_DEST. IN_COND is nonzero if we are at the top level of a condition. */ static rtx combine_simplify_rtx (rtx x, machine_mode op0_mode, int in_dest, int in_cond) { enum rtx_code code = GET_CODE (x); machine_mode mode = GET_MODE (x); rtx temp; int i; /* If this is a commutative operation, put a constant last and a complex expression first. We don't need to do this for comparisons here. */ if (COMMUTATIVE_ARITH_P (x) && swap_commutative_operands_p (XEXP (x, 0), XEXP (x, 1))) { temp = XEXP (x, 0); SUBST (XEXP (x, 0), XEXP (x, 1)); SUBST (XEXP (x, 1), temp); } /* Try to fold this expression in case we have constants that weren't present before. */ temp = 0; switch (GET_RTX_CLASS (code)) { case RTX_UNARY: if (op0_mode == VOIDmode) op0_mode = GET_MODE (XEXP (x, 0)); temp = simplify_unary_operation (code, mode, XEXP (x, 0), op0_mode); break; case RTX_COMPARE: case RTX_COMM_COMPARE: { machine_mode cmp_mode = GET_MODE (XEXP (x, 0)); if (cmp_mode == VOIDmode) { cmp_mode = GET_MODE (XEXP (x, 1)); if (cmp_mode == VOIDmode) cmp_mode = op0_mode; } temp = simplify_relational_operation (code, mode, cmp_mode, XEXP (x, 0), XEXP (x, 1)); } break; case RTX_COMM_ARITH: case RTX_BIN_ARITH: temp = simplify_binary_operation (code, mode, XEXP (x, 0), XEXP (x, 1)); break; case RTX_BITFIELD_OPS: case RTX_TERNARY: temp = simplify_ternary_operation (code, mode, op0_mode, XEXP (x, 0), XEXP (x, 1), XEXP (x, 2)); break; default: break; } if (temp) { x = temp; code = GET_CODE (temp); op0_mode = VOIDmode; mode = GET_MODE (temp); } /* If this is a simple operation applied to an IF_THEN_ELSE, try applying it to the arms of the IF_THEN_ELSE. This often simplifies things. Check for cases where both arms are testing the same condition. Don't do anything if all operands are very simple. */ if ((BINARY_P (x) && ((!OBJECT_P (XEXP (x, 0)) && ! (GET_CODE (XEXP (x, 0)) == SUBREG && OBJECT_P (SUBREG_REG (XEXP (x, 0))))) || (!OBJECT_P (XEXP (x, 1)) && ! (GET_CODE (XEXP (x, 1)) == SUBREG && OBJECT_P (SUBREG_REG (XEXP (x, 1))))))) || (UNARY_P (x) && (!OBJECT_P (XEXP (x, 0)) && ! (GET_CODE (XEXP (x, 0)) == SUBREG && OBJECT_P (SUBREG_REG (XEXP (x, 0))))))) { rtx cond, true_rtx, false_rtx; cond = if_then_else_cond (x, &true_rtx, &false_rtx); if (cond != 0 /* If everything is a comparison, what we have is highly unlikely to be simpler, so don't use it. */ && ! (COMPARISON_P (x) && (COMPARISON_P (true_rtx) || COMPARISON_P (false_rtx)))) { rtx cop1 = const0_rtx; enum rtx_code cond_code = simplify_comparison (NE, &cond, &cop1); if (cond_code == NE && COMPARISON_P (cond)) return x; /* Simplify the alternative arms; this may collapse the true and false arms to store-flag values. Be careful to use copy_rtx here since true_rtx or false_rtx might share RTL with x as a result of the if_then_else_cond call above. */ true_rtx = subst (copy_rtx (true_rtx), pc_rtx, pc_rtx, 0, 0, 0); false_rtx = subst (copy_rtx (false_rtx), pc_rtx, pc_rtx, 0, 0, 0); /* If true_rtx and false_rtx are not general_operands, an if_then_else is unlikely to be simpler. */ if (general_operand (true_rtx, VOIDmode) && general_operand (false_rtx, VOIDmode)) { enum rtx_code reversed; /* Restarting if we generate a store-flag expression will cause us to loop. Just drop through in this case. */ /* If the result values are STORE_FLAG_VALUE and zero, we can just make the comparison operation. */ if (true_rtx == const_true_rtx && false_rtx == const0_rtx) x = simplify_gen_relational (cond_code, mode, VOIDmode, cond, cop1); else if (true_rtx == const0_rtx && false_rtx == const_true_rtx && ((reversed = reversed_comparison_code_parts (cond_code, cond, cop1, NULL)) != UNKNOWN)) x = simplify_gen_relational (reversed, mode, VOIDmode, cond, cop1); /* Likewise, we can make the negate of a comparison operation if the result values are - STORE_FLAG_VALUE and zero. */ else if (CONST_INT_P (true_rtx) && INTVAL (true_rtx) == - STORE_FLAG_VALUE && false_rtx == const0_rtx) x = simplify_gen_unary (NEG, mode, simplify_gen_relational (cond_code, mode, VOIDmode, cond, cop1), mode); else if (CONST_INT_P (false_rtx) && INTVAL (false_rtx) == - STORE_FLAG_VALUE && true_rtx == const0_rtx && ((reversed = reversed_comparison_code_parts (cond_code, cond, cop1, NULL)) != UNKNOWN)) x = simplify_gen_unary (NEG, mode, simplify_gen_relational (reversed, mode, VOIDmode, cond, cop1), mode); else return gen_rtx_IF_THEN_ELSE (mode, simplify_gen_relational (cond_code, mode, VOIDmode, cond, cop1), true_rtx, false_rtx); code = GET_CODE (x); op0_mode = VOIDmode; } } } /* First see if we can apply the inverse distributive law. */ if (code == PLUS || code == MINUS || code == AND || code == IOR || code == XOR) { x = apply_distributive_law (x); code = GET_CODE (x); op0_mode = VOIDmode; } /* If CODE is an associative operation not otherwise handled, see if we can associate some operands. This can win if they are constants or if they are logically related (i.e. (a & b) & a). */ if ((code == PLUS || code == MINUS || code == MULT || code == DIV || code == AND || code == IOR || code == XOR || code == SMAX || code == SMIN || code == UMAX || code == UMIN) && ((INTEGRAL_MODE_P (mode) && code != DIV) || (flag_associative_math && FLOAT_MODE_P (mode)))) { if (GET_CODE (XEXP (x, 0)) == code) { rtx other = XEXP (XEXP (x, 0), 0); rtx inner_op0 = XEXP (XEXP (x, 0), 1); rtx inner_op1 = XEXP (x, 1); rtx inner; /* Make sure we pass the constant operand if any as the second one if this is a commutative operation. */ if (CONSTANT_P (inner_op0) && COMMUTATIVE_ARITH_P (x)) std::swap (inner_op0, inner_op1); inner = simplify_binary_operation (code == MINUS ? PLUS : code == DIV ? MULT : code, mode, inner_op0, inner_op1); /* For commutative operations, try the other pair if that one didn't simplify. */ if (inner == 0 && COMMUTATIVE_ARITH_P (x)) { other = XEXP (XEXP (x, 0), 1); inner = simplify_binary_operation (code, mode, XEXP (XEXP (x, 0), 0), XEXP (x, 1)); } if (inner) return simplify_gen_binary (code, mode, other, inner); } } /* A little bit of algebraic simplification here. */ switch (code) { case MEM: /* Ensure that our address has any ASHIFTs converted to MULT in case address-recognizing predicates are called later. */ temp = make_compound_operation (XEXP (x, 0), MEM); SUBST (XEXP (x, 0), temp); break; case SUBREG: if (op0_mode == VOIDmode) op0_mode = GET_MODE (SUBREG_REG (x)); /* See if this can be moved to simplify_subreg. */ if (CONSTANT_P (SUBREG_REG (x)) && subreg_lowpart_offset (mode, op0_mode) == SUBREG_BYTE (x) /* Don't call gen_lowpart if the inner mode is VOIDmode and we cannot simplify it, as SUBREG without inner mode is invalid. */ && (GET_MODE (SUBREG_REG (x)) != VOIDmode || gen_lowpart_common (mode, SUBREG_REG (x)))) return gen_lowpart (mode, SUBREG_REG (x)); if (GET_MODE_CLASS (GET_MODE (SUBREG_REG (x))) == MODE_CC) break; { rtx temp; temp = simplify_subreg (mode, SUBREG_REG (x), op0_mode, SUBREG_BYTE (x)); if (temp) return temp; /* If op is known to have all lower bits zero, the result is zero. */ if (!in_dest && SCALAR_INT_MODE_P (mode) && SCALAR_INT_MODE_P (op0_mode) && GET_MODE_PRECISION (mode) < GET_MODE_PRECISION (op0_mode) && subreg_lowpart_offset (mode, op0_mode) == SUBREG_BYTE (x) && HWI_COMPUTABLE_MODE_P (op0_mode) && (nonzero_bits (SUBREG_REG (x), op0_mode) & GET_MODE_MASK (mode)) == 0) return CONST0_RTX (mode); } /* Don't change the mode of the MEM if that would change the meaning of the address. */ if (MEM_P (SUBREG_REG (x)) && (MEM_VOLATILE_P (SUBREG_REG (x)) || mode_dependent_address_p (XEXP (SUBREG_REG (x), 0), MEM_ADDR_SPACE (SUBREG_REG (x))))) return gen_rtx_CLOBBER (mode, const0_rtx); /* Note that we cannot do any narrowing for non-constants since we might have been counting on using the fact that some bits were zero. We now do this in the SET. */ break; case NEG: temp = expand_compound_operation (XEXP (x, 0)); /* For C equal to the width of MODE minus 1, (neg (ashiftrt X C)) can be replaced by (lshiftrt X C). This will convert (neg (sign_extract X 1 Y)) to (zero_extract X 1 Y). */ if (GET_CODE (temp) == ASHIFTRT && CONST_INT_P (XEXP (temp, 1)) && INTVAL (XEXP (temp, 1)) == GET_MODE_PRECISION (mode) - 1) return simplify_shift_const (NULL_RTX, LSHIFTRT, mode, XEXP (temp, 0), INTVAL (XEXP (temp, 1))); /* If X has only a single bit that might be nonzero, say, bit I, convert (neg X) to (ashiftrt (ashift X C-I) C-I) where C is the bitsize of MODE minus 1. This will convert (neg (zero_extract X 1 Y)) to (sign_extract X 1 Y). But only do this if TEMP isn't a register or a SUBREG of one since we'd be making the expression more complex if it was just a register. */ if (!REG_P (temp) && ! (GET_CODE (temp) == SUBREG && REG_P (SUBREG_REG (temp))) && (i = exact_log2 (nonzero_bits (temp, mode))) >= 0) { rtx temp1 = simplify_shift_const (NULL_RTX, ASHIFTRT, mode, simplify_shift_const (NULL_RTX, ASHIFT, mode, temp, GET_MODE_PRECISION (mode) - 1 - i), GET_MODE_PRECISION (mode) - 1 - i); /* If all we did was surround TEMP with the two shifts, we haven't improved anything, so don't use it. Otherwise, we are better off with TEMP1. */ if (GET_CODE (temp1) != ASHIFTRT || GET_CODE (XEXP (temp1, 0)) != ASHIFT || XEXP (XEXP (temp1, 0), 0) != temp) return temp1; } break; case TRUNCATE: /* We can't handle truncation to a partial integer mode here because we don't know the real bitsize of the partial integer mode. */ if (GET_MODE_CLASS (mode) == MODE_PARTIAL_INT) break; if (HWI_COMPUTABLE_MODE_P (mode)) SUBST (XEXP (x, 0), force_to_mode (XEXP (x, 0), GET_MODE (XEXP (x, 0)), GET_MODE_MASK (mode), 0)); /* We can truncate a constant value and return it. */ if (CONST_INT_P (XEXP (x, 0))) return gen_int_mode (INTVAL (XEXP (x, 0)), mode); /* Similarly to what we do in simplify-rtx.c, a truncate of a register whose value is a comparison can be replaced with a subreg if STORE_FLAG_VALUE permits. */ if (HWI_COMPUTABLE_MODE_P (mode) && (STORE_FLAG_VALUE & ~GET_MODE_MASK (mode)) == 0 && (temp = get_last_value (XEXP (x, 0))) && COMPARISON_P (temp)) return gen_lowpart (mode, XEXP (x, 0)); break; case CONST: /* (const (const X)) can become (const X). Do it this way rather than returning the inner CONST since CONST can be shared with a REG_EQUAL note. */ if (GET_CODE (XEXP (x, 0)) == CONST) SUBST (XEXP (x, 0), XEXP (XEXP (x, 0), 0)); break; case LO_SUM: /* Convert (lo_sum (high FOO) FOO) to FOO. This is necessary so we can add in an offset. find_split_point will split this address up again if it doesn't match. */ if (HAVE_lo_sum && GET_CODE (XEXP (x, 0)) == HIGH && rtx_equal_p (XEXP (XEXP (x, 0), 0), XEXP (x, 1))) return XEXP (x, 1); break; case PLUS: /* (plus (xor (and (const_int pow2 - 1)) ) <-c>) when c is (const_int (pow2 + 1) / 2) is a sign extension of a bit-field and can be replaced by either a sign_extend or a sign_extract. The `and' may be a zero_extend and the two , - constants may be reversed. */ if (GET_CODE (XEXP (x, 0)) == XOR && CONST_INT_P (XEXP (x, 1)) && CONST_INT_P (XEXP (XEXP (x, 0), 1)) && INTVAL (XEXP (x, 1)) == -INTVAL (XEXP (XEXP (x, 0), 1)) && ((i = exact_log2 (UINTVAL (XEXP (XEXP (x, 0), 1)))) >= 0 || (i = exact_log2 (UINTVAL (XEXP (x, 1)))) >= 0) && HWI_COMPUTABLE_MODE_P (mode) && ((GET_CODE (XEXP (XEXP (x, 0), 0)) == AND && CONST_INT_P (XEXP (XEXP (XEXP (x, 0), 0), 1)) && (UINTVAL (XEXP (XEXP (XEXP (x, 0), 0), 1)) == ((unsigned HOST_WIDE_INT) 1 << (i + 1)) - 1)) || (GET_CODE (XEXP (XEXP (x, 0), 0)) == ZERO_EXTEND && (GET_MODE_PRECISION (GET_MODE (XEXP (XEXP (XEXP (x, 0), 0), 0))) == (unsigned int) i + 1)))) return simplify_shift_const (NULL_RTX, ASHIFTRT, mode, simplify_shift_const (NULL_RTX, ASHIFT, mode, XEXP (XEXP (XEXP (x, 0), 0), 0), GET_MODE_PRECISION (mode) - (i + 1)), GET_MODE_PRECISION (mode) - (i + 1)); /* If only the low-order bit of X is possibly nonzero, (plus x -1) can become (ashiftrt (ashift (xor x 1) C) C) where C is the bitsize of the mode - 1. This allows simplification of "a = (b & 8) == 0;" */ if (XEXP (x, 1) == constm1_rtx && !REG_P (XEXP (x, 0)) && ! (GET_CODE (XEXP (x, 0)) == SUBREG && REG_P (SUBREG_REG (XEXP (x, 0)))) && nonzero_bits (XEXP (x, 0), mode) == 1) return simplify_shift_const (NULL_RTX, ASHIFTRT, mode, simplify_shift_const (NULL_RTX, ASHIFT, mode, gen_rtx_XOR (mode, XEXP (x, 0), const1_rtx), GET_MODE_PRECISION (mode) - 1), GET_MODE_PRECISION (mode) - 1); /* If we are adding two things that have no bits in common, convert the addition into an IOR. This will often be further simplified, for example in cases like ((a & 1) + (a & 2)), which can become a & 3. */ if (HWI_COMPUTABLE_MODE_P (mode) && (nonzero_bits (XEXP (x, 0), mode) & nonzero_bits (XEXP (x, 1), mode)) == 0) { /* Try to simplify the expression further. */ rtx tor = simplify_gen_binary (IOR, mode, XEXP (x, 0), XEXP (x, 1)); temp = combine_simplify_rtx (tor, VOIDmode, in_dest, 0); /* If we could, great. If not, do not go ahead with the IOR replacement, since PLUS appears in many special purpose address arithmetic instructions. */ if (GET_CODE (temp) != CLOBBER && (GET_CODE (temp) != IOR || ((XEXP (temp, 0) != XEXP (x, 0) || XEXP (temp, 1) != XEXP (x, 1)) && (XEXP (temp, 0) != XEXP (x, 1) || XEXP (temp, 1) != XEXP (x, 0))))) return temp; } break; case MINUS: /* (minus (and (const_int -pow2))) becomes (and (const_int pow2-1)) */ if (GET_CODE (XEXP (x, 1)) == AND && CONST_INT_P (XEXP (XEXP (x, 1), 1)) && exact_log2 (-UINTVAL (XEXP (XEXP (x, 1), 1))) >= 0 && rtx_equal_p (XEXP (XEXP (x, 1), 0), XEXP (x, 0))) return simplify_and_const_int (NULL_RTX, mode, XEXP (x, 0), -INTVAL (XEXP (XEXP (x, 1), 1)) - 1); break; case MULT: /* If we have (mult (plus A B) C), apply the distributive law and then the inverse distributive law to see if things simplify. This occurs mostly in addresses, often when unrolling loops. */ if (GET_CODE (XEXP (x, 0)) == PLUS) { rtx result = distribute_and_simplify_rtx (x, 0); if (result) return result; } /* Try simplify a*(b/c) as (a*b)/c. */ if (FLOAT_MODE_P (mode) && flag_associative_math && GET_CODE (XEXP (x, 0)) == DIV) { rtx tem = simplify_binary_operation (MULT, mode, XEXP (XEXP (x, 0), 0), XEXP (x, 1)); if (tem) return simplify_gen_binary (DIV, mode, tem, XEXP (XEXP (x, 0), 1)); } break; case UDIV: /* If this is a divide by a power of two, treat it as a shift if its first operand is a shift. */ if (CONST_INT_P (XEXP (x, 1)) && (i = exact_log2 (UINTVAL (XEXP (x, 1)))) >= 0 && (GET_CODE (XEXP (x, 0)) == ASHIFT || GET_CODE (XEXP (x, 0)) == LSHIFTRT || GET_CODE (XEXP (x, 0)) == ASHIFTRT || GET_CODE (XEXP (x, 0)) == ROTATE || GET_CODE (XEXP (x, 0)) == ROTATERT)) return simplify_shift_const (NULL_RTX, LSHIFTRT, mode, XEXP (x, 0), i); break; case EQ: case NE: case GT: case GTU: case GE: case GEU: case LT: case LTU: case LE: case LEU: case UNEQ: case LTGT: case UNGT: case UNGE: case UNLT: case UNLE: case UNORDERED: case ORDERED: /* If the first operand is a condition code, we can't do anything with it. */ if (GET_CODE (XEXP (x, 0)) == COMPARE || (GET_MODE_CLASS (GET_MODE (XEXP (x, 0))) != MODE_CC && ! CC0_P (XEXP (x, 0)))) { rtx op0 = XEXP (x, 0); rtx op1 = XEXP (x, 1); enum rtx_code new_code; if (GET_CODE (op0) == COMPARE) op1 = XEXP (op0, 1), op0 = XEXP (op0, 0); /* Simplify our comparison, if possible. */ new_code = simplify_comparison (code, &op0, &op1); /* If STORE_FLAG_VALUE is 1, we can convert (ne x 0) to simply X if only the low-order bit is possibly nonzero in X (such as when X is a ZERO_EXTRACT of one bit). Similarly, we can convert EQ to (xor X 1) or (minus 1 X); we use the former. Finally, if X is known to be either 0 or -1, NE becomes a NEG and EQ becomes (plus X 1). Remove any ZERO_EXTRACT we made when thinking this was a comparison. It may now be simpler to use, e.g., an AND. If a ZERO_EXTRACT is indeed appropriate, it will be placed back by the call to make_compound_operation in the SET case. Don't apply these optimizations if the caller would prefer a comparison rather than a value. E.g., for the condition in an IF_THEN_ELSE most targets need an explicit comparison. */ if (in_cond) ; else if (STORE_FLAG_VALUE == 1 && new_code == NE && GET_MODE_CLASS (mode) == MODE_INT && op1 == const0_rtx && mode == GET_MODE (op0) && nonzero_bits (op0, mode) == 1) return gen_lowpart (mode, expand_compound_operation (op0)); else if (STORE_FLAG_VALUE == 1 && new_code == NE && GET_MODE_CLASS (mode) == MODE_INT && op1 == const0_rtx && mode == GET_MODE (op0) && (num_sign_bit_copies (op0, mode) == GET_MODE_PRECISION (mode))) { op0 = expand_compound_operation (op0); return simplify_gen_unary (NEG, mode, gen_lowpart (mode, op0), mode); } else if (STORE_FLAG_VALUE == 1 && new_code == EQ && GET_MODE_CLASS (mode) == MODE_INT && op1 == const0_rtx && mode == GET_MODE (op0) && nonzero_bits (op0, mode) == 1) { op0 = expand_compound_operation (op0); return simplify_gen_binary (XOR, mode, gen_lowpart (mode, op0), const1_rtx); } else if (STORE_FLAG_VALUE == 1 && new_code == EQ && GET_MODE_CLASS (mode) == MODE_INT && op1 == const0_rtx && mode == GET_MODE (op0) && (num_sign_bit_copies (op0, mode) == GET_MODE_PRECISION (mode))) { op0 = expand_compound_operation (op0); return plus_constant (mode, gen_lowpart (mode, op0), 1); } /* If STORE_FLAG_VALUE is -1, we have cases similar to those above. */ if (in_cond) ; else if (STORE_FLAG_VALUE == -1 && new_code == NE && GET_MODE_CLASS (mode) == MODE_INT && op1 == const0_rtx && mode == GET_MODE (op0) && (num_sign_bit_copies (op0, mode) == GET_MODE_PRECISION (mode))) return gen_lowpart (mode, expand_compound_operation (op0)); else if (STORE_FLAG_VALUE == -1 && new_code == NE && GET_MODE_CLASS (mode) == MODE_INT && op1 == const0_rtx && mode == GET_MODE (op0) && nonzero_bits (op0, mode) == 1) { op0 = expand_compound_operation (op0); return simplify_gen_unary (NEG, mode, gen_lowpart (mode, op0), mode); } else if (STORE_FLAG_VALUE == -1 && new_code == EQ && GET_MODE_CLASS (mode) == MODE_INT && op1 == const0_rtx && mode == GET_MODE (op0) && (num_sign_bit_copies (op0, mode) == GET_MODE_PRECISION (mode))) { op0 = expand_compound_operation (op0); return simplify_gen_unary (NOT, mode, gen_lowpart (mode, op0), mode); } /* If X is 0/1, (eq X 0) is X-1. */ else if (STORE_FLAG_VALUE == -1 && new_code == EQ && GET_MODE_CLASS (mode) == MODE_INT && op1 == const0_rtx && mode == GET_MODE (op0) && nonzero_bits (op0, mode) == 1) { op0 = expand_compound_operation (op0); return plus_constant (mode, gen_lowpart (mode, op0), -1); } /* If STORE_FLAG_VALUE says to just test the sign bit and X has just one bit that might be nonzero, we can convert (ne x 0) to (ashift x c) where C puts the bit in the sign bit. Remove any AND with STORE_FLAG_VALUE when we are done, since we are only going to test the sign bit. */ if (new_code == NE && GET_MODE_CLASS (mode) == MODE_INT && HWI_COMPUTABLE_MODE_P (mode) && val_signbit_p (mode, STORE_FLAG_VALUE) && op1 == const0_rtx && mode == GET_MODE (op0) && (i = exact_log2 (nonzero_bits (op0, mode))) >= 0) { x = simplify_shift_const (NULL_RTX, ASHIFT, mode, expand_compound_operation (op0), GET_MODE_PRECISION (mode) - 1 - i); if (GET_CODE (x) == AND && XEXP (x, 1) == const_true_rtx) return XEXP (x, 0); else return x; } /* If the code changed, return a whole new comparison. We also need to avoid using SUBST in cases where simplify_comparison has widened a comparison with a CONST_INT, since in that case the wider CONST_INT may fail the sanity checks in do_SUBST. */ if (new_code != code || (CONST_INT_P (op1) && GET_MODE (op0) != GET_MODE (XEXP (x, 0)) && GET_MODE (op0) != GET_MODE (XEXP (x, 1)))) return gen_rtx_fmt_ee (new_code, mode, op0, op1); /* Otherwise, keep this operation, but maybe change its operands. This also converts (ne (compare FOO BAR) 0) to (ne FOO BAR). */ SUBST (XEXP (x, 0), op0); SUBST (XEXP (x, 1), op1); } break; case IF_THEN_ELSE: return simplify_if_then_else (x); case ZERO_EXTRACT: case SIGN_EXTRACT: case ZERO_EXTEND: case SIGN_EXTEND: /* If we are processing SET_DEST, we are done. */ if (in_dest) return x; return expand_compound_operation (x); case SET: return simplify_set (x); case AND: case IOR: return simplify_logical (x); case ASHIFT: case LSHIFTRT: case ASHIFTRT: case ROTATE: case ROTATERT: /* If this is a shift by a constant amount, simplify it. */ if (CONST_INT_P (XEXP (x, 1))) return simplify_shift_const (x, code, mode, XEXP (x, 0), INTVAL (XEXP (x, 1))); else if (SHIFT_COUNT_TRUNCATED && !REG_P (XEXP (x, 1))) SUBST (XEXP (x, 1), force_to_mode (XEXP (x, 1), GET_MODE (XEXP (x, 1)), ((unsigned HOST_WIDE_INT) 1 << exact_log2 (GET_MODE_BITSIZE (GET_MODE (x)))) - 1, 0)); break; default: break; } return x; } /* Simplify X, an IF_THEN_ELSE expression. Return the new expression. */ static rtx simplify_if_then_else (rtx x) { machine_mode mode = GET_MODE (x); rtx cond = XEXP (x, 0); rtx true_rtx = XEXP (x, 1); rtx false_rtx = XEXP (x, 2); enum rtx_code true_code = GET_CODE (cond); int comparison_p = COMPARISON_P (cond); rtx temp; int i; enum rtx_code false_code; rtx reversed; /* Simplify storing of the truth value. */ if (comparison_p && true_rtx == const_true_rtx && false_rtx == const0_rtx) return simplify_gen_relational (true_code, mode, VOIDmode, XEXP (cond, 0), XEXP (cond, 1)); /* Also when the truth value has to be reversed. */ if (comparison_p && true_rtx == const0_rtx && false_rtx == const_true_rtx && (reversed = reversed_comparison (cond, mode))) return reversed; /* Sometimes we can simplify the arm of an IF_THEN_ELSE if a register used in it is being compared against certain values. Get the true and false comparisons and see if that says anything about the value of each arm. */ if (comparison_p && ((false_code = reversed_comparison_code (cond, NULL)) != UNKNOWN) && REG_P (XEXP (cond, 0))) { HOST_WIDE_INT nzb; rtx from = XEXP (cond, 0); rtx true_val = XEXP (cond, 1); rtx false_val = true_val; int swapped = 0; /* If FALSE_CODE is EQ, swap the codes and arms. */ if (false_code == EQ) { swapped = 1, true_code = EQ, false_code = NE; std::swap (true_rtx, false_rtx); } /* If we are comparing against zero and the expression being tested has only a single bit that might be nonzero, that is its value when it is not equal to zero. Similarly if it is known to be -1 or 0. */ if (true_code == EQ && true_val == const0_rtx && exact_log2 (nzb = nonzero_bits (from, GET_MODE (from))) >= 0) { false_code = EQ; false_val = gen_int_mode (nzb, GET_MODE (from)); } else if (true_code == EQ && true_val == const0_rtx && (num_sign_bit_copies (from, GET_MODE (from)) == GET_MODE_PRECISION (GET_MODE (from)))) { false_code = EQ; false_val = constm1_rtx; } /* Now simplify an arm if we know the value of the register in the branch and it is used in the arm. Be careful due to the potential of locally-shared RTL. */ if (reg_mentioned_p (from, true_rtx)) true_rtx = subst (known_cond (copy_rtx (true_rtx), true_code, from, true_val), pc_rtx, pc_rtx, 0, 0, 0); if (reg_mentioned_p (from, false_rtx)) false_rtx = subst (known_cond (copy_rtx (false_rtx), false_code, from, false_val), pc_rtx, pc_rtx, 0, 0, 0); SUBST (XEXP (x, 1), swapped ? false_rtx : true_rtx); SUBST (XEXP (x, 2), swapped ? true_rtx : false_rtx); true_rtx = XEXP (x, 1); false_rtx = XEXP (x, 2); true_code = GET_CODE (cond); } /* If we have (if_then_else FOO (pc) (label_ref BAR)) and FOO can be reversed, do so to avoid needing two sets of patterns for subtract-and-branch insns. Similarly if we have a constant in the true arm, the false arm is the same as the first operand of the comparison, or the false arm is more complicated than the true arm. */ if (comparison_p && reversed_comparison_code (cond, NULL) != UNKNOWN && (true_rtx == pc_rtx || (CONSTANT_P (true_rtx) && !CONST_INT_P (false_rtx) && false_rtx != pc_rtx) || true_rtx == const0_rtx || (OBJECT_P (true_rtx) && !OBJECT_P (false_rtx)) || (GET_CODE (true_rtx) == SUBREG && OBJECT_P (SUBREG_REG (true_rtx)) && !OBJECT_P (false_rtx)) || reg_mentioned_p (true_rtx, false_rtx) || rtx_equal_p (false_rtx, XEXP (cond, 0)))) { true_code = reversed_comparison_code (cond, NULL); SUBST (XEXP (x, 0), reversed_comparison (cond, GET_MODE (cond))); SUBST (XEXP (x, 1), false_rtx); SUBST (XEXP (x, 2), true_rtx); std::swap (true_rtx, false_rtx); cond = XEXP (x, 0); /* It is possible that the conditional has been simplified out. */ true_code = GET_CODE (cond); comparison_p = COMPARISON_P (cond); } /* If the two arms are identical, we don't need the comparison. */ if (rtx_equal_p (true_rtx, false_rtx) && ! side_effects_p (cond)) return true_rtx; /* Convert a == b ? b : a to "a". */ if (true_code == EQ && ! side_effects_p (cond) && !HONOR_NANS (mode) && rtx_equal_p (XEXP (cond, 0), false_rtx) && rtx_equal_p (XEXP (cond, 1), true_rtx)) return false_rtx; else if (true_code == NE && ! side_effects_p (cond) && !HONOR_NANS (mode) && rtx_equal_p (XEXP (cond, 0), true_rtx) && rtx_equal_p (XEXP (cond, 1), false_rtx)) return true_rtx; /* Look for cases where we have (abs x) or (neg (abs X)). */ if (GET_MODE_CLASS (mode) == MODE_INT && comparison_p && XEXP (cond, 1) == const0_rtx && GET_CODE (false_rtx) == NEG && rtx_equal_p (true_rtx, XEXP (false_rtx, 0)) && rtx_equal_p (true_rtx, XEXP (cond, 0)) && ! side_effects_p (true_rtx)) switch (true_code) { case GT: case GE: return simplify_gen_unary (ABS, mode, true_rtx, mode); case LT: case LE: return simplify_gen_unary (NEG, mode, simplify_gen_unary (ABS, mode, true_rtx, mode), mode); default: break; } /* Look for MIN or MAX. */ if ((! FLOAT_MODE_P (mode) || flag_unsafe_math_optimizations) && comparison_p && rtx_equal_p (XEXP (cond, 0), true_rtx) && rtx_equal_p (XEXP (cond, 1), false_rtx) && ! side_effects_p (cond)) switch (true_code) { case GE: case GT: return simplify_gen_binary (SMAX, mode, true_rtx, false_rtx); case LE: case LT: return simplify_gen_binary (SMIN, mode, true_rtx, false_rtx); case GEU: case GTU: return simplify_gen_binary (UMAX, mode, true_rtx, false_rtx); case LEU: case LTU: return simplify_gen_binary (UMIN, mode, true_rtx, false_rtx); default: break; } /* If we have (if_then_else COND (OP Z C1) Z) and OP is an identity when its second operand is zero, this can be done as (OP Z (mult COND C2)) where C2 = C1 * STORE_FLAG_VALUE. Similarly if OP has an outer ZERO_EXTEND or SIGN_EXTEND as long as Z is already extended (so we don't destroy it). We can do this kind of thing in some cases when STORE_FLAG_VALUE is neither 1 or -1, but it isn't worth checking for. */ if ((STORE_FLAG_VALUE == 1 || STORE_FLAG_VALUE == -1) && comparison_p && GET_MODE_CLASS (mode) == MODE_INT && ! side_effects_p (x)) { rtx t = make_compound_operation (true_rtx, SET); rtx f = make_compound_operation (false_rtx, SET); rtx cond_op0 = XEXP (cond, 0); rtx cond_op1 = XEXP (cond, 1); enum rtx_code op = UNKNOWN, extend_op = UNKNOWN; machine_mode m = mode; rtx z = 0, c1 = NULL_RTX; if ((GET_CODE (t) == PLUS || GET_CODE (t) == MINUS || GET_CODE (t) == IOR || GET_CODE (t) == XOR || GET_CODE (t) == ASHIFT || GET_CODE (t) == LSHIFTRT || GET_CODE (t) == ASHIFTRT) && rtx_equal_p (XEXP (t, 0), f)) c1 = XEXP (t, 1), op = GET_CODE (t), z = f; /* If an identity-zero op is commutative, check whether there would be a match if we swapped the operands. */ else if ((GET_CODE (t) == PLUS || GET_CODE (t) == IOR || GET_CODE (t) == XOR) && rtx_equal_p (XEXP (t, 1), f)) c1 = XEXP (t, 0), op = GET_CODE (t), z = f; else if (GET_CODE (t) == SIGN_EXTEND && (GET_CODE (XEXP (t, 0)) == PLUS || GET_CODE (XEXP (t, 0)) == MINUS || GET_CODE (XEXP (t, 0)) == IOR || GET_CODE (XEXP (t, 0)) == XOR || GET_CODE (XEXP (t, 0)) == ASHIFT || GET_CODE (XEXP (t, 0)) == LSHIFTRT || GET_CODE (XEXP (t, 0)) == ASHIFTRT) && GET_CODE (XEXP (XEXP (t, 0), 0)) == SUBREG && subreg_lowpart_p (XEXP (XEXP (t, 0), 0)) && rtx_equal_p (SUBREG_REG (XEXP (XEXP (t, 0), 0)), f) && (num_sign_bit_copies (f, GET_MODE (f)) > (unsigned int) (GET_MODE_PRECISION (mode) - GET_MODE_PRECISION (GET_MODE (XEXP (XEXP (t, 0), 0)))))) { c1 = XEXP (XEXP (t, 0), 1); z = f; op = GET_CODE (XEXP (t, 0)); extend_op = SIGN_EXTEND; m = GET_MODE (XEXP (t, 0)); } else if (GET_CODE (t) == SIGN_EXTEND && (GET_CODE (XEXP (t, 0)) == PLUS || GET_CODE (XEXP (t, 0)) == IOR || GET_CODE (XEXP (t, 0)) == XOR) && GET_CODE (XEXP (XEXP (t, 0), 1)) == SUBREG && subreg_lowpart_p (XEXP (XEXP (t, 0), 1)) && rtx_equal_p (SUBREG_REG (XEXP (XEXP (t, 0), 1)), f) && (num_sign_bit_copies (f, GET_MODE (f)) > (unsigned int) (GET_MODE_PRECISION (mode) - GET_MODE_PRECISION (GET_MODE (XEXP (XEXP (t, 0), 1)))))) { c1 = XEXP (XEXP (t, 0), 0); z = f; op = GET_CODE (XEXP (t, 0)); extend_op = SIGN_EXTEND; m = GET_MODE (XEXP (t, 0)); } else if (GET_CODE (t) == ZERO_EXTEND && (GET_CODE (XEXP (t, 0)) == PLUS || GET_CODE (XEXP (t, 0)) == MINUS || GET_CODE (XEXP (t, 0)) == IOR || GET_CODE (XEXP (t, 0)) == XOR || GET_CODE (XEXP (t, 0)) == ASHIFT || GET_CODE (XEXP (t, 0)) == LSHIFTRT || GET_CODE (XEXP (t, 0)) == ASHIFTRT) && GET_CODE (XEXP (XEXP (t, 0), 0)) == SUBREG && HWI_COMPUTABLE_MODE_P (mode) && subreg_lowpart_p (XEXP (XEXP (t, 0), 0)) && rtx_equal_p (SUBREG_REG (XEXP (XEXP (t, 0), 0)), f) && ((nonzero_bits (f, GET_MODE (f)) & ~GET_MODE_MASK (GET_MODE (XEXP (XEXP (t, 0), 0)))) == 0)) { c1 = XEXP (XEXP (t, 0), 1); z = f; op = GET_CODE (XEXP (t, 0)); extend_op = ZERO_EXTEND; m = GET_MODE (XEXP (t, 0)); } else if (GET_CODE (t) == ZERO_EXTEND && (GET_CODE (XEXP (t, 0)) == PLUS || GET_CODE (XEXP (t, 0)) == IOR || GET_CODE (XEXP (t, 0)) == XOR) && GET_CODE (XEXP (XEXP (t, 0), 1)) == SUBREG && HWI_COMPUTABLE_MODE_P (mode) && subreg_lowpart_p (XEXP (XEXP (t, 0), 1)) && rtx_equal_p (SUBREG_REG (XEXP (XEXP (t, 0), 1)), f) && ((nonzero_bits (f, GET_MODE (f)) & ~GET_MODE_MASK (GET_MODE (XEXP (XEXP (t, 0), 1)))) == 0)) { c1 = XEXP (XEXP (t, 0), 0); z = f; op = GET_CODE (XEXP (t, 0)); extend_op = ZERO_EXTEND; m = GET_MODE (XEXP (t, 0)); } if (z) { temp = subst (simplify_gen_relational (true_code, m, VOIDmode, cond_op0, cond_op1), pc_rtx, pc_rtx, 0, 0, 0); temp = simplify_gen_binary (MULT, m, temp, simplify_gen_binary (MULT, m, c1, const_true_rtx)); temp = subst (temp, pc_rtx, pc_rtx, 0, 0, 0); temp = simplify_gen_binary (op, m, gen_lowpart (m, z), temp); if (extend_op != UNKNOWN) temp = simplify_gen_unary (extend_op, mode, temp, m); return temp; } } /* If we have (if_then_else (ne A 0) C1 0) and either A is known to be 0 or 1 and C1 is a single bit or A is known to be 0 or -1 and C1 is the negation of a single bit, we can convert this operation to a shift. We can actually do this more generally, but it doesn't seem worth it. */ if (true_code == NE && XEXP (cond, 1) == const0_rtx && false_rtx == const0_rtx && CONST_INT_P (true_rtx) && ((1 == nonzero_bits (XEXP (cond, 0), mode) && (i = exact_log2 (UINTVAL (true_rtx))) >= 0) || ((num_sign_bit_copies (XEXP (cond, 0), mode) == GET_MODE_PRECISION (mode)) && (i = exact_log2 (-UINTVAL (true_rtx))) >= 0))) return simplify_shift_const (NULL_RTX, ASHIFT, mode, gen_lowpart (mode, XEXP (cond, 0)), i); /* (IF_THEN_ELSE (NE REG 0) (0) (8)) is REG for nonzero_bits (REG) == 8. */ if (true_code == NE && XEXP (cond, 1) == const0_rtx && false_rtx == const0_rtx && CONST_INT_P (true_rtx) && GET_MODE (XEXP (cond, 0)) == mode && (UINTVAL (true_rtx) & GET_MODE_MASK (mode)) == nonzero_bits (XEXP (cond, 0), mode) && (i = exact_log2 (UINTVAL (true_rtx) & GET_MODE_MASK (mode))) >= 0) return XEXP (cond, 0); return x; } /* Simplify X, a SET expression. Return the new expression. */ static rtx simplify_set (rtx x) { rtx src = SET_SRC (x); rtx dest = SET_DEST (x); machine_mode mode = GET_MODE (src) != VOIDmode ? GET_MODE (src) : GET_MODE (dest); rtx_insn *other_insn; rtx *cc_use; /* (set (pc) (return)) gets written as (return). */ if (GET_CODE (dest) == PC && ANY_RETURN_P (src)) return src; /* Now that we know for sure which bits of SRC we are using, see if we can simplify the expression for the object knowing that we only need the low-order bits. */ if (GET_MODE_CLASS (mode) == MODE_INT && HWI_COMPUTABLE_MODE_P (mode)) { src = force_to_mode (src, mode, ~(unsigned HOST_WIDE_INT) 0, 0); SUBST (SET_SRC (x), src); } /* If we are setting CC0 or if the source is a COMPARE, look for the use of the comparison result and try to simplify it unless we already have used undobuf.other_insn. */ if ((GET_MODE_CLASS (mode) == MODE_CC || GET_CODE (src) == COMPARE || CC0_P (dest)) && (cc_use = find_single_use (dest, subst_insn, &other_insn)) != 0 && (undobuf.other_insn == 0 || other_insn == undobuf.other_insn) && COMPARISON_P (*cc_use) && rtx_equal_p (XEXP (*cc_use, 0), dest)) { enum rtx_code old_code = GET_CODE (*cc_use); enum rtx_code new_code; rtx op0, op1, tmp; int other_changed = 0; rtx inner_compare = NULL_RTX; machine_mode compare_mode = GET_MODE (dest); if (GET_CODE (src) == COMPARE) { op0 = XEXP (src, 0), op1 = XEXP (src, 1); if (GET_CODE (op0) == COMPARE && op1 == const0_rtx) { inner_compare = op0; op0 = XEXP (inner_compare, 0), op1 = XEXP (inner_compare, 1); } } else op0 = src, op1 = CONST0_RTX (GET_MODE (src)); tmp = simplify_relational_operation (old_code, compare_mode, VOIDmode, op0, op1); if (!tmp) new_code = old_code; else if (!CONSTANT_P (tmp)) { new_code = GET_CODE (tmp); op0 = XEXP (tmp, 0); op1 = XEXP (tmp, 1); } else { rtx pat = PATTERN (other_insn); undobuf.other_insn = other_insn; SUBST (*cc_use, tmp); /* Attempt to simplify CC user. */ if (GET_CODE (pat) == SET) { rtx new_rtx = simplify_rtx (SET_SRC (pat)); if (new_rtx != NULL_RTX) SUBST (SET_SRC (pat), new_rtx); } /* Convert X into a no-op move. */ SUBST (SET_DEST (x), pc_rtx); SUBST (SET_SRC (x), pc_rtx); return x; } /* Simplify our comparison, if possible. */ new_code = simplify_comparison (new_code, &op0, &op1); #ifdef SELECT_CC_MODE /* If this machine has CC modes other than CCmode, check to see if we need to use a different CC mode here. */ if (GET_MODE_CLASS (GET_MODE (op0)) == MODE_CC) compare_mode = GET_MODE (op0); else if (inner_compare && GET_MODE_CLASS (GET_MODE (inner_compare)) == MODE_CC && new_code == old_code && op0 == XEXP (inner_compare, 0) && op1 == XEXP (inner_compare, 1)) compare_mode = GET_MODE (inner_compare); else compare_mode = SELECT_CC_MODE (new_code, op0, op1); /* If the mode changed, we have to change SET_DEST, the mode in the compare, and the mode in the place SET_DEST is used. If SET_DEST is a hard register, just build new versions with the proper mode. If it is a pseudo, we lose unless it is only time we set the pseudo, in which case we can safely change its mode. */ if (!HAVE_cc0 && compare_mode != GET_MODE (dest)) { if (can_change_dest_mode (dest, 0, compare_mode)) { unsigned int regno = REGNO (dest); rtx new_dest; if (regno < FIRST_PSEUDO_REGISTER) new_dest = gen_rtx_REG (compare_mode, regno); else { SUBST_MODE (regno_reg_rtx[regno], compare_mode); new_dest = regno_reg_rtx[regno]; } SUBST (SET_DEST (x), new_dest); SUBST (XEXP (*cc_use, 0), new_dest); other_changed = 1; dest = new_dest; } } #endif /* SELECT_CC_MODE */ /* If the code changed, we have to build a new comparison in undobuf.other_insn. */ if (new_code != old_code) { int other_changed_previously = other_changed; unsigned HOST_WIDE_INT mask; rtx old_cc_use = *cc_use; SUBST (*cc_use, gen_rtx_fmt_ee (new_code, GET_MODE (*cc_use), dest, const0_rtx)); other_changed = 1; /* If the only change we made was to change an EQ into an NE or vice versa, OP0 has only one bit that might be nonzero, and OP1 is zero, check if changing the user of the condition code will produce a valid insn. If it won't, we can keep the original code in that insn by surrounding our operation with an XOR. */ if (((old_code == NE && new_code == EQ) || (old_code == EQ && new_code == NE)) && ! other_changed_previously && op1 == const0_rtx && HWI_COMPUTABLE_MODE_P (GET_MODE (op0)) && exact_log2 (mask = nonzero_bits (op0, GET_MODE (op0))) >= 0) { rtx pat = PATTERN (other_insn), note = 0; if ((recog_for_combine (&pat, other_insn, ¬e) < 0 && ! check_asm_operands (pat))) { *cc_use = old_cc_use; other_changed = 0; op0 = simplify_gen_binary (XOR, GET_MODE (op0), op0, gen_int_mode (mask, GET_MODE (op0))); } } } if (other_changed) undobuf.other_insn = other_insn; /* Don't generate a compare of a CC with 0, just use that CC. */ if (GET_MODE (op0) == compare_mode && op1 == const0_rtx) { SUBST (SET_SRC (x), op0); src = SET_SRC (x); } /* Otherwise, if we didn't previously have the same COMPARE we want, create it from scratch. */ else if (GET_CODE (src) != COMPARE || GET_MODE (src) != compare_mode || XEXP (src, 0) != op0 || XEXP (src, 1) != op1) { SUBST (SET_SRC (x), gen_rtx_COMPARE (compare_mode, op0, op1)); src = SET_SRC (x); } } else { /* Get SET_SRC in a form where we have placed back any compound expressions. Then do the checks below. */ src = make_compound_operation (src, SET); SUBST (SET_SRC (x), src); } /* If we have (set x (subreg:m1 (op:m2 ...) 0)) with OP being some operation, and X being a REG or (subreg (reg)), we may be able to convert this to (set (subreg:m2 x) (op)). We can always do this if M1 is narrower than M2 because that means that we only care about the low bits of the result. However, on machines without WORD_REGISTER_OPERATIONS defined, we cannot perform a narrower operation than requested since the high-order bits will be undefined. On machine where it is defined, this transformation is safe as long as M1 and M2 have the same number of words. */ if (GET_CODE (src) == SUBREG && subreg_lowpart_p (src) && !OBJECT_P (SUBREG_REG (src)) && (((GET_MODE_SIZE (GET_MODE (src)) + (UNITS_PER_WORD - 1)) / UNITS_PER_WORD) == ((GET_MODE_SIZE (GET_MODE (SUBREG_REG (src))) + (UNITS_PER_WORD - 1)) / UNITS_PER_WORD)) && (WORD_REGISTER_OPERATIONS || (GET_MODE_SIZE (GET_MODE (src)) < GET_MODE_SIZE (GET_MODE (SUBREG_REG (src))))) #ifdef CANNOT_CHANGE_MODE_CLASS && ! (REG_P (dest) && REGNO (dest) < FIRST_PSEUDO_REGISTER && REG_CANNOT_CHANGE_MODE_P (REGNO (dest), GET_MODE (SUBREG_REG (src)), GET_MODE (src))) #endif && (REG_P (dest) || (GET_CODE (dest) == SUBREG && REG_P (SUBREG_REG (dest))))) { SUBST (SET_DEST (x), gen_lowpart (GET_MODE (SUBREG_REG (src)), dest)); SUBST (SET_SRC (x), SUBREG_REG (src)); src = SET_SRC (x), dest = SET_DEST (x); } /* If we have (set (cc0) (subreg ...)), we try to remove the subreg in SRC. */ if (dest == cc0_rtx && GET_CODE (src) == SUBREG && subreg_lowpart_p (src) && (GET_MODE_PRECISION (GET_MODE (src)) < GET_MODE_PRECISION (GET_MODE (SUBREG_REG (src))))) { rtx inner = SUBREG_REG (src); machine_mode inner_mode = GET_MODE (inner); /* Here we make sure that we don't have a sign bit on. */ if (val_signbit_known_clear_p (GET_MODE (src), nonzero_bits (inner, inner_mode))) { SUBST (SET_SRC (x), inner); src = SET_SRC (x); } } /* If we have (set FOO (subreg:M (mem:N BAR) 0)) with M wider than N, this would require a paradoxical subreg. Replace the subreg with a zero_extend to avoid the reload that would otherwise be required. */ if (GET_CODE (src) == SUBREG && subreg_lowpart_p (src) && INTEGRAL_MODE_P (GET_MODE (SUBREG_REG (src))) && LOAD_EXTEND_OP (GET_MODE (SUBREG_REG (src))) != UNKNOWN && SUBREG_BYTE (src) == 0 && paradoxical_subreg_p (src) && MEM_P (SUBREG_REG (src))) { SUBST (SET_SRC (x), gen_rtx_fmt_e (LOAD_EXTEND_OP (GET_MODE (SUBREG_REG (src))), GET_MODE (src), SUBREG_REG (src))); src = SET_SRC (x); } /* If we don't have a conditional move, SET_SRC is an IF_THEN_ELSE, and we are comparing an item known to be 0 or -1 against 0, use a logical operation instead. Check for one of the arms being an IOR of the other arm with some value. We compute three terms to be IOR'ed together. In practice, at most two will be nonzero. Then we do the IOR's. */ if (GET_CODE (dest) != PC && GET_CODE (src) == IF_THEN_ELSE && GET_MODE_CLASS (GET_MODE (src)) == MODE_INT && (GET_CODE (XEXP (src, 0)) == EQ || GET_CODE (XEXP (src, 0)) == NE) && XEXP (XEXP (src, 0), 1) == const0_rtx && GET_MODE (src) == GET_MODE (XEXP (XEXP (src, 0), 0)) && (!HAVE_conditional_move || ! can_conditionally_move_p (GET_MODE (src))) && (num_sign_bit_copies (XEXP (XEXP (src, 0), 0), GET_MODE (XEXP (XEXP (src, 0), 0))) == GET_MODE_PRECISION (GET_MODE (XEXP (XEXP (src, 0), 0)))) && ! side_effects_p (src)) { rtx true_rtx = (GET_CODE (XEXP (src, 0)) == NE ? XEXP (src, 1) : XEXP (src, 2)); rtx false_rtx = (GET_CODE (XEXP (src, 0)) == NE ? XEXP (src, 2) : XEXP (src, 1)); rtx term1 = const0_rtx, term2, term3; if (GET_CODE (true_rtx) == IOR && rtx_equal_p (XEXP (true_rtx, 0), false_rtx)) term1 = false_rtx, true_rtx = XEXP (true_rtx, 1), false_rtx = const0_rtx; else if (GET_CODE (true_rtx) == IOR && rtx_equal_p (XEXP (true_rtx, 1), false_rtx)) term1 = false_rtx, true_rtx = XEXP (true_rtx, 0), false_rtx = const0_rtx; else if (GET_CODE (false_rtx) == IOR && rtx_equal_p (XEXP (false_rtx, 0), true_rtx)) term1 = true_rtx, false_rtx = XEXP (false_rtx, 1), true_rtx = const0_rtx; else if (GET_CODE (false_rtx) == IOR && rtx_equal_p (XEXP (false_rtx, 1), true_rtx)) term1 = true_rtx, false_rtx = XEXP (false_rtx, 0), true_rtx = const0_rtx; term2 = simplify_gen_binary (AND, GET_MODE (src), XEXP (XEXP (src, 0), 0), true_rtx); term3 = simplify_gen_binary (AND, GET_MODE (src), simplify_gen_unary (NOT, GET_MODE (src), XEXP (XEXP (src, 0), 0), GET_MODE (src)), false_rtx); SUBST (SET_SRC (x), simplify_gen_binary (IOR, GET_MODE (src), simplify_gen_binary (IOR, GET_MODE (src), term1, term2), term3)); src = SET_SRC (x); } /* If either SRC or DEST is a CLOBBER of (const_int 0), make this whole thing fail. */ if (GET_CODE (src) == CLOBBER && XEXP (src, 0) == const0_rtx) return src; else if (GET_CODE (dest) == CLOBBER && XEXP (dest, 0) == const0_rtx) return dest; else /* Convert this into a field assignment operation, if possible. */ return make_field_assignment (x); } /* Simplify, X, and AND, IOR, or XOR operation, and return the simplified result. */ static rtx simplify_logical (rtx x) { machine_mode mode = GET_MODE (x); rtx op0 = XEXP (x, 0); rtx op1 = XEXP (x, 1); switch (GET_CODE (x)) { case AND: /* We can call simplify_and_const_int only if we don't lose any (sign) bits when converting INTVAL (op1) to "unsigned HOST_WIDE_INT". */ if (CONST_INT_P (op1) && (HWI_COMPUTABLE_MODE_P (mode) || INTVAL (op1) > 0)) { x = simplify_and_const_int (x, mode, op0, INTVAL (op1)); if (GET_CODE (x) != AND) return x; op0 = XEXP (x, 0); op1 = XEXP (x, 1); } /* If we have any of (and (ior A B) C) or (and (xor A B) C), apply the distributive law and then the inverse distributive law to see if things simplify. */ if (GET_CODE (op0) == IOR || GET_CODE (op0) == XOR) { rtx result = distribute_and_simplify_rtx (x, 0); if (result) return result; } if (GET_CODE (op1) == IOR || GET_CODE (op1) == XOR) { rtx result = distribute_and_simplify_rtx (x, 1); if (result) return result; } break; case IOR: /* If we have (ior (and A B) C), apply the distributive law and then the inverse distributive law to see if things simplify. */ if (GET_CODE (op0) == AND) { rtx result = distribute_and_simplify_rtx (x, 0); if (result) return result; } if (GET_CODE (op1) == AND) { rtx result = distribute_and_simplify_rtx (x, 1); if (result) return result; } break; default: gcc_unreachable (); } return x; } /* We consider ZERO_EXTRACT, SIGN_EXTRACT, and SIGN_EXTEND as "compound operations" because they can be replaced with two more basic operations. ZERO_EXTEND is also considered "compound" because it can be replaced with an AND operation, which is simpler, though only one operation. The function expand_compound_operation is called with an rtx expression and will convert it to the appropriate shifts and AND operations, simplifying at each stage. The function make_compound_operation is called to convert an expression consisting of shifts and ANDs into the equivalent compound expression. It is the inverse of this function, loosely speaking. */ static rtx expand_compound_operation (rtx x) { unsigned HOST_WIDE_INT pos = 0, len; int unsignedp = 0; unsigned int modewidth; rtx tem; switch (GET_CODE (x)) { case ZERO_EXTEND: unsignedp = 1; case SIGN_EXTEND: /* We can't necessarily use a const_int for a multiword mode; it depends on implicitly extending the value. Since we don't know the right way to extend it, we can't tell whether the implicit way is right. Even for a mode that is no wider than a const_int, we can't win, because we need to sign extend one of its bits through the rest of it, and we don't know which bit. */ if (CONST_INT_P (XEXP (x, 0))) return x; /* Return if (subreg:MODE FROM 0) is not a safe replacement for (zero_extend:MODE FROM) or (sign_extend:MODE FROM). It is for any MEM because (SUBREG (MEM...)) is guaranteed to cause the MEM to be reloaded. If not for that, MEM's would very rarely be safe. Reject MODEs bigger than a word, because we might not be able to reference a two-register group starting with an arbitrary register (and currently gen_lowpart might crash for a SUBREG). */ if (GET_MODE_SIZE (GET_MODE (XEXP (x, 0))) > UNITS_PER_WORD) return x; /* Reject MODEs that aren't scalar integers because turning vector or complex modes into shifts causes problems. */ if (! SCALAR_INT_MODE_P (GET_MODE (XEXP (x, 0)))) return x; len = GET_MODE_PRECISION (GET_MODE (XEXP (x, 0))); /* If the inner object has VOIDmode (the only way this can happen is if it is an ASM_OPERANDS), we can't do anything since we don't know how much masking to do. */ if (len == 0) return x; break; case ZERO_EXTRACT: unsignedp = 1; /* ... fall through ... */ case SIGN_EXTRACT: /* If the operand is a CLOBBER, just return it. */ if (GET_CODE (XEXP (x, 0)) == CLOBBER) return XEXP (x, 0); if (!CONST_INT_P (XEXP (x, 1)) || !CONST_INT_P (XEXP (x, 2)) || GET_MODE (XEXP (x, 0)) == VOIDmode) return x; /* Reject MODEs that aren't scalar integers because turning vector or complex modes into shifts causes problems. */ if (! SCALAR_INT_MODE_P (GET_MODE (XEXP (x, 0)))) return x; len = INTVAL (XEXP (x, 1)); pos = INTVAL (XEXP (x, 2)); /* This should stay within the object being extracted, fail otherwise. */ if (len + pos > GET_MODE_PRECISION (GET_MODE (XEXP (x, 0)))) return x; if (BITS_BIG_ENDIAN) pos = GET_MODE_PRECISION (GET_MODE (XEXP (x, 0))) - len - pos; break; default: return x; } /* Convert sign extension to zero extension, if we know that the high bit is not set, as this is easier to optimize. It will be converted back to cheaper alternative in make_extraction. */ if (GET_CODE (x) == SIGN_EXTEND && (HWI_COMPUTABLE_MODE_P (GET_MODE (x)) && ((nonzero_bits (XEXP (x, 0), GET_MODE (XEXP (x, 0))) & ~(((unsigned HOST_WIDE_INT) GET_MODE_MASK (GET_MODE (XEXP (x, 0)))) >> 1)) == 0))) { machine_mode mode = GET_MODE (x); rtx temp = gen_rtx_ZERO_EXTEND (mode, XEXP (x, 0)); rtx temp2 = expand_compound_operation (temp); /* Make sure this is a profitable operation. */ if (set_src_cost (x, mode, optimize_this_for_speed_p) > set_src_cost (temp2, mode, optimize_this_for_speed_p)) return temp2; else if (set_src_cost (x, mode, optimize_this_for_speed_p) > set_src_cost (temp, mode, optimize_this_for_speed_p)) return temp; else return x; } /* We can optimize some special cases of ZERO_EXTEND. */ if (GET_CODE (x) == ZERO_EXTEND) { /* (zero_extend:DI (truncate:SI foo:DI)) is just foo:DI if we know that the last value didn't have any inappropriate bits set. */ if (GET_CODE (XEXP (x, 0)) == TRUNCATE && GET_MODE (XEXP (XEXP (x, 0), 0)) == GET_MODE (x) && HWI_COMPUTABLE_MODE_P (GET_MODE (x)) && (nonzero_bits (XEXP (XEXP (x, 0), 0), GET_MODE (x)) & ~GET_MODE_MASK (GET_MODE (XEXP (x, 0)))) == 0) return XEXP (XEXP (x, 0), 0); /* Likewise for (zero_extend:DI (subreg:SI foo:DI 0)). */ if (GET_CODE (XEXP (x, 0)) == SUBREG && GET_MODE (SUBREG_REG (XEXP (x, 0))) == GET_MODE (x) && subreg_lowpart_p (XEXP (x, 0)) && HWI_COMPUTABLE_MODE_P (GET_MODE (x)) && (nonzero_bits (SUBREG_REG (XEXP (x, 0)), GET_MODE (x)) & ~GET_MODE_MASK (GET_MODE (XEXP (x, 0)))) == 0) return SUBREG_REG (XEXP (x, 0)); /* (zero_extend:DI (truncate:SI foo:DI)) is just foo:DI when foo is a comparison and STORE_FLAG_VALUE permits. This is like the first case, but it works even when GET_MODE (x) is larger than HOST_WIDE_INT. */ if (GET_CODE (XEXP (x, 0)) == TRUNCATE && GET_MODE (XEXP (XEXP (x, 0), 0)) == GET_MODE (x) && COMPARISON_P (XEXP (XEXP (x, 0), 0)) && (GET_MODE_PRECISION (GET_MODE (XEXP (x, 0))) <= HOST_BITS_PER_WIDE_INT) && (STORE_FLAG_VALUE & ~GET_MODE_MASK (GET_MODE (XEXP (x, 0)))) == 0) return XEXP (XEXP (x, 0), 0); /* Likewise for (zero_extend:DI (subreg:SI foo:DI 0)). */ if (GET_CODE (XEXP (x, 0)) == SUBREG && GET_MODE (SUBREG_REG (XEXP (x, 0))) == GET_MODE (x) && subreg_lowpart_p (XEXP (x, 0)) && COMPARISON_P (SUBREG_REG (XEXP (x, 0))) && (GET_MODE_PRECISION (GET_MODE (XEXP (x, 0))) <= HOST_BITS_PER_WIDE_INT) && (STORE_FLAG_VALUE & ~GET_MODE_MASK (GET_MODE (XEXP (x, 0)))) == 0) return SUBREG_REG (XEXP (x, 0)); } /* If we reach here, we want to return a pair of shifts. The inner shift is a left shift of BITSIZE - POS - LEN bits. The outer shift is a right shift of BITSIZE - LEN bits. It is arithmetic or logical depending on the value of UNSIGNEDP. If this was a ZERO_EXTEND or ZERO_EXTRACT, this pair of shifts will be converted into an AND of a shift. We must check for the case where the left shift would have a negative count. This can happen in a case like (x >> 31) & 255 on machines that can't shift by a constant. On those machines, we would first combine the shift with the AND to produce a variable-position extraction. Then the constant of 31 would be substituted in to produce such a position. */ modewidth = GET_MODE_PRECISION (GET_MODE (x)); if (modewidth >= pos + len) { machine_mode mode = GET_MODE (x); tem = gen_lowpart (mode, XEXP (x, 0)); if (!tem || GET_CODE (tem) == CLOBBER) return x; tem = simplify_shift_const (NULL_RTX, ASHIFT, mode, tem, modewidth - pos - len); tem = simplify_shift_const (NULL_RTX, unsignedp ? LSHIFTRT : ASHIFTRT, mode, tem, modewidth - len); } else if (unsignedp && len < HOST_BITS_PER_WIDE_INT) tem = simplify_and_const_int (NULL_RTX, GET_MODE (x), simplify_shift_const (NULL_RTX, LSHIFTRT, GET_MODE (x), XEXP (x, 0), pos), ((unsigned HOST_WIDE_INT) 1 << len) - 1); else /* Any other cases we can't handle. */ return x; /* If we couldn't do this for some reason, return the original expression. */ if (GET_CODE (tem) == CLOBBER) return x; return tem; } /* X is a SET which contains an assignment of one object into a part of another (such as a bit-field assignment, STRICT_LOW_PART, or certain SUBREGS). If possible, convert it into a series of logical operations. We half-heartedly support variable positions, but do not at all support variable lengths. */ static const_rtx expand_field_assignment (const_rtx x) { rtx inner; rtx pos; /* Always counts from low bit. */ int len; rtx mask, cleared, masked; machine_mode compute_mode; /* Loop until we find something we can't simplify. */ while (1) { if (GET_CODE (SET_DEST (x)) == STRICT_LOW_PART && GET_CODE (XEXP (SET_DEST (x), 0)) == SUBREG) { inner = SUBREG_REG (XEXP (SET_DEST (x), 0)); len = GET_MODE_PRECISION (GET_MODE (XEXP (SET_DEST (x), 0))); pos = GEN_INT (subreg_lsb (XEXP (SET_DEST (x), 0))); } else if (GET_CODE (SET_DEST (x)) == ZERO_EXTRACT && CONST_INT_P (XEXP (SET_DEST (x), 1))) { inner = XEXP (SET_DEST (x), 0); len = INTVAL (XEXP (SET_DEST (x), 1)); pos = XEXP (SET_DEST (x), 2); /* A constant position should stay within the width of INNER. */ if (CONST_INT_P (pos) && INTVAL (pos) + len > GET_MODE_PRECISION (GET_MODE (inner))) break; if (BITS_BIG_ENDIAN) { if (CONST_INT_P (pos)) pos = GEN_INT (GET_MODE_PRECISION (GET_MODE (inner)) - len - INTVAL (pos)); else if (GET_CODE (pos) == MINUS && CONST_INT_P (XEXP (pos, 1)) && (INTVAL (XEXP (pos, 1)) == GET_MODE_PRECISION (GET_MODE (inner)) - len)) /* If position is ADJUST - X, new position is X. */ pos = XEXP (pos, 0); else { HOST_WIDE_INT prec = GET_MODE_PRECISION (GET_MODE (inner)); pos = simplify_gen_binary (MINUS, GET_MODE (pos), gen_int_mode (prec - len, GET_MODE (pos)), pos); } } } /* A SUBREG between two modes that occupy the same numbers of words can be done by moving the SUBREG to the source. */ else if (GET_CODE (SET_DEST (x)) == SUBREG /* We need SUBREGs to compute nonzero_bits properly. */ && nonzero_sign_valid && (((GET_MODE_SIZE (GET_MODE (SET_DEST (x))) + (UNITS_PER_WORD - 1)) / UNITS_PER_WORD) == ((GET_MODE_SIZE (GET_MODE (SUBREG_REG (SET_DEST (x)))) + (UNITS_PER_WORD - 1)) / UNITS_PER_WORD))) { x = gen_rtx_SET (SUBREG_REG (SET_DEST (x)), gen_lowpart (GET_MODE (SUBREG_REG (SET_DEST (x))), SET_SRC (x))); continue; } else break; while (GET_CODE (inner) == SUBREG && subreg_lowpart_p (inner)) inner = SUBREG_REG (inner); compute_mode = GET_MODE (inner); /* Don't attempt bitwise arithmetic on non scalar integer modes. */ if (! SCALAR_INT_MODE_P (compute_mode)) { machine_mode imode; /* Don't do anything for vector or complex integral types. */ if (! FLOAT_MODE_P (compute_mode)) break; /* Try to find an integral mode to pun with. */ imode = mode_for_size (GET_MODE_BITSIZE (compute_mode), MODE_INT, 0); if (imode == BLKmode) break; compute_mode = imode; inner = gen_lowpart (imode, inner); } /* Compute a mask of LEN bits, if we can do this on the host machine. */ if (len >= HOST_BITS_PER_WIDE_INT) break; /* Now compute the equivalent expression. Make a copy of INNER for the SET_DEST in case it is a MEM into which we will substitute; we don't want shared RTL in that case. */ mask = gen_int_mode (((unsigned HOST_WIDE_INT) 1 << len) - 1, compute_mode); cleared = simplify_gen_binary (AND, compute_mode, simplify_gen_unary (NOT, compute_mode, simplify_gen_binary (ASHIFT, compute_mode, mask, pos), compute_mode), inner); masked = simplify_gen_binary (ASHIFT, compute_mode, simplify_gen_binary ( AND, compute_mode, gen_lowpart (compute_mode, SET_SRC (x)), mask), pos); x = gen_rtx_SET (copy_rtx (inner), simplify_gen_binary (IOR, compute_mode, cleared, masked)); } return x; } /* Return an RTX for a reference to LEN bits of INNER. If POS_RTX is nonzero, it is an RTX that represents the (variable) starting position; otherwise, POS is the (constant) starting bit position. Both are counted from the LSB. UNSIGNEDP is nonzero for an unsigned reference and zero for a signed one. IN_DEST is nonzero if this is a reference in the destination of a SET. This is used when a ZERO_ or SIGN_EXTRACT isn't needed. If nonzero, a STRICT_LOW_PART will be used, if zero, ZERO_EXTEND or SIGN_EXTEND will be used. IN_COMPARE is nonzero if we are in a COMPARE. This means that a ZERO_EXTRACT should be built even for bits starting at bit 0. MODE is the desired mode of the result (if IN_DEST == 0). The result is an RTX for the extraction or NULL_RTX if the target can't handle it. */ static rtx make_extraction (machine_mode mode, rtx inner, HOST_WIDE_INT pos, rtx pos_rtx, unsigned HOST_WIDE_INT len, int unsignedp, int in_dest, int in_compare) { /* This mode describes the size of the storage area to fetch the overall value from. Within that, we ignore the POS lowest bits, etc. */ machine_mode is_mode = GET_MODE (inner); machine_mode inner_mode; machine_mode wanted_inner_mode; machine_mode wanted_inner_reg_mode = word_mode; machine_mode pos_mode = word_mode; machine_mode extraction_mode = word_mode; machine_mode tmode = mode_for_size (len, MODE_INT, 1); rtx new_rtx = 0; rtx orig_pos_rtx = pos_rtx; HOST_WIDE_INT orig_pos; if (pos_rtx && CONST_INT_P (pos_rtx)) pos = INTVAL (pos_rtx), pos_rtx = 0; if (GET_CODE (inner) == SUBREG && subreg_lowpart_p (inner)) { /* If going from (subreg:SI (mem:QI ...)) to (mem:QI ...), consider just the QI as the memory to extract from. The subreg adds or removes high bits; its mode is irrelevant to the meaning of this extraction, since POS and LEN count from the lsb. */ if (MEM_P (SUBREG_REG (inner))) is_mode = GET_MODE (SUBREG_REG (inner)); inner = SUBREG_REG (inner); } else if (GET_CODE (inner) == ASHIFT && CONST_INT_P (XEXP (inner, 1)) && pos_rtx == 0 && pos == 0 && len > UINTVAL (XEXP (inner, 1))) { /* We're extracting the least significant bits of an rtx (ashift X (const_int C)), where LEN > C. Extract the least significant (LEN - C) bits of X, giving an rtx whose mode is MODE, then shift it left C times. */ new_rtx = make_extraction (mode, XEXP (inner, 0), 0, 0, len - INTVAL (XEXP (inner, 1)), unsignedp, in_dest, in_compare); if (new_rtx != 0) return gen_rtx_ASHIFT (mode, new_rtx, XEXP (inner, 1)); } else if (GET_CODE (inner) == TRUNCATE) inner = XEXP (inner, 0); inner_mode = GET_MODE (inner); /* See if this can be done without an extraction. We never can if the width of the field is not the same as that of some integer mode. For registers, we can only avoid the extraction if the position is at the low-order bit and this is either not in the destination or we have the appropriate STRICT_LOW_PART operation available. For MEM, we can avoid an extract if the field starts on an appropriate boundary and we can change the mode of the memory reference. */ if (tmode != BLKmode && ((pos_rtx == 0 && (pos % BITS_PER_WORD) == 0 && !MEM_P (inner) && (inner_mode == tmode || !REG_P (inner) || TRULY_NOOP_TRUNCATION_MODES_P (tmode, inner_mode) || reg_truncated_to_mode (tmode, inner)) && (! in_dest || (REG_P (inner) && have_insn_for (STRICT_LOW_PART, tmode)))) || (MEM_P (inner) && pos_rtx == 0 && (pos % (STRICT_ALIGNMENT ? GET_MODE_ALIGNMENT (tmode) : BITS_PER_UNIT)) == 0 /* We can't do this if we are widening INNER_MODE (it may not be aligned, for one thing). */ && GET_MODE_PRECISION (inner_mode) >= GET_MODE_PRECISION (tmode) && (inner_mode == tmode || (! mode_dependent_address_p (XEXP (inner, 0), MEM_ADDR_SPACE (inner)) && ! MEM_VOLATILE_P (inner)))))) { /* If INNER is a MEM, make a new MEM that encompasses just the desired field. If the original and current mode are the same, we need not adjust the offset. Otherwise, we do if bytes big endian. If INNER is not a MEM, get a piece consisting of just the field of interest (in this case POS % BITS_PER_WORD must be 0). */ if (MEM_P (inner)) { HOST_WIDE_INT offset; /* POS counts from lsb, but make OFFSET count in memory order. */ if (BYTES_BIG_ENDIAN) offset = (GET_MODE_PRECISION (is_mode) - len - pos) / BITS_PER_UNIT; else offset = pos / BITS_PER_UNIT; new_rtx = adjust_address_nv (inner, tmode, offset); } else if (REG_P (inner)) { if (tmode != inner_mode) { /* We can't call gen_lowpart in a DEST since we always want a SUBREG (see below) and it would sometimes return a new hard register. */ if (pos || in_dest) { HOST_WIDE_INT final_word = pos / BITS_PER_WORD; if (WORDS_BIG_ENDIAN && GET_MODE_SIZE (inner_mode) > UNITS_PER_WORD) final_word = ((GET_MODE_SIZE (inner_mode) - GET_MODE_SIZE (tmode)) / UNITS_PER_WORD) - final_word; final_word *= UNITS_PER_WORD; if (BYTES_BIG_ENDIAN && GET_MODE_SIZE (inner_mode) > GET_MODE_SIZE (tmode)) final_word += (GET_MODE_SIZE (inner_mode) - GET_MODE_SIZE (tmode)) % UNITS_PER_WORD; /* Avoid creating invalid subregs, for example when simplifying (x>>32)&255. */ if (!validate_subreg (tmode, inner_mode, inner, final_word)) return NULL_RTX; new_rtx = gen_rtx_SUBREG (tmode, inner, final_word); } else new_rtx = gen_lowpart (tmode, inner); } else new_rtx = inner; } else new_rtx = force_to_mode (inner, tmode, len >= HOST_BITS_PER_WIDE_INT ? ~(unsigned HOST_WIDE_INT) 0 : ((unsigned HOST_WIDE_INT) 1 << len) - 1, 0); /* If this extraction is going into the destination of a SET, make a STRICT_LOW_PART unless we made a MEM. */ if (in_dest) return (MEM_P (new_rtx) ? new_rtx : (GET_CODE (new_rtx) != SUBREG ? gen_rtx_CLOBBER (tmode, const0_rtx) : gen_rtx_STRICT_LOW_PART (VOIDmode, new_rtx))); if (mode == tmode) return new_rtx; if (CONST_SCALAR_INT_P (new_rtx)) return simplify_unary_operation (unsignedp ? ZERO_EXTEND : SIGN_EXTEND, mode, new_rtx, tmode); /* If we know that no extraneous bits are set, and that the high bit is not set, convert the extraction to the cheaper of sign and zero extension, that are equivalent in these cases. */ if (flag_expensive_optimizations && (HWI_COMPUTABLE_MODE_P (tmode) && ((nonzero_bits (new_rtx, tmode) & ~(((unsigned HOST_WIDE_INT)GET_MODE_MASK (tmode)) >> 1)) == 0))) { rtx temp = gen_rtx_ZERO_EXTEND (mode, new_rtx); rtx temp1 = gen_rtx_SIGN_EXTEND (mode, new_rtx); /* Prefer ZERO_EXTENSION, since it gives more information to backends. */ if (set_src_cost (temp, mode, optimize_this_for_speed_p) <= set_src_cost (temp1, mode, optimize_this_for_speed_p)) return temp; return temp1; } /* Otherwise, sign- or zero-extend unless we already are in the proper mode. */ return (gen_rtx_fmt_e (unsignedp ? ZERO_EXTEND : SIGN_EXTEND, mode, new_rtx)); } /* Unless this is a COMPARE or we have a funny memory reference, don't do anything with zero-extending field extracts starting at the low-order bit since they are simple AND operations. */ if (pos_rtx == 0 && pos == 0 && ! in_dest && ! in_compare && unsignedp) return 0; /* Unless INNER is not MEM, reject this if we would be spanning bytes or if the position is not a constant and the length is not 1. In all other cases, we would only be going outside our object in cases when an original shift would have been undefined. */ if (MEM_P (inner) && ((pos_rtx == 0 && pos + len > GET_MODE_PRECISION (is_mode)) || (pos_rtx != 0 && len != 1))) return 0; enum extraction_pattern pattern = (in_dest ? EP_insv : unsignedp ? EP_extzv : EP_extv); /* If INNER is not from memory, we want it to have the mode of a register extraction pattern's structure operand, or word_mode if there is no such pattern. The same applies to extraction_mode and pos_mode and their respective operands. For memory, assume that the desired extraction_mode and pos_mode are the same as for a register operation, since at present we don't have named patterns for aligned memory structures. */ struct extraction_insn insn; if (get_best_reg_extraction_insn (&insn, pattern, GET_MODE_BITSIZE (inner_mode), mode)) { wanted_inner_reg_mode = insn.struct_mode; pos_mode = insn.pos_mode; extraction_mode = insn.field_mode; } /* Never narrow an object, since that might not be safe. */ if (mode != VOIDmode && GET_MODE_SIZE (extraction_mode) < GET_MODE_SIZE (mode)) extraction_mode = mode; if (!MEM_P (inner)) wanted_inner_mode = wanted_inner_reg_mode; else { /* Be careful not to go beyond the extracted object and maintain the natural alignment of the memory. */ wanted_inner_mode = smallest_mode_for_size (len, MODE_INT); while (pos % GET_MODE_BITSIZE (wanted_inner_mode) + len > GET_MODE_BITSIZE (wanted_inner_mode)) { wanted_inner_mode = GET_MODE_WIDER_MODE (wanted_inner_mode); gcc_assert (wanted_inner_mode != VOIDmode); } } orig_pos = pos; if (BITS_BIG_ENDIAN) { /* POS is passed as if BITS_BIG_ENDIAN == 0, so we need to convert it to BITS_BIG_ENDIAN style. If position is constant, compute new position. Otherwise, build subtraction. Note that POS is relative to the mode of the original argument. If it's a MEM we need to recompute POS relative to that. However, if we're extracting from (or inserting into) a register, we want to recompute POS relative to wanted_inner_mode. */ int width = (MEM_P (inner) ? GET_MODE_BITSIZE (is_mode) : GET_MODE_BITSIZE (wanted_inner_mode)); if (pos_rtx == 0) pos = width - len - pos; else pos_rtx = gen_rtx_MINUS (GET_MODE (pos_rtx), gen_int_mode (width - len, GET_MODE (pos_rtx)), pos_rtx); /* POS may be less than 0 now, but we check for that below. Note that it can only be less than 0 if !MEM_P (inner). */ } /* If INNER has a wider mode, and this is a constant extraction, try to make it smaller and adjust the byte to point to the byte containing the value. */ if (wanted_inner_mode != VOIDmode && inner_mode != wanted_inner_mode && ! pos_rtx && GET_MODE_SIZE (wanted_inner_mode) < GET_MODE_SIZE (is_mode) && MEM_P (inner) && ! mode_dependent_address_p (XEXP (inner, 0), MEM_ADDR_SPACE (inner)) && ! MEM_VOLATILE_P (inner)) { int offset = 0; /* The computations below will be correct if the machine is big endian in both bits and bytes or little endian in bits and bytes. If it is mixed, we must adjust. */ /* If bytes are big endian and we had a paradoxical SUBREG, we must adjust OFFSET to compensate. */ if (BYTES_BIG_ENDIAN && GET_MODE_SIZE (inner_mode) < GET_MODE_SIZE (is_mode)) offset -= GET_MODE_SIZE (is_mode) - GET_MODE_SIZE (inner_mode); /* We can now move to the desired byte. */ offset += (pos / GET_MODE_BITSIZE (wanted_inner_mode)) * GET_MODE_SIZE (wanted_inner_mode); pos %= GET_MODE_BITSIZE (wanted_inner_mode); if (BYTES_BIG_ENDIAN != BITS_BIG_ENDIAN && is_mode != wanted_inner_mode) offset = (GET_MODE_SIZE (is_mode) - GET_MODE_SIZE (wanted_inner_mode) - offset); inner = adjust_address_nv (inner, wanted_inner_mode, offset); } /* If INNER is not memory, get it into the proper mode. If we are changing its mode, POS must be a constant and smaller than the size of the new mode. */ else if (!MEM_P (inner)) { /* On the LHS, don't create paradoxical subregs implicitely truncating the register unless TRULY_NOOP_TRUNCATION. */ if (in_dest && !TRULY_NOOP_TRUNCATION_MODES_P (GET_MODE (inner), wanted_inner_mode)) return NULL_RTX; if (GET_MODE (inner) != wanted_inner_mode && (pos_rtx != 0 || orig_pos + len > GET_MODE_BITSIZE (wanted_inner_mode))) return NULL_RTX; if (orig_pos < 0) return NULL_RTX; inner = force_to_mode (inner, wanted_inner_mode, pos_rtx || len + orig_pos >= HOST_BITS_PER_WIDE_INT ? ~(unsigned HOST_WIDE_INT) 0 : ((((unsigned HOST_WIDE_INT) 1 << len) - 1) << orig_pos), 0); } /* Adjust mode of POS_RTX, if needed. If we want a wider mode, we have to zero extend. Otherwise, we can just use a SUBREG. */ if (pos_rtx != 0 && GET_MODE_SIZE (pos_mode) > GET_MODE_SIZE (GET_MODE (pos_rtx))) { rtx temp = simplify_gen_unary (ZERO_EXTEND, pos_mode, pos_rtx, GET_MODE (pos_rtx)); /* If we know that no extraneous bits are set, and that the high bit is not set, convert extraction to cheaper one - either SIGN_EXTENSION or ZERO_EXTENSION, that are equivalent in these cases. */ if (flag_expensive_optimizations && (HWI_COMPUTABLE_MODE_P (GET_MODE (pos_rtx)) && ((nonzero_bits (pos_rtx, GET_MODE (pos_rtx)) & ~(((unsigned HOST_WIDE_INT) GET_MODE_MASK (GET_MODE (pos_rtx))) >> 1)) == 0))) { rtx temp1 = simplify_gen_unary (SIGN_EXTEND, pos_mode, pos_rtx, GET_MODE (pos_rtx)); /* Prefer ZERO_EXTENSION, since it gives more information to backends. */ if (set_src_cost (temp1, pos_mode, optimize_this_for_speed_p) < set_src_cost (temp, pos_mode, optimize_this_for_speed_p)) temp = temp1; } pos_rtx = temp; } /* Make POS_RTX unless we already have it and it is correct. If we don't have a POS_RTX but we do have an ORIG_POS_RTX, the latter must be a CONST_INT. */ if (pos_rtx == 0 && orig_pos_rtx != 0 && INTVAL (orig_pos_rtx) == pos) pos_rtx = orig_pos_rtx; else if (pos_rtx == 0) pos_rtx = GEN_INT (pos); /* Make the required operation. See if we can use existing rtx. */ new_rtx = gen_rtx_fmt_eee (unsignedp ? ZERO_EXTRACT : SIGN_EXTRACT, extraction_mode, inner, GEN_INT (len), pos_rtx); if (! in_dest) new_rtx = gen_lowpart (mode, new_rtx); return new_rtx; } /* See if X contains an ASHIFT of COUNT or more bits that can be commuted with any other operations in X. Return X without that shift if so. */ static rtx extract_left_shift (rtx x, int count) { enum rtx_code code = GET_CODE (x); machine_mode mode = GET_MODE (x); rtx tem; switch (code) { case ASHIFT: /* This is the shift itself. If it is wide enough, we will return either the value being shifted if the shift count is equal to COUNT or a shift for the difference. */ if (CONST_INT_P (XEXP (x, 1)) && INTVAL (XEXP (x, 1)) >= count) return simplify_shift_const (NULL_RTX, ASHIFT, mode, XEXP (x, 0), INTVAL (XEXP (x, 1)) - count); break; case NEG: case NOT: if ((tem = extract_left_shift (XEXP (x, 0), count)) != 0) return simplify_gen_unary (code, mode, tem, mode); break; case PLUS: case IOR: case XOR: case AND: /* If we can safely shift this constant and we find the inner shift, make a new operation. */ if (CONST_INT_P (XEXP (x, 1)) && (UINTVAL (XEXP (x, 1)) & ((((unsigned HOST_WIDE_INT) 1 << count)) - 1)) == 0 && (tem = extract_left_shift (XEXP (x, 0), count)) != 0) { HOST_WIDE_INT val = INTVAL (XEXP (x, 1)) >> count; return simplify_gen_binary (code, mode, tem, gen_int_mode (val, mode)); } break; default: break; } return 0; } /* Look at the expression rooted at X. Look for expressions equivalent to ZERO_EXTRACT, SIGN_EXTRACT, ZERO_EXTEND, SIGN_EXTEND. Form these expressions. Return the new rtx, usually just X. Also, for machines like the VAX that don't have logical shift insns, try to convert logical to arithmetic shift operations in cases where they are equivalent. This undoes the canonicalizations to logical shifts done elsewhere. We try, as much as possible, to re-use rtl expressions to save memory. IN_CODE says what kind of expression we are processing. Normally, it is SET. In a memory address it is MEM. When processing the arguments of a comparison or a COMPARE against zero, it is COMPARE. */ rtx make_compound_operation (rtx x, enum rtx_code in_code) { enum rtx_code code = GET_CODE (x); machine_mode mode = GET_MODE (x); int mode_width = GET_MODE_PRECISION (mode); rtx rhs, lhs; enum rtx_code next_code; int i, j; rtx new_rtx = 0; rtx tem; const char *fmt; /* Select the code to be used in recursive calls. Once we are inside an address, we stay there. If we have a comparison, set to COMPARE, but once inside, go back to our default of SET. */ next_code = (code == MEM ? MEM : ((code == COMPARE || COMPARISON_P (x)) && XEXP (x, 1) == const0_rtx) ? COMPARE : in_code == COMPARE ? SET : in_code); /* Process depending on the code of this operation. If NEW is set nonzero, it will be returned. */ switch (code) { case ASHIFT: /* Convert shifts by constants into multiplications if inside an address. */ if (in_code == MEM && CONST_INT_P (XEXP (x, 1)) && INTVAL (XEXP (x, 1)) < HOST_BITS_PER_WIDE_INT && INTVAL (XEXP (x, 1)) >= 0 && SCALAR_INT_MODE_P (mode)) { HOST_WIDE_INT count = INTVAL (XEXP (x, 1)); HOST_WIDE_INT multval = (HOST_WIDE_INT) 1 << count; new_rtx = make_compound_operation (XEXP (x, 0), next_code); if (GET_CODE (new_rtx) == NEG) { new_rtx = XEXP (new_rtx, 0); multval = -multval; } multval = trunc_int_for_mode (multval, mode); new_rtx = gen_rtx_MULT (mode, new_rtx, gen_int_mode (multval, mode)); } break; case PLUS: lhs = XEXP (x, 0); rhs = XEXP (x, 1); lhs = make_compound_operation (lhs, next_code); rhs = make_compound_operation (rhs, next_code); if (GET_CODE (lhs) == MULT && GET_CODE (XEXP (lhs, 0)) == NEG && SCALAR_INT_MODE_P (mode)) { tem = simplify_gen_binary (MULT, mode, XEXP (XEXP (lhs, 0), 0), XEXP (lhs, 1)); new_rtx = simplify_gen_binary (MINUS, mode, rhs, tem); } else if (GET_CODE (lhs) == MULT && (CONST_INT_P (XEXP (lhs, 1)) && INTVAL (XEXP (lhs, 1)) < 0)) { tem = simplify_gen_binary (MULT, mode, XEXP (lhs, 0), simplify_gen_unary (NEG, mode, XEXP (lhs, 1), mode)); new_rtx = simplify_gen_binary (MINUS, mode, rhs, tem); } else { SUBST (XEXP (x, 0), lhs); SUBST (XEXP (x, 1), rhs); goto maybe_swap; } x = gen_lowpart (mode, new_rtx); goto maybe_swap; case MINUS: lhs = XEXP (x, 0); rhs = XEXP (x, 1); lhs = make_compound_operation (lhs, next_code); rhs = make_compound_operation (rhs, next_code); if (GET_CODE (rhs) == MULT && GET_CODE (XEXP (rhs, 0)) == NEG && SCALAR_INT_MODE_P (mode)) { tem = simplify_gen_binary (MULT, mode, XEXP (XEXP (rhs, 0), 0), XEXP (rhs, 1)); new_rtx = simplify_gen_binary (PLUS, mode, tem, lhs); } else if (GET_CODE (rhs) == MULT && (CONST_INT_P (XEXP (rhs, 1)) && INTVAL (XEXP (rhs, 1)) < 0)) { tem = simplify_gen_binary (MULT, mode, XEXP (rhs, 0), simplify_gen_unary (NEG, mode, XEXP (rhs, 1), mode)); new_rtx = simplify_gen_binary (PLUS, mode, tem, lhs); } else { SUBST (XEXP (x, 0), lhs); SUBST (XEXP (x, 1), rhs); return x; } return gen_lowpart (mode, new_rtx); case AND: /* If the second operand is not a constant, we can't do anything with it. */ if (!CONST_INT_P (XEXP (x, 1))) break; /* If the constant is a power of two minus one and the first operand is a logical right shift, make an extraction. */ if (GET_CODE (XEXP (x, 0)) == LSHIFTRT && (i = exact_log2 (UINTVAL (XEXP (x, 1)) + 1)) >= 0) { new_rtx = make_compound_operation (XEXP (XEXP (x, 0), 0), next_code); new_rtx = make_extraction (mode, new_rtx, 0, XEXP (XEXP (x, 0), 1), i, 1, 0, in_code == COMPARE); } /* Same as previous, but for (subreg (lshiftrt ...)) in first op. */ else if (GET_CODE (XEXP (x, 0)) == SUBREG && subreg_lowpart_p (XEXP (x, 0)) && GET_CODE (SUBREG_REG (XEXP (x, 0))) == LSHIFTRT && (i = exact_log2 (UINTVAL (XEXP (x, 1)) + 1)) >= 0) { new_rtx = make_compound_operation (XEXP (SUBREG_REG (XEXP (x, 0)), 0), next_code); new_rtx = make_extraction (GET_MODE (SUBREG_REG (XEXP (x, 0))), new_rtx, 0, XEXP (SUBREG_REG (XEXP (x, 0)), 1), i, 1, 0, in_code == COMPARE); /* If that didn't give anything, see if the AND simplifies on its own. */ if (!new_rtx && i >= 0) { new_rtx = make_compound_operation (XEXP (x, 0), next_code); new_rtx = make_extraction (mode, new_rtx, 0, NULL_RTX, i, 1, 0, in_code == COMPARE); } } /* Same as previous, but for (xor/ior (lshiftrt...) (lshiftrt...)). */ else if ((GET_CODE (XEXP (x, 0)) == XOR || GET_CODE (XEXP (x, 0)) == IOR) && GET_CODE (XEXP (XEXP (x, 0), 0)) == LSHIFTRT && GET_CODE (XEXP (XEXP (x, 0), 1)) == LSHIFTRT && (i = exact_log2 (UINTVAL (XEXP (x, 1)) + 1)) >= 0) { /* Apply the distributive law, and then try to make extractions. */ new_rtx = gen_rtx_fmt_ee (GET_CODE (XEXP (x, 0)), mode, gen_rtx_AND (mode, XEXP (XEXP (x, 0), 0), XEXP (x, 1)), gen_rtx_AND (mode, XEXP (XEXP (x, 0), 1), XEXP (x, 1))); new_rtx = make_compound_operation (new_rtx, in_code); } /* If we are have (and (rotate X C) M) and C is larger than the number of bits in M, this is an extraction. */ else if (GET_CODE (XEXP (x, 0)) == ROTATE && CONST_INT_P (XEXP (XEXP (x, 0), 1)) && (i = exact_log2 (UINTVAL (XEXP (x, 1)) + 1)) >= 0 && i <= INTVAL (XEXP (XEXP (x, 0), 1))) { new_rtx = make_compound_operation (XEXP (XEXP (x, 0), 0), next_code); new_rtx = make_extraction (mode, new_rtx, (GET_MODE_PRECISION (mode) - INTVAL (XEXP (XEXP (x, 0), 1))), NULL_RTX, i, 1, 0, in_code == COMPARE); } /* On machines without logical shifts, if the operand of the AND is a logical shift and our mask turns off all the propagated sign bits, we can replace the logical shift with an arithmetic shift. */ else if (GET_CODE (XEXP (x, 0)) == LSHIFTRT && !have_insn_for (LSHIFTRT, mode) && have_insn_for (ASHIFTRT, mode) && CONST_INT_P (XEXP (XEXP (x, 0), 1)) && INTVAL (XEXP (XEXP (x, 0), 1)) >= 0 && INTVAL (XEXP (XEXP (x, 0), 1)) < HOST_BITS_PER_WIDE_INT && mode_width <= HOST_BITS_PER_WIDE_INT) { unsigned HOST_WIDE_INT mask = GET_MODE_MASK (mode); mask >>= INTVAL (XEXP (XEXP (x, 0), 1)); if ((INTVAL (XEXP (x, 1)) & ~mask) == 0) SUBST (XEXP (x, 0), gen_rtx_ASHIFTRT (mode, make_compound_operation (XEXP (XEXP (x, 0), 0), next_code), XEXP (XEXP (x, 0), 1))); } /* If the constant is one less than a power of two, this might be representable by an extraction even if no shift is present. If it doesn't end up being a ZERO_EXTEND, we will ignore it unless we are in a COMPARE. */ else if ((i = exact_log2 (UINTVAL (XEXP (x, 1)) + 1)) >= 0) new_rtx = make_extraction (mode, make_compound_operation (XEXP (x, 0), next_code), 0, NULL_RTX, i, 1, 0, in_code == COMPARE); /* If we are in a comparison and this is an AND with a power of two, convert this into the appropriate bit extract. */ else if (in_code == COMPARE && (i = exact_log2 (UINTVAL (XEXP (x, 1)))) >= 0) new_rtx = make_extraction (mode, make_compound_operation (XEXP (x, 0), next_code), i, NULL_RTX, 1, 1, 0, 1); break; case LSHIFTRT: /* If the sign bit is known to be zero, replace this with an arithmetic shift. */ if (have_insn_for (ASHIFTRT, mode) && ! have_insn_for (LSHIFTRT, mode) && mode_width <= HOST_BITS_PER_WIDE_INT && (nonzero_bits (XEXP (x, 0), mode) & (1 << (mode_width - 1))) == 0) { new_rtx = gen_rtx_ASHIFTRT (mode, make_compound_operation (XEXP (x, 0), next_code), XEXP (x, 1)); break; } /* ... fall through ... */ case ASHIFTRT: lhs = XEXP (x, 0); rhs = XEXP (x, 1); /* If we have (ashiftrt (ashift foo C1) C2) with C2 >= C1, this is a SIGN_EXTRACT. */ if (CONST_INT_P (rhs) && GET_CODE (lhs) == ASHIFT && CONST_INT_P (XEXP (lhs, 1)) && INTVAL (rhs) >= INTVAL (XEXP (lhs, 1)) && INTVAL (XEXP (lhs, 1)) >= 0 && INTVAL (rhs) < mode_width) { new_rtx = make_compound_operation (XEXP (lhs, 0), next_code); new_rtx = make_extraction (mode, new_rtx, INTVAL (rhs) - INTVAL (XEXP (lhs, 1)), NULL_RTX, mode_width - INTVAL (rhs), code == LSHIFTRT, 0, in_code == COMPARE); break; } /* See if we have operations between an ASHIFTRT and an ASHIFT. If so, try to merge the shifts into a SIGN_EXTEND. We could also do this for some cases of SIGN_EXTRACT, but it doesn't seem worth the effort; the case checked for occurs on Alpha. */ if (!OBJECT_P (lhs) && ! (GET_CODE (lhs) == SUBREG && (OBJECT_P (SUBREG_REG (lhs)))) && CONST_INT_P (rhs) && INTVAL (rhs) < HOST_BITS_PER_WIDE_INT && INTVAL (rhs) < mode_width && (new_rtx = extract_left_shift (lhs, INTVAL (rhs))) != 0) new_rtx = make_extraction (mode, make_compound_operation (new_rtx, next_code), 0, NULL_RTX, mode_width - INTVAL (rhs), code == LSHIFTRT, 0, in_code == COMPARE); break; case SUBREG: /* Call ourselves recursively on the inner expression. If we are narrowing the object and it has a different RTL code from what it originally did, do this SUBREG as a force_to_mode. */ { rtx inner = SUBREG_REG (x), simplified; enum rtx_code subreg_code = in_code; /* If in_code is COMPARE, it isn't always safe to pass it through to the recursive make_compound_operation call. */ if (subreg_code == COMPARE && (!subreg_lowpart_p (x) || GET_CODE (inner) == SUBREG /* (subreg:SI (and:DI (reg:DI) (const_int 0x800000000)) 0) is (const_int 0), rather than (subreg:SI (lshiftrt:DI (reg:DI) (const_int 35)) 0). */ || (GET_CODE (inner) == AND && CONST_INT_P (XEXP (inner, 1)) && GET_MODE_SIZE (mode) < GET_MODE_SIZE (GET_MODE (inner)) && exact_log2 (UINTVAL (XEXP (inner, 1))) >= GET_MODE_BITSIZE (mode)))) subreg_code = SET; tem = make_compound_operation (inner, subreg_code); simplified = simplify_subreg (mode, tem, GET_MODE (inner), SUBREG_BYTE (x)); if (simplified) tem = simplified; if (GET_CODE (tem) != GET_CODE (inner) && GET_MODE_SIZE (mode) < GET_MODE_SIZE (GET_MODE (inner)) && subreg_lowpart_p (x)) { rtx newer = force_to_mode (tem, mode, ~(unsigned HOST_WIDE_INT) 0, 0); /* If we have something other than a SUBREG, we might have done an expansion, so rerun ourselves. */ if (GET_CODE (newer) != SUBREG) newer = make_compound_operation (newer, in_code); /* force_to_mode can expand compounds. If it just re-expanded the compound, use gen_lowpart to convert to the desired mode. */ if (rtx_equal_p (newer, x) /* Likewise if it re-expanded the compound only partially. This happens for SUBREG of ZERO_EXTRACT if they extract the same number of bits. */ || (GET_CODE (newer) == SUBREG && (GET_CODE (SUBREG_REG (newer)) == LSHIFTRT || GET_CODE (SUBREG_REG (newer)) == ASHIFTRT) && GET_CODE (inner) == AND && rtx_equal_p (SUBREG_REG (newer), XEXP (inner, 0)))) return gen_lowpart (GET_MODE (x), tem); return newer; } if (simplified) return tem; } break; default: break; } if (new_rtx) { x = gen_lowpart (mode, new_rtx); code = GET_CODE (x); } /* Now recursively process each operand of this operation. We need to handle ZERO_EXTEND specially so that we don't lose track of the inner mode. */ if (GET_CODE (x) == ZERO_EXTEND) { new_rtx = make_compound_operation (XEXP (x, 0), next_code); tem = simplify_const_unary_operation (ZERO_EXTEND, GET_MODE (x), new_rtx, GET_MODE (XEXP (x, 0))); if (tem) return tem; SUBST (XEXP (x, 0), new_rtx); return x; } fmt = GET_RTX_FORMAT (code); for (i = 0; i < GET_RTX_LENGTH (code); i++) if (fmt[i] == 'e') { new_rtx = make_compound_operation (XEXP (x, i), next_code); SUBST (XEXP (x, i), new_rtx); } else if (fmt[i] == 'E') for (j = 0; j < XVECLEN (x, i); j++) { new_rtx = make_compound_operation (XVECEXP (x, i, j), next_code); SUBST (XVECEXP (x, i, j), new_rtx); } maybe_swap: /* If this is a commutative operation, the changes to the operands may have made it noncanonical. */ if (COMMUTATIVE_ARITH_P (x) && swap_commutative_operands_p (XEXP (x, 0), XEXP (x, 1))) { tem = XEXP (x, 0); SUBST (XEXP (x, 0), XEXP (x, 1)); SUBST (XEXP (x, 1), tem); } return x; } /* Given M see if it is a value that would select a field of bits within an item, but not the entire word. Return -1 if not. Otherwise, return the starting position of the field, where 0 is the low-order bit. *PLEN is set to the length of the field. */ static int get_pos_from_mask (unsigned HOST_WIDE_INT m, unsigned HOST_WIDE_INT *plen) { /* Get the bit number of the first 1 bit from the right, -1 if none. */ int pos = m ? ctz_hwi (m) : -1; int len = 0; if (pos >= 0) /* Now shift off the low-order zero bits and see if we have a power of two minus 1. */ len = exact_log2 ((m >> pos) + 1); if (len <= 0) pos = -1; *plen = len; return pos; } /* If X refers to a register that equals REG in value, replace these references with REG. */ static rtx canon_reg_for_combine (rtx x, rtx reg) { rtx op0, op1, op2; const char *fmt; int i; bool copied; enum rtx_code code = GET_CODE (x); switch (GET_RTX_CLASS (code)) { case RTX_UNARY: op0 = canon_reg_for_combine (XEXP (x, 0), reg); if (op0 != XEXP (x, 0)) return simplify_gen_unary (GET_CODE (x), GET_MODE (x), op0, GET_MODE (reg)); break; case RTX_BIN_ARITH: case RTX_COMM_ARITH: op0 = canon_reg_for_combine (XEXP (x, 0), reg); op1 = canon_reg_for_combine (XEXP (x, 1), reg); if (op0 != XEXP (x, 0) || op1 != XEXP (x, 1)) return simplify_gen_binary (GET_CODE (x), GET_MODE (x), op0, op1); break; case RTX_COMPARE: case RTX_COMM_COMPARE: op0 = canon_reg_for_combine (XEXP (x, 0), reg); op1 = canon_reg_for_combine (XEXP (x, 1), reg); if (op0 != XEXP (x, 0) || op1 != XEXP (x, 1)) return simplify_gen_relational (GET_CODE (x), GET_MODE (x), GET_MODE (op0), op0, op1); break; case RTX_TERNARY: case RTX_BITFIELD_OPS: op0 = canon_reg_for_combine (XEXP (x, 0), reg); op1 = canon_reg_for_combine (XEXP (x, 1), reg); op2 = canon_reg_for_combine (XEXP (x, 2), reg); if (op0 != XEXP (x, 0) || op1 != XEXP (x, 1) || op2 != XEXP (x, 2)) return simplify_gen_ternary (GET_CODE (x), GET_MODE (x), GET_MODE (op0), op0, op1, op2); case RTX_OBJ: if (REG_P (x)) { if (rtx_equal_p (get_last_value (reg), x) || rtx_equal_p (reg, get_last_value (x))) return reg; else break; } /* fall through */ default: fmt = GET_RTX_FORMAT (code); copied = false; for (i = GET_RTX_LENGTH (code) - 1; i >= 0; i--) if (fmt[i] == 'e') { rtx op = canon_reg_for_combine (XEXP (x, i), reg); if (op != XEXP (x, i)) { if (!copied) { copied = true; x = copy_rtx (x); } XEXP (x, i) = op; } } else if (fmt[i] == 'E') { int j; for (j = 0; j < XVECLEN (x, i); j++) { rtx op = canon_reg_for_combine (XVECEXP (x, i, j), reg); if (op != XVECEXP (x, i, j)) { if (!copied) { copied = true; x = copy_rtx (x); } XVECEXP (x, i, j) = op; } } } break; } return x; } /* Return X converted to MODE. If the value is already truncated to MODE we can just return a subreg even though in the general case we would need an explicit truncation. */ static rtx gen_lowpart_or_truncate (machine_mode mode, rtx x) { if (!CONST_INT_P (x) && GET_MODE_SIZE (mode) < GET_MODE_SIZE (GET_MODE (x)) && !TRULY_NOOP_TRUNCATION_MODES_P (mode, GET_MODE (x)) && !(REG_P (x) && reg_truncated_to_mode (mode, x))) { /* Bit-cast X into an integer mode. */ if (!SCALAR_INT_MODE_P (GET_MODE (x))) x = gen_lowpart (int_mode_for_mode (GET_MODE (x)), x); x = simplify_gen_unary (TRUNCATE, int_mode_for_mode (mode), x, GET_MODE (x)); } return gen_lowpart (mode, x); } /* See if X can be simplified knowing that we will only refer to it in MODE and will only refer to those bits that are nonzero in MASK. If other bits are being computed or if masking operations are done that select a superset of the bits in MASK, they can sometimes be ignored. Return a possibly simplified expression, but always convert X to MODE. If X is a CONST_INT, AND the CONST_INT with MASK. If JUST_SELECT is nonzero, don't optimize by noticing that bits in MASK are all off in X. This is used when X will be complemented, by either NOT, NEG, or XOR. */ static rtx force_to_mode (rtx x, machine_mode mode, unsigned HOST_WIDE_INT mask, int just_select) { enum rtx_code code = GET_CODE (x); int next_select = just_select || code == XOR || code == NOT || code == NEG; machine_mode op_mode; unsigned HOST_WIDE_INT fuller_mask, nonzero; rtx op0, op1, temp; /* If this is a CALL or ASM_OPERANDS, don't do anything. Some of the code below will do the wrong thing since the mode of such an expression is VOIDmode. Also do nothing if X is a CLOBBER; this can happen if X was the return value from a call to gen_lowpart. */ if (code == CALL || code == ASM_OPERANDS || code == CLOBBER) return x; /* We want to perform the operation in its present mode unless we know that the operation is valid in MODE, in which case we do the operation in MODE. */ op_mode = ((GET_MODE_CLASS (mode) == GET_MODE_CLASS (GET_MODE (x)) && have_insn_for (code, mode)) ? mode : GET_MODE (x)); /* It is not valid to do a right-shift in a narrower mode than the one it came in with. */ if ((code == LSHIFTRT || code == ASHIFTRT) && GET_MODE_PRECISION (mode) < GET_MODE_PRECISION (GET_MODE (x))) op_mode = GET_MODE (x); /* Truncate MASK to fit OP_MODE. */ if (op_mode) mask &= GET_MODE_MASK (op_mode); /* When we have an arithmetic operation, or a shift whose count we do not know, we need to assume that all bits up to the highest-order bit in MASK will be needed. This is how we form such a mask. */ if (mask & ((unsigned HOST_WIDE_INT) 1 << (HOST_BITS_PER_WIDE_INT - 1))) fuller_mask = ~(unsigned HOST_WIDE_INT) 0; else fuller_mask = (((unsigned HOST_WIDE_INT) 1 << (floor_log2 (mask) + 1)) - 1); /* Determine what bits of X are guaranteed to be (non)zero. */ nonzero = nonzero_bits (x, mode); /* If none of the bits in X are needed, return a zero. */ if (!just_select && (nonzero & mask) == 0 && !side_effects_p (x)) x = const0_rtx; /* If X is a CONST_INT, return a new one. Do this here since the test below will fail. */ if (CONST_INT_P (x)) { if (SCALAR_INT_MODE_P (mode)) return gen_int_mode (INTVAL (x) & mask, mode); else { x = GEN_INT (INTVAL (x) & mask); return gen_lowpart_common (mode, x); } } /* If X is narrower than MODE and we want all the bits in X's mode, just get X in the proper mode. */ if (GET_MODE_SIZE (GET_MODE (x)) < GET_MODE_SIZE (mode) && (GET_MODE_MASK (GET_MODE (x)) & ~mask) == 0) return gen_lowpart (mode, x); /* We can ignore the effect of a SUBREG if it narrows the mode or if the constant masks to zero all the bits the mode doesn't have. */ if (GET_CODE (x) == SUBREG && subreg_lowpart_p (x) && ((GET_MODE_SIZE (GET_MODE (x)) < GET_MODE_SIZE (GET_MODE (SUBREG_REG (x)))) || (0 == (mask & GET_MODE_MASK (GET_MODE (x)) & ~GET_MODE_MASK (GET_MODE (SUBREG_REG (x))))))) return force_to_mode (SUBREG_REG (x), mode, mask, next_select); /* The arithmetic simplifications here only work for scalar integer modes. */ if (!SCALAR_INT_MODE_P (mode) || !SCALAR_INT_MODE_P (GET_MODE (x))) return gen_lowpart_or_truncate (mode, x); switch (code) { case CLOBBER: /* If X is a (clobber (const_int)), return it since we know we are generating something that won't match. */ return x; case SIGN_EXTEND: case ZERO_EXTEND: case ZERO_EXTRACT: case SIGN_EXTRACT: x = expand_compound_operation (x); if (GET_CODE (x) != code) return force_to_mode (x, mode, mask, next_select); break; case TRUNCATE: /* Similarly for a truncate. */ return force_to_mode (XEXP (x, 0), mode, mask, next_select); case AND: /* If this is an AND with a constant, convert it into an AND whose constant is the AND of that constant with MASK. If it remains an AND of MASK, delete it since it is redundant. */ if (CONST_INT_P (XEXP (x, 1))) { x = simplify_and_const_int (x, op_mode, XEXP (x, 0), mask & INTVAL (XEXP (x, 1))); /* If X is still an AND, see if it is an AND with a mask that is just some low-order bits. If so, and it is MASK, we don't need it. */ if (GET_CODE (x) == AND && CONST_INT_P (XEXP (x, 1)) && ((INTVAL (XEXP (x, 1)) & GET_MODE_MASK (GET_MODE (x))) == mask)) x = XEXP (x, 0); /* If it remains an AND, try making another AND with the bits in the mode mask that aren't in MASK turned on. If the constant in the AND is wide enough, this might make a cheaper constant. */ if (GET_CODE (x) == AND && CONST_INT_P (XEXP (x, 1)) && GET_MODE_MASK (GET_MODE (x)) != mask && HWI_COMPUTABLE_MODE_P (GET_MODE (x))) { unsigned HOST_WIDE_INT cval = UINTVAL (XEXP (x, 1)) | (GET_MODE_MASK (GET_MODE (x)) & ~mask); rtx y; y = simplify_gen_binary (AND, GET_MODE (x), XEXP (x, 0), gen_int_mode (cval, GET_MODE (x))); if (set_src_cost (y, GET_MODE (x), optimize_this_for_speed_p) < set_src_cost (x, GET_MODE (x), optimize_this_for_speed_p)) x = y; } break; } goto binop; case PLUS: /* In (and (plus FOO C1) M), if M is a mask that just turns off low-order bits (as in an alignment operation) and FOO is already aligned to that boundary, mask C1 to that boundary as well. This may eliminate that PLUS and, later, the AND. */ { unsigned int width = GET_MODE_PRECISION (mode); unsigned HOST_WIDE_INT smask = mask; /* If MODE is narrower than HOST_WIDE_INT and mask is a negative number, sign extend it. */ if (width < HOST_BITS_PER_WIDE_INT && (smask & (HOST_WIDE_INT_1U << (width - 1))) != 0) smask |= HOST_WIDE_INT_M1U << width; if (CONST_INT_P (XEXP (x, 1)) && exact_log2 (- smask) >= 0 && (nonzero_bits (XEXP (x, 0), mode) & ~smask) == 0 && (INTVAL (XEXP (x, 1)) & ~smask) != 0) return force_to_mode (plus_constant (GET_MODE (x), XEXP (x, 0), (INTVAL (XEXP (x, 1)) & smask)), mode, smask, next_select); } /* ... fall through ... */ case MULT: /* Substituting into the operands of a widening MULT is not likely to create RTL matching a machine insn. */ if (code == MULT && (GET_CODE (XEXP (x, 0)) == ZERO_EXTEND || GET_CODE (XEXP (x, 0)) == SIGN_EXTEND) && (GET_CODE (XEXP (x, 1)) == ZERO_EXTEND || GET_CODE (XEXP (x, 1)) == SIGN_EXTEND) && REG_P (XEXP (XEXP (x, 0), 0)) && REG_P (XEXP (XEXP (x, 1), 0))) return gen_lowpart_or_truncate (mode, x); /* For PLUS, MINUS and MULT, we need any bits less significant than the most significant bit in MASK since carries from those bits will affect the bits we are interested in. */ mask = fuller_mask; goto binop; case MINUS: /* If X is (minus C Y) where C's least set bit is larger than any bit in the mask, then we may replace with (neg Y). */ if (CONST_INT_P (XEXP (x, 0)) && ((UINTVAL (XEXP (x, 0)) & -UINTVAL (XEXP (x, 0))) > mask)) { x = simplify_gen_unary (NEG, GET_MODE (x), XEXP (x, 1), GET_MODE (x)); return force_to_mode (x, mode, mask, next_select); } /* Similarly, if C contains every bit in the fuller_mask, then we may replace with (not Y). */ if (CONST_INT_P (XEXP (x, 0)) && ((UINTVAL (XEXP (x, 0)) | fuller_mask) == UINTVAL (XEXP (x, 0)))) { x = simplify_gen_unary (NOT, GET_MODE (x), XEXP (x, 1), GET_MODE (x)); return force_to_mode (x, mode, mask, next_select); } mask = fuller_mask; goto binop; case IOR: case XOR: /* If X is (ior (lshiftrt FOO C1) C2), try to commute the IOR and LSHIFTRT so we end up with an (and (lshiftrt (ior ...) ...) ...) operation which may be a bitfield extraction. Ensure that the constant we form is not wider than the mode of X. */ if (GET_CODE (XEXP (x, 0)) == LSHIFTRT && CONST_INT_P (XEXP (XEXP (x, 0), 1)) && INTVAL (XEXP (XEXP (x, 0), 1)) >= 0 && INTVAL (XEXP (XEXP (x, 0), 1)) < HOST_BITS_PER_WIDE_INT && CONST_INT_P (XEXP (x, 1)) && ((INTVAL (XEXP (XEXP (x, 0), 1)) + floor_log2 (INTVAL (XEXP (x, 1)))) < GET_MODE_PRECISION (GET_MODE (x))) && (UINTVAL (XEXP (x, 1)) & ~nonzero_bits (XEXP (x, 0), GET_MODE (x))) == 0) { temp = gen_int_mode ((INTVAL (XEXP (x, 1)) & mask) << INTVAL (XEXP (XEXP (x, 0), 1)), GET_MODE (x)); temp = simplify_gen_binary (GET_CODE (x), GET_MODE (x), XEXP (XEXP (x, 0), 0), temp); x = simplify_gen_binary (LSHIFTRT, GET_MODE (x), temp, XEXP (XEXP (x, 0), 1)); return force_to_mode (x, mode, mask, next_select); } binop: /* For most binary operations, just propagate into the operation and change the mode if we have an operation of that mode. */ op0 = force_to_mode (XEXP (x, 0), mode, mask, next_select); op1 = force_to_mode (XEXP (x, 1), mode, mask, next_select); /* If we ended up truncating both operands, truncate the result of the operation instead. */ if (GET_CODE (op0) == TRUNCATE && GET_CODE (op1) == TRUNCATE) { op0 = XEXP (op0, 0); op1 = XEXP (op1, 0); } op0 = gen_lowpart_or_truncate (op_mode, op0); op1 = gen_lowpart_or_truncate (op_mode, op1); if (op_mode != GET_MODE (x) || op0 != XEXP (x, 0) || op1 != XEXP (x, 1)) x = simplify_gen_binary (code, op_mode, op0, op1); break; case ASHIFT: /* For left shifts, do the same, but just for the first operand. However, we cannot do anything with shifts where we cannot guarantee that the counts are smaller than the size of the mode because such a count will have a different meaning in a wider mode. */ if (! (CONST_INT_P (XEXP (x, 1)) && INTVAL (XEXP (x, 1)) >= 0 && INTVAL (XEXP (x, 1)) < GET_MODE_PRECISION (mode)) && ! (GET_MODE (XEXP (x, 1)) != VOIDmode && (nonzero_bits (XEXP (x, 1), GET_MODE (XEXP (x, 1))) < (unsigned HOST_WIDE_INT) GET_MODE_PRECISION (mode)))) break; /* If the shift count is a constant and we can do arithmetic in the mode of the shift, refine which bits we need. Otherwise, use the conservative form of the mask. */ if (CONST_INT_P (XEXP (x, 1)) && INTVAL (XEXP (x, 1)) >= 0 && INTVAL (XEXP (x, 1)) < GET_MODE_PRECISION (op_mode) && HWI_COMPUTABLE_MODE_P (op_mode)) mask >>= INTVAL (XEXP (x, 1)); else mask = fuller_mask; op0 = gen_lowpart_or_truncate (op_mode, force_to_mode (XEXP (x, 0), op_mode, mask, next_select)); if (op_mode != GET_MODE (x) || op0 != XEXP (x, 0)) x = simplify_gen_binary (code, op_mode, op0, XEXP (x, 1)); break; case LSHIFTRT: /* Here we can only do something if the shift count is a constant, this shift constant is valid for the host, and we can do arithmetic in OP_MODE. */ if (CONST_INT_P (XEXP (x, 1)) && INTVAL (XEXP (x, 1)) >= 0 && INTVAL (XEXP (x, 1)) < HOST_BITS_PER_WIDE_INT && HWI_COMPUTABLE_MODE_P (op_mode)) { rtx inner = XEXP (x, 0); unsigned HOST_WIDE_INT inner_mask; /* Select the mask of the bits we need for the shift operand. */ inner_mask = mask << INTVAL (XEXP (x, 1)); /* We can only change the mode of the shift if we can do arithmetic in the mode of the shift and INNER_MASK is no wider than the width of X's mode. */ if ((inner_mask & ~GET_MODE_MASK (GET_MODE (x))) != 0) op_mode = GET_MODE (x); inner = force_to_mode (inner, op_mode, inner_mask, next_select); if (GET_MODE (x) != op_mode || inner != XEXP (x, 0)) x = simplify_gen_binary (LSHIFTRT, op_mode, inner, XEXP (x, 1)); } /* If we have (and (lshiftrt FOO C1) C2) where the combination of the shift and AND produces only copies of the sign bit (C2 is one less than a power of two), we can do this with just a shift. */ if (GET_CODE (x) == LSHIFTRT && CONST_INT_P (XEXP (x, 1)) /* The shift puts one of the sign bit copies in the least significant bit. */ && ((INTVAL (XEXP (x, 1)) + num_sign_bit_copies (XEXP (x, 0), GET_MODE (XEXP (x, 0)))) >= GET_MODE_PRECISION (GET_MODE (x))) && exact_log2 (mask + 1) >= 0 /* Number of bits left after the shift must be more than the mask needs. */ && ((INTVAL (XEXP (x, 1)) + exact_log2 (mask + 1)) <= GET_MODE_PRECISION (GET_MODE (x))) /* Must be more sign bit copies than the mask needs. */ && ((int) num_sign_bit_copies (XEXP (x, 0), GET_MODE (XEXP (x, 0))) >= exact_log2 (mask + 1))) x = simplify_gen_binary (LSHIFTRT, GET_MODE (x), XEXP (x, 0), GEN_INT (GET_MODE_PRECISION (GET_MODE (x)) - exact_log2 (mask + 1))); goto shiftrt; case ASHIFTRT: /* If we are just looking for the sign bit, we don't need this shift at all, even if it has a variable count. */ if (val_signbit_p (GET_MODE (x), mask)) return force_to_mode (XEXP (x, 0), mode, mask, next_select); /* If this is a shift by a constant, get a mask that contains those bits that are not copies of the sign bit. We then have two cases: If MASK only includes those bits, this can be a logical shift, which may allow simplifications. If MASK is a single-bit field not within those bits, we are requesting a copy of the sign bit and hence can shift the sign bit to the appropriate location. */ if (CONST_INT_P (XEXP (x, 1)) && INTVAL (XEXP (x, 1)) >= 0 && INTVAL (XEXP (x, 1)) < HOST_BITS_PER_WIDE_INT) { int i; /* If the considered data is wider than HOST_WIDE_INT, we can't represent a mask for all its bits in a single scalar. But we only care about the lower bits, so calculate these. */ if (GET_MODE_PRECISION (GET_MODE (x)) > HOST_BITS_PER_WIDE_INT) { nonzero = ~(unsigned HOST_WIDE_INT) 0; /* GET_MODE_PRECISION (GET_MODE (x)) - INTVAL (XEXP (x, 1)) is the number of bits a full-width mask would have set. We need only shift if these are fewer than nonzero can hold. If not, we must keep all bits set in nonzero. */ if (GET_MODE_PRECISION (GET_MODE (x)) - INTVAL (XEXP (x, 1)) < HOST_BITS_PER_WIDE_INT) nonzero >>= INTVAL (XEXP (x, 1)) + HOST_BITS_PER_WIDE_INT - GET_MODE_PRECISION (GET_MODE (x)) ; } else { nonzero = GET_MODE_MASK (GET_MODE (x)); nonzero >>= INTVAL (XEXP (x, 1)); } if ((mask & ~nonzero) == 0) { x = simplify_shift_const (NULL_RTX, LSHIFTRT, GET_MODE (x), XEXP (x, 0), INTVAL (XEXP (x, 1))); if (GET_CODE (x) != ASHIFTRT) return force_to_mode (x, mode, mask, next_select); } else if ((i = exact_log2 (mask)) >= 0) { x = simplify_shift_const (NULL_RTX, LSHIFTRT, GET_MODE (x), XEXP (x, 0), GET_MODE_PRECISION (GET_MODE (x)) - 1 - i); if (GET_CODE (x) != ASHIFTRT) return force_to_mode (x, mode, mask, next_select); } } /* If MASK is 1, convert this to an LSHIFTRT. This can be done even if the shift count isn't a constant. */ if (mask == 1) x = simplify_gen_binary (LSHIFTRT, GET_MODE (x), XEXP (x, 0), XEXP (x, 1)); shiftrt: /* If this is a zero- or sign-extension operation that just affects bits we don't care about, remove it. Be sure the call above returned something that is still a shift. */ if ((GET_CODE (x) == LSHIFTRT || GET_CODE (x) == ASHIFTRT) && CONST_INT_P (XEXP (x, 1)) && INTVAL (XEXP (x, 1)) >= 0 && (INTVAL (XEXP (x, 1)) <= GET_MODE_PRECISION (GET_MODE (x)) - (floor_log2 (mask) + 1)) && GET_CODE (XEXP (x, 0)) == ASHIFT && XEXP (XEXP (x, 0), 1) == XEXP (x, 1)) return force_to_mode (XEXP (XEXP (x, 0), 0), mode, mask, next_select); break; case ROTATE: case ROTATERT: /* If the shift count is constant and we can do computations in the mode of X, compute where the bits we care about are. Otherwise, we can't do anything. Don't change the mode of the shift or propagate MODE into the shift, though. */ if (CONST_INT_P (XEXP (x, 1)) && INTVAL (XEXP (x, 1)) >= 0) { temp = simplify_binary_operation (code == ROTATE ? ROTATERT : ROTATE, GET_MODE (x), gen_int_mode (mask, GET_MODE (x)), XEXP (x, 1)); if (temp && CONST_INT_P (temp)) x = simplify_gen_binary (code, GET_MODE (x), force_to_mode (XEXP (x, 0), GET_MODE (x), INTVAL (temp), next_select), XEXP (x, 1)); } break; case NEG: /* If we just want the low-order bit, the NEG isn't needed since it won't change the low-order bit. */ if (mask == 1) return force_to_mode (XEXP (x, 0), mode, mask, just_select); /* We need any bits less significant than the most significant bit in MASK since carries from those bits will affect the bits we are interested in. */ mask = fuller_mask; goto unop; case NOT: /* (not FOO) is (xor FOO CONST), so if FOO is an LSHIFTRT, we can do the same as the XOR case above. Ensure that the constant we form is not wider than the mode of X. */ if (GET_CODE (XEXP (x, 0)) == LSHIFTRT && CONST_INT_P (XEXP (XEXP (x, 0), 1)) && INTVAL (XEXP (XEXP (x, 0), 1)) >= 0 && (INTVAL (XEXP (XEXP (x, 0), 1)) + floor_log2 (mask) < GET_MODE_PRECISION (GET_MODE (x))) && INTVAL (XEXP (XEXP (x, 0), 1)) < HOST_BITS_PER_WIDE_INT) { temp = gen_int_mode (mask << INTVAL (XEXP (XEXP (x, 0), 1)), GET_MODE (x)); temp = simplify_gen_binary (XOR, GET_MODE (x), XEXP (XEXP (x, 0), 0), temp); x = simplify_gen_binary (LSHIFTRT, GET_MODE (x), temp, XEXP (XEXP (x, 0), 1)); return force_to_mode (x, mode, mask, next_select); } /* (and (not FOO) CONST) is (not (or FOO (not CONST))), so we must use the full mask inside the NOT. */ mask = fuller_mask; unop: op0 = gen_lowpart_or_truncate (op_mode, force_to_mode (XEXP (x, 0), mode, mask, next_select)); if (op_mode != GET_MODE (x) || op0 != XEXP (x, 0)) x = simplify_gen_unary (code, op_mode, op0, op_mode); break; case NE: /* (and (ne FOO 0) CONST) can be (and FOO CONST) if CONST is included in STORE_FLAG_VALUE and FOO has a single bit that might be nonzero, which is equal to STORE_FLAG_VALUE. */ if ((mask & ~STORE_FLAG_VALUE) == 0 && XEXP (x, 1) == const0_rtx && GET_MODE (XEXP (x, 0)) == mode && exact_log2 (nonzero_bits (XEXP (x, 0), mode)) >= 0 && (nonzero_bits (XEXP (x, 0), mode) == (unsigned HOST_WIDE_INT) STORE_FLAG_VALUE)) return force_to_mode (XEXP (x, 0), mode, mask, next_select); break; case IF_THEN_ELSE: /* We have no way of knowing if the IF_THEN_ELSE can itself be written in a narrower mode. We play it safe and do not do so. */ op0 = gen_lowpart_or_truncate (GET_MODE (x), force_to_mode (XEXP (x, 1), mode, mask, next_select)); op1 = gen_lowpart_or_truncate (GET_MODE (x), force_to_mode (XEXP (x, 2), mode, mask, next_select)); if (op0 != XEXP (x, 1) || op1 != XEXP (x, 2)) x = simplify_gen_ternary (IF_THEN_ELSE, GET_MODE (x), GET_MODE (XEXP (x, 0)), XEXP (x, 0), op0, op1); break; default: break; } /* Ensure we return a value of the proper mode. */ return gen_lowpart_or_truncate (mode, x); } /* Return nonzero if X is an expression that has one of two values depending on whether some other value is zero or nonzero. In that case, we return the value that is being tested, *PTRUE is set to the value if the rtx being returned has a nonzero value, and *PFALSE is set to the other alternative. If we return zero, we set *PTRUE and *PFALSE to X. */ static rtx if_then_else_cond (rtx x, rtx *ptrue, rtx *pfalse) { machine_mode mode = GET_MODE (x); enum rtx_code code = GET_CODE (x); rtx cond0, cond1, true0, true1, false0, false1; unsigned HOST_WIDE_INT nz; /* If we are comparing a value against zero, we are done. */ if ((code == NE || code == EQ) && XEXP (x, 1) == const0_rtx) { *ptrue = (code == NE) ? const_true_rtx : const0_rtx; *pfalse = (code == NE) ? const0_rtx : const_true_rtx; return XEXP (x, 0); } /* If this is a unary operation whose operand has one of two values, apply our opcode to compute those values. */ else if (UNARY_P (x) && (cond0 = if_then_else_cond (XEXP (x, 0), &true0, &false0)) != 0) { *ptrue = simplify_gen_unary (code, mode, true0, GET_MODE (XEXP (x, 0))); *pfalse = simplify_gen_unary (code, mode, false0, GET_MODE (XEXP (x, 0))); return cond0; } /* If this is a COMPARE, do nothing, since the IF_THEN_ELSE we would make can't possibly match and would suppress other optimizations. */ else if (code == COMPARE) ; /* If this is a binary operation, see if either side has only one of two values. If either one does or if both do and they are conditional on the same value, compute the new true and false values. */ else if (BINARY_P (x)) { cond0 = if_then_else_cond (XEXP (x, 0), &true0, &false0); cond1 = if_then_else_cond (XEXP (x, 1), &true1, &false1); if ((cond0 != 0 || cond1 != 0) && ! (cond0 != 0 && cond1 != 0 && ! rtx_equal_p (cond0, cond1))) { /* If if_then_else_cond returned zero, then true/false are the same rtl. We must copy one of them to prevent invalid rtl sharing. */ if (cond0 == 0) true0 = copy_rtx (true0); else if (cond1 == 0) true1 = copy_rtx (true1); if (COMPARISON_P (x)) { *ptrue = simplify_gen_relational (code, mode, VOIDmode, true0, true1); *pfalse = simplify_gen_relational (code, mode, VOIDmode, false0, false1); } else { *ptrue = simplify_gen_binary (code, mode, true0, true1); *pfalse = simplify_gen_binary (code, mode, false0, false1); } return cond0 ? cond0 : cond1; } /* See if we have PLUS, IOR, XOR, MINUS or UMAX, where one of the operands is zero when the other is nonzero, and vice-versa, and STORE_FLAG_VALUE is 1 or -1. */ if ((STORE_FLAG_VALUE == 1 || STORE_FLAG_VALUE == -1) && (code == PLUS || code == IOR || code == XOR || code == MINUS || code == UMAX) && GET_CODE (XEXP (x, 0)) == MULT && GET_CODE (XEXP (x, 1)) == MULT) { rtx op0 = XEXP (XEXP (x, 0), 1); rtx op1 = XEXP (XEXP (x, 1), 1); cond0 = XEXP (XEXP (x, 0), 0); cond1 = XEXP (XEXP (x, 1), 0); if (COMPARISON_P (cond0) && COMPARISON_P (cond1) && ((GET_CODE (cond0) == reversed_comparison_code (cond1, NULL) && rtx_equal_p (XEXP (cond0, 0), XEXP (cond1, 0)) && rtx_equal_p (XEXP (cond0, 1), XEXP (cond1, 1))) || ((swap_condition (GET_CODE (cond0)) == reversed_comparison_code (cond1, NULL)) && rtx_equal_p (XEXP (cond0, 0), XEXP (cond1, 1)) && rtx_equal_p (XEXP (cond0, 1), XEXP (cond1, 0)))) && ! side_effects_p (x)) { *ptrue = simplify_gen_binary (MULT, mode, op0, const_true_rtx); *pfalse = simplify_gen_binary (MULT, mode, (code == MINUS ? simplify_gen_unary (NEG, mode, op1, mode) : op1), const_true_rtx); return cond0; } } /* Similarly for MULT, AND and UMIN, except that for these the result is always zero. */ if ((STORE_FLAG_VALUE == 1 || STORE_FLAG_VALUE == -1) && (code == MULT || code == AND || code == UMIN) && GET_CODE (XEXP (x, 0)) == MULT && GET_CODE (XEXP (x, 1)) == MULT) { cond0 = XEXP (XEXP (x, 0), 0); cond1 = XEXP (XEXP (x, 1), 0); if (COMPARISON_P (cond0) && COMPARISON_P (cond1) && ((GET_CODE (cond0) == reversed_comparison_code (cond1, NULL) && rtx_equal_p (XEXP (cond0, 0), XEXP (cond1, 0)) && rtx_equal_p (XEXP (cond0, 1), XEXP (cond1, 1))) || ((swap_condition (GET_CODE (cond0)) == reversed_comparison_code (cond1, NULL)) && rtx_equal_p (XEXP (cond0, 0), XEXP (cond1, 1)) && rtx_equal_p (XEXP (cond0, 1), XEXP (cond1, 0)))) && ! side_effects_p (x)) { *ptrue = *pfalse = const0_rtx; return cond0; } } } else if (code == IF_THEN_ELSE) { /* If we have IF_THEN_ELSE already, extract the condition and canonicalize it if it is NE or EQ. */ cond0 = XEXP (x, 0); *ptrue = XEXP (x, 1), *pfalse = XEXP (x, 2); if (GET_CODE (cond0) == NE && XEXP (cond0, 1) == const0_rtx) return XEXP (cond0, 0); else if (GET_CODE (cond0) == EQ && XEXP (cond0, 1) == const0_rtx) { *ptrue = XEXP (x, 2), *pfalse = XEXP (x, 1); return XEXP (cond0, 0); } else return cond0; } /* If X is a SUBREG, we can narrow both the true and false values if the inner expression, if there is a condition. */ else if (code == SUBREG && 0 != (cond0 = if_then_else_cond (SUBREG_REG (x), &true0, &false0))) { true0 = simplify_gen_subreg (mode, true0, GET_MODE (SUBREG_REG (x)), SUBREG_BYTE (x)); false0 = simplify_gen_subreg (mode, false0, GET_MODE (SUBREG_REG (x)), SUBREG_BYTE (x)); if (true0 && false0) { *ptrue = true0; *pfalse = false0; return cond0; } } /* If X is a constant, this isn't special and will cause confusions if we treat it as such. Likewise if it is equivalent to a constant. */ else if (CONSTANT_P (x) || ((cond0 = get_last_value (x)) != 0 && CONSTANT_P (cond0))) ; /* If we're in BImode, canonicalize on 0 and STORE_FLAG_VALUE, as that will be least confusing to the rest of the compiler. */ else if (mode == BImode) { *ptrue = GEN_INT (STORE_FLAG_VALUE), *pfalse = const0_rtx; return x; } /* If X is known to be either 0 or -1, those are the true and false values when testing X. */ else if (x == constm1_rtx || x == const0_rtx || (mode != VOIDmode && num_sign_bit_copies (x, mode) == GET_MODE_PRECISION (mode))) { *ptrue = constm1_rtx, *pfalse = const0_rtx; return x; } /* Likewise for 0 or a single bit. */ else if (HWI_COMPUTABLE_MODE_P (mode) && exact_log2 (nz = nonzero_bits (x, mode)) >= 0) { *ptrue = gen_int_mode (nz, mode), *pfalse = const0_rtx; return x; } /* Otherwise fail; show no condition with true and false values the same. */ *ptrue = *pfalse = x; return 0; } /* Return the value of expression X given the fact that condition COND is known to be true when applied to REG as its first operand and VAL as its second. X is known to not be shared and so can be modified in place. We only handle the simplest cases, and specifically those cases that arise with IF_THEN_ELSE expressions. */ static rtx known_cond (rtx x, enum rtx_code cond, rtx reg, rtx val) { enum rtx_code code = GET_CODE (x); const char *fmt; int i, j; if (side_effects_p (x)) return x; /* If either operand of the condition is a floating point value, then we have to avoid collapsing an EQ comparison. */ if (cond == EQ && rtx_equal_p (x, reg) && ! FLOAT_MODE_P (GET_MODE (x)) && ! FLOAT_MODE_P (GET_MODE (val))) return val; if (cond == UNEQ && rtx_equal_p (x, reg)) return val; /* If X is (abs REG) and we know something about REG's relationship with zero, we may be able to simplify this. */ if (code == ABS && rtx_equal_p (XEXP (x, 0), reg) && val == const0_rtx) switch (cond) { case GE: case GT: case EQ: return XEXP (x, 0); case LT: case LE: return simplify_gen_unary (NEG, GET_MODE (XEXP (x, 0)), XEXP (x, 0), GET_MODE (XEXP (x, 0))); default: break; } /* The only other cases we handle are MIN, MAX, and comparisons if the operands are the same as REG and VAL. */ else if (COMPARISON_P (x) || COMMUTATIVE_ARITH_P (x)) { if (rtx_equal_p (XEXP (x, 0), val)) { std::swap (val, reg); cond = swap_condition (cond); } if (rtx_equal_p (XEXP (x, 0), reg) && rtx_equal_p (XEXP (x, 1), val)) { if (COMPARISON_P (x)) { if (comparison_dominates_p (cond, code)) return const_true_rtx; code = reversed_comparison_code (x, NULL); if (code != UNKNOWN && comparison_dominates_p (cond, code)) return const0_rtx; else return x; } else if (code == SMAX || code == SMIN || code == UMIN || code == UMAX) { int unsignedp = (code == UMIN || code == UMAX); /* Do not reverse the condition when it is NE or EQ. This is because we cannot conclude anything about the value of 'SMAX (x, y)' when x is not equal to y, but we can when x equals y. */ if ((code == SMAX || code == UMAX) && ! (cond == EQ || cond == NE)) cond = reverse_condition (cond); switch (cond) { case GE: case GT: return unsignedp ? x : XEXP (x, 1); case LE: case LT: return unsignedp ? x : XEXP (x, 0); case GEU: case GTU: return unsignedp ? XEXP (x, 1) : x; case LEU: case LTU: return unsignedp ? XEXP (x, 0) : x; default: break; } } } } else if (code == SUBREG) { machine_mode inner_mode = GET_MODE (SUBREG_REG (x)); rtx new_rtx, r = known_cond (SUBREG_REG (x), cond, reg, val); if (SUBREG_REG (x) != r) { /* We must simplify subreg here, before we lose track of the original inner_mode. */ new_rtx = simplify_subreg (GET_MODE (x), r, inner_mode, SUBREG_BYTE (x)); if (new_rtx) return new_rtx; else SUBST (SUBREG_REG (x), r); } return x; } /* We don't have to handle SIGN_EXTEND here, because even in the case of replacing something with a modeless CONST_INT, a CONST_INT is already (supposed to be) a valid sign extension for its narrower mode, which implies it's already properly sign-extended for the wider mode. Now, for ZERO_EXTEND, the story is different. */ else if (code == ZERO_EXTEND) { machine_mode inner_mode = GET_MODE (XEXP (x, 0)); rtx new_rtx, r = known_cond (XEXP (x, 0), cond, reg, val); if (XEXP (x, 0) != r) { /* We must simplify the zero_extend here, before we lose track of the original inner_mode. */ new_rtx = simplify_unary_operation (ZERO_EXTEND, GET_MODE (x), r, inner_mode); if (new_rtx) return new_rtx; else SUBST (XEXP (x, 0), r); } return x; } fmt = GET_RTX_FORMAT (code); for (i = GET_RTX_LENGTH (code) - 1; i >= 0; i--) { if (fmt[i] == 'e') SUBST (XEXP (x, i), known_cond (XEXP (x, i), cond, reg, val)); else if (fmt[i] == 'E') for (j = XVECLEN (x, i) - 1; j >= 0; j--) SUBST (XVECEXP (x, i, j), known_cond (XVECEXP (x, i, j), cond, reg, val)); } return x; } /* See if X and Y are equal for the purposes of seeing if we can rewrite an assignment as a field assignment. */ static int rtx_equal_for_field_assignment_p (rtx x, rtx y, bool widen_x) { if (widen_x && GET_MODE (x) != GET_MODE (y)) { if (GET_MODE_SIZE (GET_MODE (x)) > GET_MODE_SIZE (GET_MODE (y))) return 0; if (BYTES_BIG_ENDIAN != WORDS_BIG_ENDIAN) return 0; /* For big endian, adjust the memory offset. */ if (BYTES_BIG_ENDIAN) x = adjust_address_nv (x, GET_MODE (y), -subreg_lowpart_offset (GET_MODE (x), GET_MODE (y))); else x = adjust_address_nv (x, GET_MODE (y), 0); } if (x == y || rtx_equal_p (x, y)) return 1; if (x == 0 || y == 0 || GET_MODE (x) != GET_MODE (y)) return 0; /* Check for a paradoxical SUBREG of a MEM compared with the MEM. Note that all SUBREGs of MEM are paradoxical; otherwise they would have been rewritten. */ if (MEM_P (x) && GET_CODE (y) == SUBREG && MEM_P (SUBREG_REG (y)) && rtx_equal_p (SUBREG_REG (y), gen_lowpart (GET_MODE (SUBREG_REG (y)), x))) return 1; if (MEM_P (y) && GET_CODE (x) == SUBREG && MEM_P (SUBREG_REG (x)) && rtx_equal_p (SUBREG_REG (x), gen_lowpart (GET_MODE (SUBREG_REG (x)), y))) return 1; /* We used to see if get_last_value of X and Y were the same but that's not correct. In one direction, we'll cause the assignment to have the wrong destination and in the case, we'll import a register into this insn that might have already have been dead. So fail if none of the above cases are true. */ return 0; } /* See if X, a SET operation, can be rewritten as a bit-field assignment. Return that assignment if so. We only handle the most common cases. */ static rtx make_field_assignment (rtx x) { rtx dest = SET_DEST (x); rtx src = SET_SRC (x); rtx assign; rtx rhs, lhs; HOST_WIDE_INT c1; HOST_WIDE_INT pos; unsigned HOST_WIDE_INT len; rtx other; machine_mode mode; /* If SRC was (and (not (ashift (const_int 1) POS)) DEST), this is a clear of a one-bit field. We will have changed it to (and (rotate (const_int -2) POS) DEST), so check for that. Also check for a SUBREG. */ if (GET_CODE (src) == AND && GET_CODE (XEXP (src, 0)) == ROTATE && CONST_INT_P (XEXP (XEXP (src, 0), 0)) && INTVAL (XEXP (XEXP (src, 0), 0)) == -2 && rtx_equal_for_field_assignment_p (dest, XEXP (src, 1))) { assign = make_extraction (VOIDmode, dest, 0, XEXP (XEXP (src, 0), 1), 1, 1, 1, 0); if (assign != 0) return gen_rtx_SET (assign, const0_rtx); return x; } if (GET_CODE (src) == AND && GET_CODE (XEXP (src, 0)) == SUBREG && subreg_lowpart_p (XEXP (src, 0)) && (GET_MODE_SIZE (GET_MODE (XEXP (src, 0))) < GET_MODE_SIZE (GET_MODE (SUBREG_REG (XEXP (src, 0))))) && GET_CODE (SUBREG_REG (XEXP (src, 0))) == ROTATE && CONST_INT_P (XEXP (SUBREG_REG (XEXP (src, 0)), 0)) && INTVAL (XEXP (SUBREG_REG (XEXP (src, 0)), 0)) == -2 && rtx_equal_for_field_assignment_p (dest, XEXP (src, 1))) { assign = make_extraction (VOIDmode, dest, 0, XEXP (SUBREG_REG (XEXP (src, 0)), 1), 1, 1, 1, 0); if (assign != 0) return gen_rtx_SET (assign, const0_rtx); return x; } /* If SRC is (ior (ashift (const_int 1) POS) DEST), this is a set of a one-bit field. */ if (GET_CODE (src) == IOR && GET_CODE (XEXP (src, 0)) == ASHIFT && XEXP (XEXP (src, 0), 0) == const1_rtx && rtx_equal_for_field_assignment_p (dest, XEXP (src, 1))) { assign = make_extraction (VOIDmode, dest, 0, XEXP (XEXP (src, 0), 1), 1, 1, 1, 0); if (assign != 0) return gen_rtx_SET (assign, const1_rtx); return x; } /* If DEST is already a field assignment, i.e. ZERO_EXTRACT, and the SRC is an AND with all bits of that field set, then we can discard the AND. */ if (GET_CODE (dest) == ZERO_EXTRACT && CONST_INT_P (XEXP (dest, 1)) && GET_CODE (src) == AND && CONST_INT_P (XEXP (src, 1))) { HOST_WIDE_INT width = INTVAL (XEXP (dest, 1)); unsigned HOST_WIDE_INT and_mask = INTVAL (XEXP (src, 1)); unsigned HOST_WIDE_INT ze_mask; if (width >= HOST_BITS_PER_WIDE_INT) ze_mask = -1; else ze_mask = ((unsigned HOST_WIDE_INT)1 << width) - 1; /* Complete overlap. We can remove the source AND. */ if ((and_mask & ze_mask) == ze_mask) return gen_rtx_SET (dest, XEXP (src, 0)); /* Partial overlap. We can reduce the source AND. */ if ((and_mask & ze_mask) != and_mask) { mode = GET_MODE (src); src = gen_rtx_AND (mode, XEXP (src, 0), gen_int_mode (and_mask & ze_mask, mode)); return gen_rtx_SET (dest, src); } } /* The other case we handle is assignments into a constant-position field. They look like (ior/xor (and DEST C1) OTHER). If C1 represents a mask that has all one bits except for a group of zero bits and OTHER is known to have zeros where C1 has ones, this is such an assignment. Compute the position and length from C1. Shift OTHER to the appropriate position, force it to the required mode, and make the extraction. Check for the AND in both operands. */ /* One or more SUBREGs might obscure the constant-position field assignment. The first one we are likely to encounter is an outer narrowing SUBREG, which we can just strip for the purposes of identifying the constant-field assignment. */ if (GET_CODE (src) == SUBREG && subreg_lowpart_p (src)) src = SUBREG_REG (src); if (GET_CODE (src) != IOR && GET_CODE (src) != XOR) return x; rhs = expand_compound_operation (XEXP (src, 0)); lhs = expand_compound_operation (XEXP (src, 1)); if (GET_CODE (rhs) == AND && CONST_INT_P (XEXP (rhs, 1)) && rtx_equal_for_field_assignment_p (XEXP (rhs, 0), dest)) c1 = INTVAL (XEXP (rhs, 1)), other = lhs; /* The second SUBREG that might get in the way is a paradoxical SUBREG around the first operand of the AND. We want to pretend the operand is as wide as the destination here. We do this by adjusting the MEM to wider mode for the sole purpose of the call to rtx_equal_for_field_assignment_p. Also note this trick only works for MEMs. */ else if (GET_CODE (rhs) == AND && paradoxical_subreg_p (XEXP (rhs, 0)) && MEM_P (SUBREG_REG (XEXP (rhs, 0))) && CONST_INT_P (XEXP (rhs, 1)) && rtx_equal_for_field_assignment_p (SUBREG_REG (XEXP (rhs, 0)), dest, true)) c1 = INTVAL (XEXP (rhs, 1)), other = lhs; else if (GET_CODE (lhs) == AND && CONST_INT_P (XEXP (lhs, 1)) && rtx_equal_for_field_assignment_p (XEXP (lhs, 0), dest)) c1 = INTVAL (XEXP (lhs, 1)), other = rhs; /* The second SUBREG that might get in the way is a paradoxical SUBREG around the first operand of the AND. We want to pretend the operand is as wide as the destination here. We do this by adjusting the MEM to wider mode for the sole purpose of the call to rtx_equal_for_field_assignment_p. Also note this trick only works for MEMs. */ else if (GET_CODE (lhs) == AND && paradoxical_subreg_p (XEXP (lhs, 0)) && MEM_P (SUBREG_REG (XEXP (lhs, 0))) && CONST_INT_P (XEXP (lhs, 1)) && rtx_equal_for_field_assignment_p (SUBREG_REG (XEXP (lhs, 0)), dest, true)) c1 = INTVAL (XEXP (lhs, 1)), other = rhs; else return x; pos = get_pos_from_mask ((~c1) & GET_MODE_MASK (GET_MODE (dest)), &len); if (pos < 0 || pos + len > GET_MODE_PRECISION (GET_MODE (dest)) || GET_MODE_PRECISION (GET_MODE (dest)) > HOST_BITS_PER_WIDE_INT || (c1 & nonzero_bits (other, GET_MODE (dest))) != 0) return x; assign = make_extraction (VOIDmode, dest, pos, NULL_RTX, len, 1, 1, 0); if (assign == 0) return x; /* The mode to use for the source is the mode of the assignment, or of what is inside a possible STRICT_LOW_PART. */ mode = (GET_CODE (assign) == STRICT_LOW_PART ? GET_MODE (XEXP (assign, 0)) : GET_MODE (assign)); /* Shift OTHER right POS places and make it the source, restricting it to the proper length and mode. */ src = canon_reg_for_combine (simplify_shift_const (NULL_RTX, LSHIFTRT, GET_MODE (src), other, pos), dest); src = force_to_mode (src, mode, GET_MODE_PRECISION (mode) >= HOST_BITS_PER_WIDE_INT ? ~(unsigned HOST_WIDE_INT) 0 : ((unsigned HOST_WIDE_INT) 1 << len) - 1, 0); /* If SRC is masked by an AND that does not make a difference in the value being stored, strip it. */ if (GET_CODE (assign) == ZERO_EXTRACT && CONST_INT_P (XEXP (assign, 1)) && INTVAL (XEXP (assign, 1)) < HOST_BITS_PER_WIDE_INT && GET_CODE (src) == AND && CONST_INT_P (XEXP (src, 1)) && UINTVAL (XEXP (src, 1)) == ((unsigned HOST_WIDE_INT) 1 << INTVAL (XEXP (assign, 1))) - 1) src = XEXP (src, 0); return gen_rtx_SET (assign, src); } /* See if X is of the form (+ (* a c) (* b c)) and convert to (* (+ a b) c) if so. */ static rtx apply_distributive_law (rtx x) { enum rtx_code code = GET_CODE (x); enum rtx_code inner_code; rtx lhs, rhs, other; rtx tem; /* Distributivity is not true for floating point as it can change the value. So we don't do it unless -funsafe-math-optimizations. */ if (FLOAT_MODE_P (GET_MODE (x)) && ! flag_unsafe_math_optimizations) return x; /* The outer operation can only be one of the following: */ if (code != IOR && code != AND && code != XOR && code != PLUS && code != MINUS) return x; lhs = XEXP (x, 0); rhs = XEXP (x, 1); /* If either operand is a primitive we can't do anything, so get out fast. */ if (OBJECT_P (lhs) || OBJECT_P (rhs)) return x; lhs = expand_compound_operation (lhs); rhs = expand_compound_operation (rhs); inner_code = GET_CODE (lhs); if (inner_code != GET_CODE (rhs)) return x; /* See if the inner and outer operations distribute. */ switch (inner_code) { case LSHIFTRT: case ASHIFTRT: case AND: case IOR: /* These all distribute except over PLUS. */ if (code == PLUS || code == MINUS) return x; break; case MULT: if (code != PLUS && code != MINUS) return x; break; case ASHIFT: /* This is also a multiply, so it distributes over everything. */ break; /* This used to handle SUBREG, but this turned out to be counter- productive, since (subreg (op ...)) usually is not handled by insn patterns, and this "optimization" therefore transformed recognizable patterns into unrecognizable ones. Therefore the SUBREG case was removed from here. It is possible that distributing SUBREG over arithmetic operations leads to an intermediate result than can then be optimized further, e.g. by moving the outer SUBREG to the other side of a SET as done in simplify_set. This seems to have been the original intent of handling SUBREGs here. However, with current GCC this does not appear to actually happen, at least on major platforms. If some case is found where removing the SUBREG case here prevents follow-on optimizations, distributing SUBREGs ought to be re-added at that place, e.g. in simplify_set. */ default: return x; } /* Set LHS and RHS to the inner operands (A and B in the example above) and set OTHER to the common operand (C in the example). There is only one way to do this unless the inner operation is commutative. */ if (COMMUTATIVE_ARITH_P (lhs) && rtx_equal_p (XEXP (lhs, 0), XEXP (rhs, 0))) other = XEXP (lhs, 0), lhs = XEXP (lhs, 1), rhs = XEXP (rhs, 1); else if (COMMUTATIVE_ARITH_P (lhs) && rtx_equal_p (XEXP (lhs, 0), XEXP (rhs, 1))) other = XEXP (lhs, 0), lhs = XEXP (lhs, 1), rhs = XEXP (rhs, 0); else if (COMMUTATIVE_ARITH_P (lhs) && rtx_equal_p (XEXP (lhs, 1), XEXP (rhs, 0))) other = XEXP (lhs, 1), lhs = XEXP (lhs, 0), rhs = XEXP (rhs, 1); else if (rtx_equal_p (XEXP (lhs, 1), XEXP (rhs, 1))) other = XEXP (lhs, 1), lhs = XEXP (lhs, 0), rhs = XEXP (rhs, 0); else return x; /* Form the new inner operation, seeing if it simplifies first. */ tem = simplify_gen_binary (code, GET_MODE (x), lhs, rhs); /* There is one exception to the general way of distributing: (a | c) ^ (b | c) -> (a ^ b) & ~c */ if (code == XOR && inner_code == IOR) { inner_code = AND; other = simplify_gen_unary (NOT, GET_MODE (x), other, GET_MODE (x)); } /* We may be able to continuing distributing the result, so call ourselves recursively on the inner operation before forming the outer operation, which we return. */ return simplify_gen_binary (inner_code, GET_MODE (x), apply_distributive_law (tem), other); } /* See if X is of the form (* (+ A B) C), and if so convert to (+ (* A C) (* B C)) and try to simplify. Most of the time, this results in no change. However, if some of the operands are the same or inverses of each other, simplifications will result. For example, (and (ior A B) (not B)) can occur as the result of expanding a bit field assignment. When we apply the distributive law to this, we get (ior (and (A (not B))) (and (B (not B)))), which then simplifies to (and (A (not B))). Note that no checks happen on the validity of applying the inverse distributive law. This is pointless since we can do it in the few places where this routine is called. N is the index of the term that is decomposed (the arithmetic operation, i.e. (+ A B) in the first example above). !N is the index of the term that is distributed, i.e. of C in the first example above. */ static rtx distribute_and_simplify_rtx (rtx x, int n) { machine_mode mode; enum rtx_code outer_code, inner_code; rtx decomposed, distributed, inner_op0, inner_op1, new_op0, new_op1, tmp; /* Distributivity is not true for floating point as it can change the value. So we don't do it unless -funsafe-math-optimizations. */ if (FLOAT_MODE_P (GET_MODE (x)) && ! flag_unsafe_math_optimizations) return NULL_RTX; decomposed = XEXP (x, n); if (!ARITHMETIC_P (decomposed)) return NULL_RTX; mode = GET_MODE (x); outer_code = GET_CODE (x); distributed = XEXP (x, !n); inner_code = GET_CODE (decomposed); inner_op0 = XEXP (decomposed, 0); inner_op1 = XEXP (decomposed, 1); /* Special case (and (xor B C) (not A)), which is equivalent to (xor (ior A B) (ior A C)) */ if (outer_code == AND && inner_code == XOR && GET_CODE (distributed) == NOT) { distributed = XEXP (distributed, 0); outer_code = IOR; } if (n == 0) { /* Distribute the second term. */ new_op0 = simplify_gen_binary (outer_code, mode, inner_op0, distributed); new_op1 = simplify_gen_binary (outer_code, mode, inner_op1, distributed); } else { /* Distribute the first term. */ new_op0 = simplify_gen_binary (outer_code, mode, distributed, inner_op0); new_op1 = simplify_gen_binary (outer_code, mode, distributed, inner_op1); } tmp = apply_distributive_law (simplify_gen_binary (inner_code, mode, new_op0, new_op1)); if (GET_CODE (tmp) != outer_code && (set_src_cost (tmp, mode, optimize_this_for_speed_p) < set_src_cost (x, mode, optimize_this_for_speed_p))) return tmp; return NULL_RTX; } /* Simplify a logical `and' of VAROP with the constant CONSTOP, to be done in MODE. Return an equivalent form, if different from (and VAROP (const_int CONSTOP)). Otherwise, return NULL_RTX. */ static rtx simplify_and_const_int_1 (machine_mode mode, rtx varop, unsigned HOST_WIDE_INT constop) { unsigned HOST_WIDE_INT nonzero; unsigned HOST_WIDE_INT orig_constop; rtx orig_varop; int i; orig_varop = varop; orig_constop = constop; if (GET_CODE (varop) == CLOBBER) return NULL_RTX; /* Simplify VAROP knowing that we will be only looking at some of the bits in it. Note by passing in CONSTOP, we guarantee that the bits not set in CONSTOP are not significant and will never be examined. We must ensure that is the case by explicitly masking out those bits before returning. */ varop = force_to_mode (varop, mode, constop, 0); /* If VAROP is a CLOBBER, we will fail so return it. */ if (GET_CODE (varop) == CLOBBER) return varop; /* If VAROP is a CONST_INT, then we need to apply the mask in CONSTOP to VAROP and return the new constant. */ if (CONST_INT_P (varop)) return gen_int_mode (INTVAL (varop) & constop, mode); /* See what bits may be nonzero in VAROP. Unlike the general case of a call to nonzero_bits, here we don't care about bits outside MODE. */ nonzero = nonzero_bits (varop, mode) & GET_MODE_MASK (mode); /* Turn off all bits in the constant that are known to already be zero. Thus, if the AND isn't needed at all, we will have CONSTOP == NONZERO_BITS which is tested below. */ constop &= nonzero; /* If we don't have any bits left, return zero. */ if (constop == 0) return const0_rtx; /* If VAROP is a NEG of something known to be zero or 1 and CONSTOP is a power of two, we can replace this with an ASHIFT. */ if (GET_CODE (varop) == NEG && nonzero_bits (XEXP (varop, 0), mode) == 1 && (i = exact_log2 (constop)) >= 0) return simplify_shift_const (NULL_RTX, ASHIFT, mode, XEXP (varop, 0), i); /* If VAROP is an IOR or XOR, apply the AND to both branches of the IOR or XOR, then try to apply the distributive law. This may eliminate operations if either branch can be simplified because of the AND. It may also make some cases more complex, but those cases probably won't match a pattern either with or without this. */ if (GET_CODE (varop) == IOR || GET_CODE (varop) == XOR) return gen_lowpart (mode, apply_distributive_law (simplify_gen_binary (GET_CODE (varop), GET_MODE (varop), simplify_and_const_int (NULL_RTX, GET_MODE (varop), XEXP (varop, 0), constop), simplify_and_const_int (NULL_RTX, GET_MODE (varop), XEXP (varop, 1), constop)))); /* If VAROP is PLUS, and the constant is a mask of low bits, distribute the AND and see if one of the operands simplifies to zero. If so, we may eliminate it. */ if (GET_CODE (varop) == PLUS && exact_log2 (constop + 1) >= 0) { rtx o0, o1; o0 = simplify_and_const_int (NULL_RTX, mode, XEXP (varop, 0), constop); o1 = simplify_and_const_int (NULL_RTX, mode, XEXP (varop, 1), constop); if (o0 == const0_rtx) return o1; if (o1 == const0_rtx) return o0; } /* Make a SUBREG if necessary. If we can't make it, fail. */ varop = gen_lowpart (mode, varop); if (varop == NULL_RTX || GET_CODE (varop) == CLOBBER) return NULL_RTX; /* If we are only masking insignificant bits, return VAROP. */ if (constop == nonzero) return varop; if (varop == orig_varop && constop == orig_constop) return NULL_RTX; /* Otherwise, return an AND. */ return simplify_gen_binary (AND, mode, varop, gen_int_mode (constop, mode)); } /* We have X, a logical `and' of VAROP with the constant CONSTOP, to be done in MODE. Return an equivalent form, if different from X. Otherwise, return X. If X is zero, we are to always construct the equivalent form. */ static rtx simplify_and_const_int (rtx x, machine_mode mode, rtx varop, unsigned HOST_WIDE_INT constop) { rtx tem = simplify_and_const_int_1 (mode, varop, constop); if (tem) return tem; if (!x) x = simplify_gen_binary (AND, GET_MODE (varop), varop, gen_int_mode (constop, mode)); if (GET_MODE (x) != mode) x = gen_lowpart (mode, x); return x; } /* Given a REG, X, compute which bits in X can be nonzero. We don't care about bits outside of those defined in MODE. For most X this is simply GET_MODE_MASK (GET_MODE (MODE)), but if X is a shift, AND, or zero_extract, we can do better. */ static rtx reg_nonzero_bits_for_combine (const_rtx x, machine_mode mode, const_rtx known_x ATTRIBUTE_UNUSED, machine_mode known_mode ATTRIBUTE_UNUSED, unsigned HOST_WIDE_INT known_ret ATTRIBUTE_UNUSED, unsigned HOST_WIDE_INT *nonzero) { rtx tem; reg_stat_type *rsp; /* If X is a register whose nonzero bits value is current, use it. Otherwise, if X is a register whose value we can find, use that value. Otherwise, use the previously-computed global nonzero bits for this register. */ rsp = ®_stat[REGNO (x)]; if (rsp->last_set_value != 0 && (rsp->last_set_mode == mode || (GET_MODE_CLASS (rsp->last_set_mode) == MODE_INT && GET_MODE_CLASS (mode) == MODE_INT)) && ((rsp->last_set_label >= label_tick_ebb_start && rsp->last_set_label < label_tick) || (rsp->last_set_label == label_tick && DF_INSN_LUID (rsp->last_set) < subst_low_luid) || (REGNO (x) >= FIRST_PSEUDO_REGISTER && REGNO (x) < reg_n_sets_max && REG_N_SETS (REGNO (x)) == 1 && !REGNO_REG_SET_P (DF_LR_IN (ENTRY_BLOCK_PTR_FOR_FN (cfun)->next_bb), REGNO (x))))) { unsigned HOST_WIDE_INT mask = rsp->last_set_nonzero_bits; if (GET_MODE_PRECISION (rsp->last_set_mode) < GET_MODE_PRECISION (mode)) /* We don't know anything about the upper bits. */ mask |= GET_MODE_MASK (mode) ^ GET_MODE_MASK (rsp->last_set_mode); *nonzero &= mask; return NULL; } tem = get_last_value (x); if (tem) { if (SHORT_IMMEDIATES_SIGN_EXTEND) tem = sign_extend_short_imm (tem, GET_MODE (x), GET_MODE_PRECISION (mode)); return tem; } else if (nonzero_sign_valid && rsp->nonzero_bits) { unsigned HOST_WIDE_INT mask = rsp->nonzero_bits; if (GET_MODE_PRECISION (GET_MODE (x)) < GET_MODE_PRECISION (mode)) /* We don't know anything about the upper bits. */ mask |= GET_MODE_MASK (mode) ^ GET_MODE_MASK (GET_MODE (x)); *nonzero &= mask; } return NULL; } /* Return the number of bits at the high-order end of X that are known to be equal to the sign bit. X will be used in mode MODE; if MODE is VOIDmode, X will be used in its own mode. The returned value will always be between 1 and the number of bits in MODE. */ static rtx reg_num_sign_bit_copies_for_combine (const_rtx x, machine_mode mode, const_rtx known_x ATTRIBUTE_UNUSED, machine_mode known_mode ATTRIBUTE_UNUSED, unsigned int known_ret ATTRIBUTE_UNUSED, unsigned int *result) { rtx tem; reg_stat_type *rsp; rsp = ®_stat[REGNO (x)]; if (rsp->last_set_value != 0 && rsp->last_set_mode == mode && ((rsp->last_set_label >= label_tick_ebb_start && rsp->last_set_label < label_tick) || (rsp->last_set_label == label_tick && DF_INSN_LUID (rsp->last_set) < subst_low_luid) || (REGNO (x) >= FIRST_PSEUDO_REGISTER && REGNO (x) < reg_n_sets_max && REG_N_SETS (REGNO (x)) == 1 && !REGNO_REG_SET_P (DF_LR_IN (ENTRY_BLOCK_PTR_FOR_FN (cfun)->next_bb), REGNO (x))))) { *result = rsp->last_set_sign_bit_copies; return NULL; } tem = get_last_value (x); if (tem != 0) return tem; if (nonzero_sign_valid && rsp->sign_bit_copies != 0 && GET_MODE_PRECISION (GET_MODE (x)) == GET_MODE_PRECISION (mode)) *result = rsp->sign_bit_copies; return NULL; } /* Return the number of "extended" bits there are in X, when interpreted as a quantity in MODE whose signedness is indicated by UNSIGNEDP. For unsigned quantities, this is the number of high-order zero bits. For signed quantities, this is the number of copies of the sign bit minus 1. In both case, this function returns the number of "spare" bits. For example, if two quantities for which this function returns at least 1 are added, the addition is known not to overflow. This function will always return 0 unless called during combine, which implies that it must be called from a define_split. */ unsigned int extended_count (const_rtx x, machine_mode mode, int unsignedp) { if (nonzero_sign_valid == 0) return 0; return (unsignedp ? (HWI_COMPUTABLE_MODE_P (mode) ? (unsigned int) (GET_MODE_PRECISION (mode) - 1 - floor_log2 (nonzero_bits (x, mode))) : 0) : num_sign_bit_copies (x, mode) - 1); } /* This function is called from `simplify_shift_const' to merge two outer operations. Specifically, we have already found that we need to perform operation *POP0 with constant *PCONST0 at the outermost position. We would now like to also perform OP1 with constant CONST1 (with *POP0 being done last). Return 1 if we can do the operation and update *POP0 and *PCONST0 with the resulting operation. *PCOMP_P is set to 1 if we would need to complement the innermost operand, otherwise it is unchanged. MODE is the mode in which the operation will be done. No bits outside the width of this mode matter. It is assumed that the width of this mode is smaller than or equal to HOST_BITS_PER_WIDE_INT. If *POP0 or OP1 are UNKNOWN, it means no operation is required. Only NEG, PLUS, IOR, XOR, and AND are supported. We may set *POP0 to SET if the proper result is simply *PCONST0. If the resulting operation cannot be expressed as one operation, we return 0 and do not change *POP0, *PCONST0, and *PCOMP_P. */ static int merge_outer_ops (enum rtx_code *pop0, HOST_WIDE_INT *pconst0, enum rtx_code op1, HOST_WIDE_INT const1, machine_mode mode, int *pcomp_p) { enum rtx_code op0 = *pop0; HOST_WIDE_INT const0 = *pconst0; const0 &= GET_MODE_MASK (mode); const1 &= GET_MODE_MASK (mode); /* If OP0 is an AND, clear unimportant bits in CONST1. */ if (op0 == AND) const1 &= const0; /* If OP0 or OP1 is UNKNOWN, this is easy. Similarly if they are the same or if OP0 is SET. */ if (op1 == UNKNOWN || op0 == SET) return 1; else if (op0 == UNKNOWN) op0 = op1, const0 = const1; else if (op0 == op1) { switch (op0) { case AND: const0 &= const1; break; case IOR: const0 |= const1; break; case XOR: const0 ^= const1; break; case PLUS: const0 += const1; break; case NEG: op0 = UNKNOWN; break; default: break; } } /* Otherwise, if either is a PLUS or NEG, we can't do anything. */ else if (op0 == PLUS || op1 == PLUS || op0 == NEG || op1 == NEG) return 0; /* If the two constants aren't the same, we can't do anything. The remaining six cases can all be done. */ else if (const0 != const1) return 0; else switch (op0) { case IOR: if (op1 == AND) /* (a & b) | b == b */ op0 = SET; else /* op1 == XOR */ /* (a ^ b) | b == a | b */ {;} break; case XOR: if (op1 == AND) /* (a & b) ^ b == (~a) & b */ op0 = AND, *pcomp_p = 1; else /* op1 == IOR */ /* (a | b) ^ b == a & ~b */ op0 = AND, const0 = ~const0; break; case AND: if (op1 == IOR) /* (a | b) & b == b */ op0 = SET; else /* op1 == XOR */ /* (a ^ b) & b) == (~a) & b */ *pcomp_p = 1; break; default: break; } /* Check for NO-OP cases. */ const0 &= GET_MODE_MASK (mode); if (const0 == 0 && (op0 == IOR || op0 == XOR || op0 == PLUS)) op0 = UNKNOWN; else if (const0 == 0 && op0 == AND) op0 = SET; else if ((unsigned HOST_WIDE_INT) const0 == GET_MODE_MASK (mode) && op0 == AND) op0 = UNKNOWN; *pop0 = op0; /* ??? Slightly redundant with the above mask, but not entirely. Moving this above means we'd have to sign-extend the mode mask for the final test. */ if (op0 != UNKNOWN && op0 != NEG) *pconst0 = trunc_int_for_mode (const0, mode); return 1; } /* A helper to simplify_shift_const_1 to determine the mode we can perform the shift in. The original shift operation CODE is performed on OP in ORIG_MODE. Return the wider mode MODE if we can perform the operation in that mode. Return ORIG_MODE otherwise. We can also assume that the result of the shift is subject to operation OUTER_CODE with operand OUTER_CONST. */ static machine_mode try_widen_shift_mode (enum rtx_code code, rtx op, int count, machine_mode orig_mode, machine_mode mode, enum rtx_code outer_code, HOST_WIDE_INT outer_const) { if (orig_mode == mode) return mode; gcc_assert (GET_MODE_PRECISION (mode) > GET_MODE_PRECISION (orig_mode)); /* In general we can't perform in wider mode for right shift and rotate. */ switch (code) { case ASHIFTRT: /* We can still widen if the bits brought in from the left are identical to the sign bit of ORIG_MODE. */ if (num_sign_bit_copies (op, mode) > (unsigned) (GET_MODE_PRECISION (mode) - GET_MODE_PRECISION (orig_mode))) return mode; return orig_mode; case LSHIFTRT: /* Similarly here but with zero bits. */ if (HWI_COMPUTABLE_MODE_P (mode) && (nonzero_bits (op, mode) & ~GET_MODE_MASK (orig_mode)) == 0) return mode; /* We can also widen if the bits brought in will be masked off. This operation is performed in ORIG_MODE. */ if (outer_code == AND) { int care_bits = low_bitmask_len (orig_mode, outer_const); if (care_bits >= 0 && GET_MODE_PRECISION (orig_mode) - care_bits >= count) return mode; } /* fall through */ case ROTATE: return orig_mode; case ROTATERT: gcc_unreachable (); default: return mode; } } /* Simplify a shift of VAROP by ORIG_COUNT bits. CODE says what kind of shift. The result of the shift is RESULT_MODE. Return NULL_RTX if we cannot simplify it. Otherwise, return a simplified value. The shift is normally computed in the widest mode we find in VAROP, as long as it isn't a different number of words than RESULT_MODE. Exceptions are ASHIFTRT and ROTATE, which are always done in their original mode. */ static rtx simplify_shift_const_1 (enum rtx_code code, machine_mode result_mode, rtx varop, int orig_count) { enum rtx_code orig_code = code; rtx orig_varop = varop; int count; machine_mode mode = result_mode; machine_mode shift_mode, tmode; unsigned int mode_words = (GET_MODE_SIZE (mode) + (UNITS_PER_WORD - 1)) / UNITS_PER_WORD; /* We form (outer_op (code varop count) (outer_const)). */ enum rtx_code outer_op = UNKNOWN; HOST_WIDE_INT outer_const = 0; int complement_p = 0; rtx new_rtx, x; /* Make sure and truncate the "natural" shift on the way in. We don't want to do this inside the loop as it makes it more difficult to combine shifts. */ if (SHIFT_COUNT_TRUNCATED) orig_count &= GET_MODE_BITSIZE (mode) - 1; /* If we were given an invalid count, don't do anything except exactly what was requested. */ if (orig_count < 0 || orig_count >= (int) GET_MODE_PRECISION (mode)) return NULL_RTX; count = orig_count; /* Unless one of the branches of the `if' in this loop does a `continue', we will `break' the loop after the `if'. */ while (count != 0) { /* If we have an operand of (clobber (const_int 0)), fail. */ if (GET_CODE (varop) == CLOBBER) return NULL_RTX; /* Convert ROTATERT to ROTATE. */ if (code == ROTATERT) { unsigned int bitsize = GET_MODE_PRECISION (result_mode); code = ROTATE; if (VECTOR_MODE_P (result_mode)) count = bitsize / GET_MODE_NUNITS (result_mode) - count; else count = bitsize - count; } shift_mode = try_widen_shift_mode (code, varop, count, result_mode, mode, outer_op, outer_const); /* Handle cases where the count is greater than the size of the mode minus 1. For ASHIFT, use the size minus one as the count (this can occur when simplifying (lshiftrt (ashiftrt ..))). For rotates, take the count modulo the size. For other shifts, the result is zero. Since these shifts are being produced by the compiler by combining multiple operations, each of which are defined, we know what the result is supposed to be. */ if (count > (GET_MODE_PRECISION (shift_mode) - 1)) { if (code == ASHIFTRT) count = GET_MODE_PRECISION (shift_mode) - 1; else if (code == ROTATE || code == ROTATERT) count %= GET_MODE_PRECISION (shift_mode); else { /* We can't simply return zero because there may be an outer op. */ varop = const0_rtx; count = 0; break; } } /* If we discovered we had to complement VAROP, leave. Making a NOT here would cause an infinite loop. */ if (complement_p) break; /* An arithmetic right shift of a quantity known to be -1 or 0 is a no-op. */ if (code == ASHIFTRT && (num_sign_bit_copies (varop, shift_mode) == GET_MODE_PRECISION (shift_mode))) { count = 0; break; } /* If we are doing an arithmetic right shift and discarding all but the sign bit copies, this is equivalent to doing a shift by the bitsize minus one. Convert it into that shift because it will often allow other simplifications. */ if (code == ASHIFTRT && (count + num_sign_bit_copies (varop, shift_mode) >= GET_MODE_PRECISION (shift_mode))) count = GET_MODE_PRECISION (shift_mode) - 1; /* We simplify the tests below and elsewhere by converting ASHIFTRT to LSHIFTRT if we know the sign bit is clear. `make_compound_operation' will convert it to an ASHIFTRT for those machines (such as VAX) that don't have an LSHIFTRT. */ if (code == ASHIFTRT && val_signbit_known_clear_p (shift_mode, nonzero_bits (varop, shift_mode))) code = LSHIFTRT; if (((code == LSHIFTRT && HWI_COMPUTABLE_MODE_P (shift_mode) && !(nonzero_bits (varop, shift_mode) >> count)) || (code == ASHIFT && HWI_COMPUTABLE_MODE_P (shift_mode) && !((nonzero_bits (varop, shift_mode) << count) & GET_MODE_MASK (shift_mode)))) && !side_effects_p (varop)) varop = const0_rtx; switch (GET_CODE (varop)) { case SIGN_EXTEND: case ZERO_EXTEND: case SIGN_EXTRACT: case ZERO_EXTRACT: new_rtx = expand_compound_operation (varop); if (new_rtx != varop) { varop = new_rtx; continue; } break; case MEM: /* If we have (xshiftrt (mem ...) C) and C is MODE_WIDTH minus the width of a smaller mode, we can do this with a SIGN_EXTEND or ZERO_EXTEND from the narrower memory location. */ if ((code == ASHIFTRT || code == LSHIFTRT) && ! mode_dependent_address_p (XEXP (varop, 0), MEM_ADDR_SPACE (varop)) && ! MEM_VOLATILE_P (varop) && (tmode = mode_for_size (GET_MODE_BITSIZE (mode) - count, MODE_INT, 1)) != BLKmode) { new_rtx = adjust_address_nv (varop, tmode, BYTES_BIG_ENDIAN ? 0 : count / BITS_PER_UNIT); varop = gen_rtx_fmt_e (code == ASHIFTRT ? SIGN_EXTEND : ZERO_EXTEND, mode, new_rtx); count = 0; continue; } break; case SUBREG: /* If VAROP is a SUBREG, strip it as long as the inner operand has the same number of words as what we've seen so far. Then store the widest mode in MODE. */ if (subreg_lowpart_p (varop) && (GET_MODE_SIZE (GET_MODE (SUBREG_REG (varop))) > GET_MODE_SIZE (GET_MODE (varop))) && (unsigned int) ((GET_MODE_SIZE (GET_MODE (SUBREG_REG (varop))) + (UNITS_PER_WORD - 1)) / UNITS_PER_WORD) == mode_words && GET_MODE_CLASS (GET_MODE (varop)) == MODE_INT && GET_MODE_CLASS (GET_MODE (SUBREG_REG (varop))) == MODE_INT) { varop = SUBREG_REG (varop); if (GET_MODE_SIZE (GET_MODE (varop)) > GET_MODE_SIZE (mode)) mode = GET_MODE (varop); continue; } break; case MULT: /* Some machines use MULT instead of ASHIFT because MULT is cheaper. But it is still better on those machines to merge two shifts into one. */ if (CONST_INT_P (XEXP (varop, 1)) && exact_log2 (UINTVAL (XEXP (varop, 1))) >= 0) { varop = simplify_gen_binary (ASHIFT, GET_MODE (varop), XEXP (varop, 0), GEN_INT (exact_log2 ( UINTVAL (XEXP (varop, 1))))); continue; } break; case UDIV: /* Similar, for when divides are cheaper. */ if (CONST_INT_P (XEXP (varop, 1)) && exact_log2 (UINTVAL (XEXP (varop, 1))) >= 0) { varop = simplify_gen_binary (LSHIFTRT, GET_MODE (varop), XEXP (varop, 0), GEN_INT (exact_log2 ( UINTVAL (XEXP (varop, 1))))); continue; } break; case ASHIFTRT: /* If we are extracting just the sign bit of an arithmetic right shift, that shift is not needed. However, the sign bit of a wider mode may be different from what would be interpreted as the sign bit in a narrower mode, so, if the result is narrower, don't discard the shift. */ if (code == LSHIFTRT && count == (GET_MODE_BITSIZE (result_mode) - 1) && (GET_MODE_BITSIZE (result_mode) >= GET_MODE_BITSIZE (GET_MODE (varop)))) { varop = XEXP (varop, 0); continue; } /* ... fall through ... */ case LSHIFTRT: case ASHIFT: case ROTATE: /* Here we have two nested shifts. The result is usually the AND of a new shift with a mask. We compute the result below. */ if (CONST_INT_P (XEXP (varop, 1)) && INTVAL (XEXP (varop, 1)) >= 0 && INTVAL (XEXP (varop, 1)) < GET_MODE_PRECISION (GET_MODE (varop)) && HWI_COMPUTABLE_MODE_P (result_mode) && HWI_COMPUTABLE_MODE_P (mode) && !VECTOR_MODE_P (result_mode)) { enum rtx_code first_code = GET_CODE (varop); unsigned int first_count = INTVAL (XEXP (varop, 1)); unsigned HOST_WIDE_INT mask; rtx mask_rtx; /* We have one common special case. We can't do any merging if the inner code is an ASHIFTRT of a smaller mode. However, if we have (ashift:M1 (subreg:M1 (ashiftrt:M2 FOO C1) 0) C2) with C2 == GET_MODE_BITSIZE (M1) - GET_MODE_BITSIZE (M2), we can convert it to (ashiftrt:M1 (ashift:M1 (and:M1 (subreg:M1 FOO 0) C3) C2) C1). This simplifies certain SIGN_EXTEND operations. */ if (code == ASHIFT && first_code == ASHIFTRT && count == (GET_MODE_PRECISION (result_mode) - GET_MODE_PRECISION (GET_MODE (varop)))) { /* C3 has the low-order C1 bits zero. */ mask = GET_MODE_MASK (mode) & ~(((unsigned HOST_WIDE_INT) 1 << first_count) - 1); varop = simplify_and_const_int (NULL_RTX, result_mode, XEXP (varop, 0), mask); varop = simplify_shift_const (NULL_RTX, ASHIFT, result_mode, varop, count); count = first_count; code = ASHIFTRT; continue; } /* If this was (ashiftrt (ashift foo C1) C2) and FOO has more than C1 high-order bits equal to the sign bit, we can convert this to either an ASHIFT or an ASHIFTRT depending on the two counts. We cannot do this if VAROP's mode is not SHIFT_MODE. */ if (code == ASHIFTRT && first_code == ASHIFT && GET_MODE (varop) == shift_mode && (num_sign_bit_copies (XEXP (varop, 0), shift_mode) > first_count)) { varop = XEXP (varop, 0); count -= first_count; if (count < 0) { count = -count; code = ASHIFT; } continue; } /* There are some cases we can't do. If CODE is ASHIFTRT, we can only do this if FIRST_CODE is also ASHIFTRT. We can't do the case when CODE is ROTATE and FIRST_CODE is ASHIFTRT. If the mode of this shift is not the mode of the outer shift, we can't do this if either shift is a right shift or ROTATE. Finally, we can't do any of these if the mode is too wide unless the codes are the same. Handle the case where the shift codes are the same first. */ if (code == first_code) { if (GET_MODE (varop) != result_mode && (code == ASHIFTRT || code == LSHIFTRT || code == ROTATE)) break; count += first_count; varop = XEXP (varop, 0); continue; } if (code == ASHIFTRT || (code == ROTATE && first_code == ASHIFTRT) || GET_MODE_PRECISION (mode) > HOST_BITS_PER_WIDE_INT || (GET_MODE (varop) != result_mode && (first_code == ASHIFTRT || first_code == LSHIFTRT || first_code == ROTATE || code == ROTATE))) break; /* To compute the mask to apply after the shift, shift the nonzero bits of the inner shift the same way the outer shift will. */ mask_rtx = gen_int_mode (nonzero_bits (varop, GET_MODE (varop)), result_mode); mask_rtx = simplify_const_binary_operation (code, result_mode, mask_rtx, GEN_INT (count)); /* Give up if we can't compute an outer operation to use. */ if (mask_rtx == 0 || !CONST_INT_P (mask_rtx) || ! merge_outer_ops (&outer_op, &outer_const, AND, INTVAL (mask_rtx), result_mode, &complement_p)) break; /* If the shifts are in the same direction, we add the counts. Otherwise, we subtract them. */ if ((code == ASHIFTRT || code == LSHIFTRT) == (first_code == ASHIFTRT || first_code == LSHIFTRT)) count += first_count; else count -= first_count; /* If COUNT is positive, the new shift is usually CODE, except for the two exceptions below, in which case it is FIRST_CODE. If the count is negative, FIRST_CODE should always be used */ if (count > 0 && ((first_code == ROTATE && code == ASHIFT) || (first_code == ASHIFTRT && code == LSHIFTRT))) code = first_code; else if (count < 0) code = first_code, count = -count; varop = XEXP (varop, 0); continue; } /* If we have (A << B << C) for any shift, we can convert this to (A << C << B). This wins if A is a constant. Only try this if B is not a constant. */ else if (GET_CODE (varop) == code && CONST_INT_P (XEXP (varop, 0)) && !CONST_INT_P (XEXP (varop, 1))) { rtx new_rtx = simplify_const_binary_operation (code, mode, XEXP (varop, 0), GEN_INT (count)); varop = gen_rtx_fmt_ee (code, mode, new_rtx, XEXP (varop, 1)); count = 0; continue; } break; case NOT: if (VECTOR_MODE_P (mode)) break; /* Make this fit the case below. */ varop = gen_rtx_XOR (mode, XEXP (varop, 0), constm1_rtx); continue; case IOR: case AND: case XOR: /* If we have (xshiftrt (ior (plus X (const_int -1)) X) C) with C the size of VAROP - 1 and the shift is logical if STORE_FLAG_VALUE is 1 and arithmetic if STORE_FLAG_VALUE is -1, we have an (le X 0) operation. If we have an arithmetic shift and STORE_FLAG_VALUE is 1 or we have a logical shift with STORE_FLAG_VALUE of -1, we have a (neg (le X 0)) operation. */ if (GET_CODE (varop) == IOR && GET_CODE (XEXP (varop, 0)) == PLUS && XEXP (XEXP (varop, 0), 1) == constm1_rtx && (STORE_FLAG_VALUE == 1 || STORE_FLAG_VALUE == -1) && (code == LSHIFTRT || code == ASHIFTRT) && count == (GET_MODE_PRECISION (GET_MODE (varop)) - 1) && rtx_equal_p (XEXP (XEXP (varop, 0), 0), XEXP (varop, 1))) { count = 0; varop = gen_rtx_LE (GET_MODE (varop), XEXP (varop, 1), const0_rtx); if (STORE_FLAG_VALUE == 1 ? code == ASHIFTRT : code == LSHIFTRT) varop = gen_rtx_NEG (GET_MODE (varop), varop); continue; } /* If we have (shift (logical)), move the logical to the outside to allow it to possibly combine with another logical and the shift to combine with another shift. This also canonicalizes to what a ZERO_EXTRACT looks like. Also, some machines have (and (shift)) insns. */ if (CONST_INT_P (XEXP (varop, 1)) /* We can't do this if we have (ashiftrt (xor)) and the constant has its sign bit set in shift_mode with shift_mode wider than result_mode. */ && !(code == ASHIFTRT && GET_CODE (varop) == XOR && result_mode != shift_mode && 0 > trunc_int_for_mode (INTVAL (XEXP (varop, 1)), shift_mode)) && (new_rtx = simplify_const_binary_operation (code, result_mode, gen_int_mode (INTVAL (XEXP (varop, 1)), result_mode), GEN_INT (count))) != 0 && CONST_INT_P (new_rtx) && merge_outer_ops (&outer_op, &outer_const, GET_CODE (varop), INTVAL (new_rtx), result_mode, &complement_p)) { varop = XEXP (varop, 0); continue; } /* If we can't do that, try to simplify the shift in each arm of the logical expression, make a new logical expression, and apply the inverse distributive law. This also can't be done for (ashiftrt (xor)) where we've widened the shift and the constant changes the sign bit. */ if (CONST_INT_P (XEXP (varop, 1)) && !(code == ASHIFTRT && GET_CODE (varop) == XOR && result_mode != shift_mode && 0 > trunc_int_for_mode (INTVAL (XEXP (varop, 1)), shift_mode))) { rtx lhs = simplify_shift_const (NULL_RTX, code, shift_mode, XEXP (varop, 0), count); rtx rhs = simplify_shift_const (NULL_RTX, code, shift_mode, XEXP (varop, 1), count); varop = simplify_gen_binary (GET_CODE (varop), shift_mode, lhs, rhs); varop = apply_distributive_law (varop); count = 0; continue; } break; case EQ: /* Convert (lshiftrt (eq FOO 0) C) to (xor FOO 1) if STORE_FLAG_VALUE says that the sign bit can be tested, FOO has mode MODE, C is GET_MODE_PRECISION (MODE) - 1, and FOO has only its low-order bit that may be nonzero. */ if (code == LSHIFTRT && XEXP (varop, 1) == const0_rtx && GET_MODE (XEXP (varop, 0)) == result_mode && count == (GET_MODE_PRECISION (result_mode) - 1) && HWI_COMPUTABLE_MODE_P (result_mode) && STORE_FLAG_VALUE == -1 && nonzero_bits (XEXP (varop, 0), result_mode) == 1 && merge_outer_ops (&outer_op, &outer_const, XOR, 1, result_mode, &complement_p)) { varop = XEXP (varop, 0); count = 0; continue; } break; case NEG: /* (lshiftrt (neg A) C) where A is either 0 or 1 and C is one less than the number of bits in the mode is equivalent to A. */ if (code == LSHIFTRT && count == (GET_MODE_PRECISION (result_mode) - 1) && nonzero_bits (XEXP (varop, 0), result_mode) == 1) { varop = XEXP (varop, 0); count = 0; continue; } /* NEG commutes with ASHIFT since it is multiplication. Move the NEG outside to allow shifts to combine. */ if (code == ASHIFT && merge_outer_ops (&outer_op, &outer_const, NEG, 0, result_mode, &complement_p)) { varop = XEXP (varop, 0); continue; } break; case PLUS: /* (lshiftrt (plus A -1) C) where A is either 0 or 1 and C is one less than the number of bits in the mode is equivalent to (xor A 1). */ if (code == LSHIFTRT && count == (GET_MODE_PRECISION (result_mode) - 1) && XEXP (varop, 1) == constm1_rtx && nonzero_bits (XEXP (varop, 0), result_mode) == 1 && merge_outer_ops (&outer_op, &outer_const, XOR, 1, result_mode, &complement_p)) { count = 0; varop = XEXP (varop, 0); continue; } /* If we have (xshiftrt (plus FOO BAR) C), and the only bits that might be nonzero in BAR are those being shifted out and those bits are known zero in FOO, we can replace the PLUS with FOO. Similarly in the other operand order. This code occurs when we are computing the size of a variable-size array. */ if ((code == ASHIFTRT || code == LSHIFTRT) && count < HOST_BITS_PER_WIDE_INT && nonzero_bits (XEXP (varop, 1), result_mode) >> count == 0 && (nonzero_bits (XEXP (varop, 1), result_mode) & nonzero_bits (XEXP (varop, 0), result_mode)) == 0) { varop = XEXP (varop, 0); continue; } else if ((code == ASHIFTRT || code == LSHIFTRT) && count < HOST_BITS_PER_WIDE_INT && HWI_COMPUTABLE_MODE_P (result_mode) && 0 == (nonzero_bits (XEXP (varop, 0), result_mode) >> count) && 0 == (nonzero_bits (XEXP (varop, 0), result_mode) & nonzero_bits (XEXP (varop, 1), result_mode))) { varop = XEXP (varop, 1); continue; } /* (ashift (plus foo C) N) is (plus (ashift foo N) C'). */ if (code == ASHIFT && CONST_INT_P (XEXP (varop, 1)) && (new_rtx = simplify_const_binary_operation (ASHIFT, result_mode, gen_int_mode (INTVAL (XEXP (varop, 1)), result_mode), GEN_INT (count))) != 0 && CONST_INT_P (new_rtx) && merge_outer_ops (&outer_op, &outer_const, PLUS, INTVAL (new_rtx), result_mode, &complement_p)) { varop = XEXP (varop, 0); continue; } /* Check for 'PLUS signbit', which is the canonical form of 'XOR signbit', and attempt to change the PLUS to an XOR and move it to the outer operation as is done above in the AND/IOR/XOR case leg for shift(logical). See details in logical handling above for reasoning in doing so. */ if (code == LSHIFTRT && CONST_INT_P (XEXP (varop, 1)) && mode_signbit_p (result_mode, XEXP (varop, 1)) && (new_rtx = simplify_const_binary_operation (code, result_mode, gen_int_mode (INTVAL (XEXP (varop, 1)), result_mode), GEN_INT (count))) != 0 && CONST_INT_P (new_rtx) && merge_outer_ops (&outer_op, &outer_const, XOR, INTVAL (new_rtx), result_mode, &complement_p)) { varop = XEXP (varop, 0); continue; } break; case MINUS: /* If we have (xshiftrt (minus (ashiftrt X C)) X) C) with C the size of VAROP - 1 and the shift is logical if STORE_FLAG_VALUE is 1 and arithmetic if STORE_FLAG_VALUE is -1, we have a (gt X 0) operation. If the shift is arithmetic with STORE_FLAG_VALUE of 1 or logical with STORE_FLAG_VALUE == -1, we have a (neg (gt X 0)) operation. */ if ((STORE_FLAG_VALUE == 1 || STORE_FLAG_VALUE == -1) && GET_CODE (XEXP (varop, 0)) == ASHIFTRT && count == (GET_MODE_PRECISION (GET_MODE (varop)) - 1) && (code == LSHIFTRT || code == ASHIFTRT) && CONST_INT_P (XEXP (XEXP (varop, 0), 1)) && INTVAL (XEXP (XEXP (varop, 0), 1)) == count && rtx_equal_p (XEXP (XEXP (varop, 0), 0), XEXP (varop, 1))) { count = 0; varop = gen_rtx_GT (GET_MODE (varop), XEXP (varop, 1), const0_rtx); if (STORE_FLAG_VALUE == 1 ? code == ASHIFTRT : code == LSHIFTRT) varop = gen_rtx_NEG (GET_MODE (varop), varop); continue; } break; case TRUNCATE: /* Change (lshiftrt (truncate (lshiftrt))) to (truncate (lshiftrt)) if the truncate does not affect the value. */ if (code == LSHIFTRT && GET_CODE (XEXP (varop, 0)) == LSHIFTRT && CONST_INT_P (XEXP (XEXP (varop, 0), 1)) && (INTVAL (XEXP (XEXP (varop, 0), 1)) >= (GET_MODE_PRECISION (GET_MODE (XEXP (varop, 0))) - GET_MODE_PRECISION (GET_MODE (varop))))) { rtx varop_inner = XEXP (varop, 0); varop_inner = gen_rtx_LSHIFTRT (GET_MODE (varop_inner), XEXP (varop_inner, 0), GEN_INT (count + INTVAL (XEXP (varop_inner, 1)))); varop = gen_rtx_TRUNCATE (GET_MODE (varop), varop_inner); count = 0; continue; } break; default: break; } break; } shift_mode = try_widen_shift_mode (code, varop, count, result_mode, mode, outer_op, outer_const); /* We have now finished analyzing the shift. The result should be a shift of type CODE with SHIFT_MODE shifting VAROP COUNT places. If OUTER_OP is non-UNKNOWN, it is an operation that needs to be applied to the result of the shift. OUTER_CONST is the relevant constant, but we must turn off all bits turned off in the shift. */ if (outer_op == UNKNOWN && orig_code == code && orig_count == count && varop == orig_varop && shift_mode == GET_MODE (varop)) return NULL_RTX; /* Make a SUBREG if necessary. If we can't make it, fail. */ varop = gen_lowpart (shift_mode, varop); if (varop == NULL_RTX || GET_CODE (varop) == CLOBBER) return NULL_RTX; /* If we have an outer operation and we just made a shift, it is possible that we could have simplified the shift were it not for the outer operation. So try to do the simplification recursively. */ if (outer_op != UNKNOWN) x = simplify_shift_const_1 (code, shift_mode, varop, count); else x = NULL_RTX; if (x == NULL_RTX) x = simplify_gen_binary (code, shift_mode, varop, GEN_INT (count)); /* If we were doing an LSHIFTRT in a wider mode than it was originally, turn off all the bits that the shift would have turned off. */ if (orig_code == LSHIFTRT && result_mode != shift_mode) x = simplify_and_const_int (NULL_RTX, shift_mode, x, GET_MODE_MASK (result_mode) >> orig_count); /* Do the remainder of the processing in RESULT_MODE. */ x = gen_lowpart_or_truncate (result_mode, x); /* If COMPLEMENT_P is set, we have to complement X before doing the outer operation. */ if (complement_p) x = simplify_gen_unary (NOT, result_mode, x, result_mode); if (outer_op != UNKNOWN) { if (GET_RTX_CLASS (outer_op) != RTX_UNARY && GET_MODE_PRECISION (result_mode) < HOST_BITS_PER_WIDE_INT) outer_const = trunc_int_for_mode (outer_const, result_mode); if (outer_op == AND) x = simplify_and_const_int (NULL_RTX, result_mode, x, outer_const); else if (outer_op == SET) { /* This means that we have determined that the result is equivalent to a constant. This should be rare. */ if (!side_effects_p (x)) x = GEN_INT (outer_const); } else if (GET_RTX_CLASS (outer_op) == RTX_UNARY) x = simplify_gen_unary (outer_op, result_mode, x, result_mode); else x = simplify_gen_binary (outer_op, result_mode, x, GEN_INT (outer_const)); } return x; } /* Simplify a shift of VAROP by COUNT bits. CODE says what kind of shift. The result of the shift is RESULT_MODE. If we cannot simplify it, return X or, if it is NULL, synthesize the expression with simplify_gen_binary. Otherwise, return a simplified value. The shift is normally computed in the widest mode we find in VAROP, as long as it isn't a different number of words than RESULT_MODE. Exceptions are ASHIFTRT and ROTATE, which are always done in their original mode. */ static rtx simplify_shift_const (rtx x, enum rtx_code code, machine_mode result_mode, rtx varop, int count) { rtx tem = simplify_shift_const_1 (code, result_mode, varop, count); if (tem) return tem; if (!x) x = simplify_gen_binary (code, GET_MODE (varop), varop, GEN_INT (count)); if (GET_MODE (x) != result_mode) x = gen_lowpart (result_mode, x); return x; } /* A subroutine of recog_for_combine. See there for arguments and return value. */ static int recog_for_combine_1 (rtx *pnewpat, rtx_insn *insn, rtx *pnotes) { rtx pat = *pnewpat; rtx pat_without_clobbers; int insn_code_number; int num_clobbers_to_add = 0; int i; rtx notes = NULL_RTX; rtx old_notes, old_pat; int old_icode; /* If PAT is a PARALLEL, check to see if it contains the CLOBBER we use to indicate that something didn't match. If we find such a thing, force rejection. */ if (GET_CODE (pat) == PARALLEL) for (i = XVECLEN (pat, 0) - 1; i >= 0; i--) if (GET_CODE (XVECEXP (pat, 0, i)) == CLOBBER && XEXP (XVECEXP (pat, 0, i), 0) == const0_rtx) return -1; old_pat = PATTERN (insn); old_notes = REG_NOTES (insn); PATTERN (insn) = pat; REG_NOTES (insn) = NULL_RTX; insn_code_number = recog (pat, insn, &num_clobbers_to_add); if (dump_file && (dump_flags & TDF_DETAILS)) { if (insn_code_number < 0) fputs ("Failed to match this instruction:\n", dump_file); else fputs ("Successfully matched this instruction:\n", dump_file); print_rtl_single (dump_file, pat); } /* If it isn't, there is the possibility that we previously had an insn that clobbered some register as a side effect, but the combined insn doesn't need to do that. So try once more without the clobbers unless this represents an ASM insn. */ if (insn_code_number < 0 && ! check_asm_operands (pat) && GET_CODE (pat) == PARALLEL) { int pos; for (pos = 0, i = 0; i < XVECLEN (pat, 0); i++) if (GET_CODE (XVECEXP (pat, 0, i)) != CLOBBER) { if (i != pos) SUBST (XVECEXP (pat, 0, pos), XVECEXP (pat, 0, i)); pos++; } SUBST_INT (XVECLEN (pat, 0), pos); if (pos == 1) pat = XVECEXP (pat, 0, 0); PATTERN (insn) = pat; insn_code_number = recog (pat, insn, &num_clobbers_to_add); if (dump_file && (dump_flags & TDF_DETAILS)) { if (insn_code_number < 0) fputs ("Failed to match this instruction:\n", dump_file); else fputs ("Successfully matched this instruction:\n", dump_file); print_rtl_single (dump_file, pat); } } pat_without_clobbers = pat; PATTERN (insn) = old_pat; REG_NOTES (insn) = old_notes; /* Recognize all noop sets, these will be killed by followup pass. */ if (insn_code_number < 0 && GET_CODE (pat) == SET && set_noop_p (pat)) insn_code_number = NOOP_MOVE_INSN_CODE, num_clobbers_to_add = 0; /* If we had any clobbers to add, make a new pattern than contains them. Then check to make sure that all of them are dead. */ if (num_clobbers_to_add) { rtx newpat = gen_rtx_PARALLEL (VOIDmode, rtvec_alloc (GET_CODE (pat) == PARALLEL ? (XVECLEN (pat, 0) + num_clobbers_to_add) : num_clobbers_to_add + 1)); if (GET_CODE (pat) == PARALLEL) for (i = 0; i < XVECLEN (pat, 0); i++) XVECEXP (newpat, 0, i) = XVECEXP (pat, 0, i); else XVECEXP (newpat, 0, 0) = pat; add_clobbers (newpat, insn_code_number); for (i = XVECLEN (newpat, 0) - num_clobbers_to_add; i < XVECLEN (newpat, 0); i++) { if (REG_P (XEXP (XVECEXP (newpat, 0, i), 0)) && ! reg_dead_at_p (XEXP (XVECEXP (newpat, 0, i), 0), insn)) return -1; if (GET_CODE (XEXP (XVECEXP (newpat, 0, i), 0)) != SCRATCH) { gcc_assert (REG_P (XEXP (XVECEXP (newpat, 0, i), 0))); notes = alloc_reg_note (REG_UNUSED, XEXP (XVECEXP (newpat, 0, i), 0), notes); } } pat = newpat; } if (insn_code_number >= 0 && insn_code_number != NOOP_MOVE_INSN_CODE) { old_pat = PATTERN (insn); old_notes = REG_NOTES (insn); old_icode = INSN_CODE (insn); PATTERN (insn) = pat; REG_NOTES (insn) = notes; /* Allow targets to reject combined insn. */ if (!targetm.legitimate_combined_insn (insn)) { if (dump_file && (dump_flags & TDF_DETAILS)) fputs ("Instruction not appropriate for target.", dump_file); /* Callers expect recog_for_combine to strip clobbers from the pattern on failure. */ pat = pat_without_clobbers; notes = NULL_RTX; insn_code_number = -1; } PATTERN (insn) = old_pat; REG_NOTES (insn) = old_notes; INSN_CODE (insn) = old_icode; } *pnewpat = pat; *pnotes = notes; return insn_code_number; } /* Change every ZERO_EXTRACT and ZERO_EXTEND of a SUBREG that can be expressed as an AND and maybe an LSHIFTRT, to that formulation. Return whether anything was so changed. */ static bool change_zero_ext (rtx *src) { bool changed = false; subrtx_ptr_iterator::array_type array; FOR_EACH_SUBRTX_PTR (iter, array, src, NONCONST) { rtx x = **iter; machine_mode mode = GET_MODE (x); int size; if (GET_CODE (x) == ZERO_EXTRACT && CONST_INT_P (XEXP (x, 1)) && CONST_INT_P (XEXP (x, 2)) && GET_MODE (XEXP (x, 0)) == mode) { size = INTVAL (XEXP (x, 1)); int start = INTVAL (XEXP (x, 2)); if (BITS_BIG_ENDIAN) start = GET_MODE_PRECISION (mode) - size - start; x = gen_rtx_LSHIFTRT (mode, XEXP (x, 0), GEN_INT (start)); } else if (GET_CODE (x) == ZERO_EXTEND && GET_CODE (XEXP (x, 0)) == SUBREG && GET_MODE (SUBREG_REG (XEXP (x, 0))) == mode && subreg_lowpart_p (XEXP (x, 0))) { size = GET_MODE_PRECISION (GET_MODE (XEXP (x, 0))); x = SUBREG_REG (XEXP (x, 0)); } else continue; unsigned HOST_WIDE_INT mask = 1; mask <<= size; mask--; x = gen_rtx_AND (mode, x, GEN_INT (mask)); SUBST (**iter, x); changed = true; } return changed; } /* Like recog, but we receive the address of a pointer to a new pattern. We try to match the rtx that the pointer points to. If that fails, we may try to modify or replace the pattern, storing the replacement into the same pointer object. Modifications include deletion or addition of CLOBBERs. If the instruction will still not match, we change ZERO_EXTEND and ZERO_EXTRACT to the equivalent AND and perhaps LSHIFTRT patterns, and try with that (and undo if that fails). PNOTES is a pointer to a location where any REG_UNUSED notes added for the CLOBBERs are placed. The value is the final insn code from the pattern ultimately matched, or -1. */ static int recog_for_combine (rtx *pnewpat, rtx_insn *insn, rtx *pnotes) { rtx pat = PATTERN (insn); int insn_code_number = recog_for_combine_1 (pnewpat, insn, pnotes); if (insn_code_number >= 0 || check_asm_operands (pat)) return insn_code_number; void *marker = get_undo_marker (); bool changed = false; if (GET_CODE (pat) == SET) changed = change_zero_ext (&SET_SRC (pat)); else if (GET_CODE (pat) == PARALLEL) { int i; for (i = 0; i < XVECLEN (pat, 0); i++) { rtx set = XVECEXP (pat, 0, i); if (GET_CODE (set) == SET) changed |= change_zero_ext (&SET_SRC (set)); } } if (changed) { insn_code_number = recog_for_combine_1 (pnewpat, insn, pnotes); if (insn_code_number < 0) undo_to_marker (marker); } return insn_code_number; } /* Like gen_lowpart_general but for use by combine. In combine it is not possible to create any new pseudoregs. However, it is safe to create invalid memory addresses, because combine will try to recognize them and all they will do is make the combine attempt fail. If for some reason this cannot do its job, an rtx (clobber (const_int 0)) is returned. An insn containing that will not be recognized. */ static rtx gen_lowpart_for_combine (machine_mode omode, rtx x) { machine_mode imode = GET_MODE (x); unsigned int osize = GET_MODE_SIZE (omode); unsigned int isize = GET_MODE_SIZE (imode); rtx result; if (omode == imode) return x; /* We can only support MODE being wider than a word if X is a constant integer or has a mode the same size. */ if (GET_MODE_SIZE (omode) > UNITS_PER_WORD && ! (CONST_SCALAR_INT_P (x) || isize == osize)) goto fail; /* X might be a paradoxical (subreg (mem)). In that case, gen_lowpart won't know what to do. So we will strip off the SUBREG here and process normally. */ if (GET_CODE (x) == SUBREG && MEM_P (SUBREG_REG (x))) { x = SUBREG_REG (x); /* For use in case we fall down into the address adjustments further below, we need to adjust the known mode and size of x; imode and isize, since we just adjusted x. */ imode = GET_MODE (x); if (imode == omode) return x; isize = GET_MODE_SIZE (imode); } result = gen_lowpart_common (omode, x); if (result) return result; if (MEM_P (x)) { int offset = 0; /* Refuse to work on a volatile memory ref or one with a mode-dependent address. */ if (MEM_VOLATILE_P (x) || mode_dependent_address_p (XEXP (x, 0), MEM_ADDR_SPACE (x))) goto fail; /* If we want to refer to something bigger than the original memref, generate a paradoxical subreg instead. That will force a reload of the original memref X. */ if (isize < osize) return gen_rtx_SUBREG (omode, x, 0); if (WORDS_BIG_ENDIAN) offset = MAX (isize, UNITS_PER_WORD) - MAX (osize, UNITS_PER_WORD); /* Adjust the address so that the address-after-the-data is unchanged. */ if (BYTES_BIG_ENDIAN) offset -= MIN (UNITS_PER_WORD, osize) - MIN (UNITS_PER_WORD, isize); return adjust_address_nv (x, omode, offset); } /* If X is a comparison operator, rewrite it in a new mode. This probably won't match, but may allow further simplifications. */ else if (COMPARISON_P (x)) return gen_rtx_fmt_ee (GET_CODE (x), omode, XEXP (x, 0), XEXP (x, 1)); /* If we couldn't simplify X any other way, just enclose it in a SUBREG. Normally, this SUBREG won't match, but some patterns may include an explicit SUBREG or we may simplify it further in combine. */ else { rtx res; if (imode == VOIDmode) { imode = int_mode_for_mode (omode); x = gen_lowpart_common (imode, x); if (x == NULL) goto fail; } res = lowpart_subreg (omode, x, imode); if (res) return res; } fail: return gen_rtx_CLOBBER (omode, const0_rtx); } /* Try to simplify a comparison between OP0 and a constant OP1, where CODE is the comparison code that will be tested, into a (CODE OP0 const0_rtx) form. The result is a possibly different comparison code to use. *POP1 may be updated. */ static enum rtx_code simplify_compare_const (enum rtx_code code, machine_mode mode, rtx op0, rtx *pop1) { unsigned int mode_width = GET_MODE_PRECISION (mode); HOST_WIDE_INT const_op = INTVAL (*pop1); /* Get the constant we are comparing against and turn off all bits not on in our mode. */ if (mode != VOIDmode) const_op = trunc_int_for_mode (const_op, mode); /* If we are comparing against a constant power of two and the value being compared can only have that single bit nonzero (e.g., it was `and'ed with that bit), we can replace this with a comparison with zero. */ if (const_op && (code == EQ || code == NE || code == GE || code == GEU || code == LT || code == LTU) && mode_width - 1 < HOST_BITS_PER_WIDE_INT && exact_log2 (const_op & GET_MODE_MASK (mode)) >= 0 && (nonzero_bits (op0, mode) == (unsigned HOST_WIDE_INT) (const_op & GET_MODE_MASK (mode)))) { code = (code == EQ || code == GE || code == GEU ? NE : EQ); const_op = 0; } /* Similarly, if we are comparing a value known to be either -1 or 0 with -1, change it to the opposite comparison against zero. */ if (const_op == -1 && (code == EQ || code == NE || code == GT || code == LE || code == GEU || code == LTU) && num_sign_bit_copies (op0, mode) == mode_width) { code = (code == EQ || code == LE || code == GEU ? NE : EQ); const_op = 0; } /* Do some canonicalizations based on the comparison code. We prefer comparisons against zero and then prefer equality comparisons. If we can reduce the size of a constant, we will do that too. */ switch (code) { case LT: /* < C is equivalent to <= (C - 1) */ if (const_op > 0) { const_op -= 1; code = LE; /* ... fall through to LE case below. */ } else break; case LE: /* <= C is equivalent to < (C + 1); we do this for C < 0 */ if (const_op < 0) { const_op += 1; code = LT; } /* If we are doing a <= 0 comparison on a value known to have a zero sign bit, we can replace this with == 0. */ else if (const_op == 0 && mode_width - 1 < HOST_BITS_PER_WIDE_INT && (nonzero_bits (op0, mode) & ((unsigned HOST_WIDE_INT) 1 << (mode_width - 1))) == 0) code = EQ; break; case GE: /* >= C is equivalent to > (C - 1). */ if (const_op > 0) { const_op -= 1; code = GT; /* ... fall through to GT below. */ } else break; case GT: /* > C is equivalent to >= (C + 1); we do this for C < 0. */ if (const_op < 0) { const_op += 1; code = GE; } /* If we are doing a > 0 comparison on a value known to have a zero sign bit, we can replace this with != 0. */ else if (const_op == 0 && mode_width - 1 < HOST_BITS_PER_WIDE_INT && (nonzero_bits (op0, mode) & ((unsigned HOST_WIDE_INT) 1 << (mode_width - 1))) == 0) code = NE; break; case LTU: /* < C is equivalent to <= (C - 1). */ if (const_op > 0) { const_op -= 1; code = LEU; /* ... fall through ... */ } /* (unsigned) < 0x80000000 is equivalent to >= 0. */ else if (mode_width - 1 < HOST_BITS_PER_WIDE_INT && (unsigned HOST_WIDE_INT) const_op == (unsigned HOST_WIDE_INT) 1 << (mode_width - 1)) { const_op = 0; code = GE; break; } else break; case LEU: /* unsigned <= 0 is equivalent to == 0 */ if (const_op == 0) code = EQ; /* (unsigned) <= 0x7fffffff is equivalent to >= 0. */ else if (mode_width - 1 < HOST_BITS_PER_WIDE_INT && (unsigned HOST_WIDE_INT) const_op == ((unsigned HOST_WIDE_INT) 1 << (mode_width - 1)) - 1) { const_op = 0; code = GE; } break; case GEU: /* >= C is equivalent to > (C - 1). */ if (const_op > 1) { const_op -= 1; code = GTU; /* ... fall through ... */ } /* (unsigned) >= 0x80000000 is equivalent to < 0. */ else if (mode_width - 1 < HOST_BITS_PER_WIDE_INT && (unsigned HOST_WIDE_INT) const_op == (unsigned HOST_WIDE_INT) 1 << (mode_width - 1)) { const_op = 0; code = LT; break; } else break; case GTU: /* unsigned > 0 is equivalent to != 0 */ if (const_op == 0) code = NE; /* (unsigned) > 0x7fffffff is equivalent to < 0. */ else if (mode_width - 1 < HOST_BITS_PER_WIDE_INT && (unsigned HOST_WIDE_INT) const_op == ((unsigned HOST_WIDE_INT) 1 << (mode_width - 1)) - 1) { const_op = 0; code = LT; } break; default: break; } *pop1 = GEN_INT (const_op); return code; } /* Simplify a comparison between *POP0 and *POP1 where CODE is the comparison code that will be tested. The result is a possibly different comparison code to use. *POP0 and *POP1 may be updated. It is possible that we might detect that a comparison is either always true or always false. However, we do not perform general constant folding in combine, so this knowledge isn't useful. Such tautologies should have been detected earlier. Hence we ignore all such cases. */ static enum rtx_code simplify_comparison (enum rtx_code code, rtx *pop0, rtx *pop1) { rtx op0 = *pop0; rtx op1 = *pop1; rtx tem, tem1; int i; machine_mode mode, tmode; /* Try a few ways of applying the same transformation to both operands. */ while (1) { #if !WORD_REGISTER_OPERATIONS /* The test below this one won't handle SIGN_EXTENDs on these machines, so check specially. */ if (code != GTU && code != GEU && code != LTU && code != LEU && GET_CODE (op0) == ASHIFTRT && GET_CODE (op1) == ASHIFTRT && GET_CODE (XEXP (op0, 0)) == ASHIFT && GET_CODE (XEXP (op1, 0)) == ASHIFT && GET_CODE (XEXP (XEXP (op0, 0), 0)) == SUBREG && GET_CODE (XEXP (XEXP (op1, 0), 0)) == SUBREG && (GET_MODE (SUBREG_REG (XEXP (XEXP (op0, 0), 0))) == GET_MODE (SUBREG_REG (XEXP (XEXP (op1, 0), 0)))) && CONST_INT_P (XEXP (op0, 1)) && XEXP (op0, 1) == XEXP (op1, 1) && XEXP (op0, 1) == XEXP (XEXP (op0, 0), 1) && XEXP (op0, 1) == XEXP (XEXP (op1, 0), 1) && (INTVAL (XEXP (op0, 1)) == (GET_MODE_PRECISION (GET_MODE (op0)) - (GET_MODE_PRECISION (GET_MODE (SUBREG_REG (XEXP (XEXP (op0, 0), 0)))))))) { op0 = SUBREG_REG (XEXP (XEXP (op0, 0), 0)); op1 = SUBREG_REG (XEXP (XEXP (op1, 0), 0)); } #endif /* If both operands are the same constant shift, see if we can ignore the shift. We can if the shift is a rotate or if the bits shifted out of this shift are known to be zero for both inputs and if the type of comparison is compatible with the shift. */ if (GET_CODE (op0) == GET_CODE (op1) && HWI_COMPUTABLE_MODE_P (GET_MODE (op0)) && ((GET_CODE (op0) == ROTATE && (code == NE || code == EQ)) || ((GET_CODE (op0) == LSHIFTRT || GET_CODE (op0) == ASHIFT) && (code != GT && code != LT && code != GE && code != LE)) || (GET_CODE (op0) == ASHIFTRT && (code != GTU && code != LTU && code != GEU && code != LEU))) && CONST_INT_P (XEXP (op0, 1)) && INTVAL (XEXP (op0, 1)) >= 0 && INTVAL (XEXP (op0, 1)) < HOST_BITS_PER_WIDE_INT && XEXP (op0, 1) == XEXP (op1, 1)) { machine_mode mode = GET_MODE (op0); unsigned HOST_WIDE_INT mask = GET_MODE_MASK (mode); int shift_count = INTVAL (XEXP (op0, 1)); if (GET_CODE (op0) == LSHIFTRT || GET_CODE (op0) == ASHIFTRT) mask &= (mask >> shift_count) << shift_count; else if (GET_CODE (op0) == ASHIFT) mask = (mask & (mask << shift_count)) >> shift_count; if ((nonzero_bits (XEXP (op0, 0), mode) & ~mask) == 0 && (nonzero_bits (XEXP (op1, 0), mode) & ~mask) == 0) op0 = XEXP (op0, 0), op1 = XEXP (op1, 0); else break; } /* If both operands are AND's of a paradoxical SUBREG by constant, the SUBREGs are of the same mode, and, in both cases, the AND would be redundant if the comparison was done in the narrower mode, do the comparison in the narrower mode (e.g., we are AND'ing with 1 and the operand's possibly nonzero bits are 0xffffff01; in that case if we only care about QImode, we don't need the AND). This case occurs if the output mode of an scc insn is not SImode and STORE_FLAG_VALUE == 1 (e.g., the 386). Similarly, check for a case where the AND's are ZERO_EXTEND operations from some narrower mode even though a SUBREG is not present. */ else if (GET_CODE (op0) == AND && GET_CODE (op1) == AND && CONST_INT_P (XEXP (op0, 1)) && CONST_INT_P (XEXP (op1, 1))) { rtx inner_op0 = XEXP (op0, 0); rtx inner_op1 = XEXP (op1, 0); HOST_WIDE_INT c0 = INTVAL (XEXP (op0, 1)); HOST_WIDE_INT c1 = INTVAL (XEXP (op1, 1)); int changed = 0; if (paradoxical_subreg_p (inner_op0) && GET_CODE (inner_op1) == SUBREG && (GET_MODE (SUBREG_REG (inner_op0)) == GET_MODE (SUBREG_REG (inner_op1))) && (GET_MODE_PRECISION (GET_MODE (SUBREG_REG (inner_op0))) <= HOST_BITS_PER_WIDE_INT) && (0 == ((~c0) & nonzero_bits (SUBREG_REG (inner_op0), GET_MODE (SUBREG_REG (inner_op0))))) && (0 == ((~c1) & nonzero_bits (SUBREG_REG (inner_op1), GET_MODE (SUBREG_REG (inner_op1)))))) { op0 = SUBREG_REG (inner_op0); op1 = SUBREG_REG (inner_op1); /* The resulting comparison is always unsigned since we masked off the original sign bit. */ code = unsigned_condition (code); changed = 1; } else if (c0 == c1) for (tmode = GET_CLASS_NARROWEST_MODE (GET_MODE_CLASS (GET_MODE (op0))); tmode != GET_MODE (op0); tmode = GET_MODE_WIDER_MODE (tmode)) if ((unsigned HOST_WIDE_INT) c0 == GET_MODE_MASK (tmode)) { op0 = gen_lowpart_or_truncate (tmode, inner_op0); op1 = gen_lowpart_or_truncate (tmode, inner_op1); code = unsigned_condition (code); changed = 1; break; } if (! changed) break; } /* If both operands are NOT, we can strip off the outer operation and adjust the comparison code for swapped operands; similarly for NEG, except that this must be an equality comparison. */ else if ((GET_CODE (op0) == NOT && GET_CODE (op1) == NOT) || (GET_CODE (op0) == NEG && GET_CODE (op1) == NEG && (code == EQ || code == NE))) op0 = XEXP (op0, 0), op1 = XEXP (op1, 0), code = swap_condition (code); else break; } /* If the first operand is a constant, swap the operands and adjust the comparison code appropriately, but don't do this if the second operand is already a constant integer. */ if (swap_commutative_operands_p (op0, op1)) { std::swap (op0, op1); code = swap_condition (code); } /* We now enter a loop during which we will try to simplify the comparison. For the most part, we only are concerned with comparisons with zero, but some things may really be comparisons with zero but not start out looking that way. */ while (CONST_INT_P (op1)) { machine_mode mode = GET_MODE (op0); unsigned int mode_width = GET_MODE_PRECISION (mode); unsigned HOST_WIDE_INT mask = GET_MODE_MASK (mode); int equality_comparison_p; int sign_bit_comparison_p; int unsigned_comparison_p; HOST_WIDE_INT const_op; /* We only want to handle integral modes. This catches VOIDmode, CCmode, and the floating-point modes. An exception is that we can handle VOIDmode if OP0 is a COMPARE or a comparison operation. */ if (GET_MODE_CLASS (mode) != MODE_INT && ! (mode == VOIDmode && (GET_CODE (op0) == COMPARE || COMPARISON_P (op0)))) break; /* Try to simplify the compare to constant, possibly changing the comparison op, and/or changing op1 to zero. */ code = simplify_compare_const (code, mode, op0, &op1); const_op = INTVAL (op1); /* Compute some predicates to simplify code below. */ equality_comparison_p = (code == EQ || code == NE); sign_bit_comparison_p = ((code == LT || code == GE) && const_op == 0); unsigned_comparison_p = (code == LTU || code == LEU || code == GTU || code == GEU); /* If this is a sign bit comparison and we can do arithmetic in MODE, say that we will only be needing the sign bit of OP0. */ if (sign_bit_comparison_p && HWI_COMPUTABLE_MODE_P (mode)) op0 = force_to_mode (op0, mode, (unsigned HOST_WIDE_INT) 1 << (GET_MODE_PRECISION (mode) - 1), 0); /* Now try cases based on the opcode of OP0. If none of the cases does a "continue", we exit this loop immediately after the switch. */ switch (GET_CODE (op0)) { case ZERO_EXTRACT: /* If we are extracting a single bit from a variable position in a constant that has only a single bit set and are comparing it with zero, we can convert this into an equality comparison between the position and the location of the single bit. */ /* Except we can't if SHIFT_COUNT_TRUNCATED is set, since we might have already reduced the shift count modulo the word size. */ if (!SHIFT_COUNT_TRUNCATED && CONST_INT_P (XEXP (op0, 0)) && XEXP (op0, 1) == const1_rtx && equality_comparison_p && const_op == 0 && (i = exact_log2 (UINTVAL (XEXP (op0, 0)))) >= 0) { if (BITS_BIG_ENDIAN) i = BITS_PER_WORD - 1 - i; op0 = XEXP (op0, 2); op1 = GEN_INT (i); const_op = i; /* Result is nonzero iff shift count is equal to I. */ code = reverse_condition (code); continue; } /* ... fall through ... */ case SIGN_EXTRACT: tem = expand_compound_operation (op0); if (tem != op0) { op0 = tem; continue; } break; case NOT: /* If testing for equality, we can take the NOT of the constant. */ if (equality_comparison_p && (tem = simplify_unary_operation (NOT, mode, op1, mode)) != 0) { op0 = XEXP (op0, 0); op1 = tem; continue; } /* If just looking at the sign bit, reverse the sense of the comparison. */ if (sign_bit_comparison_p) { op0 = XEXP (op0, 0); code = (code == GE ? LT : GE); continue; } break; case NEG: /* If testing for equality, we can take the NEG of the constant. */ if (equality_comparison_p && (tem = simplify_unary_operation (NEG, mode, op1, mode)) != 0) { op0 = XEXP (op0, 0); op1 = tem; continue; } /* The remaining cases only apply to comparisons with zero. */ if (const_op != 0) break; /* When X is ABS or is known positive, (neg X) is < 0 if and only if X != 0. */ if (sign_bit_comparison_p && (GET_CODE (XEXP (op0, 0)) == ABS || (mode_width <= HOST_BITS_PER_WIDE_INT && (nonzero_bits (XEXP (op0, 0), mode) & ((unsigned HOST_WIDE_INT) 1 << (mode_width - 1))) == 0))) { op0 = XEXP (op0, 0); code = (code == LT ? NE : EQ); continue; } /* If we have NEG of something whose two high-order bits are the same, we know that "(-a) < 0" is equivalent to "a > 0". */ if (num_sign_bit_copies (op0, mode) >= 2) { op0 = XEXP (op0, 0); code = swap_condition (code); continue; } break; case ROTATE: /* If we are testing equality and our count is a constant, we can perform the inverse operation on our RHS. */ if (equality_comparison_p && CONST_INT_P (XEXP (op0, 1)) && (tem = simplify_binary_operation (ROTATERT, mode, op1, XEXP (op0, 1))) != 0) { op0 = XEXP (op0, 0); op1 = tem; continue; } /* If we are doing a < 0 or >= 0 comparison, it means we are testing a particular bit. Convert it to an AND of a constant of that bit. This will be converted into a ZERO_EXTRACT. */ if (const_op == 0 && sign_bit_comparison_p && CONST_INT_P (XEXP (op0, 1)) && mode_width <= HOST_BITS_PER_WIDE_INT) { op0 = simplify_and_const_int (NULL_RTX, mode, XEXP (op0, 0), ((unsigned HOST_WIDE_INT) 1 << (mode_width - 1 - INTVAL (XEXP (op0, 1))))); code = (code == LT ? NE : EQ); continue; } /* Fall through. */ case ABS: /* ABS is ignorable inside an equality comparison with zero. */ if (const_op == 0 && equality_comparison_p) { op0 = XEXP (op0, 0); continue; } break; case SIGN_EXTEND: /* Can simplify (compare (zero/sign_extend FOO) CONST) to (compare FOO CONST) if CONST fits in FOO's mode and we are either testing inequality or have an unsigned comparison with ZERO_EXTEND or a signed comparison with SIGN_EXTEND. But don't do it if we don't have a compare insn of the given mode, since we'd have to revert it later on, and then we wouldn't know whether to sign- or zero-extend. */ mode = GET_MODE (XEXP (op0, 0)); if (GET_MODE_CLASS (mode) == MODE_INT && ! unsigned_comparison_p && HWI_COMPUTABLE_MODE_P (mode) && trunc_int_for_mode (const_op, mode) == const_op && have_insn_for (COMPARE, mode)) { op0 = XEXP (op0, 0); continue; } break; case SUBREG: /* Check for the case where we are comparing A - C1 with C2, that is (subreg:MODE (plus (A) (-C1))) op (C2) with C1 a constant, and try to lift the SUBREG, i.e. to do the comparison in the wider mode. One of the following two conditions must be true in order for this to be valid: 1. The mode extension results in the same bit pattern being added on both sides and the comparison is equality or unsigned. As C2 has been truncated to fit in MODE, the pattern can only be all 0s or all 1s. 2. The mode extension results in the sign bit being copied on each side. The difficulty here is that we have predicates for A but not for (A - C1) so we need to check that C1 is within proper bounds so as to perturbate A as little as possible. */ if (mode_width <= HOST_BITS_PER_WIDE_INT && subreg_lowpart_p (op0) && GET_MODE_PRECISION (GET_MODE (SUBREG_REG (op0))) > mode_width && GET_CODE (SUBREG_REG (op0)) == PLUS && CONST_INT_P (XEXP (SUBREG_REG (op0), 1))) { machine_mode inner_mode = GET_MODE (SUBREG_REG (op0)); rtx a = XEXP (SUBREG_REG (op0), 0); HOST_WIDE_INT c1 = -INTVAL (XEXP (SUBREG_REG (op0), 1)); if ((c1 > 0 && (unsigned HOST_WIDE_INT) c1 < (unsigned HOST_WIDE_INT) 1 << (mode_width - 1) && (equality_comparison_p || unsigned_comparison_p) /* (A - C1) zero-extends if it is positive and sign-extends if it is negative, C2 both zero- and sign-extends. */ && ((0 == (nonzero_bits (a, inner_mode) & ~GET_MODE_MASK (mode)) && const_op >= 0) /* (A - C1) sign-extends if it is positive and 1-extends if it is negative, C2 both sign- and 1-extends. */ || (num_sign_bit_copies (a, inner_mode) > (unsigned int) (GET_MODE_PRECISION (inner_mode) - mode_width) && const_op < 0))) || ((unsigned HOST_WIDE_INT) c1 < (unsigned HOST_WIDE_INT) 1 << (mode_width - 2) /* (A - C1) always sign-extends, like C2. */ && num_sign_bit_copies (a, inner_mode) > (unsigned int) (GET_MODE_PRECISION (inner_mode) - (mode_width - 1)))) { op0 = SUBREG_REG (op0); continue; } } /* If the inner mode is narrower and we are extracting the low part, we can treat the SUBREG as if it were a ZERO_EXTEND. */ if (subreg_lowpart_p (op0) && GET_MODE_PRECISION (GET_MODE (SUBREG_REG (op0))) < mode_width) /* Fall through */ ; else break; /* ... fall through ... */ case ZERO_EXTEND: mode = GET_MODE (XEXP (op0, 0)); if (GET_MODE_CLASS (mode) == MODE_INT && (unsigned_comparison_p || equality_comparison_p) && HWI_COMPUTABLE_MODE_P (mode) && (unsigned HOST_WIDE_INT) const_op <= GET_MODE_MASK (mode) && const_op >= 0 && have_insn_for (COMPARE, mode)) { op0 = XEXP (op0, 0); continue; } break; case PLUS: /* (eq (plus X A) B) -> (eq X (minus B A)). We can only do this for equality comparisons due to pathological cases involving overflows. */ if (equality_comparison_p && 0 != (tem = simplify_binary_operation (MINUS, mode, op1, XEXP (op0, 1)))) { op0 = XEXP (op0, 0); op1 = tem; continue; } /* (plus (abs X) (const_int -1)) is < 0 if and only if X == 0. */ if (const_op == 0 && XEXP (op0, 1) == constm1_rtx && GET_CODE (XEXP (op0, 0)) == ABS && sign_bit_comparison_p) { op0 = XEXP (XEXP (op0, 0), 0); code = (code == LT ? EQ : NE); continue; } break; case MINUS: /* We used to optimize signed comparisons against zero, but that was incorrect. Unsigned comparisons against zero (GTU, LEU) arrive here as equality comparisons, or (GEU, LTU) are optimized away. No need to special-case them. */ /* (eq (minus A B) C) -> (eq A (plus B C)) or (eq B (minus A C)), whichever simplifies. We can only do this for equality comparisons due to pathological cases involving overflows. */ if (equality_comparison_p && 0 != (tem = simplify_binary_operation (PLUS, mode, XEXP (op0, 1), op1))) { op0 = XEXP (op0, 0); op1 = tem; continue; } if (equality_comparison_p && 0 != (tem = simplify_binary_operation (MINUS, mode, XEXP (op0, 0), op1))) { op0 = XEXP (op0, 1); op1 = tem; continue; } /* The sign bit of (minus (ashiftrt X C) X), where C is the number of bits in X minus 1, is one iff X > 0. */ if (sign_bit_comparison_p && GET_CODE (XEXP (op0, 0)) == ASHIFTRT && CONST_INT_P (XEXP (XEXP (op0, 0), 1)) && UINTVAL (XEXP (XEXP (op0, 0), 1)) == mode_width - 1 && rtx_equal_p (XEXP (XEXP (op0, 0), 0), XEXP (op0, 1))) { op0 = XEXP (op0, 1); code = (code == GE ? LE : GT); continue; } break; case XOR: /* (eq (xor A B) C) -> (eq A (xor B C)). This is a simplification if C is zero or B is a constant. */ if (equality_comparison_p && 0 != (tem = simplify_binary_operation (XOR, mode, XEXP (op0, 1), op1))) { op0 = XEXP (op0, 0); op1 = tem; continue; } break; case EQ: case NE: case UNEQ: case LTGT: case LT: case LTU: case UNLT: case LE: case LEU: case UNLE: case GT: case GTU: case UNGT: case GE: case GEU: case UNGE: case UNORDERED: case ORDERED: /* We can't do anything if OP0 is a condition code value, rather than an actual data value. */ if (const_op != 0 || CC0_P (XEXP (op0, 0)) || GET_MODE_CLASS (GET_MODE (XEXP (op0, 0))) == MODE_CC) break; /* Get the two operands being compared. */ if (GET_CODE (XEXP (op0, 0)) == COMPARE) tem = XEXP (XEXP (op0, 0), 0), tem1 = XEXP (XEXP (op0, 0), 1); else tem = XEXP (op0, 0), tem1 = XEXP (op0, 1); /* Check for the cases where we simply want the result of the earlier test or the opposite of that result. */ if (code == NE || code == EQ || (val_signbit_known_set_p (GET_MODE (op0), STORE_FLAG_VALUE) && (code == LT || code == GE))) { enum rtx_code new_code; if (code == LT || code == NE) new_code = GET_CODE (op0); else new_code = reversed_comparison_code (op0, NULL); if (new_code != UNKNOWN) { code = new_code; op0 = tem; op1 = tem1; continue; } } break; case IOR: /* The sign bit of (ior (plus X (const_int -1)) X) is nonzero iff X <= 0. */ if (sign_bit_comparison_p && GET_CODE (XEXP (op0, 0)) == PLUS && XEXP (XEXP (op0, 0), 1) == constm1_rtx && rtx_equal_p (XEXP (XEXP (op0, 0), 0), XEXP (op0, 1))) { op0 = XEXP (op0, 1); code = (code == GE ? GT : LE); continue; } break; case AND: /* Convert (and (xshift 1 X) Y) to (and (lshiftrt Y X) 1). This will be converted to a ZERO_EXTRACT later. */ if (const_op == 0 && equality_comparison_p && GET_CODE (XEXP (op0, 0)) == ASHIFT && XEXP (XEXP (op0, 0), 0) == const1_rtx) { op0 = gen_rtx_LSHIFTRT (mode, XEXP (op0, 1), XEXP (XEXP (op0, 0), 1)); op0 = simplify_and_const_int (NULL_RTX, mode, op0, 1); continue; } /* If we are comparing (and (lshiftrt X C1) C2) for equality with zero and X is a comparison and C1 and C2 describe only bits set in STORE_FLAG_VALUE, we can compare with X. */ if (const_op == 0 && equality_comparison_p && mode_width <= HOST_BITS_PER_WIDE_INT && CONST_INT_P (XEXP (op0, 1)) && GET_CODE (XEXP (op0, 0)) == LSHIFTRT && CONST_INT_P (XEXP (XEXP (op0, 0), 1)) && INTVAL (XEXP (XEXP (op0, 0), 1)) >= 0 && INTVAL (XEXP (XEXP (op0, 0), 1)) < HOST_BITS_PER_WIDE_INT) { mask = ((INTVAL (XEXP (op0, 1)) & GET_MODE_MASK (mode)) << INTVAL (XEXP (XEXP (op0, 0), 1))); if ((~STORE_FLAG_VALUE & mask) == 0 && (COMPARISON_P (XEXP (XEXP (op0, 0), 0)) || ((tem = get_last_value (XEXP (XEXP (op0, 0), 0))) != 0 && COMPARISON_P (tem)))) { op0 = XEXP (XEXP (op0, 0), 0); continue; } } /* If we are doing an equality comparison of an AND of a bit equal to the sign bit, replace this with a LT or GE comparison of the underlying value. */ if (equality_comparison_p && const_op == 0 && CONST_INT_P (XEXP (op0, 1)) && mode_width <= HOST_BITS_PER_WIDE_INT && ((INTVAL (XEXP (op0, 1)) & GET_MODE_MASK (mode)) == (unsigned HOST_WIDE_INT) 1 << (mode_width - 1))) { op0 = XEXP (op0, 0); code = (code == EQ ? GE : LT); continue; } /* If this AND operation is really a ZERO_EXTEND from a narrower mode, the constant fits within that mode, and this is either an equality or unsigned comparison, try to do this comparison in the narrower mode. Note that in: (ne:DI (and:DI (reg:DI 4) (const_int 0xffffffff)) (const_int 0)) -> (ne:DI (reg:SI 4) (const_int 0)) unless TRULY_NOOP_TRUNCATION allows it or the register is known to hold a value of the required mode the transformation is invalid. */ if ((equality_comparison_p || unsigned_comparison_p) && CONST_INT_P (XEXP (op0, 1)) && (i = exact_log2 ((UINTVAL (XEXP (op0, 1)) & GET_MODE_MASK (mode)) + 1)) >= 0 && const_op >> i == 0 && (tmode = mode_for_size (i, MODE_INT, 1)) != BLKmode) { op0 = gen_lowpart_or_truncate (tmode, XEXP (op0, 0)); continue; } /* If this is (and:M1 (subreg:M1 X:M2 0) (const_int C1)) where C1 fits in both M1 and M2 and the SUBREG is either paradoxical or represents the low part, permute the SUBREG and the AND and try again. */ if (GET_CODE (XEXP (op0, 0)) == SUBREG && CONST_INT_P (XEXP (op0, 1))) { tmode = GET_MODE (SUBREG_REG (XEXP (op0, 0))); unsigned HOST_WIDE_INT c1 = INTVAL (XEXP (op0, 1)); /* Require an integral mode, to avoid creating something like (AND:SF ...). */ if (SCALAR_INT_MODE_P (tmode) /* It is unsafe to commute the AND into the SUBREG if the SUBREG is paradoxical and WORD_REGISTER_OPERATIONS is not defined. As originally written the upper bits have a defined value due to the AND operation. However, if we commute the AND inside the SUBREG then they no longer have defined values and the meaning of the code has been changed. Also C1 should not change value in the smaller mode, see PR67028 (a positive C1 can become negative in the smaller mode, so that the AND does no longer mask the upper bits). */ && ((WORD_REGISTER_OPERATIONS && mode_width > GET_MODE_PRECISION (tmode) && mode_width <= BITS_PER_WORD && trunc_int_for_mode (c1, tmode) == (HOST_WIDE_INT) c1) || (mode_width <= GET_MODE_PRECISION (tmode) && subreg_lowpart_p (XEXP (op0, 0)))) && mode_width <= HOST_BITS_PER_WIDE_INT && HWI_COMPUTABLE_MODE_P (tmode) && (c1 & ~mask) == 0 && (c1 & ~GET_MODE_MASK (tmode)) == 0 && c1 != mask && c1 != GET_MODE_MASK (tmode)) { op0 = simplify_gen_binary (AND, tmode, SUBREG_REG (XEXP (op0, 0)), gen_int_mode (c1, tmode)); op0 = gen_lowpart (mode, op0); continue; } } /* Convert (ne (and (not X) 1) 0) to (eq (and X 1) 0). */ if (const_op == 0 && equality_comparison_p && XEXP (op0, 1) == const1_rtx && GET_CODE (XEXP (op0, 0)) == NOT) { op0 = simplify_and_const_int (NULL_RTX, mode, XEXP (XEXP (op0, 0), 0), 1); code = (code == NE ? EQ : NE); continue; } /* Convert (ne (and (lshiftrt (not X)) 1) 0) to (eq (and (lshiftrt X) 1) 0). Also handle the case where (not X) is expressed using xor. */ if (const_op == 0 && equality_comparison_p && XEXP (op0, 1) == const1_rtx && GET_CODE (XEXP (op0, 0)) == LSHIFTRT) { rtx shift_op = XEXP (XEXP (op0, 0), 0); rtx shift_count = XEXP (XEXP (op0, 0), 1); if (GET_CODE (shift_op) == NOT || (GET_CODE (shift_op) == XOR && CONST_INT_P (XEXP (shift_op, 1)) && CONST_INT_P (shift_count) && HWI_COMPUTABLE_MODE_P (mode) && (UINTVAL (XEXP (shift_op, 1)) == (unsigned HOST_WIDE_INT) 1 << INTVAL (shift_count)))) { op0 = gen_rtx_LSHIFTRT (mode, XEXP (shift_op, 0), shift_count); op0 = simplify_and_const_int (NULL_RTX, mode, op0, 1); code = (code == NE ? EQ : NE); continue; } } break; case ASHIFT: /* If we have (compare (ashift FOO N) (const_int C)) and the high order N bits of FOO (N+1 if an inequality comparison) are known to be zero, we can do this by comparing FOO with C shifted right N bits so long as the low-order N bits of C are zero. */ if (CONST_INT_P (XEXP (op0, 1)) && INTVAL (XEXP (op0, 1)) >= 0 && ((INTVAL (XEXP (op0, 1)) + ! equality_comparison_p) < HOST_BITS_PER_WIDE_INT) && (((unsigned HOST_WIDE_INT) const_op & (((unsigned HOST_WIDE_INT) 1 << INTVAL (XEXP (op0, 1))) - 1)) == 0) && mode_width <= HOST_BITS_PER_WIDE_INT && (nonzero_bits (XEXP (op0, 0), mode) & ~(mask >> (INTVAL (XEXP (op0, 1)) + ! equality_comparison_p))) == 0) { /* We must perform a logical shift, not an arithmetic one, as we want the top N bits of C to be zero. */ unsigned HOST_WIDE_INT temp = const_op & GET_MODE_MASK (mode); temp >>= INTVAL (XEXP (op0, 1)); op1 = gen_int_mode (temp, mode); op0 = XEXP (op0, 0); continue; } /* If we are doing a sign bit comparison, it means we are testing a particular bit. Convert it to the appropriate AND. */ if (sign_bit_comparison_p && CONST_INT_P (XEXP (op0, 1)) && mode_width <= HOST_BITS_PER_WIDE_INT) { op0 = simplify_and_const_int (NULL_RTX, mode, XEXP (op0, 0), ((unsigned HOST_WIDE_INT) 1 << (mode_width - 1 - INTVAL (XEXP (op0, 1))))); code = (code == LT ? NE : EQ); continue; } /* If this an equality comparison with zero and we are shifting the low bit to the sign bit, we can convert this to an AND of the low-order bit. */ if (const_op == 0 && equality_comparison_p && CONST_INT_P (XEXP (op0, 1)) && UINTVAL (XEXP (op0, 1)) == mode_width - 1) { op0 = simplify_and_const_int (NULL_RTX, mode, XEXP (op0, 0), 1); continue; } break; case ASHIFTRT: /* If this is an equality comparison with zero, we can do this as a logical shift, which might be much simpler. */ if (equality_comparison_p && const_op == 0 && CONST_INT_P (XEXP (op0, 1))) { op0 = simplify_shift_const (NULL_RTX, LSHIFTRT, mode, XEXP (op0, 0), INTVAL (XEXP (op0, 1))); continue; } /* If OP0 is a sign extension and CODE is not an unsigned comparison, do the comparison in a narrower mode. */ if (! unsigned_comparison_p && CONST_INT_P (XEXP (op0, 1)) && GET_CODE (XEXP (op0, 0)) == ASHIFT && XEXP (op0, 1) == XEXP (XEXP (op0, 0), 1) && (tmode = mode_for_size (mode_width - INTVAL (XEXP (op0, 1)), MODE_INT, 1)) != BLKmode && (((unsigned HOST_WIDE_INT) const_op + (GET_MODE_MASK (tmode) >> 1) + 1) <= GET_MODE_MASK (tmode))) { op0 = gen_lowpart (tmode, XEXP (XEXP (op0, 0), 0)); continue; } /* Likewise if OP0 is a PLUS of a sign extension with a constant, which is usually represented with the PLUS between the shifts. */ if (! unsigned_comparison_p && CONST_INT_P (XEXP (op0, 1)) && GET_CODE (XEXP (op0, 0)) == PLUS && CONST_INT_P (XEXP (XEXP (op0, 0), 1)) && GET_CODE (XEXP (XEXP (op0, 0), 0)) == ASHIFT && XEXP (op0, 1) == XEXP (XEXP (XEXP (op0, 0), 0), 1) && (tmode = mode_for_size (mode_width - INTVAL (XEXP (op0, 1)), MODE_INT, 1)) != BLKmode && (((unsigned HOST_WIDE_INT) const_op + (GET_MODE_MASK (tmode) >> 1) + 1) <= GET_MODE_MASK (tmode))) { rtx inner = XEXP (XEXP (XEXP (op0, 0), 0), 0); rtx add_const = XEXP (XEXP (op0, 0), 1); rtx new_const = simplify_gen_binary (ASHIFTRT, GET_MODE (op0), add_const, XEXP (op0, 1)); op0 = simplify_gen_binary (PLUS, tmode, gen_lowpart (tmode, inner), new_const); continue; } /* ... fall through ... */ case LSHIFTRT: /* If we have (compare (xshiftrt FOO N) (const_int C)) and the low order N bits of FOO are known to be zero, we can do this by comparing FOO with C shifted left N bits so long as no overflow occurs. Even if the low order N bits of FOO aren't known to be zero, if the comparison is >= or < we can use the same optimization and for > or <= by setting all the low order N bits in the comparison constant. */ if (CONST_INT_P (XEXP (op0, 1)) && INTVAL (XEXP (op0, 1)) > 0 && INTVAL (XEXP (op0, 1)) < HOST_BITS_PER_WIDE_INT && mode_width <= HOST_BITS_PER_WIDE_INT && (((unsigned HOST_WIDE_INT) const_op + (GET_CODE (op0) != LSHIFTRT ? ((GET_MODE_MASK (mode) >> INTVAL (XEXP (op0, 1)) >> 1) + 1) : 0)) <= GET_MODE_MASK (mode) >> INTVAL (XEXP (op0, 1)))) { unsigned HOST_WIDE_INT low_bits = (nonzero_bits (XEXP (op0, 0), mode) & (((unsigned HOST_WIDE_INT) 1 << INTVAL (XEXP (op0, 1))) - 1)); if (low_bits == 0 || !equality_comparison_p) { /* If the shift was logical, then we must make the condition unsigned. */ if (GET_CODE (op0) == LSHIFTRT) code = unsigned_condition (code); const_op <<= INTVAL (XEXP (op0, 1)); if (low_bits != 0 && (code == GT || code == GTU || code == LE || code == LEU)) const_op |= (((HOST_WIDE_INT) 1 << INTVAL (XEXP (op0, 1))) - 1); op1 = GEN_INT (const_op); op0 = XEXP (op0, 0); continue; } } /* If we are using this shift to extract just the sign bit, we can replace this with an LT or GE comparison. */ if (const_op == 0 && (equality_comparison_p || sign_bit_comparison_p) && CONST_INT_P (XEXP (op0, 1)) && UINTVAL (XEXP (op0, 1)) == mode_width - 1) { op0 = XEXP (op0, 0); code = (code == NE || code == GT ? LT : GE); continue; } break; default: break; } break; } /* Now make any compound operations involved in this comparison. Then, check for an outmost SUBREG on OP0 that is not doing anything or is paradoxical. The latter transformation must only be performed when it is known that the "extra" bits will be the same in op0 and op1 or that they don't matter. There are three cases to consider: 1. SUBREG_REG (op0) is a register. In this case the bits are don't care bits and we can assume they have any convenient value. So making the transformation is safe. 2. SUBREG_REG (op0) is a memory and LOAD_EXTEND_OP is not defined. In this case the upper bits of op0 are undefined. We should not make the simplification in that case as we do not know the contents of those bits. 3. SUBREG_REG (op0) is a memory and LOAD_EXTEND_OP is defined and not UNKNOWN. In that case we know those bits are zeros or ones. We must also be sure that they are the same as the upper bits of op1. We can never remove a SUBREG for a non-equality comparison because the sign bit is in a different place in the underlying object. */ op0 = make_compound_operation (op0, op1 == const0_rtx ? COMPARE : SET); op1 = make_compound_operation (op1, SET); if (GET_CODE (op0) == SUBREG && subreg_lowpart_p (op0) && GET_MODE_CLASS (GET_MODE (op0)) == MODE_INT && GET_MODE_CLASS (GET_MODE (SUBREG_REG (op0))) == MODE_INT && (code == NE || code == EQ)) { if (paradoxical_subreg_p (op0)) { /* For paradoxical subregs, allow case 1 as above. Case 3 isn't implemented. */ if (REG_P (SUBREG_REG (op0))) { op0 = SUBREG_REG (op0); op1 = gen_lowpart (GET_MODE (op0), op1); } } else if ((GET_MODE_PRECISION (GET_MODE (SUBREG_REG (op0))) <= HOST_BITS_PER_WIDE_INT) && (nonzero_bits (SUBREG_REG (op0), GET_MODE (SUBREG_REG (op0))) & ~GET_MODE_MASK (GET_MODE (op0))) == 0) { tem = gen_lowpart (GET_MODE (SUBREG_REG (op0)), op1); if ((nonzero_bits (tem, GET_MODE (SUBREG_REG (op0))) & ~GET_MODE_MASK (GET_MODE (op0))) == 0) op0 = SUBREG_REG (op0), op1 = tem; } } /* We now do the opposite procedure: Some machines don't have compare insns in all modes. If OP0's mode is an integer mode smaller than a word and we can't do a compare in that mode, see if there is a larger mode for which we can do the compare. There are a number of cases in which we can use the wider mode. */ mode = GET_MODE (op0); if (mode != VOIDmode && GET_MODE_CLASS (mode) == MODE_INT && GET_MODE_SIZE (mode) < UNITS_PER_WORD && ! have_insn_for (COMPARE, mode)) for (tmode = GET_MODE_WIDER_MODE (mode); (tmode != VOIDmode && HWI_COMPUTABLE_MODE_P (tmode)); tmode = GET_MODE_WIDER_MODE (tmode)) if (have_insn_for (COMPARE, tmode)) { int zero_extended; /* If this is a test for negative, we can make an explicit test of the sign bit. Test this first so we can use a paradoxical subreg to extend OP0. */ if (op1 == const0_rtx && (code == LT || code == GE) && HWI_COMPUTABLE_MODE_P (mode)) { unsigned HOST_WIDE_INT sign = (unsigned HOST_WIDE_INT) 1 << (GET_MODE_BITSIZE (mode) - 1); op0 = simplify_gen_binary (AND, tmode, gen_lowpart (tmode, op0), gen_int_mode (sign, tmode)); code = (code == LT) ? NE : EQ; break; } /* If the only nonzero bits in OP0 and OP1 are those in the narrower mode and this is an equality or unsigned comparison, we can use the wider mode. Similarly for sign-extended values, in which case it is true for all comparisons. */ zero_extended = ((code == EQ || code == NE || code == GEU || code == GTU || code == LEU || code == LTU) && (nonzero_bits (op0, tmode) & ~GET_MODE_MASK (mode)) == 0 && ((CONST_INT_P (op1) || (nonzero_bits (op1, tmode) & ~GET_MODE_MASK (mode)) == 0))); if (zero_extended || ((num_sign_bit_copies (op0, tmode) > (unsigned int) (GET_MODE_PRECISION (tmode) - GET_MODE_PRECISION (mode))) && (num_sign_bit_copies (op1, tmode) > (unsigned int) (GET_MODE_PRECISION (tmode) - GET_MODE_PRECISION (mode))))) { /* If OP0 is an AND and we don't have an AND in MODE either, make a new AND in the proper mode. */ if (GET_CODE (op0) == AND && !have_insn_for (AND, mode)) op0 = simplify_gen_binary (AND, tmode, gen_lowpart (tmode, XEXP (op0, 0)), gen_lowpart (tmode, XEXP (op0, 1))); else { if (zero_extended) { op0 = simplify_gen_unary (ZERO_EXTEND, tmode, op0, mode); op1 = simplify_gen_unary (ZERO_EXTEND, tmode, op1, mode); } else { op0 = simplify_gen_unary (SIGN_EXTEND, tmode, op0, mode); op1 = simplify_gen_unary (SIGN_EXTEND, tmode, op1, mode); } break; } } } /* We may have changed the comparison operands. Re-canonicalize. */ if (swap_commutative_operands_p (op0, op1)) { std::swap (op0, op1); code = swap_condition (code); } /* If this machine only supports a subset of valid comparisons, see if we can convert an unsupported one into a supported one. */ target_canonicalize_comparison (&code, &op0, &op1, 0); *pop0 = op0; *pop1 = op1; return code; } /* Utility function for record_value_for_reg. Count number of rtxs in X. */ static int count_rtxs (rtx x) { enum rtx_code code = GET_CODE (x); const char *fmt; int i, j, ret = 1; if (GET_RTX_CLASS (code) == RTX_BIN_ARITH || GET_RTX_CLASS (code) == RTX_COMM_ARITH) { rtx x0 = XEXP (x, 0); rtx x1 = XEXP (x, 1); if (x0 == x1) return 1 + 2 * count_rtxs (x0); if ((GET_RTX_CLASS (GET_CODE (x1)) == RTX_BIN_ARITH || GET_RTX_CLASS (GET_CODE (x1)) == RTX_COMM_ARITH) && (x0 == XEXP (x1, 0) || x0 == XEXP (x1, 1))) return 2 + 2 * count_rtxs (x0) + count_rtxs (x == XEXP (x1, 0) ? XEXP (x1, 1) : XEXP (x1, 0)); if ((GET_RTX_CLASS (GET_CODE (x0)) == RTX_BIN_ARITH || GET_RTX_CLASS (GET_CODE (x0)) == RTX_COMM_ARITH) && (x1 == XEXP (x0, 0) || x1 == XEXP (x0, 1))) return 2 + 2 * count_rtxs (x1) + count_rtxs (x == XEXP (x0, 0) ? XEXP (x0, 1) : XEXP (x0, 0)); } fmt = GET_RTX_FORMAT (code); for (i = GET_RTX_LENGTH (code) - 1; i >= 0; i--) if (fmt[i] == 'e') ret += count_rtxs (XEXP (x, i)); else if (fmt[i] == 'E') for (j = 0; j < XVECLEN (x, i); j++) ret += count_rtxs (XVECEXP (x, i, j)); return ret; } /* Utility function for following routine. Called when X is part of a value being stored into last_set_value. Sets last_set_table_tick for each register mentioned. Similar to mention_regs in cse.c */ static void update_table_tick (rtx x) { enum rtx_code code = GET_CODE (x); const char *fmt = GET_RTX_FORMAT (code); int i, j; if (code == REG) { unsigned int regno = REGNO (x); unsigned int endregno = END_REGNO (x); unsigned int r; for (r = regno; r < endregno; r++) { reg_stat_type *rsp = ®_stat[r]; rsp->last_set_table_tick = label_tick; } return; } for (i = GET_RTX_LENGTH (code) - 1; i >= 0; i--) if (fmt[i] == 'e') { /* Check for identical subexpressions. If x contains identical subexpression we only have to traverse one of them. */ if (i == 0 && ARITHMETIC_P (x)) { /* Note that at this point x1 has already been processed. */ rtx x0 = XEXP (x, 0); rtx x1 = XEXP (x, 1); /* If x0 and x1 are identical then there is no need to process x0. */ if (x0 == x1) break; /* If x0 is identical to a subexpression of x1 then while processing x1, x0 has already been processed. Thus we are done with x. */ if (ARITHMETIC_P (x1) && (x0 == XEXP (x1, 0) || x0 == XEXP (x1, 1))) break; /* If x1 is identical to a subexpression of x0 then we still have to process the rest of x0. */ if (ARITHMETIC_P (x0) && (x1 == XEXP (x0, 0) || x1 == XEXP (x0, 1))) { update_table_tick (XEXP (x0, x1 == XEXP (x0, 0) ? 1 : 0)); break; } } update_table_tick (XEXP (x, i)); } else if (fmt[i] == 'E') for (j = 0; j < XVECLEN (x, i); j++) update_table_tick (XVECEXP (x, i, j)); } /* Record that REG is set to VALUE in insn INSN. If VALUE is zero, we are saying that the register is clobbered and we no longer know its value. If INSN is zero, don't update reg_stat[].last_set; this is only permitted with VALUE also zero and is used to invalidate the register. */ static void record_value_for_reg (rtx reg, rtx_insn *insn, rtx value) { unsigned int regno = REGNO (reg); unsigned int endregno = END_REGNO (reg); unsigned int i; reg_stat_type *rsp; /* If VALUE contains REG and we have a previous value for REG, substitute the previous value. */ if (value && insn && reg_overlap_mentioned_p (reg, value)) { rtx tem; /* Set things up so get_last_value is allowed to see anything set up to our insn. */ subst_low_luid = DF_INSN_LUID (insn); tem = get_last_value (reg); /* If TEM is simply a binary operation with two CLOBBERs as operands, it isn't going to be useful and will take a lot of time to process, so just use the CLOBBER. */ if (tem) { if (ARITHMETIC_P (tem) && GET_CODE (XEXP (tem, 0)) == CLOBBER && GET_CODE (XEXP (tem, 1)) == CLOBBER) tem = XEXP (tem, 0); else if (count_occurrences (value, reg, 1) >= 2) { /* If there are two or more occurrences of REG in VALUE, prevent the value from growing too much. */ if (count_rtxs (tem) > MAX_LAST_VALUE_RTL) tem = gen_rtx_CLOBBER (GET_MODE (tem), const0_rtx); } value = replace_rtx (copy_rtx (value), reg, tem); } } /* For each register modified, show we don't know its value, that we don't know about its bitwise content, that its value has been updated, and that we don't know the location of the death of the register. */ for (i = regno; i < endregno; i++) { rsp = ®_stat[i]; if (insn) rsp->last_set = insn; rsp->last_set_value = 0; rsp->last_set_mode = VOIDmode; rsp->last_set_nonzero_bits = 0; rsp->last_set_sign_bit_copies = 0; rsp->last_death = 0; rsp->truncated_to_mode = VOIDmode; } /* Mark registers that are being referenced in this value. */ if (value) update_table_tick (value); /* Now update the status of each register being set. If someone is using this register in this block, set this register to invalid since we will get confused between the two lives in this basic block. This makes using this register always invalid. In cse, we scan the table to invalidate all entries using this register, but this is too much work for us. */ for (i = regno; i < endregno; i++) { rsp = ®_stat[i]; rsp->last_set_label = label_tick; if (!insn || (value && rsp->last_set_table_tick >= label_tick_ebb_start)) rsp->last_set_invalid = 1; else rsp->last_set_invalid = 0; } /* The value being assigned might refer to X (like in "x++;"). In that case, we must replace it with (clobber (const_int 0)) to prevent infinite loops. */ rsp = ®_stat[regno]; if (value && !get_last_value_validate (&value, insn, label_tick, 0)) { value = copy_rtx (value); if (!get_last_value_validate (&value, insn, label_tick, 1)) value = 0; } /* For the main register being modified, update the value, the mode, the nonzero bits, and the number of sign bit copies. */ rsp->last_set_value = value; if (value) { machine_mode mode = GET_MODE (reg); subst_low_luid = DF_INSN_LUID (insn); rsp->last_set_mode = mode; if (GET_MODE_CLASS (mode) == MODE_INT && HWI_COMPUTABLE_MODE_P (mode)) mode = nonzero_bits_mode; rsp->last_set_nonzero_bits = nonzero_bits (value, mode); rsp->last_set_sign_bit_copies = num_sign_bit_copies (value, GET_MODE (reg)); } } /* Called via note_stores from record_dead_and_set_regs to handle one SET or CLOBBER in an insn. DATA is the instruction in which the set is occurring. */ static void record_dead_and_set_regs_1 (rtx dest, const_rtx setter, void *data) { rtx_insn *record_dead_insn = (rtx_insn *) data; if (GET_CODE (dest) == SUBREG) dest = SUBREG_REG (dest); if (!record_dead_insn) { if (REG_P (dest)) record_value_for_reg (dest, NULL, NULL_RTX); return; } if (REG_P (dest)) { /* If we are setting the whole register, we know its value. Otherwise show that we don't know the value. We can handle SUBREG in some cases. */ if (GET_CODE (setter) == SET && dest == SET_DEST (setter)) record_value_for_reg (dest, record_dead_insn, SET_SRC (setter)); else if (GET_CODE (setter) == SET && GET_CODE (SET_DEST (setter)) == SUBREG && SUBREG_REG (SET_DEST (setter)) == dest && GET_MODE_PRECISION (GET_MODE (dest)) <= BITS_PER_WORD && subreg_lowpart_p (SET_DEST (setter))) record_value_for_reg (dest, record_dead_insn, gen_lowpart (GET_MODE (dest), SET_SRC (setter))); else record_value_for_reg (dest, record_dead_insn, NULL_RTX); } else if (MEM_P (dest) /* Ignore pushes, they clobber nothing. */ && ! push_operand (dest, GET_MODE (dest))) mem_last_set = DF_INSN_LUID (record_dead_insn); } /* Update the records of when each REG was most recently set or killed for the things done by INSN. This is the last thing done in processing INSN in the combiner loop. We update reg_stat[], in particular fields last_set, last_set_value, last_set_mode, last_set_nonzero_bits, last_set_sign_bit_copies, last_death, and also the similar information mem_last_set (which insn most recently modified memory) and last_call_luid (which insn was the most recent subroutine call). */ static void record_dead_and_set_regs (rtx_insn *insn) { rtx link; unsigned int i; for (link = REG_NOTES (insn); link; link = XEXP (link, 1)) { if (REG_NOTE_KIND (link) == REG_DEAD && REG_P (XEXP (link, 0))) { unsigned int regno = REGNO (XEXP (link, 0)); unsigned int endregno = END_REGNO (XEXP (link, 0)); for (i = regno; i < endregno; i++) { reg_stat_type *rsp; rsp = ®_stat[i]; rsp->last_death = insn; } } else if (REG_NOTE_KIND (link) == REG_INC) record_value_for_reg (XEXP (link, 0), insn, NULL_RTX); } if (CALL_P (insn)) { hard_reg_set_iterator hrsi; EXECUTE_IF_SET_IN_HARD_REG_SET (regs_invalidated_by_call, 0, i, hrsi) { reg_stat_type *rsp; rsp = ®_stat[i]; rsp->last_set_invalid = 1; rsp->last_set = insn; rsp->last_set_value = 0; rsp->last_set_mode = VOIDmode; rsp->last_set_nonzero_bits = 0; rsp->last_set_sign_bit_copies = 0; rsp->last_death = 0; rsp->truncated_to_mode = VOIDmode; } last_call_luid = mem_last_set = DF_INSN_LUID (insn); /* We can't combine into a call pattern. Remember, though, that the return value register is set at this LUID. We could still replace a register with the return value from the wrong subroutine call! */ note_stores (PATTERN (insn), record_dead_and_set_regs_1, NULL_RTX); } else note_stores (PATTERN (insn), record_dead_and_set_regs_1, insn); } /* If a SUBREG has the promoted bit set, it is in fact a property of the register present in the SUBREG, so for each such SUBREG go back and adjust nonzero and sign bit information of the registers that are known to have some zero/sign bits set. This is needed because when combine blows the SUBREGs away, the information on zero/sign bits is lost and further combines can be missed because of that. */ static void record_promoted_value (rtx_insn *insn, rtx subreg) { struct insn_link *links; rtx set; unsigned int regno = REGNO (SUBREG_REG (subreg)); machine_mode mode = GET_MODE (subreg); if (GET_MODE_PRECISION (mode) > HOST_BITS_PER_WIDE_INT) return; for (links = LOG_LINKS (insn); links;) { reg_stat_type *rsp; insn = links->insn; set = single_set (insn); if (! set || !REG_P (SET_DEST (set)) || REGNO (SET_DEST (set)) != regno || GET_MODE (SET_DEST (set)) != GET_MODE (SUBREG_REG (subreg))) { links = links->next; continue; } rsp = ®_stat[regno]; if (rsp->last_set == insn) { if (SUBREG_PROMOTED_UNSIGNED_P (subreg)) rsp->last_set_nonzero_bits &= GET_MODE_MASK (mode); } if (REG_P (SET_SRC (set))) { regno = REGNO (SET_SRC (set)); links = LOG_LINKS (insn); } else break; } } /* Check if X, a register, is known to contain a value already truncated to MODE. In this case we can use a subreg to refer to the truncated value even though in the generic case we would need an explicit truncation. */ static bool reg_truncated_to_mode (machine_mode mode, const_rtx x) { reg_stat_type *rsp = ®_stat[REGNO (x)]; machine_mode truncated = rsp->truncated_to_mode; if (truncated == 0 || rsp->truncation_label < label_tick_ebb_start) return false; if (GET_MODE_SIZE (truncated) <= GET_MODE_SIZE (mode)) return true; if (TRULY_NOOP_TRUNCATION_MODES_P (mode, truncated)) return true; return false; } /* If X is a hard reg or a subreg record the mode that the register is accessed in. For non-TRULY_NOOP_TRUNCATION targets we might be able to turn a truncate into a subreg using this information. Return true if traversing X is complete. */ static bool record_truncated_value (rtx x) { machine_mode truncated_mode; reg_stat_type *rsp; if (GET_CODE (x) == SUBREG && REG_P (SUBREG_REG (x))) { machine_mode original_mode = GET_MODE (SUBREG_REG (x)); truncated_mode = GET_MODE (x); if (GET_MODE_SIZE (original_mode) <= GET_MODE_SIZE (truncated_mode)) return true; if (TRULY_NOOP_TRUNCATION_MODES_P (truncated_mode, original_mode)) return true; x = SUBREG_REG (x); } /* ??? For hard-regs we now record everything. We might be able to optimize this using last_set_mode. */ else if (REG_P (x) && REGNO (x) < FIRST_PSEUDO_REGISTER) truncated_mode = GET_MODE (x); else return false; rsp = ®_stat[REGNO (x)]; if (rsp->truncated_to_mode == 0 || rsp->truncation_label < label_tick_ebb_start || (GET_MODE_SIZE (truncated_mode) < GET_MODE_SIZE (rsp->truncated_to_mode))) { rsp->truncated_to_mode = truncated_mode; rsp->truncation_label = label_tick; } return true; } /* Callback for note_uses. Find hardregs and subregs of pseudos and the modes they are used in. This can help truning TRUNCATEs into SUBREGs. */ static void record_truncated_values (rtx *loc, void *data ATTRIBUTE_UNUSED) { subrtx_var_iterator::array_type array; FOR_EACH_SUBRTX_VAR (iter, array, *loc, NONCONST) if (record_truncated_value (*iter)) iter.skip_subrtxes (); } /* Scan X for promoted SUBREGs. For each one found, note what it implies to the registers used in it. */ static void check_promoted_subreg (rtx_insn *insn, rtx x) { if (GET_CODE (x) == SUBREG && SUBREG_PROMOTED_VAR_P (x) && REG_P (SUBREG_REG (x))) record_promoted_value (insn, x); else { const char *format = GET_RTX_FORMAT (GET_CODE (x)); int i, j; for (i = 0; i < GET_RTX_LENGTH (GET_CODE (x)); i++) switch (format[i]) { case 'e': check_promoted_subreg (insn, XEXP (x, i)); break; case 'V': case 'E': if (XVEC (x, i) != 0) for (j = 0; j < XVECLEN (x, i); j++) check_promoted_subreg (insn, XVECEXP (x, i, j)); break; } } } /* Verify that all the registers and memory references mentioned in *LOC are still valid. *LOC was part of a value set in INSN when label_tick was equal to TICK. Return 0 if some are not. If REPLACE is nonzero, replace the invalid references with (clobber (const_int 0)) and return 1. This replacement is useful because we often can get useful information about the form of a value (e.g., if it was produced by a shift that always produces -1 or 0) even though we don't know exactly what registers it was produced from. */ static int get_last_value_validate (rtx *loc, rtx_insn *insn, int tick, int replace) { rtx x = *loc; const char *fmt = GET_RTX_FORMAT (GET_CODE (x)); int len = GET_RTX_LENGTH (GET_CODE (x)); int i, j; if (REG_P (x)) { unsigned int regno = REGNO (x); unsigned int endregno = END_REGNO (x); unsigned int j; for (j = regno; j < endregno; j++) { reg_stat_type *rsp = ®_stat[j]; if (rsp->last_set_invalid /* If this is a pseudo-register that was only set once and not live at the beginning of the function, it is always valid. */ || (! (regno >= FIRST_PSEUDO_REGISTER && regno < reg_n_sets_max && REG_N_SETS (regno) == 1 && (!REGNO_REG_SET_P (DF_LR_IN (ENTRY_BLOCK_PTR_FOR_FN (cfun)->next_bb), regno))) && rsp->last_set_label > tick)) { if (replace) *loc = gen_rtx_CLOBBER (GET_MODE (x), const0_rtx); return replace; } } return 1; } /* If this is a memory reference, make sure that there were no stores after it that might have clobbered the value. We don't have alias info, so we assume any store invalidates it. Moreover, we only have local UIDs, so we also assume that there were stores in the intervening basic blocks. */ else if (MEM_P (x) && !MEM_READONLY_P (x) && (tick != label_tick || DF_INSN_LUID (insn) <= mem_last_set)) { if (replace) *loc = gen_rtx_CLOBBER (GET_MODE (x), const0_rtx); return replace; } for (i = 0; i < len; i++) { if (fmt[i] == 'e') { /* Check for identical subexpressions. If x contains identical subexpression we only have to traverse one of them. */ if (i == 1 && ARITHMETIC_P (x)) { /* Note that at this point x0 has already been checked and found valid. */ rtx x0 = XEXP (x, 0); rtx x1 = XEXP (x, 1); /* If x0 and x1 are identical then x is also valid. */ if (x0 == x1) return 1; /* If x1 is identical to a subexpression of x0 then while checking x0, x1 has already been checked. Thus it is valid and so as x. */ if (ARITHMETIC_P (x0) && (x1 == XEXP (x0, 0) || x1 == XEXP (x0, 1))) return 1; /* If x0 is identical to a subexpression of x1 then x is valid iff the rest of x1 is valid. */ if (ARITHMETIC_P (x1) && (x0 == XEXP (x1, 0) || x0 == XEXP (x1, 1))) return get_last_value_validate (&XEXP (x1, x0 == XEXP (x1, 0) ? 1 : 0), insn, tick, replace); } if (get_last_value_validate (&XEXP (x, i), insn, tick, replace) == 0) return 0; } else if (fmt[i] == 'E') for (j = 0; j < XVECLEN (x, i); j++) if (get_last_value_validate (&XVECEXP (x, i, j), insn, tick, replace) == 0) return 0; } /* If we haven't found a reason for it to be invalid, it is valid. */ return 1; } /* Get the last value assigned to X, if known. Some registers in the value may be replaced with (clobber (const_int 0)) if their value is known longer known reliably. */ static rtx get_last_value (const_rtx x) { unsigned int regno; rtx value; reg_stat_type *rsp; /* If this is a non-paradoxical SUBREG, get the value of its operand and then convert it to the desired mode. If this is a paradoxical SUBREG, we cannot predict what values the "extra" bits might have. */ if (GET_CODE (x) == SUBREG && subreg_lowpart_p (x) && !paradoxical_subreg_p (x) && (value = get_last_value (SUBREG_REG (x))) != 0) return gen_lowpart (GET_MODE (x), value); if (!REG_P (x)) return 0; regno = REGNO (x); rsp = ®_stat[regno]; value = rsp->last_set_value; /* If we don't have a value, or if it isn't for this basic block and it's either a hard register, set more than once, or it's a live at the beginning of the function, return 0. Because if it's not live at the beginning of the function then the reg is always set before being used (is never used without being set). And, if it's set only once, and it's always set before use, then all uses must have the same last value, even if it's not from this basic block. */ if (value == 0 || (rsp->last_set_label < label_tick_ebb_start && (regno < FIRST_PSEUDO_REGISTER || regno >= reg_n_sets_max || REG_N_SETS (regno) != 1 || REGNO_REG_SET_P (DF_LR_IN (ENTRY_BLOCK_PTR_FOR_FN (cfun)->next_bb), regno)))) return 0; /* If the value was set in a later insn than the ones we are processing, we can't use it even if the register was only set once. */ if (rsp->last_set_label == label_tick && DF_INSN_LUID (rsp->last_set) >= subst_low_luid) return 0; /* If the value has all its registers valid, return it. */ if (get_last_value_validate (&value, rsp->last_set, rsp->last_set_label, 0)) return value; /* Otherwise, make a copy and replace any invalid register with (clobber (const_int 0)). If that fails for some reason, return 0. */ value = copy_rtx (value); if (get_last_value_validate (&value, rsp->last_set, rsp->last_set_label, 1)) return value; return 0; } /* Return nonzero if expression X refers to a REG or to memory that is set in an instruction more recent than FROM_LUID. */ static int use_crosses_set_p (const_rtx x, int from_luid) { const char *fmt; int i; enum rtx_code code = GET_CODE (x); if (code == REG) { unsigned int regno = REGNO (x); unsigned endreg = END_REGNO (x); #ifdef PUSH_ROUNDING /* Don't allow uses of the stack pointer to be moved, because we don't know whether the move crosses a push insn. */ if (regno == STACK_POINTER_REGNUM && PUSH_ARGS) return 1; #endif for (; regno < endreg; regno++) { reg_stat_type *rsp = ®_stat[regno]; if (rsp->last_set && rsp->last_set_label == label_tick && DF_INSN_LUID (rsp->last_set) > from_luid) return 1; } return 0; } if (code == MEM && mem_last_set > from_luid) return 1; fmt = GET_RTX_FORMAT (code); for (i = GET_RTX_LENGTH (code) - 1; i >= 0; i--) { if (fmt[i] == 'E') { int j; for (j = XVECLEN (x, i) - 1; j >= 0; j--) if (use_crosses_set_p (XVECEXP (x, i, j), from_luid)) return 1; } else if (fmt[i] == 'e' && use_crosses_set_p (XEXP (x, i), from_luid)) return 1; } return 0; } /* Define three variables used for communication between the following routines. */ static unsigned int reg_dead_regno, reg_dead_endregno; static int reg_dead_flag; /* Function called via note_stores from reg_dead_at_p. If DEST is within [reg_dead_regno, reg_dead_endregno), set reg_dead_flag to 1 if X is a CLOBBER and to -1 it is a SET. */ static void reg_dead_at_p_1 (rtx dest, const_rtx x, void *data ATTRIBUTE_UNUSED) { unsigned int regno, endregno; if (!REG_P (dest)) return; regno = REGNO (dest); endregno = END_REGNO (dest); if (reg_dead_endregno > regno && reg_dead_regno < endregno) reg_dead_flag = (GET_CODE (x) == CLOBBER) ? 1 : -1; } /* Return nonzero if REG is known to be dead at INSN. We scan backwards from INSN. If we hit a REG_DEAD note or a CLOBBER referencing REG, it is dead. If we hit a SET referencing REG, it is live. Otherwise, see if it is live or dead at the start of the basic block we are in. Hard regs marked as being live in NEWPAT_USED_REGS must be assumed to be always live. */ static int reg_dead_at_p (rtx reg, rtx_insn *insn) { basic_block block; unsigned int i; /* Set variables for reg_dead_at_p_1. */ reg_dead_regno = REGNO (reg); reg_dead_endregno = END_REGNO (reg); reg_dead_flag = 0; /* Check that reg isn't mentioned in NEWPAT_USED_REGS. For fixed registers we allow the machine description to decide whether use-and-clobber patterns are OK. */ if (reg_dead_regno < FIRST_PSEUDO_REGISTER) { for (i = reg_dead_regno; i < reg_dead_endregno; i++) if (!fixed_regs[i] && TEST_HARD_REG_BIT (newpat_used_regs, i)) return 0; } /* Scan backwards until we find a REG_DEAD note, SET, CLOBBER, or beginning of basic block. */ block = BLOCK_FOR_INSN (insn); for (;;) { if (INSN_P (insn)) { if (find_regno_note (insn, REG_UNUSED, reg_dead_regno)) return 1; note_stores (PATTERN (insn), reg_dead_at_p_1, NULL); if (reg_dead_flag) return reg_dead_flag == 1 ? 1 : 0; if (find_regno_note (insn, REG_DEAD, reg_dead_regno)) return 1; } if (insn == BB_HEAD (block)) break; insn = PREV_INSN (insn); } /* Look at live-in sets for the basic block that we were in. */ for (i = reg_dead_regno; i < reg_dead_endregno; i++) if (REGNO_REG_SET_P (df_get_live_in (block), i)) return 0; return 1; } /* Note hard registers in X that are used. */ static void mark_used_regs_combine (rtx x) { RTX_CODE code = GET_CODE (x); unsigned int regno; int i; switch (code) { case LABEL_REF: case SYMBOL_REF: case CONST: CASE_CONST_ANY: case PC: case ADDR_VEC: case ADDR_DIFF_VEC: case ASM_INPUT: /* CC0 must die in the insn after it is set, so we don't need to take special note of it here. */ case CC0: return; case CLOBBER: /* If we are clobbering a MEM, mark any hard registers inside the address as used. */ if (MEM_P (XEXP (x, 0))) mark_used_regs_combine (XEXP (XEXP (x, 0), 0)); return; case REG: regno = REGNO (x); /* A hard reg in a wide mode may really be multiple registers. If so, mark all of them just like the first. */ if (regno < FIRST_PSEUDO_REGISTER) { /* None of this applies to the stack, frame or arg pointers. */ if (regno == STACK_POINTER_REGNUM || (!HARD_FRAME_POINTER_IS_FRAME_POINTER && regno == HARD_FRAME_POINTER_REGNUM) || (FRAME_POINTER_REGNUM != ARG_POINTER_REGNUM && regno == ARG_POINTER_REGNUM && fixed_regs[regno]) || regno == FRAME_POINTER_REGNUM) return; add_to_hard_reg_set (&newpat_used_regs, GET_MODE (x), regno); } return; case SET: { /* If setting a MEM, or a SUBREG of a MEM, then note any hard regs in the address. */ rtx testreg = SET_DEST (x); while (GET_CODE (testreg) == SUBREG || GET_CODE (testreg) == ZERO_EXTRACT || GET_CODE (testreg) == STRICT_LOW_PART) testreg = XEXP (testreg, 0); if (MEM_P (testreg)) mark_used_regs_combine (XEXP (testreg, 0)); mark_used_regs_combine (SET_SRC (x)); } return; default: break; } /* Recursively scan the operands of this expression. */ { const char *fmt = GET_RTX_FORMAT (code); for (i = GET_RTX_LENGTH (code) - 1; i >= 0; i--) { if (fmt[i] == 'e') mark_used_regs_combine (XEXP (x, i)); else if (fmt[i] == 'E') { int j; for (j = 0; j < XVECLEN (x, i); j++) mark_used_regs_combine (XVECEXP (x, i, j)); } } } } /* Remove register number REGNO from the dead registers list of INSN. Return the note used to record the death, if there was one. */ rtx remove_death (unsigned int regno, rtx_insn *insn) { rtx note = find_regno_note (insn, REG_DEAD, regno); if (note) remove_note (insn, note); return note; } /* For each register (hardware or pseudo) used within expression X, if its death is in an instruction with luid between FROM_LUID (inclusive) and TO_INSN (exclusive), put a REG_DEAD note for that register in the list headed by PNOTES. That said, don't move registers killed by maybe_kill_insn. This is done when X is being merged by combination into TO_INSN. These notes will then be distributed as needed. */ static void move_deaths (rtx x, rtx maybe_kill_insn, int from_luid, rtx_insn *to_insn, rtx *pnotes) { const char *fmt; int len, i; enum rtx_code code = GET_CODE (x); if (code == REG) { unsigned int regno = REGNO (x); rtx_insn *where_dead = reg_stat[regno].last_death; /* Don't move the register if it gets killed in between from and to. */ if (maybe_kill_insn && reg_set_p (x, maybe_kill_insn) && ! reg_referenced_p (x, maybe_kill_insn)) return; if (where_dead && BLOCK_FOR_INSN (where_dead) == BLOCK_FOR_INSN (to_insn) && DF_INSN_LUID (where_dead) >= from_luid && DF_INSN_LUID (where_dead) < DF_INSN_LUID (to_insn)) { rtx note = remove_death (regno, where_dead); /* It is possible for the call above to return 0. This can occur when last_death points to I2 or I1 that we combined with. In that case make a new note. We must also check for the case where X is a hard register and NOTE is a death note for a range of hard registers including X. In that case, we must put REG_DEAD notes for the remaining registers in place of NOTE. */ if (note != 0 && regno < FIRST_PSEUDO_REGISTER && (GET_MODE_SIZE (GET_MODE (XEXP (note, 0))) > GET_MODE_SIZE (GET_MODE (x)))) { unsigned int deadregno = REGNO (XEXP (note, 0)); unsigned int deadend = END_REGNO (XEXP (note, 0)); unsigned int ourend = END_REGNO (x); unsigned int i; for (i = deadregno; i < deadend; i++) if (i < regno || i >= ourend) add_reg_note (where_dead, REG_DEAD, regno_reg_rtx[i]); } /* If we didn't find any note, or if we found a REG_DEAD note that covers only part of the given reg, and we have a multi-reg hard register, then to be safe we must check for REG_DEAD notes for each register other than the first. They could have their own REG_DEAD notes lying around. */ else if ((note == 0 || (note != 0 && (GET_MODE_SIZE (GET_MODE (XEXP (note, 0))) < GET_MODE_SIZE (GET_MODE (x))))) && regno < FIRST_PSEUDO_REGISTER && REG_NREGS (x) > 1) { unsigned int ourend = END_REGNO (x); unsigned int i, offset; rtx oldnotes = 0; if (note) offset = hard_regno_nregs[regno][GET_MODE (XEXP (note, 0))]; else offset = 1; for (i = regno + offset; i < ourend; i++) move_deaths (regno_reg_rtx[i], maybe_kill_insn, from_luid, to_insn, &oldnotes); } if (note != 0 && GET_MODE (XEXP (note, 0)) == GET_MODE (x)) { XEXP (note, 1) = *pnotes; *pnotes = note; } else *pnotes = alloc_reg_note (REG_DEAD, x, *pnotes); } return; } else if (GET_CODE (x) == SET) { rtx dest = SET_DEST (x); move_deaths (SET_SRC (x), maybe_kill_insn, from_luid, to_insn, pnotes); /* In the case of a ZERO_EXTRACT, a STRICT_LOW_PART, or a SUBREG that accesses one word of a multi-word item, some piece of everything register in the expression is used by this insn, so remove any old death. */ /* ??? So why do we test for equality of the sizes? */ if (GET_CODE (dest) == ZERO_EXTRACT || GET_CODE (dest) == STRICT_LOW_PART || (GET_CODE (dest) == SUBREG && (((GET_MODE_SIZE (GET_MODE (dest)) + UNITS_PER_WORD - 1) / UNITS_PER_WORD) == ((GET_MODE_SIZE (GET_MODE (SUBREG_REG (dest))) + UNITS_PER_WORD - 1) / UNITS_PER_WORD)))) { move_deaths (dest, maybe_kill_insn, from_luid, to_insn, pnotes); return; } /* If this is some other SUBREG, we know it replaces the entire value, so use that as the destination. */ if (GET_CODE (dest) == SUBREG) dest = SUBREG_REG (dest); /* If this is a MEM, adjust deaths of anything used in the address. For a REG (the only other possibility), the entire value is being replaced so the old value is not used in this insn. */ if (MEM_P (dest)) move_deaths (XEXP (dest, 0), maybe_kill_insn, from_luid, to_insn, pnotes); return; } else if (GET_CODE (x) == CLOBBER) return; len = GET_RTX_LENGTH (code); fmt = GET_RTX_FORMAT (code); for (i = 0; i < len; i++) { if (fmt[i] == 'E') { int j; for (j = XVECLEN (x, i) - 1; j >= 0; j--) move_deaths (XVECEXP (x, i, j), maybe_kill_insn, from_luid, to_insn, pnotes); } else if (fmt[i] == 'e') move_deaths (XEXP (x, i), maybe_kill_insn, from_luid, to_insn, pnotes); } } /* Return 1 if X is the target of a bit-field assignment in BODY, the pattern of an insn. X must be a REG. */ static int reg_bitfield_target_p (rtx x, rtx body) { int i; if (GET_CODE (body) == SET) { rtx dest = SET_DEST (body); rtx target; unsigned int regno, tregno, endregno, endtregno; if (GET_CODE (dest) == ZERO_EXTRACT) target = XEXP (dest, 0); else if (GET_CODE (dest) == STRICT_LOW_PART) target = SUBREG_REG (XEXP (dest, 0)); else return 0; if (GET_CODE (target) == SUBREG) target = SUBREG_REG (target); if (!REG_P (target)) return 0; tregno = REGNO (target), regno = REGNO (x); if (tregno >= FIRST_PSEUDO_REGISTER || regno >= FIRST_PSEUDO_REGISTER) return target == x; endtregno = end_hard_regno (GET_MODE (target), tregno); endregno = end_hard_regno (GET_MODE (x), regno); return endregno > tregno && regno < endtregno; } else if (GET_CODE (body) == PARALLEL) for (i = XVECLEN (body, 0) - 1; i >= 0; i--) if (reg_bitfield_target_p (x, XVECEXP (body, 0, i))) return 1; return 0; } /* Given a chain of REG_NOTES originally from FROM_INSN, try to place them as appropriate. I3 and I2 are the insns resulting from the combination insns including FROM (I2 may be zero). ELIM_I2 and ELIM_I1 are either zero or registers that we know will not need REG_DEAD notes because they are being substituted for. This saves searching in the most common cases. Each note in the list is either ignored or placed on some insns, depending on the type of note. */ static void distribute_notes (rtx notes, rtx_insn *from_insn, rtx_insn *i3, rtx_insn *i2, rtx elim_i2, rtx elim_i1, rtx elim_i0) { rtx note, next_note; rtx tem_note; rtx_insn *tem_insn; for (note = notes; note; note = next_note) { rtx_insn *place = 0, *place2 = 0; next_note = XEXP (note, 1); switch (REG_NOTE_KIND (note)) { case REG_BR_PROB: case REG_BR_PRED: /* Doesn't matter much where we put this, as long as it's somewhere. It is preferable to keep these notes on branches, which is most likely to be i3. */ place = i3; break; case REG_NON_LOCAL_GOTO: if (JUMP_P (i3)) place = i3; else { gcc_assert (i2 && JUMP_P (i2)); place = i2; } break; case REG_EH_REGION: /* These notes must remain with the call or trapping instruction. */ if (CALL_P (i3)) place = i3; else if (i2 && CALL_P (i2)) place = i2; else { gcc_assert (cfun->can_throw_non_call_exceptions); if (may_trap_p (i3)) place = i3; else if (i2 && may_trap_p (i2)) place = i2; /* ??? Otherwise assume we've combined things such that we can now prove that the instructions can't trap. Drop the note in this case. */ } break; case REG_ARGS_SIZE: /* ??? How to distribute between i3-i1. Assume i3 contains the entire adjustment. Assert i3 contains at least some adjust. */ if (!noop_move_p (i3)) { int old_size, args_size = INTVAL (XEXP (note, 0)); /* fixup_args_size_notes looks at REG_NORETURN note, so ensure the note is placed there first. */ if (CALL_P (i3)) { rtx *np; for (np = &next_note; *np; np = &XEXP (*np, 1)) if (REG_NOTE_KIND (*np) == REG_NORETURN) { rtx n = *np; *np = XEXP (n, 1); XEXP (n, 1) = REG_NOTES (i3); REG_NOTES (i3) = n; break; } } old_size = fixup_args_size_notes (PREV_INSN (i3), i3, args_size); /* emit_call_1 adds for !ACCUMULATE_OUTGOING_ARGS REG_ARGS_SIZE note to all noreturn calls, allow that here. */ gcc_assert (old_size != args_size || (CALL_P (i3) && !ACCUMULATE_OUTGOING_ARGS && find_reg_note (i3, REG_NORETURN, NULL_RTX))); } break; case REG_NORETURN: case REG_SETJMP: case REG_TM: case REG_CALL_DECL: /* These notes must remain with the call. It should not be possible for both I2 and I3 to be a call. */ if (CALL_P (i3)) place = i3; else { gcc_assert (i2 && CALL_P (i2)); place = i2; } break; case REG_UNUSED: /* Any clobbers for i3 may still exist, and so we must process REG_UNUSED notes from that insn. Any clobbers from i2 or i1 can only exist if they were added by recog_for_combine. In that case, recog_for_combine created the necessary REG_UNUSED notes. Trying to keep any original REG_UNUSED notes from these insns can cause incorrect output if it is for the same register as the original i3 dest. In that case, we will notice that the register is set in i3, and then add a REG_UNUSED note for the destination of i3, which is wrong. However, it is possible to have REG_UNUSED notes from i2 or i1 for register which were both used and clobbered, so we keep notes from i2 or i1 if they will turn into REG_DEAD notes. */ /* If this register is set or clobbered in I3, put the note there unless there is one already. */ if (reg_set_p (XEXP (note, 0), PATTERN (i3))) { if (from_insn != i3) break; if (! (REG_P (XEXP (note, 0)) ? find_regno_note (i3, REG_UNUSED, REGNO (XEXP (note, 0))) : find_reg_note (i3, REG_UNUSED, XEXP (note, 0)))) place = i3; } /* Otherwise, if this register is used by I3, then this register now dies here, so we must put a REG_DEAD note here unless there is one already. */ else if (reg_referenced_p (XEXP (note, 0), PATTERN (i3)) && ! (REG_P (XEXP (note, 0)) ? find_regno_note (i3, REG_DEAD, REGNO (XEXP (note, 0))) : find_reg_note (i3, REG_DEAD, XEXP (note, 0)))) { PUT_REG_NOTE_KIND (note, REG_DEAD); place = i3; } break; case REG_EQUAL: case REG_EQUIV: case REG_NOALIAS: /* These notes say something about results of an insn. We can only support them if they used to be on I3 in which case they remain on I3. Otherwise they are ignored. If the note refers to an expression that is not a constant, we must also ignore the note since we cannot tell whether the equivalence is still true. It might be possible to do slightly better than this (we only have a problem if I2DEST or I1DEST is present in the expression), but it doesn't seem worth the trouble. */ if (from_insn == i3 && (XEXP (note, 0) == 0 || CONSTANT_P (XEXP (note, 0)))) place = i3; break; case REG_INC: /* These notes say something about how a register is used. They must be present on any use of the register in I2 or I3. */ if (reg_mentioned_p (XEXP (note, 0), PATTERN (i3))) place = i3; if (i2 && reg_mentioned_p (XEXP (note, 0), PATTERN (i2))) { if (place) place2 = i2; else place = i2; } break; case REG_LABEL_TARGET: case REG_LABEL_OPERAND: /* This can show up in several ways -- either directly in the pattern, or hidden off in the constant pool with (or without?) a REG_EQUAL note. */ /* ??? Ignore the without-reg_equal-note problem for now. */ if (reg_mentioned_p (XEXP (note, 0), PATTERN (i3)) || ((tem_note = find_reg_note (i3, REG_EQUAL, NULL_RTX)) && GET_CODE (XEXP (tem_note, 0)) == LABEL_REF && LABEL_REF_LABEL (XEXP (tem_note, 0)) == XEXP (note, 0))) place = i3; if (i2 && (reg_mentioned_p (XEXP (note, 0), PATTERN (i2)) || ((tem_note = find_reg_note (i2, REG_EQUAL, NULL_RTX)) && GET_CODE (XEXP (tem_note, 0)) == LABEL_REF && LABEL_REF_LABEL (XEXP (tem_note, 0)) == XEXP (note, 0)))) { if (place) place2 = i2; else place = i2; } /* For REG_LABEL_TARGET on a JUMP_P, we prefer to put the note as a JUMP_LABEL or decrement LABEL_NUSES if it's already there. */ if (place && JUMP_P (place) && REG_NOTE_KIND (note) == REG_LABEL_TARGET && (JUMP_LABEL (place) == NULL || JUMP_LABEL (place) == XEXP (note, 0))) { rtx label = JUMP_LABEL (place); if (!label) JUMP_LABEL (place) = XEXP (note, 0); else if (LABEL_P (label)) LABEL_NUSES (label)--; } if (place2 && JUMP_P (place2) && REG_NOTE_KIND (note) == REG_LABEL_TARGET && (JUMP_LABEL (place2) == NULL || JUMP_LABEL (place2) == XEXP (note, 0))) { rtx label = JUMP_LABEL (place2); if (!label) JUMP_LABEL (place2) = XEXP (note, 0); else if (LABEL_P (label)) LABEL_NUSES (label)--; place2 = 0; } break; case REG_NONNEG: /* This note says something about the value of a register prior to the execution of an insn. It is too much trouble to see if the note is still correct in all situations. It is better to simply delete it. */ break; case REG_DEAD: /* If we replaced the right hand side of FROM_INSN with a REG_EQUAL note, the original use of the dying register will not have been combined into I3 and I2. In such cases, FROM_INSN is guaranteed to be the first of the combined instructions, so we simply need to search back before FROM_INSN for the previous use or set of this register, then alter the notes there appropriately. If the register is used as an input in I3, it dies there. Similarly for I2, if it is nonzero and adjacent to I3. If the register is not used as an input in either I3 or I2 and it is not one of the registers we were supposed to eliminate, there are two possibilities. We might have a non-adjacent I2 or we might have somehow eliminated an additional register from a computation. For example, we might have had A & B where we discover that B will always be zero. In this case we will eliminate the reference to A. In both cases, we must search to see if we can find a previous use of A and put the death note there. */ if (from_insn && from_insn == i2mod && !reg_overlap_mentioned_p (XEXP (note, 0), i2mod_new_rhs)) tem_insn = from_insn; else { if (from_insn && CALL_P (from_insn) && find_reg_fusage (from_insn, USE, XEXP (note, 0))) place = from_insn; else if (reg_referenced_p (XEXP (note, 0), PATTERN (i3))) place = i3; else if (i2 != 0 && next_nonnote_nondebug_insn (i2) == i3 && reg_referenced_p (XEXP (note, 0), PATTERN (i2))) place = i2; else if ((rtx_equal_p (XEXP (note, 0), elim_i2) && !(i2mod && reg_overlap_mentioned_p (XEXP (note, 0), i2mod_old_rhs))) || rtx_equal_p (XEXP (note, 0), elim_i1) || rtx_equal_p (XEXP (note, 0), elim_i0)) break; tem_insn = i3; /* If the new I2 sets the same register that is marked dead in the note, the note now should not be put on I2, as the note refers to a previous incarnation of the reg. */ if (i2 != 0 && reg_set_p (XEXP (note, 0), PATTERN (i2))) tem_insn = i2; } if (place == 0) { basic_block bb = this_basic_block; for (tem_insn = PREV_INSN (tem_insn); place == 0; tem_insn = PREV_INSN (tem_insn)) { if (!NONDEBUG_INSN_P (tem_insn)) { if (tem_insn == BB_HEAD (bb)) break; continue; } /* If the register is being set at TEM_INSN, see if that is all TEM_INSN is doing. If so, delete TEM_INSN. Otherwise, make this into a REG_UNUSED note instead. Don't delete sets to global register vars. */ if ((REGNO (XEXP (note, 0)) >= FIRST_PSEUDO_REGISTER || !global_regs[REGNO (XEXP (note, 0))]) && reg_set_p (XEXP (note, 0), PATTERN (tem_insn))) { rtx set = single_set (tem_insn); rtx inner_dest = 0; rtx_insn *cc0_setter = NULL; if (set != 0) for (inner_dest = SET_DEST (set); (GET_CODE (inner_dest) == STRICT_LOW_PART || GET_CODE (inner_dest) == SUBREG || GET_CODE (inner_dest) == ZERO_EXTRACT); inner_dest = XEXP (inner_dest, 0)) ; /* Verify that it was the set, and not a clobber that modified the register. CC0 targets must be careful to maintain setter/user pairs. If we cannot delete the setter due to side effects, mark the user with an UNUSED note instead of deleting it. */ if (set != 0 && ! side_effects_p (SET_SRC (set)) && rtx_equal_p (XEXP (note, 0), inner_dest) && (!HAVE_cc0 || (! reg_mentioned_p (cc0_rtx, SET_SRC (set)) || ((cc0_setter = prev_cc0_setter (tem_insn)) != NULL && sets_cc0_p (PATTERN (cc0_setter)) > 0)))) { /* Move the notes and links of TEM_INSN elsewhere. This might delete other dead insns recursively. First set the pattern to something that won't use any register. */ rtx old_notes = REG_NOTES (tem_insn); PATTERN (tem_insn) = pc_rtx; REG_NOTES (tem_insn) = NULL; distribute_notes (old_notes, tem_insn, tem_insn, NULL, NULL_RTX, NULL_RTX, NULL_RTX); distribute_links (LOG_LINKS (tem_insn)); SET_INSN_DELETED (tem_insn); if (tem_insn == i2) i2 = NULL; /* Delete the setter too. */ if (cc0_setter) { PATTERN (cc0_setter) = pc_rtx; old_notes = REG_NOTES (cc0_setter); REG_NOTES (cc0_setter) = NULL; distribute_notes (old_notes, cc0_setter, cc0_setter, NULL, NULL_RTX, NULL_RTX, NULL_RTX); distribute_links (LOG_LINKS (cc0_setter)); SET_INSN_DELETED (cc0_setter); if (cc0_setter == i2) i2 = NULL; } } else { PUT_REG_NOTE_KIND (note, REG_UNUSED); /* If there isn't already a REG_UNUSED note, put one here. Do not place a REG_DEAD note, even if the register is also used here; that would not match the algorithm used in lifetime analysis and can cause the consistency check in the scheduler to fail. */ if (! find_regno_note (tem_insn, REG_UNUSED, REGNO (XEXP (note, 0)))) place = tem_insn; break; } } else if (reg_referenced_p (XEXP (note, 0), PATTERN (tem_insn)) || (CALL_P (tem_insn) && find_reg_fusage (tem_insn, USE, XEXP (note, 0)))) { place = tem_insn; /* If we are doing a 3->2 combination, and we have a register which formerly died in i3 and was not used by i2, which now no longer dies in i3 and is used in i2 but does not die in i2, and place is between i2 and i3, then we may need to move a link from place to i2. */ if (i2 && DF_INSN_LUID (place) > DF_INSN_LUID (i2) && from_insn && DF_INSN_LUID (from_insn) > DF_INSN_LUID (i2) && reg_referenced_p (XEXP (note, 0), PATTERN (i2))) { struct insn_link *links = LOG_LINKS (place); LOG_LINKS (place) = NULL; distribute_links (links); } break; } if (tem_insn == BB_HEAD (bb)) break; } } /* If the register is set or already dead at PLACE, we needn't do anything with this note if it is still a REG_DEAD note. We check here if it is set at all, not if is it totally replaced, which is what `dead_or_set_p' checks, so also check for it being set partially. */ if (place && REG_NOTE_KIND (note) == REG_DEAD) { unsigned int regno = REGNO (XEXP (note, 0)); reg_stat_type *rsp = ®_stat[regno]; if (dead_or_set_p (place, XEXP (note, 0)) || reg_bitfield_target_p (XEXP (note, 0), PATTERN (place))) { /* Unless the register previously died in PLACE, clear last_death. [I no longer understand why this is being done.] */ if (rsp->last_death != place) rsp->last_death = 0; place = 0; } else rsp->last_death = place; /* If this is a death note for a hard reg that is occupying multiple registers, ensure that we are still using all parts of the object. If we find a piece of the object that is unused, we must arrange for an appropriate REG_DEAD note to be added for it. However, we can't just emit a USE and tag the note to it, since the register might actually be dead; so we recourse, and the recursive call then finds the previous insn that used this register. */ if (place && REG_NREGS (XEXP (note, 0)) > 1) { unsigned int endregno = END_REGNO (XEXP (note, 0)); bool all_used = true; unsigned int i; for (i = regno; i < endregno; i++) if ((! refers_to_regno_p (i, PATTERN (place)) && ! find_regno_fusage (place, USE, i)) || dead_or_set_regno_p (place, i)) { all_used = false; break; } if (! all_used) { /* Put only REG_DEAD notes for pieces that are not already dead or set. */ for (i = regno; i < endregno; i += hard_regno_nregs[i][reg_raw_mode[i]]) { rtx piece = regno_reg_rtx[i]; basic_block bb = this_basic_block; if (! dead_or_set_p (place, piece) && ! reg_bitfield_target_p (piece, PATTERN (place))) { rtx new_note = alloc_reg_note (REG_DEAD, piece, NULL_RTX); distribute_notes (new_note, place, place, NULL, NULL_RTX, NULL_RTX, NULL_RTX); } else if (! refers_to_regno_p (i, PATTERN (place)) && ! find_regno_fusage (place, USE, i)) for (tem_insn = PREV_INSN (place); ; tem_insn = PREV_INSN (tem_insn)) { if (!NONDEBUG_INSN_P (tem_insn)) { if (tem_insn == BB_HEAD (bb)) break; continue; } if (dead_or_set_p (tem_insn, piece) || reg_bitfield_target_p (piece, PATTERN (tem_insn))) { add_reg_note (tem_insn, REG_UNUSED, piece); break; } } } place = 0; } } } break; default: /* Any other notes should not be present at this point in the compilation. */ gcc_unreachable (); } if (place) { XEXP (note, 1) = REG_NOTES (place); REG_NOTES (place) = note; } if (place2) add_shallow_copy_of_reg_note (place2, note); } } /* Similarly to above, distribute the LOG_LINKS that used to be present on I3, I2, and I1 to new locations. This is also called to add a link pointing at I3 when I3's destination is changed. */ static void distribute_links (struct insn_link *links) { struct insn_link *link, *next_link; for (link = links; link; link = next_link) { rtx_insn *place = 0; rtx_insn *insn; rtx set, reg; next_link = link->next; /* If the insn that this link points to is a NOTE, ignore it. */ if (NOTE_P (link->insn)) continue; set = 0; rtx pat = PATTERN (link->insn); if (GET_CODE (pat) == SET) set = pat; else if (GET_CODE (pat) == PARALLEL) { int i; for (i = 0; i < XVECLEN (pat, 0); i++) { set = XVECEXP (pat, 0, i); if (GET_CODE (set) != SET) continue; reg = SET_DEST (set); while (GET_CODE (reg) == ZERO_EXTRACT || GET_CODE (reg) == STRICT_LOW_PART || GET_CODE (reg) == SUBREG) reg = XEXP (reg, 0); if (!REG_P (reg)) continue; if (REGNO (reg) == link->regno) break; } if (i == XVECLEN (pat, 0)) continue; } else continue; reg = SET_DEST (set); while (GET_CODE (reg) == ZERO_EXTRACT || GET_CODE (reg) == STRICT_LOW_PART || GET_CODE (reg) == SUBREG) reg = XEXP (reg, 0); /* A LOG_LINK is defined as being placed on the first insn that uses a register and points to the insn that sets the register. Start searching at the next insn after the target of the link and stop when we reach a set of the register or the end of the basic block. Note that this correctly handles the link that used to point from I3 to I2. Also note that not much searching is typically done here since most links don't point very far away. */ for (insn = NEXT_INSN (link->insn); (insn && (this_basic_block->next_bb == EXIT_BLOCK_PTR_FOR_FN (cfun) || BB_HEAD (this_basic_block->next_bb) != insn)); insn = NEXT_INSN (insn)) if (DEBUG_INSN_P (insn)) continue; else if (INSN_P (insn) && reg_overlap_mentioned_p (reg, PATTERN (insn))) { if (reg_referenced_p (reg, PATTERN (insn))) place = insn; break; } else if (CALL_P (insn) && find_reg_fusage (insn, USE, reg)) { place = insn; break; } else if (INSN_P (insn) && reg_set_p (reg, insn)) break; /* If we found a place to put the link, place it there unless there is already a link to the same insn as LINK at that point. */ if (place) { struct insn_link *link2; FOR_EACH_LOG_LINK (link2, place) if (link2->insn == link->insn && link2->regno == link->regno) break; if (link2 == NULL) { link->next = LOG_LINKS (place); LOG_LINKS (place) = link; /* Set added_links_insn to the earliest insn we added a link to. */ if (added_links_insn == 0 || DF_INSN_LUID (added_links_insn) > DF_INSN_LUID (place)) added_links_insn = place; } } } } /* Check for any register or memory mentioned in EQUIV that is not mentioned in EXPR. This is used to restrict EQUIV to "specializations" of EXPR where some registers may have been replaced by constants. */ static bool unmentioned_reg_p (rtx equiv, rtx expr) { subrtx_iterator::array_type array; FOR_EACH_SUBRTX (iter, array, equiv, NONCONST) { const_rtx x = *iter; if ((REG_P (x) || MEM_P (x)) && !reg_mentioned_p (x, expr)) return true; } return false; } DEBUG_FUNCTION void dump_combine_stats (FILE *file) { fprintf (file, ";; Combiner statistics: %d attempts, %d substitutions (%d requiring new space),\n;; %d successes.\n\n", combine_attempts, combine_merges, combine_extras, combine_successes); } void dump_combine_total_stats (FILE *file) { fprintf (file, "\n;; Combiner totals: %d attempts, %d substitutions (%d requiring new space),\n;; %d successes.\n", total_attempts, total_merges, total_extras, total_successes); } /* Try combining insns through substitution. */ static unsigned int rest_of_handle_combine (void) { int rebuild_jump_labels_after_combine; df_set_flags (DF_LR_RUN_DCE + DF_DEFER_INSN_RESCAN); df_note_add_problem (); df_analyze (); regstat_init_n_sets_and_refs (); reg_n_sets_max = max_reg_num (); rebuild_jump_labels_after_combine = combine_instructions (get_insns (), max_reg_num ()); /* Combining insns may have turned an indirect jump into a direct jump. Rebuild the JUMP_LABEL fields of jumping instructions. */ if (rebuild_jump_labels_after_combine) { timevar_push (TV_JUMP); rebuild_jump_labels (get_insns ()); cleanup_cfg (0); timevar_pop (TV_JUMP); } regstat_free_n_sets_and_refs (); return 0; } namespace { const pass_data pass_data_combine = { RTL_PASS, /* type */ "combine", /* name */ OPTGROUP_NONE, /* optinfo_flags */ TV_COMBINE, /* tv_id */ PROP_cfglayout, /* properties_required */ 0, /* properties_provided */ 0, /* properties_destroyed */ 0, /* todo_flags_start */ TODO_df_finish, /* todo_flags_finish */ }; class pass_combine : public rtl_opt_pass { public: pass_combine (gcc::context *ctxt) : rtl_opt_pass (pass_data_combine, ctxt) {} /* opt_pass methods: */ virtual bool gate (function *) { return (optimize > 0); } virtual unsigned int execute (function *) { return rest_of_handle_combine (); } }; // class pass_combine } // anon namespace rtl_opt_pass * make_pass_combine (gcc::context *ctxt) { return new pass_combine (ctxt); }