/* Target-dependent code for the MIPS architecture, for GDB, the GNU Debugger. Copyright (C) 1988-2019 Free Software Foundation, Inc. Contributed by Alessandro Forin(af@cs.cmu.edu) at CMU and by Per Bothner(bothner@cs.wisc.edu) at U.Wisconsin. This file is part of GDB. This program 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 of the License, or (at your option) any later version. This program 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 this program. If not, see . */ #include "defs.h" #include "frame.h" #include "inferior.h" #include "symtab.h" #include "value.h" #include "gdbcmd.h" #include "language.h" #include "gdbcore.h" #include "symfile.h" #include "objfiles.h" #include "gdbtypes.h" #include "target.h" #include "arch-utils.h" #include "regcache.h" #include "osabi.h" #include "mips-tdep.h" #include "block.h" #include "reggroups.h" #include "opcode/mips.h" #include "elf/mips.h" #include "elf-bfd.h" #include "symcat.h" #include "sim-regno.h" #include "dis-asm.h" #include "disasm.h" #include "frame-unwind.h" #include "frame-base.h" #include "trad-frame.h" #include "infcall.h" #include "remote.h" #include "target-descriptions.h" #include "dwarf2-frame.h" #include "user-regs.h" #include "valprint.h" #include "ax.h" #include "target-float.h" #include static struct type *mips_register_type (struct gdbarch *gdbarch, int regnum); static int mips32_instruction_has_delay_slot (struct gdbarch *gdbarch, ULONGEST inst); static int micromips_instruction_has_delay_slot (ULONGEST insn, int mustbe32); static int mips16_instruction_has_delay_slot (unsigned short inst, int mustbe32); static int mips32_insn_at_pc_has_delay_slot (struct gdbarch *gdbarch, CORE_ADDR addr); static int micromips_insn_at_pc_has_delay_slot (struct gdbarch *gdbarch, CORE_ADDR addr, int mustbe32); static int mips16_insn_at_pc_has_delay_slot (struct gdbarch *gdbarch, CORE_ADDR addr, int mustbe32); static void mips_print_float_info (struct gdbarch *, struct ui_file *, struct frame_info *, const char *); /* A useful bit in the CP0 status register (MIPS_PS_REGNUM). */ /* This bit is set if we are emulating 32-bit FPRs on a 64-bit chip. */ #define ST0_FR (1 << 26) /* The sizes of floating point registers. */ enum { MIPS_FPU_SINGLE_REGSIZE = 4, MIPS_FPU_DOUBLE_REGSIZE = 8 }; enum { MIPS32_REGSIZE = 4, MIPS64_REGSIZE = 8 }; static const char *mips_abi_string; static const char *const mips_abi_strings[] = { "auto", "n32", "o32", "n64", "o64", "eabi32", "eabi64", NULL }; /* Enum describing the different kinds of breakpoints. */ enum mips_breakpoint_kind { /* 16-bit MIPS16 mode breakpoint. */ MIPS_BP_KIND_MIPS16 = 2, /* 16-bit microMIPS mode breakpoint. */ MIPS_BP_KIND_MICROMIPS16 = 3, /* 32-bit standard MIPS mode breakpoint. */ MIPS_BP_KIND_MIPS32 = 4, /* 32-bit microMIPS mode breakpoint. */ MIPS_BP_KIND_MICROMIPS32 = 5, }; /* For backwards compatibility we default to MIPS16. This flag is overridden as soon as unambiguous ELF file flags tell us the compressed ISA encoding used. */ static const char mips_compression_mips16[] = "mips16"; static const char mips_compression_micromips[] = "micromips"; static const char *const mips_compression_strings[] = { mips_compression_mips16, mips_compression_micromips, NULL }; static const char *mips_compression_string = mips_compression_mips16; /* The standard register names, and all the valid aliases for them. */ struct register_alias { const char *name; int regnum; }; /* Aliases for o32 and most other ABIs. */ const struct register_alias mips_o32_aliases[] = { { "ta0", 12 }, { "ta1", 13 }, { "ta2", 14 }, { "ta3", 15 } }; /* Aliases for n32 and n64. */ const struct register_alias mips_n32_n64_aliases[] = { { "ta0", 8 }, { "ta1", 9 }, { "ta2", 10 }, { "ta3", 11 } }; /* Aliases for ABI-independent registers. */ const struct register_alias mips_register_aliases[] = { /* The architecture manuals specify these ABI-independent names for the GPRs. */ #define R(n) { "r" #n, n } R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8), R(9), R(10), R(11), R(12), R(13), R(14), R(15), R(16), R(17), R(18), R(19), R(20), R(21), R(22), R(23), R(24), R(25), R(26), R(27), R(28), R(29), R(30), R(31), #undef R /* k0 and k1 are sometimes called these instead (for "kernel temp"). */ { "kt0", 26 }, { "kt1", 27 }, /* This is the traditional GDB name for the CP0 status register. */ { "sr", MIPS_PS_REGNUM }, /* This is the traditional GDB name for the CP0 BadVAddr register. */ { "bad", MIPS_EMBED_BADVADDR_REGNUM }, /* This is the traditional GDB name for the FCSR. */ { "fsr", MIPS_EMBED_FP0_REGNUM + 32 } }; const struct register_alias mips_numeric_register_aliases[] = { #define R(n) { #n, n } R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8), R(9), R(10), R(11), R(12), R(13), R(14), R(15), R(16), R(17), R(18), R(19), R(20), R(21), R(22), R(23), R(24), R(25), R(26), R(27), R(28), R(29), R(30), R(31), #undef R }; #ifndef MIPS_DEFAULT_FPU_TYPE #define MIPS_DEFAULT_FPU_TYPE MIPS_FPU_DOUBLE #endif static int mips_fpu_type_auto = 1; static enum mips_fpu_type mips_fpu_type = MIPS_DEFAULT_FPU_TYPE; static unsigned int mips_debug = 0; /* Properties (for struct target_desc) describing the g/G packet layout. */ #define PROPERTY_GP32 "internal: transfers-32bit-registers" #define PROPERTY_GP64 "internal: transfers-64bit-registers" struct target_desc *mips_tdesc_gp32; struct target_desc *mips_tdesc_gp64; /* The current set of options to be passed to the disassembler. */ static char *mips_disassembler_options; /* Implicit disassembler options for individual ABIs. These tell libopcodes to use general-purpose register names corresponding to the ABI we have selected, perhaps via a `set mips abi ...' override, rather than ones inferred from the ABI set in the ELF headers of the binary file selected for debugging. */ static const char mips_disassembler_options_o32[] = "gpr-names=32"; static const char mips_disassembler_options_n32[] = "gpr-names=n32"; static const char mips_disassembler_options_n64[] = "gpr-names=64"; const struct mips_regnum * mips_regnum (struct gdbarch *gdbarch) { return gdbarch_tdep (gdbarch)->regnum; } static int mips_fpa0_regnum (struct gdbarch *gdbarch) { return mips_regnum (gdbarch)->fp0 + 12; } /* Return 1 if REGNUM refers to a floating-point general register, raw or cooked. Otherwise return 0. */ static int mips_float_register_p (struct gdbarch *gdbarch, int regnum) { int rawnum = regnum % gdbarch_num_regs (gdbarch); return (rawnum >= mips_regnum (gdbarch)->fp0 && rawnum < mips_regnum (gdbarch)->fp0 + 32); } #define MIPS_EABI(gdbarch) (gdbarch_tdep (gdbarch)->mips_abi \ == MIPS_ABI_EABI32 \ || gdbarch_tdep (gdbarch)->mips_abi == MIPS_ABI_EABI64) #define MIPS_LAST_FP_ARG_REGNUM(gdbarch) \ (gdbarch_tdep (gdbarch)->mips_last_fp_arg_regnum) #define MIPS_LAST_ARG_REGNUM(gdbarch) \ (gdbarch_tdep (gdbarch)->mips_last_arg_regnum) #define MIPS_FPU_TYPE(gdbarch) (gdbarch_tdep (gdbarch)->mips_fpu_type) /* Return the MIPS ABI associated with GDBARCH. */ enum mips_abi mips_abi (struct gdbarch *gdbarch) { return gdbarch_tdep (gdbarch)->mips_abi; } int mips_isa_regsize (struct gdbarch *gdbarch) { struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch); /* If we know how big the registers are, use that size. */ if (tdep->register_size_valid_p) return tdep->register_size; /* Fall back to the previous behavior. */ return (gdbarch_bfd_arch_info (gdbarch)->bits_per_word / gdbarch_bfd_arch_info (gdbarch)->bits_per_byte); } /* Max saved register size. */ #define MAX_MIPS_ABI_REGSIZE 8 /* Return the currently configured (or set) saved register size. */ unsigned int mips_abi_regsize (struct gdbarch *gdbarch) { switch (mips_abi (gdbarch)) { case MIPS_ABI_EABI32: case MIPS_ABI_O32: return 4; case MIPS_ABI_N32: case MIPS_ABI_N64: case MIPS_ABI_O64: case MIPS_ABI_EABI64: return 8; case MIPS_ABI_UNKNOWN: case MIPS_ABI_LAST: default: internal_error (__FILE__, __LINE__, _("bad switch")); } } /* MIPS16/microMIPS function addresses are odd (bit 0 is set). Here are some functions to handle addresses associated with compressed code including but not limited to testing, setting, or clearing bit 0 of such addresses. */ /* Return one iff compressed code is the MIPS16 instruction set. */ static int is_mips16_isa (struct gdbarch *gdbarch) { return gdbarch_tdep (gdbarch)->mips_isa == ISA_MIPS16; } /* Return one iff compressed code is the microMIPS instruction set. */ static int is_micromips_isa (struct gdbarch *gdbarch) { return gdbarch_tdep (gdbarch)->mips_isa == ISA_MICROMIPS; } /* Return one iff ADDR denotes compressed code. */ static int is_compact_addr (CORE_ADDR addr) { return ((addr) & 1); } /* Return one iff ADDR denotes standard ISA code. */ static int is_mips_addr (CORE_ADDR addr) { return !is_compact_addr (addr); } /* Return one iff ADDR denotes MIPS16 code. */ static int is_mips16_addr (struct gdbarch *gdbarch, CORE_ADDR addr) { return is_compact_addr (addr) && is_mips16_isa (gdbarch); } /* Return one iff ADDR denotes microMIPS code. */ static int is_micromips_addr (struct gdbarch *gdbarch, CORE_ADDR addr) { return is_compact_addr (addr) && is_micromips_isa (gdbarch); } /* Strip the ISA (compression) bit off from ADDR. */ static CORE_ADDR unmake_compact_addr (CORE_ADDR addr) { return ((addr) & ~(CORE_ADDR) 1); } /* Add the ISA (compression) bit to ADDR. */ static CORE_ADDR make_compact_addr (CORE_ADDR addr) { return ((addr) | (CORE_ADDR) 1); } /* Extern version of unmake_compact_addr; we use a separate function so that unmake_compact_addr can be inlined throughout this file. */ CORE_ADDR mips_unmake_compact_addr (CORE_ADDR addr) { return unmake_compact_addr (addr); } /* Functions for setting and testing a bit in a minimal symbol that marks it as MIPS16 or microMIPS function. The MSB of the minimal symbol's "info" field is used for this purpose. gdbarch_elf_make_msymbol_special tests whether an ELF symbol is "special", i.e. refers to a MIPS16 or microMIPS function, and sets one of the "special" bits in a minimal symbol to mark it accordingly. The test checks an ELF-private flag that is valid for true function symbols only; for synthetic symbols such as for PLT stubs that have no ELF-private part at all the MIPS BFD backend arranges for this information to be carried in the asymbol's udata field instead. msymbol_is_mips16 and msymbol_is_micromips test the "special" bit in a minimal symbol. */ static void mips_elf_make_msymbol_special (asymbol * sym, struct minimal_symbol *msym) { elf_symbol_type *elfsym = (elf_symbol_type *) sym; unsigned char st_other; if ((sym->flags & BSF_SYNTHETIC) == 0) st_other = elfsym->internal_elf_sym.st_other; else if ((sym->flags & BSF_FUNCTION) != 0) st_other = sym->udata.i; else return; if (ELF_ST_IS_MICROMIPS (st_other)) { MSYMBOL_TARGET_FLAG_MICROMIPS (msym) = 1; SET_MSYMBOL_VALUE_ADDRESS (msym, MSYMBOL_VALUE_RAW_ADDRESS (msym) | 1); } else if (ELF_ST_IS_MIPS16 (st_other)) { MSYMBOL_TARGET_FLAG_MIPS16 (msym) = 1; SET_MSYMBOL_VALUE_ADDRESS (msym, MSYMBOL_VALUE_RAW_ADDRESS (msym) | 1); } } /* Return one iff MSYM refers to standard ISA code. */ static int msymbol_is_mips (struct minimal_symbol *msym) { return !(MSYMBOL_TARGET_FLAG_MIPS16 (msym) | MSYMBOL_TARGET_FLAG_MICROMIPS (msym)); } /* Return one iff MSYM refers to MIPS16 code. */ static int msymbol_is_mips16 (struct minimal_symbol *msym) { return MSYMBOL_TARGET_FLAG_MIPS16 (msym); } /* Return one iff MSYM refers to microMIPS code. */ static int msymbol_is_micromips (struct minimal_symbol *msym) { return MSYMBOL_TARGET_FLAG_MICROMIPS (msym); } /* Set the ISA bit in the main symbol too, complementing the corresponding minimal symbol setting and reflecting the run-time value of the symbol. The need for comes from the ISA bit having been cleared as code in `_bfd_mips_elf_symbol_processing' separated it into the ELF symbol's `st_other' STO_MIPS16 or STO_MICROMIPS annotation, making the values of symbols referring to compressed code different in GDB to the values used by actual code. That in turn makes them evaluate incorrectly in expressions, producing results different to what the same expressions yield when compiled into the program being debugged. */ static void mips_make_symbol_special (struct symbol *sym, struct objfile *objfile) { if (SYMBOL_CLASS (sym) == LOC_BLOCK) { /* We are in symbol reading so it is OK to cast away constness. */ struct block *block = (struct block *) SYMBOL_BLOCK_VALUE (sym); CORE_ADDR compact_block_start; struct bound_minimal_symbol msym; compact_block_start = BLOCK_START (block) | 1; msym = lookup_minimal_symbol_by_pc (compact_block_start); if (msym.minsym && !msymbol_is_mips (msym.minsym)) { BLOCK_START (block) = compact_block_start; } } } /* XFER a value from the big/little/left end of the register. Depending on the size of the value it might occupy the entire register or just part of it. Make an allowance for this, aligning things accordingly. */ static void mips_xfer_register (struct gdbarch *gdbarch, struct regcache *regcache, int reg_num, int length, enum bfd_endian endian, gdb_byte *in, const gdb_byte *out, int buf_offset) { int reg_offset = 0; gdb_assert (reg_num >= gdbarch_num_regs (gdbarch)); /* Need to transfer the left or right part of the register, based on the targets byte order. */ switch (endian) { case BFD_ENDIAN_BIG: reg_offset = register_size (gdbarch, reg_num) - length; break; case BFD_ENDIAN_LITTLE: reg_offset = 0; break; case BFD_ENDIAN_UNKNOWN: /* Indicates no alignment. */ reg_offset = 0; break; default: internal_error (__FILE__, __LINE__, _("bad switch")); } if (mips_debug) fprintf_unfiltered (gdb_stderr, "xfer $%d, reg offset %d, buf offset %d, length %d, ", reg_num, reg_offset, buf_offset, length); if (mips_debug && out != NULL) { int i; fprintf_unfiltered (gdb_stdlog, "out "); for (i = 0; i < length; i++) fprintf_unfiltered (gdb_stdlog, "%02x", out[buf_offset + i]); } if (in != NULL) regcache->cooked_read_part (reg_num, reg_offset, length, in + buf_offset); if (out != NULL) regcache->cooked_write_part (reg_num, reg_offset, length, out + buf_offset); if (mips_debug && in != NULL) { int i; fprintf_unfiltered (gdb_stdlog, "in "); for (i = 0; i < length; i++) fprintf_unfiltered (gdb_stdlog, "%02x", in[buf_offset + i]); } if (mips_debug) fprintf_unfiltered (gdb_stdlog, "\n"); } /* Determine if a MIPS3 or later cpu is operating in MIPS{1,2} FPU compatiblity mode. A return value of 1 means that we have physical 64-bit registers, but should treat them as 32-bit registers. */ static int mips2_fp_compat (struct frame_info *frame) { struct gdbarch *gdbarch = get_frame_arch (frame); /* MIPS1 and MIPS2 have only 32 bit FPRs, and the FR bit is not meaningful. */ if (register_size (gdbarch, mips_regnum (gdbarch)->fp0) == 4) return 0; #if 0 /* FIXME drow 2002-03-10: This is disabled until we can do it consistently, in all the places we deal with FP registers. PR gdb/413. */ /* Otherwise check the FR bit in the status register - it controls the FP compatiblity mode. If it is clear we are in compatibility mode. */ if ((get_frame_register_unsigned (frame, MIPS_PS_REGNUM) & ST0_FR) == 0) return 1; #endif return 0; } #define VM_MIN_ADDRESS (CORE_ADDR)0x400000 static CORE_ADDR heuristic_proc_start (struct gdbarch *, CORE_ADDR); /* The list of available "set mips " and "show mips " commands. */ static struct cmd_list_element *setmipscmdlist = NULL; static struct cmd_list_element *showmipscmdlist = NULL; /* Integer registers 0 thru 31 are handled explicitly by mips_register_name(). Processor specific registers 32 and above are listed in the following tables. */ enum { NUM_MIPS_PROCESSOR_REGS = (90 - 32) }; /* Generic MIPS. */ static const char *mips_generic_reg_names[NUM_MIPS_PROCESSOR_REGS] = { "sr", "lo", "hi", "bad", "cause", "pc", "f0", "f1", "f2", "f3", "f4", "f5", "f6", "f7", "f8", "f9", "f10", "f11", "f12", "f13", "f14", "f15", "f16", "f17", "f18", "f19", "f20", "f21", "f22", "f23", "f24", "f25", "f26", "f27", "f28", "f29", "f30", "f31", "fsr", "fir", }; /* Names of tx39 registers. */ static const char *mips_tx39_reg_names[NUM_MIPS_PROCESSOR_REGS] = { "sr", "lo", "hi", "bad", "cause", "pc", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "", "config", "cache", "debug", "depc", "epc", }; /* Names of registers with Linux kernels. */ static const char *mips_linux_reg_names[NUM_MIPS_PROCESSOR_REGS] = { "sr", "lo", "hi", "bad", "cause", "pc", "f0", "f1", "f2", "f3", "f4", "f5", "f6", "f7", "f8", "f9", "f10", "f11", "f12", "f13", "f14", "f15", "f16", "f17", "f18", "f19", "f20", "f21", "f22", "f23", "f24", "f25", "f26", "f27", "f28", "f29", "f30", "f31", "fsr", "fir" }; /* Return the name of the register corresponding to REGNO. */ static const char * mips_register_name (struct gdbarch *gdbarch, int regno) { struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch); /* GPR names for all ABIs other than n32/n64. */ static const char *mips_gpr_names[] = { "zero", "at", "v0", "v1", "a0", "a1", "a2", "a3", "t0", "t1", "t2", "t3", "t4", "t5", "t6", "t7", "s0", "s1", "s2", "s3", "s4", "s5", "s6", "s7", "t8", "t9", "k0", "k1", "gp", "sp", "s8", "ra", }; /* GPR names for n32 and n64 ABIs. */ static const char *mips_n32_n64_gpr_names[] = { "zero", "at", "v0", "v1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "t0", "t1", "t2", "t3", "s0", "s1", "s2", "s3", "s4", "s5", "s6", "s7", "t8", "t9", "k0", "k1", "gp", "sp", "s8", "ra" }; enum mips_abi abi = mips_abi (gdbarch); /* Map [gdbarch_num_regs .. 2*gdbarch_num_regs) onto the raw registers, but then don't make the raw register names visible. This (upper) range of user visible register numbers are the pseudo-registers. This approach was adopted accommodate the following scenario: It is possible to debug a 64-bit device using a 32-bit programming model. In such instances, the raw registers are configured to be 64-bits wide, while the pseudo registers are configured to be 32-bits wide. The registers that the user sees - the pseudo registers - match the users expectations given the programming model being used. */ int rawnum = regno % gdbarch_num_regs (gdbarch); if (regno < gdbarch_num_regs (gdbarch)) return ""; /* The MIPS integer registers are always mapped from 0 to 31. The names of the registers (which reflects the conventions regarding register use) vary depending on the ABI. */ if (0 <= rawnum && rawnum < 32) { if (abi == MIPS_ABI_N32 || abi == MIPS_ABI_N64) return mips_n32_n64_gpr_names[rawnum]; else return mips_gpr_names[rawnum]; } else if (tdesc_has_registers (gdbarch_target_desc (gdbarch))) return tdesc_register_name (gdbarch, rawnum); else if (32 <= rawnum && rawnum < gdbarch_num_regs (gdbarch)) { gdb_assert (rawnum - 32 < NUM_MIPS_PROCESSOR_REGS); if (tdep->mips_processor_reg_names[rawnum - 32]) return tdep->mips_processor_reg_names[rawnum - 32]; return ""; } else internal_error (__FILE__, __LINE__, _("mips_register_name: bad register number %d"), rawnum); } /* Return the groups that a MIPS register can be categorised into. */ static int mips_register_reggroup_p (struct gdbarch *gdbarch, int regnum, struct reggroup *reggroup) { int vector_p; int float_p; int raw_p; int rawnum = regnum % gdbarch_num_regs (gdbarch); int pseudo = regnum / gdbarch_num_regs (gdbarch); if (reggroup == all_reggroup) return pseudo; vector_p = TYPE_VECTOR (register_type (gdbarch, regnum)); float_p = TYPE_CODE (register_type (gdbarch, regnum)) == TYPE_CODE_FLT; /* FIXME: cagney/2003-04-13: Can't yet use gdbarch_num_regs (gdbarch), as not all architectures are multi-arch. */ raw_p = rawnum < gdbarch_num_regs (gdbarch); if (gdbarch_register_name (gdbarch, regnum) == NULL || gdbarch_register_name (gdbarch, regnum)[0] == '\0') return 0; if (reggroup == float_reggroup) return float_p && pseudo; if (reggroup == vector_reggroup) return vector_p && pseudo; if (reggroup == general_reggroup) return (!vector_p && !float_p) && pseudo; /* Save the pseudo registers. Need to make certain that any code extracting register values from a saved register cache also uses pseudo registers. */ if (reggroup == save_reggroup) return raw_p && pseudo; /* Restore the same pseudo register. */ if (reggroup == restore_reggroup) return raw_p && pseudo; return 0; } /* Return the groups that a MIPS register can be categorised into. This version is only used if we have a target description which describes real registers (and their groups). */ static int mips_tdesc_register_reggroup_p (struct gdbarch *gdbarch, int regnum, struct reggroup *reggroup) { int rawnum = regnum % gdbarch_num_regs (gdbarch); int pseudo = regnum / gdbarch_num_regs (gdbarch); int ret; /* Only save, restore, and display the pseudo registers. Need to make certain that any code extracting register values from a saved register cache also uses pseudo registers. Note: saving and restoring the pseudo registers is slightly strange; if we have 64 bits, we should save and restore all 64 bits. But this is hard and has little benefit. */ if (!pseudo) return 0; ret = tdesc_register_in_reggroup_p (gdbarch, rawnum, reggroup); if (ret != -1) return ret; return mips_register_reggroup_p (gdbarch, regnum, reggroup); } /* Map the symbol table registers which live in the range [1 * gdbarch_num_regs .. 2 * gdbarch_num_regs) back onto the corresponding raw registers. Take care of alignment and size problems. */ static enum register_status mips_pseudo_register_read (struct gdbarch *gdbarch, readable_regcache *regcache, int cookednum, gdb_byte *buf) { int rawnum = cookednum % gdbarch_num_regs (gdbarch); gdb_assert (cookednum >= gdbarch_num_regs (gdbarch) && cookednum < 2 * gdbarch_num_regs (gdbarch)); if (register_size (gdbarch, rawnum) == register_size (gdbarch, cookednum)) return regcache->raw_read (rawnum, buf); else if (register_size (gdbarch, rawnum) > register_size (gdbarch, cookednum)) { if (gdbarch_tdep (gdbarch)->mips64_transfers_32bit_regs_p) return regcache->raw_read_part (rawnum, 0, 4, buf); else { enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); LONGEST regval; enum register_status status; status = regcache->raw_read (rawnum, ®val); if (status == REG_VALID) store_signed_integer (buf, 4, byte_order, regval); return status; } } else internal_error (__FILE__, __LINE__, _("bad register size")); } static void mips_pseudo_register_write (struct gdbarch *gdbarch, struct regcache *regcache, int cookednum, const gdb_byte *buf) { int rawnum = cookednum % gdbarch_num_regs (gdbarch); gdb_assert (cookednum >= gdbarch_num_regs (gdbarch) && cookednum < 2 * gdbarch_num_regs (gdbarch)); if (register_size (gdbarch, rawnum) == register_size (gdbarch, cookednum)) regcache->raw_write (rawnum, buf); else if (register_size (gdbarch, rawnum) > register_size (gdbarch, cookednum)) { if (gdbarch_tdep (gdbarch)->mips64_transfers_32bit_regs_p) regcache->raw_write_part (rawnum, 0, 4, buf); else { /* Sign extend the shortened version of the register prior to placing it in the raw register. This is required for some mips64 parts in order to avoid unpredictable behavior. */ enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); LONGEST regval = extract_signed_integer (buf, 4, byte_order); regcache_raw_write_signed (regcache, rawnum, regval); } } else internal_error (__FILE__, __LINE__, _("bad register size")); } static int mips_ax_pseudo_register_collect (struct gdbarch *gdbarch, struct agent_expr *ax, int reg) { int rawnum = reg % gdbarch_num_regs (gdbarch); gdb_assert (reg >= gdbarch_num_regs (gdbarch) && reg < 2 * gdbarch_num_regs (gdbarch)); ax_reg_mask (ax, rawnum); return 0; } static int mips_ax_pseudo_register_push_stack (struct gdbarch *gdbarch, struct agent_expr *ax, int reg) { int rawnum = reg % gdbarch_num_regs (gdbarch); gdb_assert (reg >= gdbarch_num_regs (gdbarch) && reg < 2 * gdbarch_num_regs (gdbarch)); if (register_size (gdbarch, rawnum) >= register_size (gdbarch, reg)) { ax_reg (ax, rawnum); if (register_size (gdbarch, rawnum) > register_size (gdbarch, reg)) { if (!gdbarch_tdep (gdbarch)->mips64_transfers_32bit_regs_p || gdbarch_byte_order (gdbarch) != BFD_ENDIAN_BIG) { ax_const_l (ax, 32); ax_simple (ax, aop_lsh); } ax_const_l (ax, 32); ax_simple (ax, aop_rsh_signed); } } else internal_error (__FILE__, __LINE__, _("bad register size")); return 0; } /* Table to translate 3-bit register field to actual register number. */ static const signed char mips_reg3_to_reg[8] = { 16, 17, 2, 3, 4, 5, 6, 7 }; /* Heuristic_proc_start may hunt through the text section for a long time across a 2400 baud serial line. Allows the user to limit this search. */ static int heuristic_fence_post = 0; /* Number of bytes of storage in the actual machine representation for register N. NOTE: This defines the pseudo register type so need to rebuild the architecture vector. */ static bool mips64_transfers_32bit_regs_p = false; static void set_mips64_transfers_32bit_regs (const char *args, int from_tty, struct cmd_list_element *c) { struct gdbarch_info info; gdbarch_info_init (&info); /* FIXME: cagney/2003-11-15: Should be setting a field in "info" instead of relying on globals. Doing that would let generic code handle the search for this specific architecture. */ if (!gdbarch_update_p (info)) { mips64_transfers_32bit_regs_p = 0; error (_("32-bit compatibility mode not supported")); } } /* Convert to/from a register and the corresponding memory value. */ /* This predicate tests for the case of an 8 byte floating point value that is being transferred to or from a pair of floating point registers each of which are (or are considered to be) only 4 bytes wide. */ static int mips_convert_register_float_case_p (struct gdbarch *gdbarch, int regnum, struct type *type) { return (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG && register_size (gdbarch, regnum) == 4 && mips_float_register_p (gdbarch, regnum) && TYPE_CODE (type) == TYPE_CODE_FLT && TYPE_LENGTH (type) == 8); } /* This predicate tests for the case of a value of less than 8 bytes in width that is being transfered to or from an 8 byte general purpose register. */ static int mips_convert_register_gpreg_case_p (struct gdbarch *gdbarch, int regnum, struct type *type) { int num_regs = gdbarch_num_regs (gdbarch); return (register_size (gdbarch, regnum) == 8 && regnum % num_regs > 0 && regnum % num_regs < 32 && TYPE_LENGTH (type) < 8); } static int mips_convert_register_p (struct gdbarch *gdbarch, int regnum, struct type *type) { return (mips_convert_register_float_case_p (gdbarch, regnum, type) || mips_convert_register_gpreg_case_p (gdbarch, regnum, type)); } static int mips_register_to_value (struct frame_info *frame, int regnum, struct type *type, gdb_byte *to, int *optimizedp, int *unavailablep) { struct gdbarch *gdbarch = get_frame_arch (frame); if (mips_convert_register_float_case_p (gdbarch, regnum, type)) { get_frame_register (frame, regnum + 0, to + 4); get_frame_register (frame, regnum + 1, to + 0); if (!get_frame_register_bytes (frame, regnum + 0, 0, 4, to + 4, optimizedp, unavailablep)) return 0; if (!get_frame_register_bytes (frame, regnum + 1, 0, 4, to + 0, optimizedp, unavailablep)) return 0; *optimizedp = *unavailablep = 0; return 1; } else if (mips_convert_register_gpreg_case_p (gdbarch, regnum, type)) { int len = TYPE_LENGTH (type); CORE_ADDR offset; offset = gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG ? 8 - len : 0; if (!get_frame_register_bytes (frame, regnum, offset, len, to, optimizedp, unavailablep)) return 0; *optimizedp = *unavailablep = 0; return 1; } else { internal_error (__FILE__, __LINE__, _("mips_register_to_value: unrecognized case")); } } static void mips_value_to_register (struct frame_info *frame, int regnum, struct type *type, const gdb_byte *from) { struct gdbarch *gdbarch = get_frame_arch (frame); if (mips_convert_register_float_case_p (gdbarch, regnum, type)) { put_frame_register (frame, regnum + 0, from + 4); put_frame_register (frame, regnum + 1, from + 0); } else if (mips_convert_register_gpreg_case_p (gdbarch, regnum, type)) { gdb_byte fill[8]; int len = TYPE_LENGTH (type); /* Sign extend values, irrespective of type, that are stored to a 64-bit general purpose register. (32-bit unsigned values are stored as signed quantities within a 64-bit register. When performing an operation, in compiled code, that combines a 32-bit unsigned value with a signed 64-bit value, a type conversion is first performed that zeroes out the high 32 bits.) */ if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG) { if (from[0] & 0x80) store_signed_integer (fill, 8, BFD_ENDIAN_BIG, -1); else store_signed_integer (fill, 8, BFD_ENDIAN_BIG, 0); put_frame_register_bytes (frame, regnum, 0, 8 - len, fill); put_frame_register_bytes (frame, regnum, 8 - len, len, from); } else { if (from[len-1] & 0x80) store_signed_integer (fill, 8, BFD_ENDIAN_LITTLE, -1); else store_signed_integer (fill, 8, BFD_ENDIAN_LITTLE, 0); put_frame_register_bytes (frame, regnum, 0, len, from); put_frame_register_bytes (frame, regnum, len, 8 - len, fill); } } else { internal_error (__FILE__, __LINE__, _("mips_value_to_register: unrecognized case")); } } /* Return the GDB type object for the "standard" data type of data in register REG. */ static struct type * mips_register_type (struct gdbarch *gdbarch, int regnum) { gdb_assert (regnum >= 0 && regnum < 2 * gdbarch_num_regs (gdbarch)); if (mips_float_register_p (gdbarch, regnum)) { /* The floating-point registers raw, or cooked, always match mips_isa_regsize(), and also map 1:1, byte for byte. */ if (mips_isa_regsize (gdbarch) == 4) return builtin_type (gdbarch)->builtin_float; else return builtin_type (gdbarch)->builtin_double; } else if (regnum < gdbarch_num_regs (gdbarch)) { /* The raw or ISA registers. These are all sized according to the ISA regsize. */ if (mips_isa_regsize (gdbarch) == 4) return builtin_type (gdbarch)->builtin_int32; else return builtin_type (gdbarch)->builtin_int64; } else { int rawnum = regnum - gdbarch_num_regs (gdbarch); /* The cooked or ABI registers. These are sized according to the ABI (with a few complications). */ if (rawnum == mips_regnum (gdbarch)->fp_control_status || rawnum == mips_regnum (gdbarch)->fp_implementation_revision) return builtin_type (gdbarch)->builtin_int32; else if (gdbarch_osabi (gdbarch) != GDB_OSABI_LINUX && rawnum >= MIPS_FIRST_EMBED_REGNUM && rawnum <= MIPS_LAST_EMBED_REGNUM) /* The pseudo/cooked view of the embedded registers is always 32-bit. The raw view is handled below. */ return builtin_type (gdbarch)->builtin_int32; else if (gdbarch_tdep (gdbarch)->mips64_transfers_32bit_regs_p) /* The target, while possibly using a 64-bit register buffer, is only transfering 32-bits of each integer register. Reflect this in the cooked/pseudo (ABI) register value. */ return builtin_type (gdbarch)->builtin_int32; else if (mips_abi_regsize (gdbarch) == 4) /* The ABI is restricted to 32-bit registers (the ISA could be 32- or 64-bit). */ return builtin_type (gdbarch)->builtin_int32; else /* 64-bit ABI. */ return builtin_type (gdbarch)->builtin_int64; } } /* Return the GDB type for the pseudo register REGNUM, which is the ABI-level view. This function is only called if there is a target description which includes registers, so we know precisely the types of hardware registers. */ static struct type * mips_pseudo_register_type (struct gdbarch *gdbarch, int regnum) { const int num_regs = gdbarch_num_regs (gdbarch); int rawnum = regnum % num_regs; struct type *rawtype; gdb_assert (regnum >= num_regs && regnum < 2 * num_regs); /* Absent registers are still absent. */ rawtype = gdbarch_register_type (gdbarch, rawnum); if (TYPE_LENGTH (rawtype) == 0) return rawtype; /* Present the floating point registers however the hardware did; do not try to convert between FPU layouts. */ if (mips_float_register_p (gdbarch, rawnum)) return rawtype; /* Floating-point control registers are always 32-bit even though for backwards compatibility reasons 64-bit targets will transfer them as 64-bit quantities even if using XML descriptions. */ if (rawnum == mips_regnum (gdbarch)->fp_control_status || rawnum == mips_regnum (gdbarch)->fp_implementation_revision) return builtin_type (gdbarch)->builtin_int32; /* Use pointer types for registers if we can. For n32 we can not, since we do not have a 64-bit pointer type. */ if (mips_abi_regsize (gdbarch) == TYPE_LENGTH (builtin_type (gdbarch)->builtin_data_ptr)) { if (rawnum == MIPS_SP_REGNUM || rawnum == mips_regnum (gdbarch)->badvaddr) return builtin_type (gdbarch)->builtin_data_ptr; else if (rawnum == mips_regnum (gdbarch)->pc) return builtin_type (gdbarch)->builtin_func_ptr; } if (mips_abi_regsize (gdbarch) == 4 && TYPE_LENGTH (rawtype) == 8 && ((rawnum >= MIPS_ZERO_REGNUM && rawnum <= MIPS_PS_REGNUM) || rawnum == mips_regnum (gdbarch)->lo || rawnum == mips_regnum (gdbarch)->hi || rawnum == mips_regnum (gdbarch)->badvaddr || rawnum == mips_regnum (gdbarch)->cause || rawnum == mips_regnum (gdbarch)->pc || (mips_regnum (gdbarch)->dspacc != -1 && rawnum >= mips_regnum (gdbarch)->dspacc && rawnum < mips_regnum (gdbarch)->dspacc + 6))) return builtin_type (gdbarch)->builtin_int32; /* The pseudo/cooked view of embedded registers is always 32-bit, even if the target transfers 64-bit values for them. New targets relying on XML descriptions should only transfer the necessary 32 bits, but older versions of GDB expected 64, so allow the target to provide 64 bits without interfering with the displayed type. */ if (gdbarch_osabi (gdbarch) != GDB_OSABI_LINUX && rawnum >= MIPS_FIRST_EMBED_REGNUM && rawnum <= MIPS_LAST_EMBED_REGNUM) return builtin_type (gdbarch)->builtin_int32; /* For all other registers, pass through the hardware type. */ return rawtype; } /* Should the upper word of 64-bit addresses be zeroed? */ static enum auto_boolean mask_address_var = AUTO_BOOLEAN_AUTO; static int mips_mask_address_p (struct gdbarch_tdep *tdep) { switch (mask_address_var) { case AUTO_BOOLEAN_TRUE: return 1; case AUTO_BOOLEAN_FALSE: return 0; break; case AUTO_BOOLEAN_AUTO: return tdep->default_mask_address_p; default: internal_error (__FILE__, __LINE__, _("mips_mask_address_p: bad switch")); return -1; } } static void show_mask_address (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { struct gdbarch_tdep *tdep = gdbarch_tdep (target_gdbarch ()); deprecated_show_value_hack (file, from_tty, c, value); switch (mask_address_var) { case AUTO_BOOLEAN_TRUE: printf_filtered ("The 32 bit mips address mask is enabled\n"); break; case AUTO_BOOLEAN_FALSE: printf_filtered ("The 32 bit mips address mask is disabled\n"); break; case AUTO_BOOLEAN_AUTO: printf_filtered ("The 32 bit address mask is set automatically. Currently %s\n", mips_mask_address_p (tdep) ? "enabled" : "disabled"); break; default: internal_error (__FILE__, __LINE__, _("show_mask_address: bad switch")); break; } } /* Tell if the program counter value in MEMADDR is in a standard ISA function. */ int mips_pc_is_mips (CORE_ADDR memaddr) { struct bound_minimal_symbol sym; /* Flags indicating that this is a MIPS16 or microMIPS function is stored by elfread.c in the high bit of the info field. Use this to decide if the function is standard MIPS. Otherwise if bit 0 of the address is clear, then this is a standard MIPS function. */ sym = lookup_minimal_symbol_by_pc (make_compact_addr (memaddr)); if (sym.minsym) return msymbol_is_mips (sym.minsym); else return is_mips_addr (memaddr); } /* Tell if the program counter value in MEMADDR is in a MIPS16 function. */ int mips_pc_is_mips16 (struct gdbarch *gdbarch, CORE_ADDR memaddr) { struct bound_minimal_symbol sym; /* A flag indicating that this is a MIPS16 function is stored by elfread.c in the high bit of the info field. Use this to decide if the function is MIPS16. Otherwise if bit 0 of the address is set, then ELF file flags will tell if this is a MIPS16 function. */ sym = lookup_minimal_symbol_by_pc (make_compact_addr (memaddr)); if (sym.minsym) return msymbol_is_mips16 (sym.minsym); else return is_mips16_addr (gdbarch, memaddr); } /* Tell if the program counter value in MEMADDR is in a microMIPS function. */ int mips_pc_is_micromips (struct gdbarch *gdbarch, CORE_ADDR memaddr) { struct bound_minimal_symbol sym; /* A flag indicating that this is a microMIPS function is stored by elfread.c in the high bit of the info field. Use this to decide if the function is microMIPS. Otherwise if bit 0 of the address is set, then ELF file flags will tell if this is a microMIPS function. */ sym = lookup_minimal_symbol_by_pc (make_compact_addr (memaddr)); if (sym.minsym) return msymbol_is_micromips (sym.minsym); else return is_micromips_addr (gdbarch, memaddr); } /* Tell the ISA type of the function the program counter value in MEMADDR is in. */ static enum mips_isa mips_pc_isa (struct gdbarch *gdbarch, CORE_ADDR memaddr) { struct bound_minimal_symbol sym; /* A flag indicating that this is a MIPS16 or a microMIPS function is stored by elfread.c in the high bit of the info field. Use this to decide if the function is MIPS16 or microMIPS or normal MIPS. Otherwise if bit 0 of the address is set, then ELF file flags will tell if this is a MIPS16 or a microMIPS function. */ sym = lookup_minimal_symbol_by_pc (make_compact_addr (memaddr)); if (sym.minsym) { if (msymbol_is_micromips (sym.minsym)) return ISA_MICROMIPS; else if (msymbol_is_mips16 (sym.minsym)) return ISA_MIPS16; else return ISA_MIPS; } else { if (is_mips_addr (memaddr)) return ISA_MIPS; else if (is_micromips_addr (gdbarch, memaddr)) return ISA_MICROMIPS; else return ISA_MIPS16; } } /* Set the ISA bit correctly in the PC, used by DWARF-2 machinery. The need for comes from the ISA bit having been cleared, making addresses in FDE, range records, etc. referring to compressed code different to those in line information, the symbol table and finally the PC register. That in turn confuses many operations. */ static CORE_ADDR mips_adjust_dwarf2_addr (CORE_ADDR pc) { pc = unmake_compact_addr (pc); return mips_pc_is_mips (pc) ? pc : make_compact_addr (pc); } /* Recalculate the line record requested so that the resulting PC has the ISA bit set correctly, used by DWARF-2 machinery. The need for this adjustment comes from some records associated with compressed code having the ISA bit cleared, most notably at function prologue ends. The ISA bit is in this context retrieved from the minimal symbol covering the address requested, which in turn has been constructed from the binary's symbol table rather than DWARF-2 information. The correct setting of the ISA bit is required for breakpoint addresses to correctly match against the stop PC. As line entries can specify relative address adjustments we need to keep track of the absolute value of the last line address recorded in line information, so that we can calculate the actual address to apply the ISA bit adjustment to. We use PC for this tracking and keep the original address there. As such relative address adjustments can be odd within compressed code we need to keep track of the last line address with the ISA bit adjustment applied too, as the original address may or may not have had the ISA bit set. We use ADJ_PC for this tracking and keep the adjusted address there. For relative address adjustments we then use these variables to calculate the address intended by line information, which will be PC-relative, and return an updated adjustment carrying ISA bit information, which will be ADJ_PC-relative. For absolute address adjustments we just return the same address that we store in ADJ_PC too. As the first line entry can be relative to an implied address value of 0 we need to have the initial address set up that we store in PC and ADJ_PC. This is arranged with a call from `dwarf_decode_lines_1' that sets PC to 0 and ADJ_PC accordingly, usually 0 as well. */ static CORE_ADDR mips_adjust_dwarf2_line (CORE_ADDR addr, int rel) { static CORE_ADDR adj_pc; static CORE_ADDR pc; CORE_ADDR isa_pc; pc = rel ? pc + addr : addr; isa_pc = mips_adjust_dwarf2_addr (pc); addr = rel ? isa_pc - adj_pc : isa_pc; adj_pc = isa_pc; return addr; } /* Various MIPS16 thunk (aka stub or trampoline) names. */ static const char mips_str_mips16_call_stub[] = "__mips16_call_stub_"; static const char mips_str_mips16_ret_stub[] = "__mips16_ret_"; static const char mips_str_call_fp_stub[] = "__call_stub_fp_"; static const char mips_str_call_stub[] = "__call_stub_"; static const char mips_str_fn_stub[] = "__fn_stub_"; /* This is used as a PIC thunk prefix. */ static const char mips_str_pic[] = ".pic."; /* Return non-zero if the PC is inside a call thunk (aka stub or trampoline) that should be treated as a temporary frame. */ static int mips_in_frame_stub (CORE_ADDR pc) { CORE_ADDR start_addr; const char *name; /* Find the starting address of the function containing the PC. */ if (find_pc_partial_function (pc, &name, &start_addr, NULL) == 0) return 0; /* If the PC is in __mips16_call_stub_*, this is a call/return stub. */ if (startswith (name, mips_str_mips16_call_stub)) return 1; /* If the PC is in __call_stub_*, this is a call/return or a call stub. */ if (startswith (name, mips_str_call_stub)) return 1; /* If the PC is in __fn_stub_*, this is a call stub. */ if (startswith (name, mips_str_fn_stub)) return 1; return 0; /* Not a stub. */ } /* MIPS believes that the PC has a sign extended value. Perhaps the all registers should be sign extended for simplicity? */ static CORE_ADDR mips_read_pc (readable_regcache *regcache) { int regnum = gdbarch_pc_regnum (regcache->arch ()); LONGEST pc; regcache->cooked_read (regnum, &pc); return pc; } static CORE_ADDR mips_unwind_pc (struct gdbarch *gdbarch, struct frame_info *next_frame) { CORE_ADDR pc; pc = frame_unwind_register_signed (next_frame, gdbarch_pc_regnum (gdbarch)); /* macro/2012-04-20: This hack skips over MIPS16 call thunks as intermediate frames. In this case we can get the caller's address from $ra, or if $ra contains an address within a thunk as well, then it must be in the return path of __mips16_call_stub_{s,d}{f,c}_{0..10} and thus the caller's address is in $s2. */ if (frame_relative_level (next_frame) >= 0 && mips_in_frame_stub (pc)) { pc = frame_unwind_register_signed (next_frame, gdbarch_num_regs (gdbarch) + MIPS_RA_REGNUM); if (mips_in_frame_stub (pc)) pc = frame_unwind_register_signed (next_frame, gdbarch_num_regs (gdbarch) + MIPS_S2_REGNUM); } return pc; } static CORE_ADDR mips_unwind_sp (struct gdbarch *gdbarch, struct frame_info *next_frame) { return frame_unwind_register_signed (next_frame, gdbarch_num_regs (gdbarch) + MIPS_SP_REGNUM); } /* Assuming THIS_FRAME is a dummy, return the frame ID of that dummy frame. The frame ID's base needs to match the TOS value saved by save_dummy_frame_tos(), and the PC match the dummy frame's breakpoint. */ static struct frame_id mips_dummy_id (struct gdbarch *gdbarch, struct frame_info *this_frame) { return frame_id_build (get_frame_register_signed (this_frame, gdbarch_num_regs (gdbarch) + MIPS_SP_REGNUM), get_frame_pc (this_frame)); } /* Implement the "write_pc" gdbarch method. */ void mips_write_pc (struct regcache *regcache, CORE_ADDR pc) { int regnum = gdbarch_pc_regnum (regcache->arch ()); regcache_cooked_write_unsigned (regcache, regnum, pc); } /* Fetch and return instruction from the specified location. Handle MIPS16/microMIPS as appropriate. */ static ULONGEST mips_fetch_instruction (struct gdbarch *gdbarch, enum mips_isa isa, CORE_ADDR addr, int *errp) { enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); gdb_byte buf[MIPS_INSN32_SIZE]; int instlen; int err; switch (isa) { case ISA_MICROMIPS: case ISA_MIPS16: instlen = MIPS_INSN16_SIZE; addr = unmake_compact_addr (addr); break; case ISA_MIPS: instlen = MIPS_INSN32_SIZE; break; default: internal_error (__FILE__, __LINE__, _("invalid ISA")); break; } err = target_read_memory (addr, buf, instlen); if (errp != NULL) *errp = err; if (err != 0) { if (errp == NULL) memory_error (TARGET_XFER_E_IO, addr); return 0; } return extract_unsigned_integer (buf, instlen, byte_order); } /* These are the fields of 32 bit mips instructions. */ #define mips32_op(x) (x >> 26) #define itype_op(x) (x >> 26) #define itype_rs(x) ((x >> 21) & 0x1f) #define itype_rt(x) ((x >> 16) & 0x1f) #define itype_immediate(x) (x & 0xffff) #define jtype_op(x) (x >> 26) #define jtype_target(x) (x & 0x03ffffff) #define rtype_op(x) (x >> 26) #define rtype_rs(x) ((x >> 21) & 0x1f) #define rtype_rt(x) ((x >> 16) & 0x1f) #define rtype_rd(x) ((x >> 11) & 0x1f) #define rtype_shamt(x) ((x >> 6) & 0x1f) #define rtype_funct(x) (x & 0x3f) /* MicroMIPS instruction fields. */ #define micromips_op(x) ((x) >> 10) /* 16-bit/32-bit-high-part instruction formats, B and S refer to the lowest bit and the size respectively of the field extracted. */ #define b0s4_imm(x) ((x) & 0xf) #define b0s5_imm(x) ((x) & 0x1f) #define b0s5_reg(x) ((x) & 0x1f) #define b0s7_imm(x) ((x) & 0x7f) #define b0s10_imm(x) ((x) & 0x3ff) #define b1s4_imm(x) (((x) >> 1) & 0xf) #define b1s9_imm(x) (((x) >> 1) & 0x1ff) #define b2s3_cc(x) (((x) >> 2) & 0x7) #define b4s2_regl(x) (((x) >> 4) & 0x3) #define b5s5_op(x) (((x) >> 5) & 0x1f) #define b5s5_reg(x) (((x) >> 5) & 0x1f) #define b6s4_op(x) (((x) >> 6) & 0xf) #define b7s3_reg(x) (((x) >> 7) & 0x7) /* 32-bit instruction formats, B and S refer to the lowest bit and the size respectively of the field extracted. */ #define b0s6_op(x) ((x) & 0x3f) #define b0s11_op(x) ((x) & 0x7ff) #define b0s12_imm(x) ((x) & 0xfff) #define b0s16_imm(x) ((x) & 0xffff) #define b0s26_imm(x) ((x) & 0x3ffffff) #define b6s10_ext(x) (((x) >> 6) & 0x3ff) #define b11s5_reg(x) (((x) >> 11) & 0x1f) #define b12s4_op(x) (((x) >> 12) & 0xf) /* Return the size in bytes of the instruction INSN encoded in the ISA instruction set. */ static int mips_insn_size (enum mips_isa isa, ULONGEST insn) { switch (isa) { case ISA_MICROMIPS: if ((micromips_op (insn) & 0x4) == 0x4 || (micromips_op (insn) & 0x7) == 0x0) return 2 * MIPS_INSN16_SIZE; else return MIPS_INSN16_SIZE; case ISA_MIPS16: if ((insn & 0xf800) == 0xf000) return 2 * MIPS_INSN16_SIZE; else return MIPS_INSN16_SIZE; case ISA_MIPS: return MIPS_INSN32_SIZE; } internal_error (__FILE__, __LINE__, _("invalid ISA")); } static LONGEST mips32_relative_offset (ULONGEST inst) { return ((itype_immediate (inst) ^ 0x8000) - 0x8000) << 2; } /* Determine the address of the next instruction executed after the INST floating condition branch instruction at PC. COUNT specifies the number of the floating condition bits tested by the branch. */ static CORE_ADDR mips32_bc1_pc (struct gdbarch *gdbarch, struct regcache *regcache, ULONGEST inst, CORE_ADDR pc, int count) { int fcsr = mips_regnum (gdbarch)->fp_control_status; int cnum = (itype_rt (inst) >> 2) & (count - 1); int tf = itype_rt (inst) & 1; int mask = (1 << count) - 1; ULONGEST fcs; int cond; if (fcsr == -1) /* No way to handle; it'll most likely trap anyway. */ return pc; fcs = regcache_raw_get_unsigned (regcache, fcsr); cond = ((fcs >> 24) & 0xfe) | ((fcs >> 23) & 0x01); if (((cond >> cnum) & mask) != mask * !tf) pc += mips32_relative_offset (inst); else pc += 4; return pc; } /* Return nonzero if the gdbarch is an Octeon series. */ static int is_octeon (struct gdbarch *gdbarch) { const struct bfd_arch_info *info = gdbarch_bfd_arch_info (gdbarch); return (info->mach == bfd_mach_mips_octeon || info->mach == bfd_mach_mips_octeonp || info->mach == bfd_mach_mips_octeon2); } /* Return true if the OP represents the Octeon's BBIT instruction. */ static int is_octeon_bbit_op (int op, struct gdbarch *gdbarch) { if (!is_octeon (gdbarch)) return 0; /* BBIT0 is encoded as LWC2: 110 010. */ /* BBIT032 is encoded as LDC2: 110 110. */ /* BBIT1 is encoded as SWC2: 111 010. */ /* BBIT132 is encoded as SDC2: 111 110. */ if (op == 50 || op == 54 || op == 58 || op == 62) return 1; return 0; } /* Determine where to set a single step breakpoint while considering branch prediction. */ static CORE_ADDR mips32_next_pc (struct regcache *regcache, CORE_ADDR pc) { struct gdbarch *gdbarch = regcache->arch (); unsigned long inst; int op; inst = mips_fetch_instruction (gdbarch, ISA_MIPS, pc, NULL); op = itype_op (inst); if ((inst & 0xe0000000) != 0) /* Not a special, jump or branch instruction. */ { if (op >> 2 == 5) /* BEQL, BNEL, BLEZL, BGTZL: bits 0101xx */ { switch (op & 0x03) { case 0: /* BEQL */ goto equal_branch; case 1: /* BNEL */ goto neq_branch; case 2: /* BLEZL */ goto less_branch; case 3: /* BGTZL */ goto greater_branch; default: pc += 4; } } else if (op == 17 && itype_rs (inst) == 8) /* BC1F, BC1FL, BC1T, BC1TL: 010001 01000 */ pc = mips32_bc1_pc (gdbarch, regcache, inst, pc + 4, 1); else if (op == 17 && itype_rs (inst) == 9 && (itype_rt (inst) & 2) == 0) /* BC1ANY2F, BC1ANY2T: 010001 01001 xxx0x */ pc = mips32_bc1_pc (gdbarch, regcache, inst, pc + 4, 2); else if (op == 17 && itype_rs (inst) == 10 && (itype_rt (inst) & 2) == 0) /* BC1ANY4F, BC1ANY4T: 010001 01010 xxx0x */ pc = mips32_bc1_pc (gdbarch, regcache, inst, pc + 4, 4); else if (op == 29) /* JALX: 011101 */ /* The new PC will be alternate mode. */ { unsigned long reg; reg = jtype_target (inst) << 2; /* Add 1 to indicate 16-bit mode -- invert ISA mode. */ pc = ((pc + 4) & ~(CORE_ADDR) 0x0fffffff) + reg + 1; } else if (is_octeon_bbit_op (op, gdbarch)) { int bit, branch_if; branch_if = op == 58 || op == 62; bit = itype_rt (inst); /* Take into account the *32 instructions. */ if (op == 54 || op == 62) bit += 32; if (((regcache_raw_get_signed (regcache, itype_rs (inst)) >> bit) & 1) == branch_if) pc += mips32_relative_offset (inst) + 4; else pc += 8; /* After the delay slot. */ } else pc += 4; /* Not a branch, next instruction is easy. */ } else { /* This gets way messy. */ /* Further subdivide into SPECIAL, REGIMM and other. */ switch (op & 0x07) /* Extract bits 28,27,26. */ { case 0: /* SPECIAL */ op = rtype_funct (inst); switch (op) { case 8: /* JR */ case 9: /* JALR */ /* Set PC to that address. */ pc = regcache_raw_get_signed (regcache, rtype_rs (inst)); break; case 12: /* SYSCALL */ { struct gdbarch_tdep *tdep; tdep = gdbarch_tdep (gdbarch); if (tdep->syscall_next_pc != NULL) pc = tdep->syscall_next_pc (get_current_frame ()); else pc += 4; } break; default: pc += 4; } break; /* end SPECIAL */ case 1: /* REGIMM */ { op = itype_rt (inst); /* branch condition */ switch (op) { case 0: /* BLTZ */ case 2: /* BLTZL */ case 16: /* BLTZAL */ case 18: /* BLTZALL */ less_branch: if (regcache_raw_get_signed (regcache, itype_rs (inst)) < 0) pc += mips32_relative_offset (inst) + 4; else pc += 8; /* after the delay slot */ break; case 1: /* BGEZ */ case 3: /* BGEZL */ case 17: /* BGEZAL */ case 19: /* BGEZALL */ if (regcache_raw_get_signed (regcache, itype_rs (inst)) >= 0) pc += mips32_relative_offset (inst) + 4; else pc += 8; /* after the delay slot */ break; case 0x1c: /* BPOSGE32 */ case 0x1e: /* BPOSGE64 */ pc += 4; if (itype_rs (inst) == 0) { unsigned int pos = (op & 2) ? 64 : 32; int dspctl = mips_regnum (gdbarch)->dspctl; if (dspctl == -1) /* No way to handle; it'll most likely trap anyway. */ break; if ((regcache_raw_get_unsigned (regcache, dspctl) & 0x7f) >= pos) pc += mips32_relative_offset (inst); else pc += 4; } break; /* All of the other instructions in the REGIMM category */ default: pc += 4; } } break; /* end REGIMM */ case 2: /* J */ case 3: /* JAL */ { unsigned long reg; reg = jtype_target (inst) << 2; /* Upper four bits get never changed... */ pc = reg + ((pc + 4) & ~(CORE_ADDR) 0x0fffffff); } break; case 4: /* BEQ, BEQL */ equal_branch: if (regcache_raw_get_signed (regcache, itype_rs (inst)) == regcache_raw_get_signed (regcache, itype_rt (inst))) pc += mips32_relative_offset (inst) + 4; else pc += 8; break; case 5: /* BNE, BNEL */ neq_branch: if (regcache_raw_get_signed (regcache, itype_rs (inst)) != regcache_raw_get_signed (regcache, itype_rt (inst))) pc += mips32_relative_offset (inst) + 4; else pc += 8; break; case 6: /* BLEZ, BLEZL */ if (regcache_raw_get_signed (regcache, itype_rs (inst)) <= 0) pc += mips32_relative_offset (inst) + 4; else pc += 8; break; case 7: default: greater_branch: /* BGTZ, BGTZL */ if (regcache_raw_get_signed (regcache, itype_rs (inst)) > 0) pc += mips32_relative_offset (inst) + 4; else pc += 8; break; } /* switch */ } /* else */ return pc; } /* mips32_next_pc */ /* Extract the 7-bit signed immediate offset from the microMIPS instruction INSN. */ static LONGEST micromips_relative_offset7 (ULONGEST insn) { return ((b0s7_imm (insn) ^ 0x40) - 0x40) << 1; } /* Extract the 10-bit signed immediate offset from the microMIPS instruction INSN. */ static LONGEST micromips_relative_offset10 (ULONGEST insn) { return ((b0s10_imm (insn) ^ 0x200) - 0x200) << 1; } /* Extract the 16-bit signed immediate offset from the microMIPS instruction INSN. */ static LONGEST micromips_relative_offset16 (ULONGEST insn) { return ((b0s16_imm (insn) ^ 0x8000) - 0x8000) << 1; } /* Return the size in bytes of the microMIPS instruction at the address PC. */ static int micromips_pc_insn_size (struct gdbarch *gdbarch, CORE_ADDR pc) { ULONGEST insn; insn = mips_fetch_instruction (gdbarch, ISA_MICROMIPS, pc, NULL); return mips_insn_size (ISA_MICROMIPS, insn); } /* Calculate the address of the next microMIPS instruction to execute after the INSN coprocessor 1 conditional branch instruction at the address PC. COUNT denotes the number of coprocessor condition bits examined by the branch. */ static CORE_ADDR micromips_bc1_pc (struct gdbarch *gdbarch, struct regcache *regcache, ULONGEST insn, CORE_ADDR pc, int count) { int fcsr = mips_regnum (gdbarch)->fp_control_status; int cnum = b2s3_cc (insn >> 16) & (count - 1); int tf = b5s5_op (insn >> 16) & 1; int mask = (1 << count) - 1; ULONGEST fcs; int cond; if (fcsr == -1) /* No way to handle; it'll most likely trap anyway. */ return pc; fcs = regcache_raw_get_unsigned (regcache, fcsr); cond = ((fcs >> 24) & 0xfe) | ((fcs >> 23) & 0x01); if (((cond >> cnum) & mask) != mask * !tf) pc += micromips_relative_offset16 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); return pc; } /* Calculate the address of the next microMIPS instruction to execute after the instruction at the address PC. */ static CORE_ADDR micromips_next_pc (struct regcache *regcache, CORE_ADDR pc) { struct gdbarch *gdbarch = regcache->arch (); ULONGEST insn; insn = mips_fetch_instruction (gdbarch, ISA_MICROMIPS, pc, NULL); pc += MIPS_INSN16_SIZE; switch (mips_insn_size (ISA_MICROMIPS, insn)) { /* 32-bit instructions. */ case 2 * MIPS_INSN16_SIZE: insn <<= 16; insn |= mips_fetch_instruction (gdbarch, ISA_MICROMIPS, pc, NULL); pc += MIPS_INSN16_SIZE; switch (micromips_op (insn >> 16)) { case 0x00: /* POOL32A: bits 000000 */ switch (b0s6_op (insn)) { case 0x3c: /* POOL32Axf: bits 000000 ... 111100 */ switch (b6s10_ext (insn)) { case 0x3c: /* JALR: 000000 0000111100 111100 */ case 0x7c: /* JALR.HB: 000000 0001111100 111100 */ case 0x13c: /* JALRS: 000000 0100111100 111100 */ case 0x17c: /* JALRS.HB: 000000 0101111100 111100 */ pc = regcache_raw_get_signed (regcache, b0s5_reg (insn >> 16)); break; case 0x22d: /* SYSCALL: 000000 1000101101 111100 */ { struct gdbarch_tdep *tdep; tdep = gdbarch_tdep (gdbarch); if (tdep->syscall_next_pc != NULL) pc = tdep->syscall_next_pc (get_current_frame ()); } break; } break; } break; case 0x10: /* POOL32I: bits 010000 */ switch (b5s5_op (insn >> 16)) { case 0x00: /* BLTZ: bits 010000 00000 */ case 0x01: /* BLTZAL: bits 010000 00001 */ case 0x11: /* BLTZALS: bits 010000 10001 */ if (regcache_raw_get_signed (regcache, b0s5_reg (insn >> 16)) < 0) pc += micromips_relative_offset16 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); break; case 0x02: /* BGEZ: bits 010000 00010 */ case 0x03: /* BGEZAL: bits 010000 00011 */ case 0x13: /* BGEZALS: bits 010000 10011 */ if (regcache_raw_get_signed (regcache, b0s5_reg (insn >> 16)) >= 0) pc += micromips_relative_offset16 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); break; case 0x04: /* BLEZ: bits 010000 00100 */ if (regcache_raw_get_signed (regcache, b0s5_reg (insn >> 16)) <= 0) pc += micromips_relative_offset16 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); break; case 0x05: /* BNEZC: bits 010000 00101 */ if (regcache_raw_get_signed (regcache, b0s5_reg (insn >> 16)) != 0) pc += micromips_relative_offset16 (insn); break; case 0x06: /* BGTZ: bits 010000 00110 */ if (regcache_raw_get_signed (regcache, b0s5_reg (insn >> 16)) > 0) pc += micromips_relative_offset16 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); break; case 0x07: /* BEQZC: bits 010000 00111 */ if (regcache_raw_get_signed (regcache, b0s5_reg (insn >> 16)) == 0) pc += micromips_relative_offset16 (insn); break; case 0x14: /* BC2F: bits 010000 10100 xxx00 */ case 0x15: /* BC2T: bits 010000 10101 xxx00 */ if (((insn >> 16) & 0x3) == 0x0) /* BC2F, BC2T: don't know how to handle these. */ break; break; case 0x1a: /* BPOSGE64: bits 010000 11010 */ case 0x1b: /* BPOSGE32: bits 010000 11011 */ { unsigned int pos = (b5s5_op (insn >> 16) & 1) ? 32 : 64; int dspctl = mips_regnum (gdbarch)->dspctl; if (dspctl == -1) /* No way to handle; it'll most likely trap anyway. */ break; if ((regcache_raw_get_unsigned (regcache, dspctl) & 0x7f) >= pos) pc += micromips_relative_offset16 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); } break; case 0x1c: /* BC1F: bits 010000 11100 xxx00 */ /* BC1ANY2F: bits 010000 11100 xxx01 */ case 0x1d: /* BC1T: bits 010000 11101 xxx00 */ /* BC1ANY2T: bits 010000 11101 xxx01 */ if (((insn >> 16) & 0x2) == 0x0) pc = micromips_bc1_pc (gdbarch, regcache, insn, pc, ((insn >> 16) & 0x1) + 1); break; case 0x1e: /* BC1ANY4F: bits 010000 11110 xxx01 */ case 0x1f: /* BC1ANY4T: bits 010000 11111 xxx01 */ if (((insn >> 16) & 0x3) == 0x1) pc = micromips_bc1_pc (gdbarch, regcache, insn, pc, 4); break; } break; case 0x1d: /* JALS: bits 011101 */ case 0x35: /* J: bits 110101 */ case 0x3d: /* JAL: bits 111101 */ pc = ((pc | 0x7fffffe) ^ 0x7fffffe) | (b0s26_imm (insn) << 1); break; case 0x25: /* BEQ: bits 100101 */ if (regcache_raw_get_signed (regcache, b0s5_reg (insn >> 16)) == regcache_raw_get_signed (regcache, b5s5_reg (insn >> 16))) pc += micromips_relative_offset16 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); break; case 0x2d: /* BNE: bits 101101 */ if (regcache_raw_get_signed (regcache, b0s5_reg (insn >> 16)) != regcache_raw_get_signed (regcache, b5s5_reg (insn >> 16))) pc += micromips_relative_offset16 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); break; case 0x3c: /* JALX: bits 111100 */ pc = ((pc | 0xfffffff) ^ 0xfffffff) | (b0s26_imm (insn) << 2); break; } break; /* 16-bit instructions. */ case MIPS_INSN16_SIZE: switch (micromips_op (insn)) { case 0x11: /* POOL16C: bits 010001 */ if ((b5s5_op (insn) & 0x1c) == 0xc) /* JR16, JRC, JALR16, JALRS16: 010001 011xx */ pc = regcache_raw_get_signed (regcache, b0s5_reg (insn)); else if (b5s5_op (insn) == 0x18) /* JRADDIUSP: bits 010001 11000 */ pc = regcache_raw_get_signed (regcache, MIPS_RA_REGNUM); break; case 0x23: /* BEQZ16: bits 100011 */ { int rs = mips_reg3_to_reg[b7s3_reg (insn)]; if (regcache_raw_get_signed (regcache, rs) == 0) pc += micromips_relative_offset7 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); } break; case 0x2b: /* BNEZ16: bits 101011 */ { int rs = mips_reg3_to_reg[b7s3_reg (insn)]; if (regcache_raw_get_signed (regcache, rs) != 0) pc += micromips_relative_offset7 (insn); else pc += micromips_pc_insn_size (gdbarch, pc); } break; case 0x33: /* B16: bits 110011 */ pc += micromips_relative_offset10 (insn); break; } break; } return pc; } /* Decoding the next place to set a breakpoint is irregular for the mips 16 variant, but fortunately, there fewer instructions. We have to cope ith extensions for 16 bit instructions and a pair of actual 32 bit instructions. We dont want to set a single step instruction on the extend instruction either. */ /* Lots of mips16 instruction formats */ /* Predicting jumps requires itype,ritype,i8type and their extensions extItype,extritype,extI8type. */ enum mips16_inst_fmts { itype, /* 0 immediate 5,10 */ ritype, /* 1 5,3,8 */ rrtype, /* 2 5,3,3,5 */ rritype, /* 3 5,3,3,5 */ rrrtype, /* 4 5,3,3,3,2 */ rriatype, /* 5 5,3,3,1,4 */ shifttype, /* 6 5,3,3,3,2 */ i8type, /* 7 5,3,8 */ i8movtype, /* 8 5,3,3,5 */ i8mov32rtype, /* 9 5,3,5,3 */ i64type, /* 10 5,3,8 */ ri64type, /* 11 5,3,3,5 */ jalxtype, /* 12 5,1,5,5,16 - a 32 bit instruction */ exiItype, /* 13 5,6,5,5,1,1,1,1,1,1,5 */ extRitype, /* 14 5,6,5,5,3,1,1,1,5 */ extRRItype, /* 15 5,5,5,5,3,3,5 */ extRRIAtype, /* 16 5,7,4,5,3,3,1,4 */ EXTshifttype, /* 17 5,5,1,1,1,1,1,1,5,3,3,1,1,1,2 */ extI8type, /* 18 5,6,5,5,3,1,1,1,5 */ extI64type, /* 19 5,6,5,5,3,1,1,1,5 */ extRi64type, /* 20 5,6,5,5,3,3,5 */ extshift64type /* 21 5,5,1,1,1,1,1,1,5,1,1,1,3,5 */ }; /* I am heaping all the fields of the formats into one structure and then, only the fields which are involved in instruction extension. */ struct upk_mips16 { CORE_ADDR offset; unsigned int regx; /* Function in i8 type. */ unsigned int regy; }; /* The EXT-I, EXT-ri nad EXT-I8 instructions all have the same format for the bits which make up the immediate extension. */ static CORE_ADDR extended_offset (unsigned int extension) { CORE_ADDR value; value = (extension >> 16) & 0x1f; /* Extract 15:11. */ value = value << 6; value |= (extension >> 21) & 0x3f; /* Extract 10:5. */ value = value << 5; value |= extension & 0x1f; /* Extract 4:0. */ return value; } /* Only call this function if you know that this is an extendable instruction. It won't malfunction, but why make excess remote memory references? If the immediate operands get sign extended or something, do it after the extension is performed. */ /* FIXME: Every one of these cases needs to worry about sign extension when the offset is to be used in relative addressing. */ static unsigned int fetch_mips_16 (struct gdbarch *gdbarch, CORE_ADDR pc) { enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); gdb_byte buf[8]; pc = unmake_compact_addr (pc); /* Clear the low order bit. */ target_read_memory (pc, buf, 2); return extract_unsigned_integer (buf, 2, byte_order); } static void unpack_mips16 (struct gdbarch *gdbarch, CORE_ADDR pc, unsigned int extension, unsigned int inst, enum mips16_inst_fmts insn_format, struct upk_mips16 *upk) { CORE_ADDR offset; int regx; int regy; switch (insn_format) { case itype: { CORE_ADDR value; if (extension) { value = extended_offset ((extension << 16) | inst); value = (value ^ 0x8000) - 0x8000; /* Sign-extend. */ } else { value = inst & 0x7ff; value = (value ^ 0x400) - 0x400; /* Sign-extend. */ } offset = value; regx = -1; regy = -1; } break; case ritype: case i8type: { /* A register identifier and an offset. */ /* Most of the fields are the same as I type but the immediate value is of a different length. */ CORE_ADDR value; if (extension) { value = extended_offset ((extension << 16) | inst); value = (value ^ 0x8000) - 0x8000; /* Sign-extend. */ } else { value = inst & 0xff; /* 8 bits */ value = (value ^ 0x80) - 0x80; /* Sign-extend. */ } offset = value; regx = (inst >> 8) & 0x07; /* i8 funct */ regy = -1; break; } case jalxtype: { unsigned long value; unsigned int nexthalf; value = ((inst & 0x1f) << 5) | ((inst >> 5) & 0x1f); value = value << 16; nexthalf = mips_fetch_instruction (gdbarch, ISA_MIPS16, pc + 2, NULL); /* Low bit still set. */ value |= nexthalf; offset = value; regx = -1; regy = -1; break; } default: internal_error (__FILE__, __LINE__, _("bad switch")); } upk->offset = offset; upk->regx = regx; upk->regy = regy; } /* Calculate the destination of a branch whose 16-bit opcode word is at PC, and having a signed 16-bit OFFSET. */ static CORE_ADDR add_offset_16 (CORE_ADDR pc, int offset) { return pc + (offset << 1) + 2; } static CORE_ADDR extended_mips16_next_pc (regcache *regcache, CORE_ADDR pc, unsigned int extension, unsigned int insn) { struct gdbarch *gdbarch = regcache->arch (); int op = (insn >> 11); switch (op) { case 2: /* Branch */ { struct upk_mips16 upk; unpack_mips16 (gdbarch, pc, extension, insn, itype, &upk); pc = add_offset_16 (pc, upk.offset); break; } case 3: /* JAL , JALX - Watch out, these are 32 bit instructions. */ { struct upk_mips16 upk; unpack_mips16 (gdbarch, pc, extension, insn, jalxtype, &upk); pc = ((pc + 2) & (~(CORE_ADDR) 0x0fffffff)) | (upk.offset << 2); if ((insn >> 10) & 0x01) /* Exchange mode */ pc = pc & ~0x01; /* Clear low bit, indicate 32 bit mode. */ else pc |= 0x01; break; } case 4: /* beqz */ { struct upk_mips16 upk; int reg; unpack_mips16 (gdbarch, pc, extension, insn, ritype, &upk); reg = regcache_raw_get_signed (regcache, mips_reg3_to_reg[upk.regx]); if (reg == 0) pc = add_offset_16 (pc, upk.offset); else pc += 2; break; } case 5: /* bnez */ { struct upk_mips16 upk; int reg; unpack_mips16 (gdbarch, pc, extension, insn, ritype, &upk); reg = regcache_raw_get_signed (regcache, mips_reg3_to_reg[upk.regx]); if (reg != 0) pc = add_offset_16 (pc, upk.offset); else pc += 2; break; } case 12: /* I8 Formats btez btnez */ { struct upk_mips16 upk; int reg; unpack_mips16 (gdbarch, pc, extension, insn, i8type, &upk); /* upk.regx contains the opcode */ /* Test register is 24 */ reg = regcache_raw_get_signed (regcache, 24); if (((upk.regx == 0) && (reg == 0)) /* BTEZ */ || ((upk.regx == 1) && (reg != 0))) /* BTNEZ */ pc = add_offset_16 (pc, upk.offset); else pc += 2; break; } case 29: /* RR Formats JR, JALR, JALR-RA */ { struct upk_mips16 upk; /* upk.fmt = rrtype; */ op = insn & 0x1f; if (op == 0) { int reg; upk.regx = (insn >> 8) & 0x07; upk.regy = (insn >> 5) & 0x07; if ((upk.regy & 1) == 0) reg = mips_reg3_to_reg[upk.regx]; else reg = 31; /* Function return instruction. */ pc = regcache_raw_get_signed (regcache, reg); } else pc += 2; break; } case 30: /* This is an instruction extension. Fetch the real instruction (which follows the extension) and decode things based on that. */ { pc += 2; pc = extended_mips16_next_pc (regcache, pc, insn, fetch_mips_16 (gdbarch, pc)); break; } default: { pc += 2; break; } } return pc; } static CORE_ADDR mips16_next_pc (struct regcache *regcache, CORE_ADDR pc) { struct gdbarch *gdbarch = regcache->arch (); unsigned int insn = fetch_mips_16 (gdbarch, pc); return extended_mips16_next_pc (regcache, pc, 0, insn); } /* The mips_next_pc function supports single_step when the remote target monitor or stub is not developed enough to do a single_step. It works by decoding the current instruction and predicting where a branch will go. This isn't hard because all the data is available. The MIPS32, MIPS16 and microMIPS variants are quite different. */ static CORE_ADDR mips_next_pc (struct regcache *regcache, CORE_ADDR pc) { struct gdbarch *gdbarch = regcache->arch (); if (mips_pc_is_mips16 (gdbarch, pc)) return mips16_next_pc (regcache, pc); else if (mips_pc_is_micromips (gdbarch, pc)) return micromips_next_pc (regcache, pc); else return mips32_next_pc (regcache, pc); } /* Return non-zero if the MIPS16 instruction INSN is a compact branch or jump. */ static int mips16_instruction_is_compact_branch (unsigned short insn) { switch (insn & 0xf800) { case 0xe800: return (insn & 0x009f) == 0x80; /* JALRC/JRC */ case 0x6000: return (insn & 0x0600) == 0; /* BTNEZ/BTEQZ */ case 0x2800: /* BNEZ */ case 0x2000: /* BEQZ */ case 0x1000: /* B */ return 1; default: return 0; } } /* Return non-zero if the microMIPS instruction INSN is a compact branch or jump. */ static int micromips_instruction_is_compact_branch (unsigned short insn) { switch (micromips_op (insn)) { case 0x11: /* POOL16C: bits 010001 */ return (b5s5_op (insn) == 0x18 /* JRADDIUSP: bits 010001 11000 */ || b5s5_op (insn) == 0xd); /* JRC: bits 010011 01101 */ case 0x10: /* POOL32I: bits 010000 */ return (b5s5_op (insn) & 0x1d) == 0x5; /* BEQZC/BNEZC: bits 010000 001x1 */ default: return 0; } } struct mips_frame_cache { CORE_ADDR base; struct trad_frame_saved_reg *saved_regs; }; /* Set a register's saved stack address in temp_saved_regs. If an address has already been set for this register, do nothing; this way we will only recognize the first save of a given register in a function prologue. For simplicity, save the address in both [0 .. gdbarch_num_regs) and [gdbarch_num_regs .. 2*gdbarch_num_regs). Strictly speaking, only the second range is used as it is only second range (the ABI instead of ISA registers) that comes into play when finding saved registers in a frame. */ static void set_reg_offset (struct gdbarch *gdbarch, struct mips_frame_cache *this_cache, int regnum, CORE_ADDR offset) { if (this_cache != NULL && this_cache->saved_regs[regnum].addr == -1) { this_cache->saved_regs[regnum + 0 * gdbarch_num_regs (gdbarch)].addr = offset; this_cache->saved_regs[regnum + 1 * gdbarch_num_regs (gdbarch)].addr = offset; } } /* Fetch the immediate value from a MIPS16 instruction. If the previous instruction was an EXTEND, use it to extend the upper bits of the immediate value. This is a helper function for mips16_scan_prologue. */ static int mips16_get_imm (unsigned short prev_inst, /* previous instruction */ unsigned short inst, /* current instruction */ int nbits, /* number of bits in imm field */ int scale, /* scale factor to be applied to imm */ int is_signed) /* is the imm field signed? */ { int offset; if ((prev_inst & 0xf800) == 0xf000) /* prev instruction was EXTEND? */ { offset = ((prev_inst & 0x1f) << 11) | (prev_inst & 0x7e0); if (offset & 0x8000) /* check for negative extend */ offset = 0 - (0x10000 - (offset & 0xffff)); return offset | (inst & 0x1f); } else { int max_imm = 1 << nbits; int mask = max_imm - 1; int sign_bit = max_imm >> 1; offset = inst & mask; if (is_signed && (offset & sign_bit)) offset = 0 - (max_imm - offset); return offset * scale; } } /* Analyze the function prologue from START_PC to LIMIT_PC. Builds the associated FRAME_CACHE if not null. Return the address of the first instruction past the prologue. */ static CORE_ADDR mips16_scan_prologue (struct gdbarch *gdbarch, CORE_ADDR start_pc, CORE_ADDR limit_pc, struct frame_info *this_frame, struct mips_frame_cache *this_cache) { int prev_non_prologue_insn = 0; int this_non_prologue_insn; int non_prologue_insns = 0; CORE_ADDR prev_pc; CORE_ADDR cur_pc; CORE_ADDR frame_addr = 0; /* Value of $r17, used as frame pointer. */ CORE_ADDR sp; long frame_offset = 0; /* Size of stack frame. */ long frame_adjust = 0; /* Offset of FP from SP. */ int frame_reg = MIPS_SP_REGNUM; unsigned short prev_inst = 0; /* saved copy of previous instruction. */ unsigned inst = 0; /* current instruction */ unsigned entry_inst = 0; /* the entry instruction */ unsigned save_inst = 0; /* the save instruction */ int prev_delay_slot = 0; int in_delay_slot; int reg, offset; int extend_bytes = 0; int prev_extend_bytes = 0; CORE_ADDR end_prologue_addr; /* Can be called when there's no process, and hence when there's no THIS_FRAME. */ if (this_frame != NULL) sp = get_frame_register_signed (this_frame, gdbarch_num_regs (gdbarch) + MIPS_SP_REGNUM); else sp = 0; if (limit_pc > start_pc + 200) limit_pc = start_pc + 200; prev_pc = start_pc; /* Permit at most one non-prologue non-control-transfer instruction in the middle which may have been reordered by the compiler for optimisation. */ for (cur_pc = start_pc; cur_pc < limit_pc; cur_pc += MIPS_INSN16_SIZE) { this_non_prologue_insn = 0; in_delay_slot = 0; /* Save the previous instruction. If it's an EXTEND, we'll extract the immediate offset extension from it in mips16_get_imm. */ prev_inst = inst; /* Fetch and decode the instruction. */ inst = (unsigned short) mips_fetch_instruction (gdbarch, ISA_MIPS16, cur_pc, NULL); /* Normally we ignore extend instructions. However, if it is not followed by a valid prologue instruction, then this instruction is not part of the prologue either. We must remember in this case to adjust the end_prologue_addr back over the extend. */ if ((inst & 0xf800) == 0xf000) /* extend */ { extend_bytes = MIPS_INSN16_SIZE; continue; } prev_extend_bytes = extend_bytes; extend_bytes = 0; if ((inst & 0xff00) == 0x6300 /* addiu sp */ || (inst & 0xff00) == 0xfb00) /* daddiu sp */ { offset = mips16_get_imm (prev_inst, inst, 8, 8, 1); if (offset < 0) /* Negative stack adjustment? */ frame_offset -= offset; else /* Exit loop if a positive stack adjustment is found, which usually means that the stack cleanup code in the function epilogue is reached. */ break; } else if ((inst & 0xf800) == 0xd000) /* sw reg,n($sp) */ { offset = mips16_get_imm (prev_inst, inst, 8, 4, 0); reg = mips_reg3_to_reg[(inst & 0x700) >> 8]; set_reg_offset (gdbarch, this_cache, reg, sp + offset); } else if ((inst & 0xff00) == 0xf900) /* sd reg,n($sp) */ { offset = mips16_get_imm (prev_inst, inst, 5, 8, 0); reg = mips_reg3_to_reg[(inst & 0xe0) >> 5]; set_reg_offset (gdbarch, this_cache, reg, sp + offset); } else if ((inst & 0xff00) == 0x6200) /* sw $ra,n($sp) */ { offset = mips16_get_imm (prev_inst, inst, 8, 4, 0); set_reg_offset (gdbarch, this_cache, MIPS_RA_REGNUM, sp + offset); } else if ((inst & 0xff00) == 0xfa00) /* sd $ra,n($sp) */ { offset = mips16_get_imm (prev_inst, inst, 8, 8, 0); set_reg_offset (gdbarch, this_cache, MIPS_RA_REGNUM, sp + offset); } else if (inst == 0x673d) /* move $s1, $sp */ { frame_addr = sp; frame_reg = 17; } else if ((inst & 0xff00) == 0x0100) /* addiu $s1,sp,n */ { offset = mips16_get_imm (prev_inst, inst, 8, 4, 0); frame_addr = sp + offset; frame_reg = 17; frame_adjust = offset; } else if ((inst & 0xFF00) == 0xd900) /* sw reg,offset($s1) */ { offset = mips16_get_imm (prev_inst, inst, 5, 4, 0); reg = mips_reg3_to_reg[(inst & 0xe0) >> 5]; set_reg_offset (gdbarch, this_cache, reg, frame_addr + offset); } else if ((inst & 0xFF00) == 0x7900) /* sd reg,offset($s1) */ { offset = mips16_get_imm (prev_inst, inst, 5, 8, 0); reg = mips_reg3_to_reg[(inst & 0xe0) >> 5]; set_reg_offset (gdbarch, this_cache, reg, frame_addr + offset); } else if ((inst & 0xf81f) == 0xe809 && (inst & 0x700) != 0x700) /* entry */ entry_inst = inst; /* Save for later processing. */ else if ((inst & 0xff80) == 0x6480) /* save */ { save_inst = inst; /* Save for later processing. */ if (prev_extend_bytes) /* extend */ save_inst |= prev_inst << 16; } else if ((inst & 0xff1c) == 0x6704) /* move reg,$a0-$a3 */ { /* This instruction is part of the prologue, but we don't need to do anything special to handle it. */ } else if (mips16_instruction_has_delay_slot (inst, 0)) /* JAL/JALR/JALX/JR */ { /* The instruction in the delay slot can be a part of the prologue, so move forward once more. */ in_delay_slot = 1; if (mips16_instruction_has_delay_slot (inst, 1)) /* JAL/JALX */ { prev_extend_bytes = MIPS_INSN16_SIZE; cur_pc += MIPS_INSN16_SIZE; /* 32-bit instruction */ } } else { this_non_prologue_insn = 1; } non_prologue_insns += this_non_prologue_insn; /* A jump or branch, or enough non-prologue insns seen? If so, then we must have reached the end of the prologue by now. */ if (prev_delay_slot || non_prologue_insns > 1 || mips16_instruction_is_compact_branch (inst)) break; prev_non_prologue_insn = this_non_prologue_insn; prev_delay_slot = in_delay_slot; prev_pc = cur_pc - prev_extend_bytes; } /* The entry instruction is typically the first instruction in a function, and it stores registers at offsets relative to the value of the old SP (before the prologue). But the value of the sp parameter to this function is the new SP (after the prologue has been executed). So we can't calculate those offsets until we've seen the entire prologue, and can calculate what the old SP must have been. */ if (entry_inst != 0) { int areg_count = (entry_inst >> 8) & 7; int sreg_count = (entry_inst >> 6) & 3; /* The entry instruction always subtracts 32 from the SP. */ frame_offset += 32; /* Now we can calculate what the SP must have been at the start of the function prologue. */ sp += frame_offset; /* Check if a0-a3 were saved in the caller's argument save area. */ for (reg = 4, offset = 0; reg < areg_count + 4; reg++) { set_reg_offset (gdbarch, this_cache, reg, sp + offset); offset += mips_abi_regsize (gdbarch); } /* Check if the ra register was pushed on the stack. */ offset = -4; if (entry_inst & 0x20) { set_reg_offset (gdbarch, this_cache, MIPS_RA_REGNUM, sp + offset); offset -= mips_abi_regsize (gdbarch); } /* Check if the s0 and s1 registers were pushed on the stack. */ for (reg = 16; reg < sreg_count + 16; reg++) { set_reg_offset (gdbarch, this_cache, reg, sp + offset); offset -= mips_abi_regsize (gdbarch); } } /* The SAVE instruction is similar to ENTRY, except that defined by the MIPS16e ASE of the MIPS Architecture. Unlike with ENTRY though, the size of the frame is specified as an immediate field of instruction and an extended variation exists which lets additional registers and frame space to be specified. The instruction always treats registers as 32-bit so its usefulness for 64-bit ABIs is questionable. */ if (save_inst != 0 && mips_abi_regsize (gdbarch) == 4) { static int args_table[16] = { 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 0, 3, 3, 4, -1, }; static int astatic_table[16] = { 0, 1, 2, 3, 0, 1, 2, 3, 0, 1, 2, 4, 0, 1, 0, -1, }; int aregs = (save_inst >> 16) & 0xf; int xsregs = (save_inst >> 24) & 0x7; int args = args_table[aregs]; int astatic = astatic_table[aregs]; long frame_size; if (args < 0) { warning (_("Invalid number of argument registers encoded in SAVE.")); args = 0; } if (astatic < 0) { warning (_("Invalid number of static registers encoded in SAVE.")); astatic = 0; } /* For standard SAVE the frame size of 0 means 128. */ frame_size = ((save_inst >> 16) & 0xf0) | (save_inst & 0xf); if (frame_size == 0 && (save_inst >> 16) == 0) frame_size = 16; frame_size *= 8; frame_offset += frame_size; /* Now we can calculate what the SP must have been at the start of the function prologue. */ sp += frame_offset; /* Check if A0-A3 were saved in the caller's argument save area. */ for (reg = MIPS_A0_REGNUM, offset = 0; reg < args + 4; reg++) { set_reg_offset (gdbarch, this_cache, reg, sp + offset); offset += mips_abi_regsize (gdbarch); } offset = -4; /* Check if the RA register was pushed on the stack. */ if (save_inst & 0x40) { set_reg_offset (gdbarch, this_cache, MIPS_RA_REGNUM, sp + offset); offset -= mips_abi_regsize (gdbarch); } /* Check if the S8 register was pushed on the stack. */ if (xsregs > 6) { set_reg_offset (gdbarch, this_cache, 30, sp + offset); offset -= mips_abi_regsize (gdbarch); xsregs--; } /* Check if S2-S7 were pushed on the stack. */ for (reg = 18 + xsregs - 1; reg > 18 - 1; reg--) { set_reg_offset (gdbarch, this_cache, reg, sp + offset); offset -= mips_abi_regsize (gdbarch); } /* Check if the S1 register was pushed on the stack. */ if (save_inst & 0x10) { set_reg_offset (gdbarch, this_cache, 17, sp + offset); offset -= mips_abi_regsize (gdbarch); } /* Check if the S0 register was pushed on the stack. */ if (save_inst & 0x20) { set_reg_offset (gdbarch, this_cache, 16, sp + offset); offset -= mips_abi_regsize (gdbarch); } /* Check if A0-A3 were pushed on the stack. */ for (reg = MIPS_A0_REGNUM + 3; reg > MIPS_A0_REGNUM + 3 - astatic; reg--) { set_reg_offset (gdbarch, this_cache, reg, sp + offset); offset -= mips_abi_regsize (gdbarch); } } if (this_cache != NULL) { this_cache->base = (get_frame_register_signed (this_frame, gdbarch_num_regs (gdbarch) + frame_reg) + frame_offset - frame_adjust); /* FIXME: brobecker/2004-10-10: Just as in the mips32 case, we should be able to get rid of the assignment below, evetually. But it's still needed for now. */ this_cache->saved_regs[gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->pc] = this_cache->saved_regs[gdbarch_num_regs (gdbarch) + MIPS_RA_REGNUM]; } /* Set end_prologue_addr to the address of the instruction immediately after the last one we scanned. Unless the last one looked like a non-prologue instruction (and we looked ahead), in which case use its address instead. */ end_prologue_addr = (prev_non_prologue_insn || prev_delay_slot ? prev_pc : cur_pc - prev_extend_bytes); return end_prologue_addr; } /* Heuristic unwinder for 16-bit MIPS instruction set (aka MIPS16). Procedures that use the 32-bit instruction set are handled by the mips_insn32 unwinder. */ static struct mips_frame_cache * mips_insn16_frame_cache (struct frame_info *this_frame, void **this_cache) { struct gdbarch *gdbarch = get_frame_arch (this_frame); struct mips_frame_cache *cache; if ((*this_cache) != NULL) return (struct mips_frame_cache *) (*this_cache); cache = FRAME_OBSTACK_ZALLOC (struct mips_frame_cache); (*this_cache) = cache; cache->saved_regs = trad_frame_alloc_saved_regs (this_frame); /* Analyze the function prologue. */ { const CORE_ADDR pc = get_frame_address_in_block (this_frame); CORE_ADDR start_addr; find_pc_partial_function (pc, NULL, &start_addr, NULL); if (start_addr == 0) start_addr = heuristic_proc_start (gdbarch, pc); /* We can't analyze the prologue if we couldn't find the begining of the function. */ if (start_addr == 0) return cache; mips16_scan_prologue (gdbarch, start_addr, pc, this_frame, (struct mips_frame_cache *) *this_cache); } /* gdbarch_sp_regnum contains the value and not the address. */ trad_frame_set_value (cache->saved_regs, gdbarch_num_regs (gdbarch) + MIPS_SP_REGNUM, cache->base); return (struct mips_frame_cache *) (*this_cache); } static void mips_insn16_frame_this_id (struct frame_info *this_frame, void **this_cache, struct frame_id *this_id) { struct mips_frame_cache *info = mips_insn16_frame_cache (this_frame, this_cache); /* This marks the outermost frame. */ if (info->base == 0) return; (*this_id) = frame_id_build (info->base, get_frame_func (this_frame)); } static struct value * mips_insn16_frame_prev_register (struct frame_info *this_frame, void **this_cache, int regnum) { struct mips_frame_cache *info = mips_insn16_frame_cache (this_frame, this_cache); return trad_frame_get_prev_register (this_frame, info->saved_regs, regnum); } static int mips_insn16_frame_sniffer (const struct frame_unwind *self, struct frame_info *this_frame, void **this_cache) { struct gdbarch *gdbarch = get_frame_arch (this_frame); CORE_ADDR pc = get_frame_pc (this_frame); if (mips_pc_is_mips16 (gdbarch, pc)) return 1; return 0; } static const struct frame_unwind mips_insn16_frame_unwind = { NORMAL_FRAME, default_frame_unwind_stop_reason, mips_insn16_frame_this_id, mips_insn16_frame_prev_register, NULL, mips_insn16_frame_sniffer }; static CORE_ADDR mips_insn16_frame_base_address (struct frame_info *this_frame, void **this_cache) { struct mips_frame_cache *info = mips_insn16_frame_cache (this_frame, this_cache); return info->base; } static const struct frame_base mips_insn16_frame_base = { &mips_insn16_frame_unwind, mips_insn16_frame_base_address, mips_insn16_frame_base_address, mips_insn16_frame_base_address }; static const struct frame_base * mips_insn16_frame_base_sniffer (struct frame_info *this_frame) { struct gdbarch *gdbarch = get_frame_arch (this_frame); CORE_ADDR pc = get_frame_pc (this_frame); if (mips_pc_is_mips16 (gdbarch, pc)) return &mips_insn16_frame_base; else return NULL; } /* Decode a 9-bit signed immediate argument of ADDIUSP -- -2 is mapped to -258, -1 -- to -257, 0 -- to 256, 1 -- to 257 and other values are interpreted directly, and then multiplied by 4. */ static int micromips_decode_imm9 (int imm) { imm = (imm ^ 0x100) - 0x100; if (imm > -3 && imm < 2) imm ^= 0x100; return imm << 2; } /* Analyze the function prologue from START_PC to LIMIT_PC. Return the address of the first instruction past the prologue. */ static CORE_ADDR micromips_scan_prologue (struct gdbarch *gdbarch, CORE_ADDR start_pc, CORE_ADDR limit_pc, struct frame_info *this_frame, struct mips_frame_cache *this_cache) { CORE_ADDR end_prologue_addr; int prev_non_prologue_insn = 0; int frame_reg = MIPS_SP_REGNUM; int this_non_prologue_insn; int non_prologue_insns = 0; long frame_offset = 0; /* Size of stack frame. */ long frame_adjust = 0; /* Offset of FP from SP. */ int prev_delay_slot = 0; int in_delay_slot; CORE_ADDR prev_pc; CORE_ADDR cur_pc; ULONGEST insn; /* current instruction */ CORE_ADDR sp; long offset; long sp_adj; long v1_off = 0; /* The assumption is LUI will replace it. */ int reglist; int breg; int dreg; int sreg; int treg; int loc; int op; int s; int i; /* Can be called when there's no process, and hence when there's no THIS_FRAME. */ if (this_frame != NULL) sp = get_frame_register_signed (this_frame, gdbarch_num_regs (gdbarch) + MIPS_SP_REGNUM); else sp = 0; if (limit_pc > start_pc + 200) limit_pc = start_pc + 200; prev_pc = start_pc; /* Permit at most one non-prologue non-control-transfer instruction in the middle which may have been reordered by the compiler for optimisation. */ for (cur_pc = start_pc; cur_pc < limit_pc; cur_pc += loc) { this_non_prologue_insn = 0; in_delay_slot = 0; sp_adj = 0; loc = 0; insn = mips_fetch_instruction (gdbarch, ISA_MICROMIPS, cur_pc, NULL); loc += MIPS_INSN16_SIZE; switch (mips_insn_size (ISA_MICROMIPS, insn)) { /* 32-bit instructions. */ case 2 * MIPS_INSN16_SIZE: insn <<= 16; insn |= mips_fetch_instruction (gdbarch, ISA_MICROMIPS, cur_pc + loc, NULL); loc += MIPS_INSN16_SIZE; switch (micromips_op (insn >> 16)) { /* Record $sp/$fp adjustment. */ /* Discard (D)ADDU $gp,$jp used for PIC code. */ case 0x0: /* POOL32A: bits 000000 */ case 0x16: /* POOL32S: bits 010110 */ op = b0s11_op (insn); sreg = b0s5_reg (insn >> 16); treg = b5s5_reg (insn >> 16); dreg = b11s5_reg (insn); if (op == 0x1d0 /* SUBU: bits 000000 00111010000 */ /* DSUBU: bits 010110 00111010000 */ && dreg == MIPS_SP_REGNUM && sreg == MIPS_SP_REGNUM && treg == 3) /* (D)SUBU $sp, $v1 */ sp_adj = v1_off; else if (op != 0x150 /* ADDU: bits 000000 00101010000 */ /* DADDU: bits 010110 00101010000 */ || dreg != 28 || sreg != 28 || treg != MIPS_T9_REGNUM) this_non_prologue_insn = 1; break; case 0x8: /* POOL32B: bits 001000 */ op = b12s4_op (insn); breg = b0s5_reg (insn >> 16); reglist = sreg = b5s5_reg (insn >> 16); offset = (b0s12_imm (insn) ^ 0x800) - 0x800; if ((op == 0x9 || op == 0xc) /* SWP: bits 001000 1001 */ /* SDP: bits 001000 1100 */ && breg == MIPS_SP_REGNUM && sreg < MIPS_RA_REGNUM) /* S[DW]P reg,offset($sp) */ { s = 4 << ((b12s4_op (insn) & 0x4) == 0x4); set_reg_offset (gdbarch, this_cache, sreg, sp + offset); set_reg_offset (gdbarch, this_cache, sreg + 1, sp + offset + s); } else if ((op == 0xd || op == 0xf) /* SWM: bits 001000 1101 */ /* SDM: bits 001000 1111 */ && breg == MIPS_SP_REGNUM /* SWM reglist,offset($sp) */ && ((reglist >= 1 && reglist <= 9) || (reglist >= 16 && reglist <= 25))) { int sreglist = std::min(reglist & 0xf, 8); s = 4 << ((b12s4_op (insn) & 0x2) == 0x2); for (i = 0; i < sreglist; i++) set_reg_offset (gdbarch, this_cache, 16 + i, sp + s * i); if ((reglist & 0xf) > 8) set_reg_offset (gdbarch, this_cache, 30, sp + s * i++); if ((reglist & 0x10) == 0x10) set_reg_offset (gdbarch, this_cache, MIPS_RA_REGNUM, sp + s * i++); } else this_non_prologue_insn = 1; break; /* Record $sp/$fp adjustment. */ /* Discard (D)ADDIU $gp used for PIC code. */ case 0xc: /* ADDIU: bits 001100 */ case 0x17: /* DADDIU: bits 010111 */ sreg = b0s5_reg (insn >> 16); dreg = b5s5_reg (insn >> 16); offset = (b0s16_imm (insn) ^ 0x8000) - 0x8000; if (sreg == MIPS_SP_REGNUM && dreg == MIPS_SP_REGNUM) /* (D)ADDIU $sp, imm */ sp_adj = offset; else if (sreg == MIPS_SP_REGNUM && dreg == 30) /* (D)ADDIU $fp, $sp, imm */ { frame_adjust = offset; frame_reg = 30; } else if (sreg != 28 || dreg != 28) /* (D)ADDIU $gp, imm */ this_non_prologue_insn = 1; break; /* LUI $v1 is used for larger $sp adjustments. */ /* Discard LUI $gp used for PIC code. */ case 0x10: /* POOL32I: bits 010000 */ if (b5s5_op (insn >> 16) == 0xd /* LUI: bits 010000 001101 */ && b0s5_reg (insn >> 16) == 3) /* LUI $v1, imm */ v1_off = ((b0s16_imm (insn) << 16) ^ 0x80000000) - 0x80000000; else if (b5s5_op (insn >> 16) != 0xd /* LUI: bits 010000 001101 */ || b0s5_reg (insn >> 16) != 28) /* LUI $gp, imm */ this_non_prologue_insn = 1; break; /* ORI $v1 is used for larger $sp adjustments. */ case 0x14: /* ORI: bits 010100 */ sreg = b0s5_reg (insn >> 16); dreg = b5s5_reg (insn >> 16); if (sreg == 3 && dreg == 3) /* ORI $v1, imm */ v1_off |= b0s16_imm (insn); else this_non_prologue_insn = 1; break; case 0x26: /* SWC1: bits 100110 */ case 0x2e: /* SDC1: bits 101110 */ breg = b0s5_reg (insn >> 16); if (breg != MIPS_SP_REGNUM) /* S[DW]C1 reg,offset($sp) */ this_non_prologue_insn = 1; break; case 0x36: /* SD: bits 110110 */ case 0x3e: /* SW: bits 111110 */ breg = b0s5_reg (insn >> 16); sreg = b5s5_reg (insn >> 16); offset = (b0s16_imm (insn) ^ 0x8000) - 0x8000; if (breg == MIPS_SP_REGNUM) /* S[DW] reg,offset($sp) */ set_reg_offset (gdbarch, this_cache, sreg, sp + offset); else this_non_prologue_insn = 1; break; default: /* The instruction in the delay slot can be a part of the prologue, so move forward once more. */ if (micromips_instruction_has_delay_slot (insn, 0)) in_delay_slot = 1; else this_non_prologue_insn = 1; break; } insn >>= 16; break; /* 16-bit instructions. */ case MIPS_INSN16_SIZE: switch (micromips_op (insn)) { case 0x3: /* MOVE: bits 000011 */ sreg = b0s5_reg (insn); dreg = b5s5_reg (insn); if (sreg == MIPS_SP_REGNUM && dreg == 30) /* MOVE $fp, $sp */ frame_reg = 30; else if ((sreg & 0x1c) != 0x4) /* MOVE reg, $a0-$a3 */ this_non_prologue_insn = 1; break; case 0x11: /* POOL16C: bits 010001 */ if (b6s4_op (insn) == 0x5) /* SWM: bits 010001 0101 */ { offset = ((b0s4_imm (insn) << 2) ^ 0x20) - 0x20; reglist = b4s2_regl (insn); for (i = 0; i <= reglist; i++) set_reg_offset (gdbarch, this_cache, 16 + i, sp + 4 * i); set_reg_offset (gdbarch, this_cache, MIPS_RA_REGNUM, sp + 4 * i++); } else this_non_prologue_insn = 1; break; case 0x13: /* POOL16D: bits 010011 */ if ((insn & 0x1) == 0x1) /* ADDIUSP: bits 010011 1 */ sp_adj = micromips_decode_imm9 (b1s9_imm (insn)); else if (b5s5_reg (insn) == MIPS_SP_REGNUM) /* ADDIUS5: bits 010011 0 */ /* ADDIUS5 $sp, imm */ sp_adj = (b1s4_imm (insn) ^ 8) - 8; else this_non_prologue_insn = 1; break; case 0x32: /* SWSP: bits 110010 */ offset = b0s5_imm (insn) << 2; sreg = b5s5_reg (insn); set_reg_offset (gdbarch, this_cache, sreg, sp + offset); break; default: /* The instruction in the delay slot can be a part of the prologue, so move forward once more. */ if (micromips_instruction_has_delay_slot (insn << 16, 0)) in_delay_slot = 1; else this_non_prologue_insn = 1; break; } break; } if (sp_adj < 0) frame_offset -= sp_adj; non_prologue_insns += this_non_prologue_insn; /* A jump or branch, enough non-prologue insns seen or positive stack adjustment? If so, then we must have reached the end of the prologue by now. */ if (prev_delay_slot || non_prologue_insns > 1 || sp_adj > 0 || micromips_instruction_is_compact_branch (insn)) break; prev_non_prologue_insn = this_non_prologue_insn; prev_delay_slot = in_delay_slot; prev_pc = cur_pc; } if (this_cache != NULL) { this_cache->base = (get_frame_register_signed (this_frame, gdbarch_num_regs (gdbarch) + frame_reg) + frame_offset - frame_adjust); /* FIXME: brobecker/2004-10-10: Just as in the mips32 case, we should be able to get rid of the assignment below, evetually. But it's still needed for now. */ this_cache->saved_regs[gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->pc] = this_cache->saved_regs[gdbarch_num_regs (gdbarch) + MIPS_RA_REGNUM]; } /* Set end_prologue_addr to the address of the instruction immediately after the last one we scanned. Unless the last one looked like a non-prologue instruction (and we looked ahead), in which case use its address instead. */ end_prologue_addr = prev_non_prologue_insn || prev_delay_slot ? prev_pc : cur_pc; return end_prologue_addr; } /* Heuristic unwinder for procedures using microMIPS instructions. Procedures that use the 32-bit instruction set are handled by the mips_insn32 unwinder. Likewise MIPS16 and the mips_insn16 unwinder. */ static struct mips_frame_cache * mips_micro_frame_cache (struct frame_info *this_frame, void **this_cache) { struct gdbarch *gdbarch = get_frame_arch (this_frame); struct mips_frame_cache *cache; if ((*this_cache) != NULL) return (struct mips_frame_cache *) (*this_cache); cache = FRAME_OBSTACK_ZALLOC (struct mips_frame_cache); (*this_cache) = cache; cache->saved_regs = trad_frame_alloc_saved_regs (this_frame); /* Analyze the function prologue. */ { const CORE_ADDR pc = get_frame_address_in_block (this_frame); CORE_ADDR start_addr; find_pc_partial_function (pc, NULL, &start_addr, NULL); if (start_addr == 0) start_addr = heuristic_proc_start (get_frame_arch (this_frame), pc); /* We can't analyze the prologue if we couldn't find the begining of the function. */ if (start_addr == 0) return cache; micromips_scan_prologue (gdbarch, start_addr, pc, this_frame, (struct mips_frame_cache *) *this_cache); } /* gdbarch_sp_regnum contains the value and not the address. */ trad_frame_set_value (cache->saved_regs, gdbarch_num_regs (gdbarch) + MIPS_SP_REGNUM, cache->base); return (struct mips_frame_cache *) (*this_cache); } static void mips_micro_frame_this_id (struct frame_info *this_frame, void **this_cache, struct frame_id *this_id) { struct mips_frame_cache *info = mips_micro_frame_cache (this_frame, this_cache); /* This marks the outermost frame. */ if (info->base == 0) return; (*this_id) = frame_id_build (info->base, get_frame_func (this_frame)); } static struct value * mips_micro_frame_prev_register (struct frame_info *this_frame, void **this_cache, int regnum) { struct mips_frame_cache *info = mips_micro_frame_cache (this_frame, this_cache); return trad_frame_get_prev_register (this_frame, info->saved_regs, regnum); } static int mips_micro_frame_sniffer (const struct frame_unwind *self, struct frame_info *this_frame, void **this_cache) { struct gdbarch *gdbarch = get_frame_arch (this_frame); CORE_ADDR pc = get_frame_pc (this_frame); if (mips_pc_is_micromips (gdbarch, pc)) return 1; return 0; } static const struct frame_unwind mips_micro_frame_unwind = { NORMAL_FRAME, default_frame_unwind_stop_reason, mips_micro_frame_this_id, mips_micro_frame_prev_register, NULL, mips_micro_frame_sniffer }; static CORE_ADDR mips_micro_frame_base_address (struct frame_info *this_frame, void **this_cache) { struct mips_frame_cache *info = mips_micro_frame_cache (this_frame, this_cache); return info->base; } static const struct frame_base mips_micro_frame_base = { &mips_micro_frame_unwind, mips_micro_frame_base_address, mips_micro_frame_base_address, mips_micro_frame_base_address }; static const struct frame_base * mips_micro_frame_base_sniffer (struct frame_info *this_frame) { struct gdbarch *gdbarch = get_frame_arch (this_frame); CORE_ADDR pc = get_frame_pc (this_frame); if (mips_pc_is_micromips (gdbarch, pc)) return &mips_micro_frame_base; else return NULL; } /* Mark all the registers as unset in the saved_regs array of THIS_CACHE. Do nothing if THIS_CACHE is null. */ static void reset_saved_regs (struct gdbarch *gdbarch, struct mips_frame_cache *this_cache) { if (this_cache == NULL || this_cache->saved_regs == NULL) return; { const int num_regs = gdbarch_num_regs (gdbarch); int i; for (i = 0; i < num_regs; i++) { this_cache->saved_regs[i].addr = -1; } } } /* Analyze the function prologue from START_PC to LIMIT_PC. Builds the associated FRAME_CACHE if not null. Return the address of the first instruction past the prologue. */ static CORE_ADDR mips32_scan_prologue (struct gdbarch *gdbarch, CORE_ADDR start_pc, CORE_ADDR limit_pc, struct frame_info *this_frame, struct mips_frame_cache *this_cache) { int prev_non_prologue_insn; int this_non_prologue_insn; int non_prologue_insns; CORE_ADDR frame_addr = 0; /* Value of $r30. Used by gcc for frame-pointer. */ int prev_delay_slot; CORE_ADDR prev_pc; CORE_ADDR cur_pc; CORE_ADDR sp; long frame_offset; int frame_reg = MIPS_SP_REGNUM; CORE_ADDR end_prologue_addr; int seen_sp_adjust = 0; int load_immediate_bytes = 0; int in_delay_slot; int regsize_is_64_bits = (mips_abi_regsize (gdbarch) == 8); /* Can be called when there's no process, and hence when there's no THIS_FRAME. */ if (this_frame != NULL) sp = get_frame_register_signed (this_frame, gdbarch_num_regs (gdbarch) + MIPS_SP_REGNUM); else sp = 0; if (limit_pc > start_pc + 200) limit_pc = start_pc + 200; restart: prev_non_prologue_insn = 0; non_prologue_insns = 0; prev_delay_slot = 0; prev_pc = start_pc; /* Permit at most one non-prologue non-control-transfer instruction in the middle which may have been reordered by the compiler for optimisation. */ frame_offset = 0; for (cur_pc = start_pc; cur_pc < limit_pc; cur_pc += MIPS_INSN32_SIZE) { unsigned long inst, high_word; long offset; int reg; this_non_prologue_insn = 0; in_delay_slot = 0; /* Fetch the instruction. */ inst = (unsigned long) mips_fetch_instruction (gdbarch, ISA_MIPS, cur_pc, NULL); /* Save some code by pre-extracting some useful fields. */ high_word = (inst >> 16) & 0xffff; offset = ((inst & 0xffff) ^ 0x8000) - 0x8000; reg = high_word & 0x1f; if (high_word == 0x27bd /* addiu $sp,$sp,-i */ || high_word == 0x23bd /* addi $sp,$sp,-i */ || high_word == 0x67bd) /* daddiu $sp,$sp,-i */ { if (offset < 0) /* Negative stack adjustment? */ frame_offset -= offset; else /* Exit loop if a positive stack adjustment is found, which usually means that the stack cleanup code in the function epilogue is reached. */ break; seen_sp_adjust = 1; } else if (((high_word & 0xFFE0) == 0xafa0) /* sw reg,offset($sp) */ && !regsize_is_64_bits) { set_reg_offset (gdbarch, this_cache, reg, sp + offset); } else if (((high_word & 0xFFE0) == 0xffa0) /* sd reg,offset($sp) */ && regsize_is_64_bits) { /* Irix 6.2 N32 ABI uses sd instructions for saving $gp and $ra. */ set_reg_offset (gdbarch, this_cache, reg, sp + offset); } else if (high_word == 0x27be) /* addiu $30,$sp,size */ { /* Old gcc frame, r30 is virtual frame pointer. */ if (offset != frame_offset) frame_addr = sp + offset; else if (this_frame && frame_reg == MIPS_SP_REGNUM) { unsigned alloca_adjust; frame_reg = 30; frame_addr = get_frame_register_signed (this_frame, gdbarch_num_regs (gdbarch) + 30); frame_offset = 0; alloca_adjust = (unsigned) (frame_addr - (sp + offset)); if (alloca_adjust > 0) { /* FP > SP + frame_size. This may be because of an alloca or somethings similar. Fix sp to "pre-alloca" value, and try again. */ sp += alloca_adjust; /* Need to reset the status of all registers. Otherwise, we will hit a guard that prevents the new address for each register to be recomputed during the second pass. */ reset_saved_regs (gdbarch, this_cache); goto restart; } } } /* move $30,$sp. With different versions of gas this will be either `addu $30,$sp,$zero' or `or $30,$sp,$zero' or `daddu 30,sp,$0'. Accept any one of these. */ else if (inst == 0x03A0F021 || inst == 0x03a0f025 || inst == 0x03a0f02d) { /* New gcc frame, virtual frame pointer is at r30 + frame_size. */ if (this_frame && frame_reg == MIPS_SP_REGNUM) { unsigned alloca_adjust; frame_reg = 30; frame_addr = get_frame_register_signed (this_frame, gdbarch_num_regs (gdbarch) + 30); alloca_adjust = (unsigned) (frame_addr - sp); if (alloca_adjust > 0) { /* FP > SP + frame_size. This may be because of an alloca or somethings similar. Fix sp to "pre-alloca" value, and try again. */ sp = frame_addr; /* Need to reset the status of all registers. Otherwise, we will hit a guard that prevents the new address for each register to be recomputed during the second pass. */ reset_saved_regs (gdbarch, this_cache); goto restart; } } } else if ((high_word & 0xFFE0) == 0xafc0 /* sw reg,offset($30) */ && !regsize_is_64_bits) { set_reg_offset (gdbarch, this_cache, reg, frame_addr + offset); } else if ((high_word & 0xFFE0) == 0xE7A0 /* swc1 freg,n($sp) */ || (high_word & 0xF3E0) == 0xA3C0 /* sx reg,n($s8) */ || (inst & 0xFF9F07FF) == 0x00800021 /* move reg,$a0-$a3 */ || high_word == 0x3c1c /* lui $gp,n */ || high_word == 0x279c /* addiu $gp,$gp,n */ || inst == 0x0399e021 /* addu $gp,$gp,$t9 */ || inst == 0x033ce021 /* addu $gp,$t9,$gp */ ) { /* These instructions are part of the prologue, but we don't need to do anything special to handle them. */ } /* The instructions below load $at or $t0 with an immediate value in preparation for a stack adjustment via subu $sp,$sp,[$at,$t0]. These instructions could also initialize a local variable, so we accept them only before a stack adjustment instruction was seen. */ else if (!seen_sp_adjust && !prev_delay_slot && (high_word == 0x3c01 /* lui $at,n */ || high_word == 0x3c08 /* lui $t0,n */ || high_word == 0x3421 /* ori $at,$at,n */ || high_word == 0x3508 /* ori $t0,$t0,n */ || high_word == 0x3401 /* ori $at,$zero,n */ || high_word == 0x3408 /* ori $t0,$zero,n */ )) { load_immediate_bytes += MIPS_INSN32_SIZE; /* FIXME! */ } /* Check for branches and jumps. The instruction in the delay slot can be a part of the prologue, so move forward once more. */ else if (mips32_instruction_has_delay_slot (gdbarch, inst)) { in_delay_slot = 1; } /* This instruction is not an instruction typically found in a prologue, so we must have reached the end of the prologue. */ else { this_non_prologue_insn = 1; } non_prologue_insns += this_non_prologue_insn; /* A jump or branch, or enough non-prologue insns seen? If so, then we must have reached the end of the prologue by now. */ if (prev_delay_slot || non_prologue_insns > 1) break; prev_non_prologue_insn = this_non_prologue_insn; prev_delay_slot = in_delay_slot; prev_pc = cur_pc; } if (this_cache != NULL) { this_cache->base = (get_frame_register_signed (this_frame, gdbarch_num_regs (gdbarch) + frame_reg) + frame_offset); /* FIXME: brobecker/2004-09-15: We should be able to get rid of this assignment below, eventually. But it's still needed for now. */ this_cache->saved_regs[gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->pc] = this_cache->saved_regs[gdbarch_num_regs (gdbarch) + MIPS_RA_REGNUM]; } /* Set end_prologue_addr to the address of the instruction immediately after the last one we scanned. Unless the last one looked like a non-prologue instruction (and we looked ahead), in which case use its address instead. */ end_prologue_addr = prev_non_prologue_insn || prev_delay_slot ? prev_pc : cur_pc; /* In a frameless function, we might have incorrectly skipped some load immediate instructions. Undo the skipping if the load immediate was not followed by a stack adjustment. */ if (load_immediate_bytes && !seen_sp_adjust) end_prologue_addr -= load_immediate_bytes; return end_prologue_addr; } /* Heuristic unwinder for procedures using 32-bit instructions (covers both 32-bit and 64-bit MIPS ISAs). Procedures using 16-bit instructions (a.k.a. MIPS16) are handled by the mips_insn16 unwinder. Likewise microMIPS and the mips_micro unwinder. */ static struct mips_frame_cache * mips_insn32_frame_cache (struct frame_info *this_frame, void **this_cache) { struct gdbarch *gdbarch = get_frame_arch (this_frame); struct mips_frame_cache *cache; if ((*this_cache) != NULL) return (struct mips_frame_cache *) (*this_cache); cache = FRAME_OBSTACK_ZALLOC (struct mips_frame_cache); (*this_cache) = cache; cache->saved_regs = trad_frame_alloc_saved_regs (this_frame); /* Analyze the function prologue. */ { const CORE_ADDR pc = get_frame_address_in_block (this_frame); CORE_ADDR start_addr; find_pc_partial_function (pc, NULL, &start_addr, NULL); if (start_addr == 0) start_addr = heuristic_proc_start (gdbarch, pc); /* We can't analyze the prologue if we couldn't find the begining of the function. */ if (start_addr == 0) return cache; mips32_scan_prologue (gdbarch, start_addr, pc, this_frame, (struct mips_frame_cache *) *this_cache); } /* gdbarch_sp_regnum contains the value and not the address. */ trad_frame_set_value (cache->saved_regs, gdbarch_num_regs (gdbarch) + MIPS_SP_REGNUM, cache->base); return (struct mips_frame_cache *) (*this_cache); } static void mips_insn32_frame_this_id (struct frame_info *this_frame, void **this_cache, struct frame_id *this_id) { struct mips_frame_cache *info = mips_insn32_frame_cache (this_frame, this_cache); /* This marks the outermost frame. */ if (info->base == 0) return; (*this_id) = frame_id_build (info->base, get_frame_func (this_frame)); } static struct value * mips_insn32_frame_prev_register (struct frame_info *this_frame, void **this_cache, int regnum) { struct mips_frame_cache *info = mips_insn32_frame_cache (this_frame, this_cache); return trad_frame_get_prev_register (this_frame, info->saved_regs, regnum); } static int mips_insn32_frame_sniffer (const struct frame_unwind *self, struct frame_info *this_frame, void **this_cache) { CORE_ADDR pc = get_frame_pc (this_frame); if (mips_pc_is_mips (pc)) return 1; return 0; } static const struct frame_unwind mips_insn32_frame_unwind = { NORMAL_FRAME, default_frame_unwind_stop_reason, mips_insn32_frame_this_id, mips_insn32_frame_prev_register, NULL, mips_insn32_frame_sniffer }; static CORE_ADDR mips_insn32_frame_base_address (struct frame_info *this_frame, void **this_cache) { struct mips_frame_cache *info = mips_insn32_frame_cache (this_frame, this_cache); return info->base; } static const struct frame_base mips_insn32_frame_base = { &mips_insn32_frame_unwind, mips_insn32_frame_base_address, mips_insn32_frame_base_address, mips_insn32_frame_base_address }; static const struct frame_base * mips_insn32_frame_base_sniffer (struct frame_info *this_frame) { CORE_ADDR pc = get_frame_pc (this_frame); if (mips_pc_is_mips (pc)) return &mips_insn32_frame_base; else return NULL; } static struct trad_frame_cache * mips_stub_frame_cache (struct frame_info *this_frame, void **this_cache) { CORE_ADDR pc; CORE_ADDR start_addr; CORE_ADDR stack_addr; struct trad_frame_cache *this_trad_cache; struct gdbarch *gdbarch = get_frame_arch (this_frame); int num_regs = gdbarch_num_regs (gdbarch); if ((*this_cache) != NULL) return (struct trad_frame_cache *) (*this_cache); this_trad_cache = trad_frame_cache_zalloc (this_frame); (*this_cache) = this_trad_cache; /* The return address is in the link register. */ trad_frame_set_reg_realreg (this_trad_cache, gdbarch_pc_regnum (gdbarch), num_regs + MIPS_RA_REGNUM); /* Frame ID, since it's a frameless / stackless function, no stack space is allocated and SP on entry is the current SP. */ pc = get_frame_pc (this_frame); find_pc_partial_function (pc, NULL, &start_addr, NULL); stack_addr = get_frame_register_signed (this_frame, num_regs + MIPS_SP_REGNUM); trad_frame_set_id (this_trad_cache, frame_id_build (stack_addr, start_addr)); /* Assume that the frame's base is the same as the stack-pointer. */ trad_frame_set_this_base (this_trad_cache, stack_addr); return this_trad_cache; } static void mips_stub_frame_this_id (struct frame_info *this_frame, void **this_cache, struct frame_id *this_id) { struct trad_frame_cache *this_trad_cache = mips_stub_frame_cache (this_frame, this_cache); trad_frame_get_id (this_trad_cache, this_id); } static struct value * mips_stub_frame_prev_register (struct frame_info *this_frame, void **this_cache, int regnum) { struct trad_frame_cache *this_trad_cache = mips_stub_frame_cache (this_frame, this_cache); return trad_frame_get_register (this_trad_cache, this_frame, regnum); } static int mips_stub_frame_sniffer (const struct frame_unwind *self, struct frame_info *this_frame, void **this_cache) { gdb_byte dummy[4]; CORE_ADDR pc = get_frame_address_in_block (this_frame); struct bound_minimal_symbol msym; /* Use the stub unwinder for unreadable code. */ if (target_read_memory (get_frame_pc (this_frame), dummy, 4) != 0) return 1; if (in_plt_section (pc) || in_mips_stubs_section (pc)) return 1; /* Calling a PIC function from a non-PIC function passes through a stub. The stub for foo is named ".pic.foo". */ msym = lookup_minimal_symbol_by_pc (pc); if (msym.minsym != NULL && msym.minsym->linkage_name () != NULL && startswith (msym.minsym->linkage_name (), ".pic.")) return 1; return 0; } static const struct frame_unwind mips_stub_frame_unwind = { NORMAL_FRAME, default_frame_unwind_stop_reason, mips_stub_frame_this_id, mips_stub_frame_prev_register, NULL, mips_stub_frame_sniffer }; static CORE_ADDR mips_stub_frame_base_address (struct frame_info *this_frame, void **this_cache) { struct trad_frame_cache *this_trad_cache = mips_stub_frame_cache (this_frame, this_cache); return trad_frame_get_this_base (this_trad_cache); } static const struct frame_base mips_stub_frame_base = { &mips_stub_frame_unwind, mips_stub_frame_base_address, mips_stub_frame_base_address, mips_stub_frame_base_address }; static const struct frame_base * mips_stub_frame_base_sniffer (struct frame_info *this_frame) { if (mips_stub_frame_sniffer (&mips_stub_frame_unwind, this_frame, NULL)) return &mips_stub_frame_base; else return NULL; } /* mips_addr_bits_remove - remove useless address bits */ static CORE_ADDR mips_addr_bits_remove (struct gdbarch *gdbarch, CORE_ADDR addr) { struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch); if (mips_mask_address_p (tdep) && (((ULONGEST) addr) >> 32 == 0xffffffffUL)) /* This hack is a work-around for existing boards using PMON, the simulator, and any other 64-bit targets that doesn't have true 64-bit addressing. On these targets, the upper 32 bits of addresses are ignored by the hardware. Thus, the PC or SP are likely to have been sign extended to all 1s by instruction sequences that load 32-bit addresses. For example, a typical piece of code that loads an address is this: lui $r2, ori $r2, But the lui sign-extends the value such that the upper 32 bits may be all 1s. The workaround is simply to mask off these bits. In the future, gcc may be changed to support true 64-bit addressing, and this masking will have to be disabled. */ return addr &= 0xffffffffUL; else return addr; } /* Checks for an atomic sequence of instructions beginning with a LL/LLD instruction and ending with a SC/SCD instruction. If such a sequence is found, attempt to step through it. A breakpoint is placed at the end of the sequence. */ /* Instructions used during single-stepping of atomic sequences, standard ISA version. */ #define LL_OPCODE 0x30 #define LLD_OPCODE 0x34 #define SC_OPCODE 0x38 #define SCD_OPCODE 0x3c static std::vector mips_deal_with_atomic_sequence (struct gdbarch *gdbarch, CORE_ADDR pc) { CORE_ADDR breaks[2] = {CORE_ADDR_MAX, CORE_ADDR_MAX}; CORE_ADDR loc = pc; CORE_ADDR branch_bp; /* Breakpoint at branch instruction's destination. */ ULONGEST insn; int insn_count; int index; int last_breakpoint = 0; /* Defaults to 0 (no breakpoints placed). */ const int atomic_sequence_length = 16; /* Instruction sequence length. */ insn = mips_fetch_instruction (gdbarch, ISA_MIPS, loc, NULL); /* Assume all atomic sequences start with a ll/lld instruction. */ if (itype_op (insn) != LL_OPCODE && itype_op (insn) != LLD_OPCODE) return {}; /* Assume that no atomic sequence is longer than "atomic_sequence_length" instructions. */ for (insn_count = 0; insn_count < atomic_sequence_length; ++insn_count) { int is_branch = 0; loc += MIPS_INSN32_SIZE; insn = mips_fetch_instruction (gdbarch, ISA_MIPS, loc, NULL); /* Assume that there is at most one branch in the atomic sequence. If a branch is found, put a breakpoint in its destination address. */ switch (itype_op (insn)) { case 0: /* SPECIAL */ if (rtype_funct (insn) >> 1 == 4) /* JR, JALR */ return {}; /* fallback to the standard single-step code. */ break; case 1: /* REGIMM */ is_branch = ((itype_rt (insn) & 0xc) == 0 /* B{LT,GE}Z* */ || ((itype_rt (insn) & 0x1e) == 0 && itype_rs (insn) == 0)); /* BPOSGE* */ break; case 2: /* J */ case 3: /* JAL */ return {}; /* fallback to the standard single-step code. */ case 4: /* BEQ */ case 5: /* BNE */ case 6: /* BLEZ */ case 7: /* BGTZ */ case 20: /* BEQL */ case 21: /* BNEL */ case 22: /* BLEZL */ case 23: /* BGTTL */ is_branch = 1; break; case 17: /* COP1 */ is_branch = ((itype_rs (insn) == 9 || itype_rs (insn) == 10) && (itype_rt (insn) & 0x2) == 0); if (is_branch) /* BC1ANY2F, BC1ANY2T, BC1ANY4F, BC1ANY4T */ break; /* Fall through. */ case 18: /* COP2 */ case 19: /* COP3 */ is_branch = (itype_rs (insn) == 8); /* BCzF, BCzFL, BCzT, BCzTL */ break; } if (is_branch) { branch_bp = loc + mips32_relative_offset (insn) + 4; if (last_breakpoint >= 1) return {}; /* More than one branch found, fallback to the standard single-step code. */ breaks[1] = branch_bp; last_breakpoint++; } if (itype_op (insn) == SC_OPCODE || itype_op (insn) == SCD_OPCODE) break; } /* Assume that the atomic sequence ends with a sc/scd instruction. */ if (itype_op (insn) != SC_OPCODE && itype_op (insn) != SCD_OPCODE) return {}; loc += MIPS_INSN32_SIZE; /* Insert a breakpoint right after the end of the atomic sequence. */ breaks[0] = loc; /* Check for duplicated breakpoints. Check also for a breakpoint placed (branch instruction's destination) in the atomic sequence. */ if (last_breakpoint && pc <= breaks[1] && breaks[1] <= breaks[0]) last_breakpoint = 0; std::vector next_pcs; /* Effectively inserts the breakpoints. */ for (index = 0; index <= last_breakpoint; index++) next_pcs.push_back (breaks[index]); return next_pcs; } static std::vector micromips_deal_with_atomic_sequence (struct gdbarch *gdbarch, CORE_ADDR pc) { const int atomic_sequence_length = 16; /* Instruction sequence length. */ int last_breakpoint = 0; /* Defaults to 0 (no breakpoints placed). */ CORE_ADDR breaks[2] = {CORE_ADDR_MAX, CORE_ADDR_MAX}; CORE_ADDR branch_bp = 0; /* Breakpoint at branch instruction's destination. */ CORE_ADDR loc = pc; int sc_found = 0; ULONGEST insn; int insn_count; int index; /* Assume all atomic sequences start with a ll/lld instruction. */ insn = mips_fetch_instruction (gdbarch, ISA_MICROMIPS, loc, NULL); if (micromips_op (insn) != 0x18) /* POOL32C: bits 011000 */ return {}; loc += MIPS_INSN16_SIZE; insn <<= 16; insn |= mips_fetch_instruction (gdbarch, ISA_MICROMIPS, loc, NULL); if ((b12s4_op (insn) & 0xb) != 0x3) /* LL, LLD: bits 011000 0x11 */ return {}; loc += MIPS_INSN16_SIZE; /* Assume all atomic sequences end with an sc/scd instruction. Assume that no atomic sequence is longer than "atomic_sequence_length" instructions. */ for (insn_count = 0; !sc_found && insn_count < atomic_sequence_length; ++insn_count) { int is_branch = 0; insn = mips_fetch_instruction (gdbarch, ISA_MICROMIPS, loc, NULL); loc += MIPS_INSN16_SIZE; /* Assume that there is at most one conditional branch in the atomic sequence. If a branch is found, put a breakpoint in its destination address. */ switch (mips_insn_size (ISA_MICROMIPS, insn)) { /* 32-bit instructions. */ case 2 * MIPS_INSN16_SIZE: switch (micromips_op (insn)) { case 0x10: /* POOL32I: bits 010000 */ if ((b5s5_op (insn) & 0x18) != 0x0 /* BLTZ, BLTZAL, BGEZ, BGEZAL: 010000 000xx */ /* BLEZ, BNEZC, BGTZ, BEQZC: 010000 001xx */ && (b5s5_op (insn) & 0x1d) != 0x11 /* BLTZALS, BGEZALS: bits 010000 100x1 */ && ((b5s5_op (insn) & 0x1e) != 0x14 || (insn & 0x3) != 0x0) /* BC2F, BC2T: bits 010000 1010x xxx00 */ && (b5s5_op (insn) & 0x1e) != 0x1a /* BPOSGE64, BPOSGE32: bits 010000 1101x */ && ((b5s5_op (insn) & 0x1e) != 0x1c || (insn & 0x3) != 0x0) /* BC1F, BC1T: bits 010000 1110x xxx00 */ && ((b5s5_op (insn) & 0x1c) != 0x1c || (insn & 0x3) != 0x1)) /* BC1ANY*: bits 010000 111xx xxx01 */ break; /* Fall through. */ case 0x25: /* BEQ: bits 100101 */ case 0x2d: /* BNE: bits 101101 */ insn <<= 16; insn |= mips_fetch_instruction (gdbarch, ISA_MICROMIPS, loc, NULL); branch_bp = (loc + MIPS_INSN16_SIZE + micromips_relative_offset16 (insn)); is_branch = 1; break; case 0x00: /* POOL32A: bits 000000 */ insn <<= 16; insn |= mips_fetch_instruction (gdbarch, ISA_MICROMIPS, loc, NULL); if (b0s6_op (insn) != 0x3c /* POOL32Axf: bits 000000 ... 111100 */ || (b6s10_ext (insn) & 0x2bf) != 0x3c) /* JALR, JALR.HB: 000000 000x111100 111100 */ /* JALRS, JALRS.HB: 000000 010x111100 111100 */ break; /* Fall through. */ case 0x1d: /* JALS: bits 011101 */ case 0x35: /* J: bits 110101 */ case 0x3d: /* JAL: bits 111101 */ case 0x3c: /* JALX: bits 111100 */ return {}; /* Fall back to the standard single-step code. */ case 0x18: /* POOL32C: bits 011000 */ if ((b12s4_op (insn) & 0xb) == 0xb) /* SC, SCD: bits 011000 1x11 */ sc_found = 1; break; } loc += MIPS_INSN16_SIZE; break; /* 16-bit instructions. */ case MIPS_INSN16_SIZE: switch (micromips_op (insn)) { case 0x23: /* BEQZ16: bits 100011 */ case 0x2b: /* BNEZ16: bits 101011 */ branch_bp = loc + micromips_relative_offset7 (insn); is_branch = 1; break; case 0x11: /* POOL16C: bits 010001 */ if ((b5s5_op (insn) & 0x1c) != 0xc /* JR16, JRC, JALR16, JALRS16: 010001 011xx */ && b5s5_op (insn) != 0x18) /* JRADDIUSP: bits 010001 11000 */ break; return {}; /* Fall back to the standard single-step code. */ case 0x33: /* B16: bits 110011 */ return {}; /* Fall back to the standard single-step code. */ } break; } if (is_branch) { if (last_breakpoint >= 1) return {}; /* More than one branch found, fallback to the standard single-step code. */ breaks[1] = branch_bp; last_breakpoint++; } } if (!sc_found) return {}; /* Insert a breakpoint right after the end of the atomic sequence. */ breaks[0] = loc; /* Check for duplicated breakpoints. Check also for a breakpoint placed (branch instruction's destination) in the atomic sequence */ if (last_breakpoint && pc <= breaks[1] && breaks[1] <= breaks[0]) last_breakpoint = 0; std::vector next_pcs; /* Effectively inserts the breakpoints. */ for (index = 0; index <= last_breakpoint; index++) next_pcs.push_back (breaks[index]); return next_pcs; } static std::vector deal_with_atomic_sequence (struct gdbarch *gdbarch, CORE_ADDR pc) { if (mips_pc_is_mips (pc)) return mips_deal_with_atomic_sequence (gdbarch, pc); else if (mips_pc_is_micromips (gdbarch, pc)) return micromips_deal_with_atomic_sequence (gdbarch, pc); else return {}; } /* mips_software_single_step() is called just before we want to resume the inferior, if we want to single-step it but there is no hardware or kernel single-step support (MIPS on GNU/Linux for example). We find the target of the coming instruction and breakpoint it. */ std::vector mips_software_single_step (struct regcache *regcache) { struct gdbarch *gdbarch = regcache->arch (); CORE_ADDR pc, next_pc; pc = regcache_read_pc (regcache); std::vector next_pcs = deal_with_atomic_sequence (gdbarch, pc); if (!next_pcs.empty ()) return next_pcs; next_pc = mips_next_pc (regcache, pc); return {next_pc}; } /* Test whether the PC points to the return instruction at the end of a function. */ static int mips_about_to_return (struct gdbarch *gdbarch, CORE_ADDR pc) { ULONGEST insn; ULONGEST hint; /* This used to check for MIPS16, but this piece of code is never called for MIPS16 functions. And likewise microMIPS ones. */ gdb_assert (mips_pc_is_mips (pc)); insn = mips_fetch_instruction (gdbarch, ISA_MIPS, pc, NULL); hint = 0x7c0; return (insn & ~hint) == 0x3e00008; /* jr(.hb) $ra */ } /* This fencepost looks highly suspicious to me. Removing it also seems suspicious as it could affect remote debugging across serial lines. */ static CORE_ADDR heuristic_proc_start (struct gdbarch *gdbarch, CORE_ADDR pc) { CORE_ADDR start_pc; CORE_ADDR fence; int instlen; int seen_adjsp = 0; struct inferior *inf; pc = gdbarch_addr_bits_remove (gdbarch, pc); start_pc = pc; fence = start_pc - heuristic_fence_post; if (start_pc == 0) return 0; if (heuristic_fence_post == -1 || fence < VM_MIN_ADDRESS) fence = VM_MIN_ADDRESS; instlen = mips_pc_is_mips (pc) ? MIPS_INSN32_SIZE : MIPS_INSN16_SIZE; inf = current_inferior (); /* Search back for previous return. */ for (start_pc -= instlen;; start_pc -= instlen) if (start_pc < fence) { /* It's not clear to me why we reach this point when stop_soon, but with this test, at least we don't print out warnings for every child forked (eg, on decstation). 22apr93 rich@cygnus.com. */ if (inf->control.stop_soon == NO_STOP_QUIETLY) { static int blurb_printed = 0; warning (_("GDB can't find the start of the function at %s."), paddress (gdbarch, pc)); if (!blurb_printed) { /* This actually happens frequently in embedded development, when you first connect to a board and your stack pointer and pc are nowhere in particular. This message needs to give people in that situation enough information to determine that it's no big deal. */ printf_filtered ("\n\ GDB is unable to find the start of the function at %s\n\ and thus can't determine the size of that function's stack frame.\n\ This means that GDB may be unable to access that stack frame, or\n\ the frames below it.\n\ This problem is most likely caused by an invalid program counter or\n\ stack pointer.\n\ However, if you think GDB should simply search farther back\n\ from %s for code which looks like the beginning of a\n\ function, you can increase the range of the search using the `set\n\ heuristic-fence-post' command.\n", paddress (gdbarch, pc), paddress (gdbarch, pc)); blurb_printed = 1; } } return 0; } else if (mips_pc_is_mips16 (gdbarch, start_pc)) { unsigned short inst; /* On MIPS16, any one of the following is likely to be the start of a function: extend save save entry addiu sp,-n daddiu sp,-n extend -n followed by 'addiu sp,+n' or 'daddiu sp,+n'. */ inst = mips_fetch_instruction (gdbarch, ISA_MIPS16, start_pc, NULL); if ((inst & 0xff80) == 0x6480) /* save */ { if (start_pc - instlen >= fence) { inst = mips_fetch_instruction (gdbarch, ISA_MIPS16, start_pc - instlen, NULL); if ((inst & 0xf800) == 0xf000) /* extend */ start_pc -= instlen; } break; } else if (((inst & 0xf81f) == 0xe809 && (inst & 0x700) != 0x700) /* entry */ || (inst & 0xff80) == 0x6380 /* addiu sp,-n */ || (inst & 0xff80) == 0xfb80 /* daddiu sp,-n */ || ((inst & 0xf810) == 0xf010 && seen_adjsp)) /* extend -n */ break; else if ((inst & 0xff00) == 0x6300 /* addiu sp */ || (inst & 0xff00) == 0xfb00) /* daddiu sp */ seen_adjsp = 1; else seen_adjsp = 0; } else if (mips_pc_is_micromips (gdbarch, start_pc)) { ULONGEST insn; int stop = 0; long offset; int dreg; int sreg; /* On microMIPS, any one of the following is likely to be the start of a function: ADDIUSP -imm (D)ADDIU $sp, -imm LUI $gp, imm */ insn = mips_fetch_instruction (gdbarch, ISA_MICROMIPS, pc, NULL); switch (micromips_op (insn)) { case 0xc: /* ADDIU: bits 001100 */ case 0x17: /* DADDIU: bits 010111 */ sreg = b0s5_reg (insn); dreg = b5s5_reg (insn); insn <<= 16; insn |= mips_fetch_instruction (gdbarch, ISA_MICROMIPS, pc + MIPS_INSN16_SIZE, NULL); offset = (b0s16_imm (insn) ^ 0x8000) - 0x8000; if (sreg == MIPS_SP_REGNUM && dreg == MIPS_SP_REGNUM /* (D)ADDIU $sp, imm */ && offset < 0) stop = 1; break; case 0x10: /* POOL32I: bits 010000 */ if (b5s5_op (insn) == 0xd /* LUI: bits 010000 001101 */ && b0s5_reg (insn >> 16) == 28) /* LUI $gp, imm */ stop = 1; break; case 0x13: /* POOL16D: bits 010011 */ if ((insn & 0x1) == 0x1) /* ADDIUSP: bits 010011 1 */ { offset = micromips_decode_imm9 (b1s9_imm (insn)); if (offset < 0) /* ADDIUSP -imm */ stop = 1; } else /* ADDIUS5: bits 010011 0 */ { dreg = b5s5_reg (insn); offset = (b1s4_imm (insn) ^ 8) - 8; if (dreg == MIPS_SP_REGNUM && offset < 0) /* ADDIUS5 $sp, -imm */ stop = 1; } break; } if (stop) break; } else if (mips_about_to_return (gdbarch, start_pc)) { /* Skip return and its delay slot. */ start_pc += 2 * MIPS_INSN32_SIZE; break; } return start_pc; } struct mips_objfile_private { bfd_size_type size; char *contents; }; /* According to the current ABI, should the type be passed in a floating-point register (assuming that there is space)? When there is no FPU, FP are not even considered as possible candidates for FP registers and, consequently this returns false - forces FP arguments into integer registers. */ static int fp_register_arg_p (struct gdbarch *gdbarch, enum type_code typecode, struct type *arg_type) { return ((typecode == TYPE_CODE_FLT || (MIPS_EABI (gdbarch) && (typecode == TYPE_CODE_STRUCT || typecode == TYPE_CODE_UNION) && TYPE_NFIELDS (arg_type) == 1 && TYPE_CODE (check_typedef (TYPE_FIELD_TYPE (arg_type, 0))) == TYPE_CODE_FLT)) && MIPS_FPU_TYPE(gdbarch) != MIPS_FPU_NONE); } /* On o32, argument passing in GPRs depends on the alignment of the type being passed. Return 1 if this type must be aligned to a doubleword boundary. */ static int mips_type_needs_double_align (struct type *type) { enum type_code typecode = TYPE_CODE (type); if (typecode == TYPE_CODE_FLT && TYPE_LENGTH (type) == 8) return 1; else if (typecode == TYPE_CODE_STRUCT) { if (TYPE_NFIELDS (type) < 1) return 0; return mips_type_needs_double_align (TYPE_FIELD_TYPE (type, 0)); } else if (typecode == TYPE_CODE_UNION) { int i, n; n = TYPE_NFIELDS (type); for (i = 0; i < n; i++) if (mips_type_needs_double_align (TYPE_FIELD_TYPE (type, i))) return 1; return 0; } return 0; } /* Adjust the address downward (direction of stack growth) so that it is correctly aligned for a new stack frame. */ static CORE_ADDR mips_frame_align (struct gdbarch *gdbarch, CORE_ADDR addr) { return align_down (addr, 16); } /* Implement the "push_dummy_code" gdbarch method. */ static CORE_ADDR mips_push_dummy_code (struct gdbarch *gdbarch, CORE_ADDR sp, CORE_ADDR funaddr, struct value **args, int nargs, struct type *value_type, CORE_ADDR *real_pc, CORE_ADDR *bp_addr, struct regcache *regcache) { static gdb_byte nop_insn[] = { 0, 0, 0, 0 }; CORE_ADDR nop_addr; CORE_ADDR bp_slot; /* Reserve enough room on the stack for our breakpoint instruction. */ bp_slot = sp - sizeof (nop_insn); /* Return to microMIPS mode if calling microMIPS code to avoid triggering an address error exception on processors that only support microMIPS execution. */ *bp_addr = (mips_pc_is_micromips (gdbarch, funaddr) ? make_compact_addr (bp_slot) : bp_slot); /* The breakpoint layer automatically adjusts the address of breakpoints inserted in a branch delay slot. With enough bad luck, the 4 bytes located just before our breakpoint instruction could look like a branch instruction, and thus trigger the adjustement, and break the function call entirely. So, we reserve those 4 bytes and write a nop instruction to prevent that from happening. */ nop_addr = bp_slot - sizeof (nop_insn); write_memory (nop_addr, nop_insn, sizeof (nop_insn)); sp = mips_frame_align (gdbarch, nop_addr); /* Inferior resumes at the function entry point. */ *real_pc = funaddr; return sp; } static CORE_ADDR mips_eabi_push_dummy_call (struct gdbarch *gdbarch, struct value *function, struct regcache *regcache, CORE_ADDR bp_addr, int nargs, struct value **args, CORE_ADDR sp, function_call_return_method return_method, CORE_ADDR struct_addr) { int argreg; int float_argreg; int argnum; int arg_space = 0; int stack_offset = 0; enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); CORE_ADDR func_addr = find_function_addr (function, NULL); int abi_regsize = mips_abi_regsize (gdbarch); /* For shared libraries, "t9" needs to point at the function address. */ regcache_cooked_write_signed (regcache, MIPS_T9_REGNUM, func_addr); /* Set the return address register to point to the entry point of the program, where a breakpoint lies in wait. */ regcache_cooked_write_signed (regcache, MIPS_RA_REGNUM, bp_addr); /* First ensure that the stack and structure return address (if any) are properly aligned. The stack has to be at least 64-bit aligned even on 32-bit machines, because doubles must be 64-bit aligned. For n32 and n64, stack frames need to be 128-bit aligned, so we round to this widest known alignment. */ sp = align_down (sp, 16); struct_addr = align_down (struct_addr, 16); /* Now make space on the stack for the args. We allocate more than necessary for EABI, because the first few arguments are passed in registers, but that's OK. */ for (argnum = 0; argnum < nargs; argnum++) arg_space += align_up (TYPE_LENGTH (value_type (args[argnum])), abi_regsize); sp -= align_up (arg_space, 16); if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_eabi_push_dummy_call: sp=%s allocated %ld\n", paddress (gdbarch, sp), (long) align_up (arg_space, 16)); /* Initialize the integer and float register pointers. */ argreg = MIPS_A0_REGNUM; float_argreg = mips_fpa0_regnum (gdbarch); /* The struct_return pointer occupies the first parameter-passing reg. */ if (return_method == return_method_struct) { if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_eabi_push_dummy_call: " "struct_return reg=%d %s\n", argreg, paddress (gdbarch, struct_addr)); regcache_cooked_write_unsigned (regcache, argreg++, struct_addr); } /* Now load as many as possible of the first arguments into registers, and push the rest onto the stack. Loop thru args from first to last. */ for (argnum = 0; argnum < nargs; argnum++) { const gdb_byte *val; /* This holds the address of structures that are passed by reference. */ gdb_byte ref_valbuf[MAX_MIPS_ABI_REGSIZE]; struct value *arg = args[argnum]; struct type *arg_type = check_typedef (value_type (arg)); int len = TYPE_LENGTH (arg_type); enum type_code typecode = TYPE_CODE (arg_type); if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_eabi_push_dummy_call: %d len=%d type=%d", argnum + 1, len, (int) typecode); /* The EABI passes structures that do not fit in a register by reference. */ if (len > abi_regsize && (typecode == TYPE_CODE_STRUCT || typecode == TYPE_CODE_UNION)) { gdb_assert (abi_regsize <= ARRAY_SIZE (ref_valbuf)); store_unsigned_integer (ref_valbuf, abi_regsize, byte_order, value_address (arg)); typecode = TYPE_CODE_PTR; len = abi_regsize; val = ref_valbuf; if (mips_debug) fprintf_unfiltered (gdb_stdlog, " push"); } else val = value_contents (arg); /* 32-bit ABIs always start floating point arguments in an even-numbered floating point register. Round the FP register up before the check to see if there are any FP registers left. Non MIPS_EABI targets also pass the FP in the integer registers so also round up normal registers. */ if (abi_regsize < 8 && fp_register_arg_p (gdbarch, typecode, arg_type)) { if ((float_argreg & 1)) float_argreg++; } /* Floating point arguments passed in registers have to be treated specially. On 32-bit architectures, doubles are passed in register pairs; the even register gets the low word, and the odd register gets the high word. On non-EABI processors, the first two floating point arguments are also copied to general registers, because MIPS16 functions don't use float registers for arguments. This duplication of arguments in general registers can't hurt non-MIPS16 functions because those registers are normally skipped. */ /* MIPS_EABI squeezes a struct that contains a single floating point value into an FP register instead of pushing it onto the stack. */ if (fp_register_arg_p (gdbarch, typecode, arg_type) && float_argreg <= MIPS_LAST_FP_ARG_REGNUM (gdbarch)) { /* EABI32 will pass doubles in consecutive registers, even on 64-bit cores. At one time, we used to check the size of `float_argreg' to determine whether or not to pass doubles in consecutive registers, but this is not sufficient for making the ABI determination. */ if (len == 8 && mips_abi (gdbarch) == MIPS_ABI_EABI32) { int low_offset = gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG ? 4 : 0; long regval; /* Write the low word of the double to the even register(s). */ regval = extract_signed_integer (val + low_offset, 4, byte_order); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg, phex (regval, 4)); regcache_cooked_write_signed (regcache, float_argreg++, regval); /* Write the high word of the double to the odd register(s). */ regval = extract_signed_integer (val + 4 - low_offset, 4, byte_order); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg, phex (regval, 4)); regcache_cooked_write_signed (regcache, float_argreg++, regval); } else { /* This is a floating point value that fits entirely in a single register. */ /* On 32 bit ABI's the float_argreg is further adjusted above to ensure that it is even register aligned. */ LONGEST regval = extract_signed_integer (val, len, byte_order); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg, phex (regval, len)); regcache_cooked_write_signed (regcache, float_argreg++, regval); } } else { /* Copy the argument to general registers or the stack in register-sized pieces. Large arguments are split between registers and stack. */ /* Note: structs whose size is not a multiple of abi_regsize are treated specially: Irix cc passes them in registers where gcc sometimes puts them on the stack. For maximum compatibility, we will put them in both places. */ int odd_sized_struct = (len > abi_regsize && len % abi_regsize != 0); /* Note: Floating-point values that didn't fit into an FP register are only written to memory. */ while (len > 0) { /* Remember if the argument was written to the stack. */ int stack_used_p = 0; int partial_len = (len < abi_regsize ? len : abi_regsize); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " -- partial=%d", partial_len); /* Write this portion of the argument to the stack. */ if (argreg > MIPS_LAST_ARG_REGNUM (gdbarch) || odd_sized_struct || fp_register_arg_p (gdbarch, typecode, arg_type)) { /* Should shorter than int integer values be promoted to int before being stored? */ int longword_offset = 0; CORE_ADDR addr; stack_used_p = 1; if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG) { if (abi_regsize == 8 && (typecode == TYPE_CODE_INT || typecode == TYPE_CODE_PTR || typecode == TYPE_CODE_FLT) && len <= 4) longword_offset = abi_regsize - len; else if ((typecode == TYPE_CODE_STRUCT || typecode == TYPE_CODE_UNION) && TYPE_LENGTH (arg_type) < abi_regsize) longword_offset = abi_regsize - len; } if (mips_debug) { fprintf_unfiltered (gdb_stdlog, " - stack_offset=%s", paddress (gdbarch, stack_offset)); fprintf_unfiltered (gdb_stdlog, " longword_offset=%s", paddress (gdbarch, longword_offset)); } addr = sp + stack_offset + longword_offset; if (mips_debug) { int i; fprintf_unfiltered (gdb_stdlog, " @%s ", paddress (gdbarch, addr)); for (i = 0; i < partial_len; i++) { fprintf_unfiltered (gdb_stdlog, "%02x", val[i] & 0xff); } } write_memory (addr, val, partial_len); } /* Note!!! This is NOT an else clause. Odd sized structs may go thru BOTH paths. Floating point arguments will not. */ /* Write this portion of the argument to a general purpose register. */ if (argreg <= MIPS_LAST_ARG_REGNUM (gdbarch) && !fp_register_arg_p (gdbarch, typecode, arg_type)) { LONGEST regval = extract_signed_integer (val, partial_len, byte_order); if (mips_debug) fprintf_filtered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, abi_regsize)); regcache_cooked_write_signed (regcache, argreg, regval); argreg++; } len -= partial_len; val += partial_len; /* Compute the offset into the stack at which we will copy the next parameter. In the new EABI (and the NABI32), the stack_offset only needs to be adjusted when it has been used. */ if (stack_used_p) stack_offset += align_up (partial_len, abi_regsize); } } if (mips_debug) fprintf_unfiltered (gdb_stdlog, "\n"); } regcache_cooked_write_signed (regcache, MIPS_SP_REGNUM, sp); /* Return adjusted stack pointer. */ return sp; } /* Determine the return value convention being used. */ static enum return_value_convention mips_eabi_return_value (struct gdbarch *gdbarch, struct value *function, struct type *type, struct regcache *regcache, gdb_byte *readbuf, const gdb_byte *writebuf) { struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch); int fp_return_type = 0; int offset, regnum, xfer; if (TYPE_LENGTH (type) > 2 * mips_abi_regsize (gdbarch)) return RETURN_VALUE_STRUCT_CONVENTION; /* Floating point type? */ if (tdep->mips_fpu_type != MIPS_FPU_NONE) { if (TYPE_CODE (type) == TYPE_CODE_FLT) fp_return_type = 1; /* Structs with a single field of float type are returned in a floating point register. */ if ((TYPE_CODE (type) == TYPE_CODE_STRUCT || TYPE_CODE (type) == TYPE_CODE_UNION) && TYPE_NFIELDS (type) == 1) { struct type *fieldtype = TYPE_FIELD_TYPE (type, 0); if (TYPE_CODE (check_typedef (fieldtype)) == TYPE_CODE_FLT) fp_return_type = 1; } } if (fp_return_type) { /* A floating-point value belongs in the least significant part of FP0/FP1. */ if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return float in $fp0\n"); regnum = mips_regnum (gdbarch)->fp0; } else { /* An integer value goes in V0/V1. */ if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return scalar in $v0\n"); regnum = MIPS_V0_REGNUM; } for (offset = 0; offset < TYPE_LENGTH (type); offset += mips_abi_regsize (gdbarch), regnum++) { xfer = mips_abi_regsize (gdbarch); if (offset + xfer > TYPE_LENGTH (type)) xfer = TYPE_LENGTH (type) - offset; mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum, xfer, gdbarch_byte_order (gdbarch), readbuf, writebuf, offset); } return RETURN_VALUE_REGISTER_CONVENTION; } /* N32/N64 ABI stuff. */ /* Search for a naturally aligned double at OFFSET inside a struct ARG_TYPE. The N32 / N64 ABIs pass these in floating point registers. */ static int mips_n32n64_fp_arg_chunk_p (struct gdbarch *gdbarch, struct type *arg_type, int offset) { int i; if (TYPE_CODE (arg_type) != TYPE_CODE_STRUCT) return 0; if (MIPS_FPU_TYPE (gdbarch) != MIPS_FPU_DOUBLE) return 0; if (TYPE_LENGTH (arg_type) < offset + MIPS64_REGSIZE) return 0; for (i = 0; i < TYPE_NFIELDS (arg_type); i++) { int pos; struct type *field_type; /* We're only looking at normal fields. */ if (field_is_static (&TYPE_FIELD (arg_type, i)) || (TYPE_FIELD_BITPOS (arg_type, i) % 8) != 0) continue; /* If we have gone past the offset, there is no double to pass. */ pos = TYPE_FIELD_BITPOS (arg_type, i) / 8; if (pos > offset) return 0; field_type = check_typedef (TYPE_FIELD_TYPE (arg_type, i)); /* If this field is entirely before the requested offset, go on to the next one. */ if (pos + TYPE_LENGTH (field_type) <= offset) continue; /* If this is our special aligned double, we can stop. */ if (TYPE_CODE (field_type) == TYPE_CODE_FLT && TYPE_LENGTH (field_type) == MIPS64_REGSIZE) return 1; /* This field starts at or before the requested offset, and overlaps it. If it is a structure, recurse inwards. */ return mips_n32n64_fp_arg_chunk_p (gdbarch, field_type, offset - pos); } return 0; } static CORE_ADDR mips_n32n64_push_dummy_call (struct gdbarch *gdbarch, struct value *function, struct regcache *regcache, CORE_ADDR bp_addr, int nargs, struct value **args, CORE_ADDR sp, function_call_return_method return_method, CORE_ADDR struct_addr) { int argreg; int float_argreg; int argnum; int arg_space = 0; int stack_offset = 0; enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); CORE_ADDR func_addr = find_function_addr (function, NULL); /* For shared libraries, "t9" needs to point at the function address. */ regcache_cooked_write_signed (regcache, MIPS_T9_REGNUM, func_addr); /* Set the return address register to point to the entry point of the program, where a breakpoint lies in wait. */ regcache_cooked_write_signed (regcache, MIPS_RA_REGNUM, bp_addr); /* First ensure that the stack and structure return address (if any) are properly aligned. The stack has to be at least 64-bit aligned even on 32-bit machines, because doubles must be 64-bit aligned. For n32 and n64, stack frames need to be 128-bit aligned, so we round to this widest known alignment. */ sp = align_down (sp, 16); struct_addr = align_down (struct_addr, 16); /* Now make space on the stack for the args. */ for (argnum = 0; argnum < nargs; argnum++) arg_space += align_up (TYPE_LENGTH (value_type (args[argnum])), MIPS64_REGSIZE); sp -= align_up (arg_space, 16); if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_n32n64_push_dummy_call: sp=%s allocated %ld\n", paddress (gdbarch, sp), (long) align_up (arg_space, 16)); /* Initialize the integer and float register pointers. */ argreg = MIPS_A0_REGNUM; float_argreg = mips_fpa0_regnum (gdbarch); /* The struct_return pointer occupies the first parameter-passing reg. */ if (return_method == return_method_struct) { if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_n32n64_push_dummy_call: " "struct_return reg=%d %s\n", argreg, paddress (gdbarch, struct_addr)); regcache_cooked_write_unsigned (regcache, argreg++, struct_addr); } /* Now load as many as possible of the first arguments into registers, and push the rest onto the stack. Loop thru args from first to last. */ for (argnum = 0; argnum < nargs; argnum++) { const gdb_byte *val; struct value *arg = args[argnum]; struct type *arg_type = check_typedef (value_type (arg)); int len = TYPE_LENGTH (arg_type); enum type_code typecode = TYPE_CODE (arg_type); if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_n32n64_push_dummy_call: %d len=%d type=%d", argnum + 1, len, (int) typecode); val = value_contents (arg); /* A 128-bit long double value requires an even-odd pair of floating-point registers. */ if (len == 16 && fp_register_arg_p (gdbarch, typecode, arg_type) && (float_argreg & 1)) { float_argreg++; argreg++; } if (fp_register_arg_p (gdbarch, typecode, arg_type) && argreg <= MIPS_LAST_ARG_REGNUM (gdbarch)) { /* This is a floating point value that fits entirely in a single register or a pair of registers. */ int reglen = (len <= MIPS64_REGSIZE ? len : MIPS64_REGSIZE); LONGEST regval = extract_unsigned_integer (val, reglen, byte_order); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg, phex (regval, reglen)); regcache_cooked_write_unsigned (regcache, float_argreg, regval); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, reglen)); regcache_cooked_write_unsigned (regcache, argreg, regval); float_argreg++; argreg++; if (len == 16) { regval = extract_unsigned_integer (val + reglen, reglen, byte_order); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg, phex (regval, reglen)); regcache_cooked_write_unsigned (regcache, float_argreg, regval); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, reglen)); regcache_cooked_write_unsigned (regcache, argreg, regval); float_argreg++; argreg++; } } else { /* Copy the argument to general registers or the stack in register-sized pieces. Large arguments are split between registers and stack. */ /* For N32/N64, structs, unions, or other composite types are treated as a sequence of doublewords, and are passed in integer or floating point registers as though they were simple scalar parameters to the extent that they fit, with any excess on the stack packed according to the normal memory layout of the object. The caller does not reserve space for the register arguments; the callee is responsible for reserving it if required. */ /* Note: Floating-point values that didn't fit into an FP register are only written to memory. */ while (len > 0) { /* Remember if the argument was written to the stack. */ int stack_used_p = 0; int partial_len = (len < MIPS64_REGSIZE ? len : MIPS64_REGSIZE); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " -- partial=%d", partial_len); if (fp_register_arg_p (gdbarch, typecode, arg_type)) gdb_assert (argreg > MIPS_LAST_ARG_REGNUM (gdbarch)); /* Write this portion of the argument to the stack. */ if (argreg > MIPS_LAST_ARG_REGNUM (gdbarch)) { /* Should shorter than int integer values be promoted to int before being stored? */ int longword_offset = 0; CORE_ADDR addr; stack_used_p = 1; if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG) { if ((typecode == TYPE_CODE_INT || typecode == TYPE_CODE_PTR) && len <= 4) longword_offset = MIPS64_REGSIZE - len; } if (mips_debug) { fprintf_unfiltered (gdb_stdlog, " - stack_offset=%s", paddress (gdbarch, stack_offset)); fprintf_unfiltered (gdb_stdlog, " longword_offset=%s", paddress (gdbarch, longword_offset)); } addr = sp + stack_offset + longword_offset; if (mips_debug) { int i; fprintf_unfiltered (gdb_stdlog, " @%s ", paddress (gdbarch, addr)); for (i = 0; i < partial_len; i++) { fprintf_unfiltered (gdb_stdlog, "%02x", val[i] & 0xff); } } write_memory (addr, val, partial_len); } /* Note!!! This is NOT an else clause. Odd sized structs may go thru BOTH paths. */ /* Write this portion of the argument to a general purpose register. */ if (argreg <= MIPS_LAST_ARG_REGNUM (gdbarch)) { LONGEST regval; /* Sign extend pointers, 32-bit integers and signed 16-bit and 8-bit integers; everything else is taken as is. */ if ((partial_len == 4 && (typecode == TYPE_CODE_PTR || typecode == TYPE_CODE_INT)) || (partial_len < 4 && typecode == TYPE_CODE_INT && !TYPE_UNSIGNED (arg_type))) regval = extract_signed_integer (val, partial_len, byte_order); else regval = extract_unsigned_integer (val, partial_len, byte_order); /* A non-floating-point argument being passed in a general register. If a struct or union, and if the remaining length is smaller than the register size, we have to adjust the register value on big endian targets. It does not seem to be necessary to do the same for integral types. */ if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG && partial_len < MIPS64_REGSIZE && (typecode == TYPE_CODE_STRUCT || typecode == TYPE_CODE_UNION)) regval <<= ((MIPS64_REGSIZE - partial_len) * TARGET_CHAR_BIT); if (mips_debug) fprintf_filtered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, MIPS64_REGSIZE)); regcache_cooked_write_unsigned (regcache, argreg, regval); if (mips_n32n64_fp_arg_chunk_p (gdbarch, arg_type, TYPE_LENGTH (arg_type) - len)) { if (mips_debug) fprintf_filtered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg, phex (regval, MIPS64_REGSIZE)); regcache_cooked_write_unsigned (regcache, float_argreg, regval); } float_argreg++; argreg++; } len -= partial_len; val += partial_len; /* Compute the offset into the stack at which we will copy the next parameter. In N32 (N64?), the stack_offset only needs to be adjusted when it has been used. */ if (stack_used_p) stack_offset += align_up (partial_len, MIPS64_REGSIZE); } } if (mips_debug) fprintf_unfiltered (gdb_stdlog, "\n"); } regcache_cooked_write_signed (regcache, MIPS_SP_REGNUM, sp); /* Return adjusted stack pointer. */ return sp; } static enum return_value_convention mips_n32n64_return_value (struct gdbarch *gdbarch, struct value *function, struct type *type, struct regcache *regcache, gdb_byte *readbuf, const gdb_byte *writebuf) { struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch); /* From MIPSpro N32 ABI Handbook, Document Number: 007-2816-004 Function results are returned in $2 (and $3 if needed), or $f0 (and $f2 if needed), as appropriate for the type. Composite results (struct, union, or array) are returned in $2/$f0 and $3/$f2 according to the following rules: * A struct with only one or two floating point fields is returned in $f0 (and $f2 if necessary). This is a generalization of the Fortran COMPLEX case. * Any other composite results of at most 128 bits are returned in $2 (first 64 bits) and $3 (remainder, if necessary). * Larger composite results are handled by converting the function to a procedure with an implicit first parameter, which is a pointer to an area reserved by the caller to receive the result. [The o32-bit ABI requires that all composite results be handled by conversion to implicit first parameters. The MIPS/SGI Fortran implementation has always made a specific exception to return COMPLEX results in the floating point registers.] */ if (TYPE_LENGTH (type) > 2 * MIPS64_REGSIZE) return RETURN_VALUE_STRUCT_CONVENTION; else if (TYPE_CODE (type) == TYPE_CODE_FLT && TYPE_LENGTH (type) == 16 && tdep->mips_fpu_type != MIPS_FPU_NONE) { /* A 128-bit floating-point value fills both $f0 and $f2. The two registers are used in the same as memory order, so the eight bytes with the lower memory address are in $f0. */ if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return float in $f0 and $f2\n"); mips_xfer_register (gdbarch, regcache, (gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->fp0), 8, gdbarch_byte_order (gdbarch), readbuf, writebuf, 0); mips_xfer_register (gdbarch, regcache, (gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->fp0 + 2), 8, gdbarch_byte_order (gdbarch), readbuf ? readbuf + 8 : readbuf, writebuf ? writebuf + 8 : writebuf, 0); return RETURN_VALUE_REGISTER_CONVENTION; } else if (TYPE_CODE (type) == TYPE_CODE_FLT && tdep->mips_fpu_type != MIPS_FPU_NONE) { /* A single or double floating-point value that fits in FP0. */ if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return float in $fp0\n"); mips_xfer_register (gdbarch, regcache, (gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->fp0), TYPE_LENGTH (type), gdbarch_byte_order (gdbarch), readbuf, writebuf, 0); return RETURN_VALUE_REGISTER_CONVENTION; } else if (TYPE_CODE (type) == TYPE_CODE_STRUCT && TYPE_NFIELDS (type) <= 2 && TYPE_NFIELDS (type) >= 1 && ((TYPE_NFIELDS (type) == 1 && (TYPE_CODE (check_typedef (TYPE_FIELD_TYPE (type, 0))) == TYPE_CODE_FLT)) || (TYPE_NFIELDS (type) == 2 && (TYPE_CODE (check_typedef (TYPE_FIELD_TYPE (type, 0))) == TYPE_CODE_FLT) && (TYPE_CODE (check_typedef (TYPE_FIELD_TYPE (type, 1))) == TYPE_CODE_FLT)))) { /* A struct that contains one or two floats. Each value is part in the least significant part of their floating point register (or GPR, for soft float). */ int regnum; int field; for (field = 0, regnum = (tdep->mips_fpu_type != MIPS_FPU_NONE ? mips_regnum (gdbarch)->fp0 : MIPS_V0_REGNUM); field < TYPE_NFIELDS (type); field++, regnum += 2) { int offset = (FIELD_BITPOS (TYPE_FIELDS (type)[field]) / TARGET_CHAR_BIT); if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return float struct+%d\n", offset); if (TYPE_LENGTH (TYPE_FIELD_TYPE (type, field)) == 16) { /* A 16-byte long double field goes in two consecutive registers. */ mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum, 8, gdbarch_byte_order (gdbarch), readbuf, writebuf, offset); mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum + 1, 8, gdbarch_byte_order (gdbarch), readbuf, writebuf, offset + 8); } else mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum, TYPE_LENGTH (TYPE_FIELD_TYPE (type, field)), gdbarch_byte_order (gdbarch), readbuf, writebuf, offset); } return RETURN_VALUE_REGISTER_CONVENTION; } else if (TYPE_CODE (type) == TYPE_CODE_STRUCT || TYPE_CODE (type) == TYPE_CODE_UNION || TYPE_CODE (type) == TYPE_CODE_ARRAY) { /* A composite type. Extract the left justified value, regardless of the byte order. I.e. DO NOT USE mips_xfer_lower. */ int offset; int regnum; for (offset = 0, regnum = MIPS_V0_REGNUM; offset < TYPE_LENGTH (type); offset += register_size (gdbarch, regnum), regnum++) { int xfer = register_size (gdbarch, regnum); if (offset + xfer > TYPE_LENGTH (type)) xfer = TYPE_LENGTH (type) - offset; if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return struct+%d:%d in $%d\n", offset, xfer, regnum); mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum, xfer, BFD_ENDIAN_UNKNOWN, readbuf, writebuf, offset); } return RETURN_VALUE_REGISTER_CONVENTION; } else { /* A scalar extract each part but least-significant-byte justified. */ int offset; int regnum; for (offset = 0, regnum = MIPS_V0_REGNUM; offset < TYPE_LENGTH (type); offset += register_size (gdbarch, regnum), regnum++) { int xfer = register_size (gdbarch, regnum); if (offset + xfer > TYPE_LENGTH (type)) xfer = TYPE_LENGTH (type) - offset; if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return scalar+%d:%d in $%d\n", offset, xfer, regnum); mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum, xfer, gdbarch_byte_order (gdbarch), readbuf, writebuf, offset); } return RETURN_VALUE_REGISTER_CONVENTION; } } /* Which registers to use for passing floating-point values between function calls, one of floating-point, general and both kinds of registers. O32 and O64 use different register kinds for standard MIPS and MIPS16 code; to make the handling of cases where we may not know what kind of code is being used (e.g. no debug information) easier we sometimes use both kinds. */ enum mips_fval_reg { mips_fval_fpr, mips_fval_gpr, mips_fval_both }; /* O32 ABI stuff. */ static CORE_ADDR mips_o32_push_dummy_call (struct gdbarch *gdbarch, struct value *function, struct regcache *regcache, CORE_ADDR bp_addr, int nargs, struct value **args, CORE_ADDR sp, function_call_return_method return_method, CORE_ADDR struct_addr) { int argreg; int float_argreg; int argnum; int arg_space = 0; int stack_offset = 0; enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); CORE_ADDR func_addr = find_function_addr (function, NULL); /* For shared libraries, "t9" needs to point at the function address. */ regcache_cooked_write_signed (regcache, MIPS_T9_REGNUM, func_addr); /* Set the return address register to point to the entry point of the program, where a breakpoint lies in wait. */ regcache_cooked_write_signed (regcache, MIPS_RA_REGNUM, bp_addr); /* First ensure that the stack and structure return address (if any) are properly aligned. The stack has to be at least 64-bit aligned even on 32-bit machines, because doubles must be 64-bit aligned. For n32 and n64, stack frames need to be 128-bit aligned, so we round to this widest known alignment. */ sp = align_down (sp, 16); struct_addr = align_down (struct_addr, 16); /* Now make space on the stack for the args. */ for (argnum = 0; argnum < nargs; argnum++) { struct type *arg_type = check_typedef (value_type (args[argnum])); /* Align to double-word if necessary. */ if (mips_type_needs_double_align (arg_type)) arg_space = align_up (arg_space, MIPS32_REGSIZE * 2); /* Allocate space on the stack. */ arg_space += align_up (TYPE_LENGTH (arg_type), MIPS32_REGSIZE); } sp -= align_up (arg_space, 16); if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_o32_push_dummy_call: sp=%s allocated %ld\n", paddress (gdbarch, sp), (long) align_up (arg_space, 16)); /* Initialize the integer and float register pointers. */ argreg = MIPS_A0_REGNUM; float_argreg = mips_fpa0_regnum (gdbarch); /* The struct_return pointer occupies the first parameter-passing reg. */ if (return_method == return_method_struct) { if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_o32_push_dummy_call: " "struct_return reg=%d %s\n", argreg, paddress (gdbarch, struct_addr)); regcache_cooked_write_unsigned (regcache, argreg++, struct_addr); stack_offset += MIPS32_REGSIZE; } /* Now load as many as possible of the first arguments into registers, and push the rest onto the stack. Loop thru args from first to last. */ for (argnum = 0; argnum < nargs; argnum++) { const gdb_byte *val; struct value *arg = args[argnum]; struct type *arg_type = check_typedef (value_type (arg)); int len = TYPE_LENGTH (arg_type); enum type_code typecode = TYPE_CODE (arg_type); if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_o32_push_dummy_call: %d len=%d type=%d", argnum + 1, len, (int) typecode); val = value_contents (arg); /* 32-bit ABIs always start floating point arguments in an even-numbered floating point register. Round the FP register up before the check to see if there are any FP registers left. O32 targets also pass the FP in the integer registers so also round up normal registers. */ if (fp_register_arg_p (gdbarch, typecode, arg_type)) { if ((float_argreg & 1)) float_argreg++; } /* Floating point arguments passed in registers have to be treated specially. On 32-bit architectures, doubles are passed in register pairs; the even FP register gets the low word, and the odd FP register gets the high word. On O32, the first two floating point arguments are also copied to general registers, following their memory order, because MIPS16 functions don't use float registers for arguments. This duplication of arguments in general registers can't hurt non-MIPS16 functions, because those registers are normally skipped. */ if (fp_register_arg_p (gdbarch, typecode, arg_type) && float_argreg <= MIPS_LAST_FP_ARG_REGNUM (gdbarch)) { if (register_size (gdbarch, float_argreg) < 8 && len == 8) { int freg_offset = gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG ? 1 : 0; unsigned long regval; /* First word. */ regval = extract_unsigned_integer (val, 4, byte_order); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg + freg_offset, phex (regval, 4)); regcache_cooked_write_unsigned (regcache, float_argreg++ + freg_offset, regval); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, 4)); regcache_cooked_write_unsigned (regcache, argreg++, regval); /* Second word. */ regval = extract_unsigned_integer (val + 4, 4, byte_order); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg - freg_offset, phex (regval, 4)); regcache_cooked_write_unsigned (regcache, float_argreg++ - freg_offset, regval); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, 4)); regcache_cooked_write_unsigned (regcache, argreg++, regval); } else { /* This is a floating point value that fits entirely in a single register. */ /* On 32 bit ABI's the float_argreg is further adjusted above to ensure that it is even register aligned. */ LONGEST regval = extract_unsigned_integer (val, len, byte_order); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg, phex (regval, len)); regcache_cooked_write_unsigned (regcache, float_argreg++, regval); /* Although two FP registers are reserved for each argument, only one corresponding integer register is reserved. */ if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, len)); regcache_cooked_write_unsigned (regcache, argreg++, regval); } /* Reserve space for the FP register. */ stack_offset += align_up (len, MIPS32_REGSIZE); } else { /* Copy the argument to general registers or the stack in register-sized pieces. Large arguments are split between registers and stack. */ /* Note: structs whose size is not a multiple of MIPS32_REGSIZE are treated specially: Irix cc passes them in registers where gcc sometimes puts them on the stack. For maximum compatibility, we will put them in both places. */ int odd_sized_struct = (len > MIPS32_REGSIZE && len % MIPS32_REGSIZE != 0); /* Structures should be aligned to eight bytes (even arg registers) on MIPS_ABI_O32, if their first member has double precision. */ if (mips_type_needs_double_align (arg_type)) { if ((argreg & 1)) { argreg++; stack_offset += MIPS32_REGSIZE; } } while (len > 0) { int partial_len = (len < MIPS32_REGSIZE ? len : MIPS32_REGSIZE); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " -- partial=%d", partial_len); /* Write this portion of the argument to the stack. */ if (argreg > MIPS_LAST_ARG_REGNUM (gdbarch) || odd_sized_struct) { /* Should shorter than int integer values be promoted to int before being stored? */ int longword_offset = 0; CORE_ADDR addr; if (mips_debug) { fprintf_unfiltered (gdb_stdlog, " - stack_offset=%s", paddress (gdbarch, stack_offset)); fprintf_unfiltered (gdb_stdlog, " longword_offset=%s", paddress (gdbarch, longword_offset)); } addr = sp + stack_offset + longword_offset; if (mips_debug) { int i; fprintf_unfiltered (gdb_stdlog, " @%s ", paddress (gdbarch, addr)); for (i = 0; i < partial_len; i++) { fprintf_unfiltered (gdb_stdlog, "%02x", val[i] & 0xff); } } write_memory (addr, val, partial_len); } /* Note!!! This is NOT an else clause. Odd sized structs may go thru BOTH paths. */ /* Write this portion of the argument to a general purpose register. */ if (argreg <= MIPS_LAST_ARG_REGNUM (gdbarch)) { LONGEST regval = extract_signed_integer (val, partial_len, byte_order); /* Value may need to be sign extended, because mips_isa_regsize() != mips_abi_regsize(). */ /* A non-floating-point argument being passed in a general register. If a struct or union, and if the remaining length is smaller than the register size, we have to adjust the register value on big endian targets. It does not seem to be necessary to do the same for integral types. Also don't do this adjustment on O64 binaries. cagney/2001-07-23: gdb/179: Also, GCC, when outputting LE O32 with sizeof (struct) < mips_abi_regsize(), generates a left shift as part of storing the argument in a register (the left shift isn't generated when sizeof (struct) >= mips_abi_regsize()). Since it is quite possible that this is GCC contradicting the LE/O32 ABI, GDB has not been adjusted to accommodate this. Either someone needs to demonstrate that the LE/O32 ABI specifies such a left shift OR this new ABI gets identified as such and GDB gets tweaked accordingly. */ if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG && partial_len < MIPS32_REGSIZE && (typecode == TYPE_CODE_STRUCT || typecode == TYPE_CODE_UNION)) regval <<= ((MIPS32_REGSIZE - partial_len) * TARGET_CHAR_BIT); if (mips_debug) fprintf_filtered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, MIPS32_REGSIZE)); regcache_cooked_write_unsigned (regcache, argreg, regval); argreg++; /* Prevent subsequent floating point arguments from being passed in floating point registers. */ float_argreg = MIPS_LAST_FP_ARG_REGNUM (gdbarch) + 1; } len -= partial_len; val += partial_len; /* Compute the offset into the stack at which we will copy the next parameter. In older ABIs, the caller reserved space for registers that contained arguments. This was loosely refered to as their "home". Consequently, space is always allocated. */ stack_offset += align_up (partial_len, MIPS32_REGSIZE); } } if (mips_debug) fprintf_unfiltered (gdb_stdlog, "\n"); } regcache_cooked_write_signed (regcache, MIPS_SP_REGNUM, sp); /* Return adjusted stack pointer. */ return sp; } static enum return_value_convention mips_o32_return_value (struct gdbarch *gdbarch, struct value *function, struct type *type, struct regcache *regcache, gdb_byte *readbuf, const gdb_byte *writebuf) { CORE_ADDR func_addr = function ? find_function_addr (function, NULL) : 0; int mips16 = mips_pc_is_mips16 (gdbarch, func_addr); struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch); enum mips_fval_reg fval_reg; fval_reg = readbuf ? mips16 ? mips_fval_gpr : mips_fval_fpr : mips_fval_both; if (TYPE_CODE (type) == TYPE_CODE_STRUCT || TYPE_CODE (type) == TYPE_CODE_UNION || TYPE_CODE (type) == TYPE_CODE_ARRAY) return RETURN_VALUE_STRUCT_CONVENTION; else if (TYPE_CODE (type) == TYPE_CODE_FLT && TYPE_LENGTH (type) == 4 && tdep->mips_fpu_type != MIPS_FPU_NONE) { /* A single-precision floating-point value. If reading in or copying, then we get it from/put it to FP0 for standard MIPS code or GPR2 for MIPS16 code. If writing out only, then we put it to both FP0 and GPR2. We do not support reading in with no function known, if this safety check ever triggers, then we'll have to try harder. */ gdb_assert (function || !readbuf); if (mips_debug) switch (fval_reg) { case mips_fval_fpr: fprintf_unfiltered (gdb_stderr, "Return float in $fp0\n"); break; case mips_fval_gpr: fprintf_unfiltered (gdb_stderr, "Return float in $2\n"); break; case mips_fval_both: fprintf_unfiltered (gdb_stderr, "Return float in $fp0 and $2\n"); break; } if (fval_reg != mips_fval_gpr) mips_xfer_register (gdbarch, regcache, (gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->fp0), TYPE_LENGTH (type), gdbarch_byte_order (gdbarch), readbuf, writebuf, 0); if (fval_reg != mips_fval_fpr) mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + 2, TYPE_LENGTH (type), gdbarch_byte_order (gdbarch), readbuf, writebuf, 0); return RETURN_VALUE_REGISTER_CONVENTION; } else if (TYPE_CODE (type) == TYPE_CODE_FLT && TYPE_LENGTH (type) == 8 && tdep->mips_fpu_type != MIPS_FPU_NONE) { /* A double-precision floating-point value. If reading in or copying, then we get it from/put it to FP1 and FP0 for standard MIPS code or GPR2 and GPR3 for MIPS16 code. If writing out only, then we put it to both FP1/FP0 and GPR2/GPR3. We do not support reading in with no function known, if this safety check ever triggers, then we'll have to try harder. */ gdb_assert (function || !readbuf); if (mips_debug) switch (fval_reg) { case mips_fval_fpr: fprintf_unfiltered (gdb_stderr, "Return float in $fp1/$fp0\n"); break; case mips_fval_gpr: fprintf_unfiltered (gdb_stderr, "Return float in $2/$3\n"); break; case mips_fval_both: fprintf_unfiltered (gdb_stderr, "Return float in $fp1/$fp0 and $2/$3\n"); break; } if (fval_reg != mips_fval_gpr) { /* The most significant part goes in FP1, and the least significant in FP0. */ switch (gdbarch_byte_order (gdbarch)) { case BFD_ENDIAN_LITTLE: mips_xfer_register (gdbarch, regcache, (gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->fp0 + 0), 4, gdbarch_byte_order (gdbarch), readbuf, writebuf, 0); mips_xfer_register (gdbarch, regcache, (gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->fp0 + 1), 4, gdbarch_byte_order (gdbarch), readbuf, writebuf, 4); break; case BFD_ENDIAN_BIG: mips_xfer_register (gdbarch, regcache, (gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->fp0 + 1), 4, gdbarch_byte_order (gdbarch), readbuf, writebuf, 0); mips_xfer_register (gdbarch, regcache, (gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->fp0 + 0), 4, gdbarch_byte_order (gdbarch), readbuf, writebuf, 4); break; default: internal_error (__FILE__, __LINE__, _("bad switch")); } } if (fval_reg != mips_fval_fpr) { /* The two 32-bit parts are always placed in GPR2 and GPR3 following these registers' memory order. */ mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + 2, 4, gdbarch_byte_order (gdbarch), readbuf, writebuf, 0); mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + 3, 4, gdbarch_byte_order (gdbarch), readbuf, writebuf, 4); } return RETURN_VALUE_REGISTER_CONVENTION; } #if 0 else if (TYPE_CODE (type) == TYPE_CODE_STRUCT && TYPE_NFIELDS (type) <= 2 && TYPE_NFIELDS (type) >= 1 && ((TYPE_NFIELDS (type) == 1 && (TYPE_CODE (TYPE_FIELD_TYPE (type, 0)) == TYPE_CODE_FLT)) || (TYPE_NFIELDS (type) == 2 && (TYPE_CODE (TYPE_FIELD_TYPE (type, 0)) == TYPE_CODE_FLT) && (TYPE_CODE (TYPE_FIELD_TYPE (type, 1)) == TYPE_CODE_FLT))) && tdep->mips_fpu_type != MIPS_FPU_NONE) { /* A struct that contains one or two floats. Each value is part in the least significant part of their floating point register.. */ int regnum; int field; for (field = 0, regnum = mips_regnum (gdbarch)->fp0; field < TYPE_NFIELDS (type); field++, regnum += 2) { int offset = (FIELD_BITPOS (TYPE_FIELDS (type)[field]) / TARGET_CHAR_BIT); if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return float struct+%d\n", offset); mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum, TYPE_LENGTH (TYPE_FIELD_TYPE (type, field)), gdbarch_byte_order (gdbarch), readbuf, writebuf, offset); } return RETURN_VALUE_REGISTER_CONVENTION; } #endif #if 0 else if (TYPE_CODE (type) == TYPE_CODE_STRUCT || TYPE_CODE (type) == TYPE_CODE_UNION) { /* A structure or union. Extract the left justified value, regardless of the byte order. I.e. DO NOT USE mips_xfer_lower. */ int offset; int regnum; for (offset = 0, regnum = MIPS_V0_REGNUM; offset < TYPE_LENGTH (type); offset += register_size (gdbarch, regnum), regnum++) { int xfer = register_size (gdbarch, regnum); if (offset + xfer > TYPE_LENGTH (type)) xfer = TYPE_LENGTH (type) - offset; if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return struct+%d:%d in $%d\n", offset, xfer, regnum); mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum, xfer, BFD_ENDIAN_UNKNOWN, readbuf, writebuf, offset); } return RETURN_VALUE_REGISTER_CONVENTION; } #endif else { /* A scalar extract each part but least-significant-byte justified. o32 thinks registers are 4 byte, regardless of the ISA. */ int offset; int regnum; for (offset = 0, regnum = MIPS_V0_REGNUM; offset < TYPE_LENGTH (type); offset += MIPS32_REGSIZE, regnum++) { int xfer = MIPS32_REGSIZE; if (offset + xfer > TYPE_LENGTH (type)) xfer = TYPE_LENGTH (type) - offset; if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return scalar+%d:%d in $%d\n", offset, xfer, regnum); mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum, xfer, gdbarch_byte_order (gdbarch), readbuf, writebuf, offset); } return RETURN_VALUE_REGISTER_CONVENTION; } } /* O64 ABI. This is a hacked up kind of 64-bit version of the o32 ABI. */ static CORE_ADDR mips_o64_push_dummy_call (struct gdbarch *gdbarch, struct value *function, struct regcache *regcache, CORE_ADDR bp_addr, int nargs, struct value **args, CORE_ADDR sp, function_call_return_method return_method, CORE_ADDR struct_addr) { int argreg; int float_argreg; int argnum; int arg_space = 0; int stack_offset = 0; enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); CORE_ADDR func_addr = find_function_addr (function, NULL); /* For shared libraries, "t9" needs to point at the function address. */ regcache_cooked_write_signed (regcache, MIPS_T9_REGNUM, func_addr); /* Set the return address register to point to the entry point of the program, where a breakpoint lies in wait. */ regcache_cooked_write_signed (regcache, MIPS_RA_REGNUM, bp_addr); /* First ensure that the stack and structure return address (if any) are properly aligned. The stack has to be at least 64-bit aligned even on 32-bit machines, because doubles must be 64-bit aligned. For n32 and n64, stack frames need to be 128-bit aligned, so we round to this widest known alignment. */ sp = align_down (sp, 16); struct_addr = align_down (struct_addr, 16); /* Now make space on the stack for the args. */ for (argnum = 0; argnum < nargs; argnum++) { struct type *arg_type = check_typedef (value_type (args[argnum])); /* Allocate space on the stack. */ arg_space += align_up (TYPE_LENGTH (arg_type), MIPS64_REGSIZE); } sp -= align_up (arg_space, 16); if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_o64_push_dummy_call: sp=%s allocated %ld\n", paddress (gdbarch, sp), (long) align_up (arg_space, 16)); /* Initialize the integer and float register pointers. */ argreg = MIPS_A0_REGNUM; float_argreg = mips_fpa0_regnum (gdbarch); /* The struct_return pointer occupies the first parameter-passing reg. */ if (return_method == return_method_struct) { if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_o64_push_dummy_call: " "struct_return reg=%d %s\n", argreg, paddress (gdbarch, struct_addr)); regcache_cooked_write_unsigned (regcache, argreg++, struct_addr); stack_offset += MIPS64_REGSIZE; } /* Now load as many as possible of the first arguments into registers, and push the rest onto the stack. Loop thru args from first to last. */ for (argnum = 0; argnum < nargs; argnum++) { const gdb_byte *val; struct value *arg = args[argnum]; struct type *arg_type = check_typedef (value_type (arg)); int len = TYPE_LENGTH (arg_type); enum type_code typecode = TYPE_CODE (arg_type); if (mips_debug) fprintf_unfiltered (gdb_stdlog, "mips_o64_push_dummy_call: %d len=%d type=%d", argnum + 1, len, (int) typecode); val = value_contents (arg); /* Floating point arguments passed in registers have to be treated specially. On 32-bit architectures, doubles are passed in register pairs; the even FP register gets the low word, and the odd FP register gets the high word. On O64, the first two floating point arguments are also copied to general registers, because MIPS16 functions don't use float registers for arguments. This duplication of arguments in general registers can't hurt non-MIPS16 functions because those registers are normally skipped. */ if (fp_register_arg_p (gdbarch, typecode, arg_type) && float_argreg <= MIPS_LAST_FP_ARG_REGNUM (gdbarch)) { LONGEST regval = extract_unsigned_integer (val, len, byte_order); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - fpreg=%d val=%s", float_argreg, phex (regval, len)); regcache_cooked_write_unsigned (regcache, float_argreg++, regval); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, len)); regcache_cooked_write_unsigned (regcache, argreg, regval); argreg++; /* Reserve space for the FP register. */ stack_offset += align_up (len, MIPS64_REGSIZE); } else { /* Copy the argument to general registers or the stack in register-sized pieces. Large arguments are split between registers and stack. */ /* Note: structs whose size is not a multiple of MIPS64_REGSIZE are treated specially: Irix cc passes them in registers where gcc sometimes puts them on the stack. For maximum compatibility, we will put them in both places. */ int odd_sized_struct = (len > MIPS64_REGSIZE && len % MIPS64_REGSIZE != 0); while (len > 0) { int partial_len = (len < MIPS64_REGSIZE ? len : MIPS64_REGSIZE); if (mips_debug) fprintf_unfiltered (gdb_stdlog, " -- partial=%d", partial_len); /* Write this portion of the argument to the stack. */ if (argreg > MIPS_LAST_ARG_REGNUM (gdbarch) || odd_sized_struct) { /* Should shorter than int integer values be promoted to int before being stored? */ int longword_offset = 0; CORE_ADDR addr; if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG) { if ((typecode == TYPE_CODE_INT || typecode == TYPE_CODE_PTR || typecode == TYPE_CODE_FLT) && len <= 4) longword_offset = MIPS64_REGSIZE - len; } if (mips_debug) { fprintf_unfiltered (gdb_stdlog, " - stack_offset=%s", paddress (gdbarch, stack_offset)); fprintf_unfiltered (gdb_stdlog, " longword_offset=%s", paddress (gdbarch, longword_offset)); } addr = sp + stack_offset + longword_offset; if (mips_debug) { int i; fprintf_unfiltered (gdb_stdlog, " @%s ", paddress (gdbarch, addr)); for (i = 0; i < partial_len; i++) { fprintf_unfiltered (gdb_stdlog, "%02x", val[i] & 0xff); } } write_memory (addr, val, partial_len); } /* Note!!! This is NOT an else clause. Odd sized structs may go thru BOTH paths. */ /* Write this portion of the argument to a general purpose register. */ if (argreg <= MIPS_LAST_ARG_REGNUM (gdbarch)) { LONGEST regval = extract_signed_integer (val, partial_len, byte_order); /* Value may need to be sign extended, because mips_isa_regsize() != mips_abi_regsize(). */ /* A non-floating-point argument being passed in a general register. If a struct or union, and if the remaining length is smaller than the register size, we have to adjust the register value on big endian targets. It does not seem to be necessary to do the same for integral types. */ if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG && partial_len < MIPS64_REGSIZE && (typecode == TYPE_CODE_STRUCT || typecode == TYPE_CODE_UNION)) regval <<= ((MIPS64_REGSIZE - partial_len) * TARGET_CHAR_BIT); if (mips_debug) fprintf_filtered (gdb_stdlog, " - reg=%d val=%s", argreg, phex (regval, MIPS64_REGSIZE)); regcache_cooked_write_unsigned (regcache, argreg, regval); argreg++; /* Prevent subsequent floating point arguments from being passed in floating point registers. */ float_argreg = MIPS_LAST_FP_ARG_REGNUM (gdbarch) + 1; } len -= partial_len; val += partial_len; /* Compute the offset into the stack at which we will copy the next parameter. In older ABIs, the caller reserved space for registers that contained arguments. This was loosely refered to as their "home". Consequently, space is always allocated. */ stack_offset += align_up (partial_len, MIPS64_REGSIZE); } } if (mips_debug) fprintf_unfiltered (gdb_stdlog, "\n"); } regcache_cooked_write_signed (regcache, MIPS_SP_REGNUM, sp); /* Return adjusted stack pointer. */ return sp; } static enum return_value_convention mips_o64_return_value (struct gdbarch *gdbarch, struct value *function, struct type *type, struct regcache *regcache, gdb_byte *readbuf, const gdb_byte *writebuf) { CORE_ADDR func_addr = function ? find_function_addr (function, NULL) : 0; int mips16 = mips_pc_is_mips16 (gdbarch, func_addr); enum mips_fval_reg fval_reg; fval_reg = readbuf ? mips16 ? mips_fval_gpr : mips_fval_fpr : mips_fval_both; if (TYPE_CODE (type) == TYPE_CODE_STRUCT || TYPE_CODE (type) == TYPE_CODE_UNION || TYPE_CODE (type) == TYPE_CODE_ARRAY) return RETURN_VALUE_STRUCT_CONVENTION; else if (fp_register_arg_p (gdbarch, TYPE_CODE (type), type)) { /* A floating-point value. If reading in or copying, then we get it from/put it to FP0 for standard MIPS code or GPR2 for MIPS16 code. If writing out only, then we put it to both FP0 and GPR2. We do not support reading in with no function known, if this safety check ever triggers, then we'll have to try harder. */ gdb_assert (function || !readbuf); if (mips_debug) switch (fval_reg) { case mips_fval_fpr: fprintf_unfiltered (gdb_stderr, "Return float in $fp0\n"); break; case mips_fval_gpr: fprintf_unfiltered (gdb_stderr, "Return float in $2\n"); break; case mips_fval_both: fprintf_unfiltered (gdb_stderr, "Return float in $fp0 and $2\n"); break; } if (fval_reg != mips_fval_gpr) mips_xfer_register (gdbarch, regcache, (gdbarch_num_regs (gdbarch) + mips_regnum (gdbarch)->fp0), TYPE_LENGTH (type), gdbarch_byte_order (gdbarch), readbuf, writebuf, 0); if (fval_reg != mips_fval_fpr) mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + 2, TYPE_LENGTH (type), gdbarch_byte_order (gdbarch), readbuf, writebuf, 0); return RETURN_VALUE_REGISTER_CONVENTION; } else { /* A scalar extract each part but least-significant-byte justified. */ int offset; int regnum; for (offset = 0, regnum = MIPS_V0_REGNUM; offset < TYPE_LENGTH (type); offset += MIPS64_REGSIZE, regnum++) { int xfer = MIPS64_REGSIZE; if (offset + xfer > TYPE_LENGTH (type)) xfer = TYPE_LENGTH (type) - offset; if (mips_debug) fprintf_unfiltered (gdb_stderr, "Return scalar+%d:%d in $%d\n", offset, xfer, regnum); mips_xfer_register (gdbarch, regcache, gdbarch_num_regs (gdbarch) + regnum, xfer, gdbarch_byte_order (gdbarch), readbuf, writebuf, offset); } return RETURN_VALUE_REGISTER_CONVENTION; } } /* Floating point register management. Background: MIPS1 & 2 fp registers are 32 bits wide. To support 64bit operations, these early MIPS cpus treat fp register pairs (f0,f1) as a single register (d0). Later MIPS cpu's have 64 bit fp registers and offer a compatibility mode that emulates the MIPS2 fp model. When operating in MIPS2 fp compat mode, later cpu's split double precision floats into two 32-bit chunks and store them in consecutive fp regs. To display 64-bit floats stored in this fashion, we have to combine 32 bits from f0 and 32 bits from f1. Throw in user-configurable endianness and you have a real mess. The way this works is: - If we are in 32-bit mode or on a 32-bit processor, then a 64-bit double-precision value will be split across two logical registers. The lower-numbered logical register will hold the low-order bits, regardless of the processor's endianness. - If we are on a 64-bit processor, and we are looking for a single-precision value, it will be in the low ordered bits of a 64-bit GPR (after mfc1, for example) or a 64-bit register save slot in memory. - If we are in 64-bit mode, everything is straightforward. Note that this code only deals with "live" registers at the top of the stack. We will attempt to deal with saved registers later, when the raw/cooked register interface is in place. (We need a general interface that can deal with dynamic saved register sizes -- fp regs could be 32 bits wide in one frame and 64 on the frame above and below). */ /* Copy a 32-bit single-precision value from the current frame into rare_buffer. */ static void mips_read_fp_register_single (struct frame_info *frame, int regno, gdb_byte *rare_buffer) { struct gdbarch *gdbarch = get_frame_arch (frame); int raw_size = register_size (gdbarch, regno); gdb_byte *raw_buffer = (gdb_byte *) alloca (raw_size); if (!deprecated_frame_register_read (frame, regno, raw_buffer)) error (_("can't read register %d (%s)"), regno, gdbarch_register_name (gdbarch, regno)); if (raw_size == 8) { /* We have a 64-bit value for this register. Find the low-order 32 bits. */ int offset; if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG) offset = 4; else offset = 0; memcpy (rare_buffer, raw_buffer + offset, 4); } else { memcpy (rare_buffer, raw_buffer, 4); } } /* Copy a 64-bit double-precision value from the current frame into rare_buffer. This may include getting half of it from the next register. */ static void mips_read_fp_register_double (struct frame_info *frame, int regno, gdb_byte *rare_buffer) { struct gdbarch *gdbarch = get_frame_arch (frame); int raw_size = register_size (gdbarch, regno); if (raw_size == 8 && !mips2_fp_compat (frame)) { /* We have a 64-bit value for this register, and we should use all 64 bits. */ if (!deprecated_frame_register_read (frame, regno, rare_buffer)) error (_("can't read register %d (%s)"), regno, gdbarch_register_name (gdbarch, regno)); } else { int rawnum = regno % gdbarch_num_regs (gdbarch); if ((rawnum - mips_regnum (gdbarch)->fp0) & 1) internal_error (__FILE__, __LINE__, _("mips_read_fp_register_double: bad access to " "odd-numbered FP register")); /* mips_read_fp_register_single will find the correct 32 bits from each register. */ if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG) { mips_read_fp_register_single (frame, regno, rare_buffer + 4); mips_read_fp_register_single (frame, regno + 1, rare_buffer); } else { mips_read_fp_register_single (frame, regno, rare_buffer); mips_read_fp_register_single (frame, regno + 1, rare_buffer + 4); } } } static void mips_print_fp_register (struct ui_file *file, struct frame_info *frame, int regnum) { /* Do values for FP (float) regs. */ struct gdbarch *gdbarch = get_frame_arch (frame); gdb_byte *raw_buffer; std::string flt_str, dbl_str; const struct type *flt_type = builtin_type (gdbarch)->builtin_float; const struct type *dbl_type = builtin_type (gdbarch)->builtin_double; raw_buffer = ((gdb_byte *) alloca (2 * register_size (gdbarch, mips_regnum (gdbarch)->fp0))); fprintf_filtered (file, "%s:", gdbarch_register_name (gdbarch, regnum)); fprintf_filtered (file, "%*s", 4 - (int) strlen (gdbarch_register_name (gdbarch, regnum)), ""); if (register_size (gdbarch, regnum) == 4 || mips2_fp_compat (frame)) { struct value_print_options opts; /* 4-byte registers: Print hex and floating. Also print even numbered registers as doubles. */ mips_read_fp_register_single (frame, regnum, raw_buffer); flt_str = target_float_to_string (raw_buffer, flt_type, "%-17.9g"); get_formatted_print_options (&opts, 'x'); print_scalar_formatted (raw_buffer, builtin_type (gdbarch)->builtin_uint32, &opts, 'w', file); fprintf_filtered (file, " flt: %s", flt_str.c_str ()); if ((regnum - gdbarch_num_regs (gdbarch)) % 2 == 0) { mips_read_fp_register_double (frame, regnum, raw_buffer); dbl_str = target_float_to_string (raw_buffer, dbl_type, "%-24.17g"); fprintf_filtered (file, " dbl: %s", dbl_str.c_str ()); } } else { struct value_print_options opts; /* Eight byte registers: print each one as hex, float and double. */ mips_read_fp_register_single (frame, regnum, raw_buffer); flt_str = target_float_to_string (raw_buffer, flt_type, "%-17.9g"); mips_read_fp_register_double (frame, regnum, raw_buffer); dbl_str = target_float_to_string (raw_buffer, dbl_type, "%-24.17g"); get_formatted_print_options (&opts, 'x'); print_scalar_formatted (raw_buffer, builtin_type (gdbarch)->builtin_uint64, &opts, 'g', file); fprintf_filtered (file, " flt: %s", flt_str.c_str ()); fprintf_filtered (file, " dbl: %s", dbl_str.c_str ()); } } static void mips_print_register (struct ui_file *file, struct frame_info *frame, int regnum) { struct gdbarch *gdbarch = get_frame_arch (frame); struct value_print_options opts; struct value *val; if (mips_float_register_p (gdbarch, regnum)) { mips_print_fp_register (file, frame, regnum); return; } val = get_frame_register_value (frame, regnum); fputs_filtered (gdbarch_register_name (gdbarch, regnum), file); /* The problem with printing numeric register names (r26, etc.) is that the user can't use them on input. Probably the best solution is to fix it so that either the numeric or the funky (a2, etc.) names are accepted on input. */ if (regnum < MIPS_NUMREGS) fprintf_filtered (file, "(r%d): ", regnum); else fprintf_filtered (file, ": "); get_formatted_print_options (&opts, 'x'); val_print_scalar_formatted (value_type (val), value_embedded_offset (val), val, &opts, 0, file); } /* Print IEEE exception condition bits in FLAGS. */ static void print_fpu_flags (struct ui_file *file, int flags) { if (flags & (1 << 0)) fputs_filtered (" inexact", file); if (flags & (1 << 1)) fputs_filtered (" uflow", file); if (flags & (1 << 2)) fputs_filtered (" oflow", file); if (flags & (1 << 3)) fputs_filtered (" div0", file); if (flags & (1 << 4)) fputs_filtered (" inval", file); if (flags & (1 << 5)) fputs_filtered (" unimp", file); fputc_filtered ('\n', file); } /* Print interesting information about the floating point processor (if present) or emulator. */ static void mips_print_float_info (struct gdbarch *gdbarch, struct ui_file *file, struct frame_info *frame, const char *args) { int fcsr = mips_regnum (gdbarch)->fp_control_status; enum mips_fpu_type type = MIPS_FPU_TYPE (gdbarch); ULONGEST fcs = 0; int i; if (fcsr == -1 || !read_frame_register_unsigned (frame, fcsr, &fcs)) type = MIPS_FPU_NONE; fprintf_filtered (file, "fpu type: %s\n", type == MIPS_FPU_DOUBLE ? "double-precision" : type == MIPS_FPU_SINGLE ? "single-precision" : "none / unused"); if (type == MIPS_FPU_NONE) return; fprintf_filtered (file, "reg size: %d bits\n", register_size (gdbarch, mips_regnum (gdbarch)->fp0) * 8); fputs_filtered ("cond :", file); if (fcs & (1 << 23)) fputs_filtered (" 0", file); for (i = 1; i <= 7; i++) if (fcs & (1 << (24 + i))) fprintf_filtered (file, " %d", i); fputc_filtered ('\n', file); fputs_filtered ("cause :", file); print_fpu_flags (file, (fcs >> 12) & 0x3f); fputs ("mask :", stdout); print_fpu_flags (file, (fcs >> 7) & 0x1f); fputs ("flags :", stdout); print_fpu_flags (file, (fcs >> 2) & 0x1f); fputs_filtered ("rounding: ", file); switch (fcs & 3) { case 0: fputs_filtered ("nearest\n", file); break; case 1: fputs_filtered ("zero\n", file); break; case 2: fputs_filtered ("+inf\n", file); break; case 3: fputs_filtered ("-inf\n", file); break; } fputs_filtered ("flush :", file); if (fcs & (1 << 21)) fputs_filtered (" nearest", file); if (fcs & (1 << 22)) fputs_filtered (" override", file); if (fcs & (1 << 24)) fputs_filtered (" zero", file); if ((fcs & (0xb << 21)) == 0) fputs_filtered (" no", file); fputc_filtered ('\n', file); fprintf_filtered (file, "nan2008 : %s\n", fcs & (1 << 18) ? "yes" : "no"); fprintf_filtered (file, "abs2008 : %s\n", fcs & (1 << 19) ? "yes" : "no"); fputc_filtered ('\n', file); default_print_float_info (gdbarch, file, frame, args); } /* Replacement for generic do_registers_info. Print regs in pretty columns. */ static int print_fp_register_row (struct ui_file *file, struct frame_info *frame, int regnum) { fprintf_filtered (file, " "); mips_print_fp_register (file, frame, regnum); fprintf_filtered (file, "\n"); return regnum + 1; } /* Print a row's worth of GP (int) registers, with name labels above. */ static int print_gp_register_row (struct ui_file *file, struct frame_info *frame, int start_regnum) { struct gdbarch *gdbarch = get_frame_arch (frame); /* Do values for GP (int) regs. */ const gdb_byte *raw_buffer; struct value *value; int ncols = (mips_abi_regsize (gdbarch) == 8 ? 4 : 8); /* display cols per row. */ int col, byte; int regnum; /* For GP registers, we print a separate row of names above the vals. */ for (col = 0, regnum = start_regnum; col < ncols && regnum < gdbarch_num_cooked_regs (gdbarch); regnum++) { if (*gdbarch_register_name (gdbarch, regnum) == '\0') continue; /* unused register */ if (mips_float_register_p (gdbarch, regnum)) break; /* End the row: reached FP register. */ /* Large registers are handled separately. */ if (register_size (gdbarch, regnum) > mips_abi_regsize (gdbarch)) { if (col > 0) break; /* End the row before this register. */ /* Print this register on a row by itself. */ mips_print_register (file, frame, regnum); fprintf_filtered (file, "\n"); return regnum + 1; } if (col == 0) fprintf_filtered (file, " "); fprintf_filtered (file, mips_abi_regsize (gdbarch) == 8 ? "%17s" : "%9s", gdbarch_register_name (gdbarch, regnum)); col++; } if (col == 0) return regnum; /* Print the R0 to R31 names. */ if ((start_regnum % gdbarch_num_regs (gdbarch)) < MIPS_NUMREGS) fprintf_filtered (file, "\n R%-4d", start_regnum % gdbarch_num_regs (gdbarch)); else fprintf_filtered (file, "\n "); /* Now print the values in hex, 4 or 8 to the row. */ for (col = 0, regnum = start_regnum; col < ncols && regnum < gdbarch_num_cooked_regs (gdbarch); regnum++) { if (*gdbarch_register_name (gdbarch, regnum) == '\0') continue; /* unused register */ if (mips_float_register_p (gdbarch, regnum)) break; /* End row: reached FP register. */ if (register_size (gdbarch, regnum) > mips_abi_regsize (gdbarch)) break; /* End row: large register. */ /* OK: get the data in raw format. */ value = get_frame_register_value (frame, regnum); if (value_optimized_out (value) || !value_entirely_available (value)) { fprintf_filtered (file, "%*s ", (int) mips_abi_regsize (gdbarch) * 2, (mips_abi_regsize (gdbarch) == 4 ? "" : "")); col++; continue; } raw_buffer = value_contents_all (value); /* pad small registers */ for (byte = 0; byte < (mips_abi_regsize (gdbarch) - register_size (gdbarch, regnum)); byte++) fprintf_filtered (file, " "); /* Now print the register value in hex, endian order. */ if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG) for (byte = register_size (gdbarch, regnum) - register_size (gdbarch, regnum); byte < register_size (gdbarch, regnum); byte++) fprintf_filtered (file, "%02x", raw_buffer[byte]); else for (byte = register_size (gdbarch, regnum) - 1; byte >= 0; byte--) fprintf_filtered (file, "%02x", raw_buffer[byte]); fprintf_filtered (file, " "); col++; } if (col > 0) /* ie. if we actually printed anything... */ fprintf_filtered (file, "\n"); return regnum; } /* MIPS_DO_REGISTERS_INFO(): called by "info register" command. */ static void mips_print_registers_info (struct gdbarch *gdbarch, struct ui_file *file, struct frame_info *frame, int regnum, int all) { if (regnum != -1) /* Do one specified register. */ { gdb_assert (regnum >= gdbarch_num_regs (gdbarch)); if (*(gdbarch_register_name (gdbarch, regnum)) == '\0') error (_("Not a valid register for the current processor type")); mips_print_register (file, frame, regnum); fprintf_filtered (file, "\n"); } else /* Do all (or most) registers. */ { regnum = gdbarch_num_regs (gdbarch); while (regnum < gdbarch_num_cooked_regs (gdbarch)) { if (mips_float_register_p (gdbarch, regnum)) { if (all) /* True for "INFO ALL-REGISTERS" command. */ regnum = print_fp_register_row (file, frame, regnum); else regnum += MIPS_NUMREGS; /* Skip floating point regs. */ } else regnum = print_gp_register_row (file, frame, regnum); } } } static int mips_single_step_through_delay (struct gdbarch *gdbarch, struct frame_info *frame) { CORE_ADDR pc = get_frame_pc (frame); enum mips_isa isa; ULONGEST insn; int size; if ((mips_pc_is_mips (pc) && !mips32_insn_at_pc_has_delay_slot (gdbarch, pc)) || (mips_pc_is_micromips (gdbarch, pc) && !micromips_insn_at_pc_has_delay_slot (gdbarch, pc, 0)) || (mips_pc_is_mips16 (gdbarch, pc) && !mips16_insn_at_pc_has_delay_slot (gdbarch, pc, 0))) return 0; isa = mips_pc_isa (gdbarch, pc); /* _has_delay_slot above will have validated the read. */ insn = mips_fetch_instruction (gdbarch, isa, pc, NULL); size = mips_insn_size (isa, insn); const address_space *aspace = get_frame_address_space (frame); return breakpoint_here_p (aspace, pc + size) != no_breakpoint_here; } /* To skip prologues, I use this predicate. Returns either PC itself if the code at PC does not look like a function prologue; otherwise returns an address that (if we're lucky) follows the prologue. If LENIENT, then we must skip everything which is involved in setting up the frame (it's OK to skip more, just so long as we don't skip anything which might clobber the registers which are being saved. We must skip more in the case where part of the prologue is in the delay slot of a non-prologue instruction). */ static CORE_ADDR mips_skip_prologue (struct gdbarch *gdbarch, CORE_ADDR pc) { CORE_ADDR limit_pc; CORE_ADDR func_addr; /* See if we can determine the end of the prologue via the symbol table. If so, then return either PC, or the PC after the prologue, whichever is greater. */ if (find_pc_partial_function (pc, NULL, &func_addr, NULL)) { CORE_ADDR post_prologue_pc = skip_prologue_using_sal (gdbarch, func_addr); if (post_prologue_pc != 0) return std::max (pc, post_prologue_pc); } /* Can't determine prologue from the symbol table, need to examine instructions. */ /* Find an upper limit on the function prologue using the debug information. If the debug information could not be used to provide that bound, then use an arbitrary large number as the upper bound. */ limit_pc = skip_prologue_using_sal (gdbarch, pc); if (limit_pc == 0) limit_pc = pc + 100; /* Magic. */ if (mips_pc_is_mips16 (gdbarch, pc)) return mips16_scan_prologue (gdbarch, pc, limit_pc, NULL, NULL); else if (mips_pc_is_micromips (gdbarch, pc)) return micromips_scan_prologue (gdbarch, pc, limit_pc, NULL, NULL); else return mips32_scan_prologue (gdbarch, pc, limit_pc, NULL, NULL); } /* Implement the stack_frame_destroyed_p gdbarch method (32-bit version). This is a helper function for mips_stack_frame_destroyed_p. */ static int mips32_stack_frame_destroyed_p (struct gdbarch *gdbarch, CORE_ADDR pc) { CORE_ADDR func_addr = 0, func_end = 0; if (find_pc_partial_function (pc, NULL, &func_addr, &func_end)) { /* The MIPS epilogue is max. 12 bytes long. */ CORE_ADDR addr = func_end - 12; if (addr < func_addr + 4) addr = func_addr + 4; if (pc < addr) return 0; for (; pc < func_end; pc += MIPS_INSN32_SIZE) { unsigned long high_word; unsigned long inst; inst = mips_fetch_instruction (gdbarch, ISA_MIPS, pc, NULL); high_word = (inst >> 16) & 0xffff; if (high_word != 0x27bd /* addiu $sp,$sp,offset */ && high_word != 0x67bd /* daddiu $sp,$sp,offset */ && inst != 0x03e00008 /* jr $ra */ && inst != 0x00000000) /* nop */ return 0; } return 1; } return 0; } /* Implement the stack_frame_destroyed_p gdbarch method (microMIPS version). This is a helper function for mips_stack_frame_destroyed_p. */ static int micromips_stack_frame_destroyed_p (struct gdbarch *gdbarch, CORE_ADDR pc) { CORE_ADDR func_addr = 0; CORE_ADDR func_end = 0; CORE_ADDR addr; ULONGEST insn; long offset; int dreg; int sreg; int loc; if (!find_pc_partial_function (pc, NULL, &func_addr, &func_end)) return 0; /* The microMIPS epilogue is max. 12 bytes long. */ addr = func_end - 12; if (addr < func_addr + 2) addr = func_addr + 2; if (pc < addr) return 0; for (; pc < func_end; pc += loc) { loc = 0; insn = mips_fetch_instruction (gdbarch, ISA_MICROMIPS, pc, NULL); loc += MIPS_INSN16_SIZE; switch (mips_insn_size (ISA_MICROMIPS, insn)) { /* 32-bit instructions. */ case 2 * MIPS_INSN16_SIZE: insn <<= 16; insn |= mips_fetch_instruction (gdbarch, ISA_MICROMIPS, pc + loc, NULL); loc += MIPS_INSN16_SIZE; switch (micromips_op (insn >> 16)) { case 0xc: /* ADDIU: bits 001100 */ case 0x17: /* DADDIU: bits 010111 */ sreg = b0s5_reg (insn >> 16); dreg = b5s5_reg (insn >> 16); offset = (b0s16_imm (insn) ^ 0x8000) - 0x8000; if (sreg == MIPS_SP_REGNUM && dreg == MIPS_SP_REGNUM /* (D)ADDIU $sp, imm */ && offset >= 0) break; return 0; default: return 0; } break; /* 16-bit instructions. */ case MIPS_INSN16_SIZE: switch (micromips_op (insn)) { case 0x3: /* MOVE: bits 000011 */ sreg = b0s5_reg (insn); dreg = b5s5_reg (insn); if (sreg == 0 && dreg == 0) /* MOVE $zero, $zero aka NOP */ break; return 0; case 0x11: /* POOL16C: bits 010001 */ if (b5s5_op (insn) == 0x18 /* JRADDIUSP: bits 010011 11000 */ || (b5s5_op (insn) == 0xd /* JRC: bits 010011 01101 */ && b0s5_reg (insn) == MIPS_RA_REGNUM)) /* JRC $ra */ break; return 0; case 0x13: /* POOL16D: bits 010011 */ offset = micromips_decode_imm9 (b1s9_imm (insn)); if ((insn & 0x1) == 0x1 /* ADDIUSP: bits 010011 1 */ && offset > 0) break; return 0; default: return 0; } } } return 1; } /* Implement the stack_frame_destroyed_p gdbarch method (16-bit version). This is a helper function for mips_stack_frame_destroyed_p. */ static int mips16_stack_frame_destroyed_p (struct gdbarch *gdbarch, CORE_ADDR pc) { CORE_ADDR func_addr = 0, func_end = 0; if (find_pc_partial_function (pc, NULL, &func_addr, &func_end)) { /* The MIPS epilogue is max. 12 bytes long. */ CORE_ADDR addr = func_end - 12; if (addr < func_addr + 4) addr = func_addr + 4; if (pc < addr) return 0; for (; pc < func_end; pc += MIPS_INSN16_SIZE) { unsigned short inst; inst = mips_fetch_instruction (gdbarch, ISA_MIPS16, pc, NULL); if ((inst & 0xf800) == 0xf000) /* extend */ continue; if (inst != 0x6300 /* addiu $sp,offset */ && inst != 0xfb00 /* daddiu $sp,$sp,offset */ && inst != 0xe820 /* jr $ra */ && inst != 0xe8a0 /* jrc $ra */ && inst != 0x6500) /* nop */ return 0; } return 1; } return 0; } /* Implement the stack_frame_destroyed_p gdbarch method. The epilogue is defined here as the area at the end of a function, after an instruction which destroys the function's stack frame. */ static int mips_stack_frame_destroyed_p (struct gdbarch *gdbarch, CORE_ADDR pc) { if (mips_pc_is_mips16 (gdbarch, pc)) return mips16_stack_frame_destroyed_p (gdbarch, pc); else if (mips_pc_is_micromips (gdbarch, pc)) return micromips_stack_frame_destroyed_p (gdbarch, pc); else return mips32_stack_frame_destroyed_p (gdbarch, pc); } /* Root of all "set mips "/"show mips " commands. This will eventually be used for all MIPS-specific commands. */ static void show_mips_command (const char *args, int from_tty) { help_list (showmipscmdlist, "show mips ", all_commands, gdb_stdout); } static void set_mips_command (const char *args, int from_tty) { printf_unfiltered ("\"set mips\" must be followed by an appropriate subcommand.\n"); help_list (setmipscmdlist, "set mips ", all_commands, gdb_stdout); } /* Commands to show/set the MIPS FPU type. */ static void show_mipsfpu_command (const char *args, int from_tty) { const char *fpu; if (gdbarch_bfd_arch_info (target_gdbarch ())->arch != bfd_arch_mips) { printf_unfiltered ("The MIPS floating-point coprocessor is unknown " "because the current architecture is not MIPS.\n"); return; } switch (MIPS_FPU_TYPE (target_gdbarch ())) { case MIPS_FPU_SINGLE: fpu = "single-precision"; break; case MIPS_FPU_DOUBLE: fpu = "double-precision"; break; case MIPS_FPU_NONE: fpu = "absent (none)"; break; default: internal_error (__FILE__, __LINE__, _("bad switch")); } if (mips_fpu_type_auto) printf_unfiltered ("The MIPS floating-point coprocessor " "is set automatically (currently %s)\n", fpu); else printf_unfiltered ("The MIPS floating-point coprocessor is assumed to be %s\n", fpu); } static void set_mipsfpu_command (const char *args, int from_tty) { printf_unfiltered ("\"set mipsfpu\" must be followed by \"double\", " "\"single\",\"none\" or \"auto\".\n"); show_mipsfpu_command (args, from_tty); } static void set_mipsfpu_single_command (const char *args, int from_tty) { struct gdbarch_info info; gdbarch_info_init (&info); mips_fpu_type = MIPS_FPU_SINGLE; mips_fpu_type_auto = 0; /* FIXME: cagney/2003-11-15: Should be setting a field in "info" instead of relying on globals. Doing that would let generic code handle the search for this specific architecture. */ if (!gdbarch_update_p (info)) internal_error (__FILE__, __LINE__, _("set mipsfpu failed")); } static void set_mipsfpu_double_command (const char *args, int from_tty) { struct gdbarch_info info; gdbarch_info_init (&info); mips_fpu_type = MIPS_FPU_DOUBLE; mips_fpu_type_auto = 0; /* FIXME: cagney/2003-11-15: Should be setting a field in "info" instead of relying on globals. Doing that would let generic code handle the search for this specific architecture. */ if (!gdbarch_update_p (info)) internal_error (__FILE__, __LINE__, _("set mipsfpu failed")); } static void set_mipsfpu_none_command (const char *args, int from_tty) { struct gdbarch_info info; gdbarch_info_init (&info); mips_fpu_type = MIPS_FPU_NONE; mips_fpu_type_auto = 0; /* FIXME: cagney/2003-11-15: Should be setting a field in "info" instead of relying on globals. Doing that would let generic code handle the search for this specific architecture. */ if (!gdbarch_update_p (info)) internal_error (__FILE__, __LINE__, _("set mipsfpu failed")); } static void set_mipsfpu_auto_command (const char *args, int from_tty) { mips_fpu_type_auto = 1; } /* Just like reinit_frame_cache, but with the right arguments to be callable as an sfunc. */ static void reinit_frame_cache_sfunc (const char *args, int from_tty, struct cmd_list_element *c) { reinit_frame_cache (); } static int gdb_print_insn_mips (bfd_vma memaddr, struct disassemble_info *info) { gdb_disassembler *di = static_cast(info->application_data); struct gdbarch *gdbarch = di->arch (); /* FIXME: cagney/2003-06-26: Is this even necessary? The disassembler needs to be able to locally determine the ISA, and not rely on GDB. Otherwize the stand-alone 'objdump -d' will not work. */ if (mips_pc_is_mips16 (gdbarch, memaddr)) info->mach = bfd_mach_mips16; else if (mips_pc_is_micromips (gdbarch, memaddr)) info->mach = bfd_mach_mips_micromips; /* Round down the instruction address to the appropriate boundary. */ memaddr &= (info->mach == bfd_mach_mips16 || info->mach == bfd_mach_mips_micromips) ? ~1 : ~3; return default_print_insn (memaddr, info); } /* Implement the breakpoint_kind_from_pc gdbarch method. */ static int mips_breakpoint_kind_from_pc (struct gdbarch *gdbarch, CORE_ADDR *pcptr) { CORE_ADDR pc = *pcptr; if (mips_pc_is_mips16 (gdbarch, pc)) { *pcptr = unmake_compact_addr (pc); return MIPS_BP_KIND_MIPS16; } else if (mips_pc_is_micromips (gdbarch, pc)) { ULONGEST insn; int status; *pcptr = unmake_compact_addr (pc); insn = mips_fetch_instruction (gdbarch, ISA_MICROMIPS, pc, &status); if (status || (mips_insn_size (ISA_MICROMIPS, insn) == 2)) return MIPS_BP_KIND_MICROMIPS16; else return MIPS_BP_KIND_MICROMIPS32; } else return MIPS_BP_KIND_MIPS32; } /* Implement the sw_breakpoint_from_kind gdbarch method. */ static const gdb_byte * mips_sw_breakpoint_from_kind (struct gdbarch *gdbarch, int kind, int *size) { enum bfd_endian byte_order_for_code = gdbarch_byte_order_for_code (gdbarch); switch (kind) { case MIPS_BP_KIND_MIPS16: { static gdb_byte mips16_big_breakpoint[] = { 0xe8, 0xa5 }; static gdb_byte mips16_little_breakpoint[] = { 0xa5, 0xe8 }; *size = 2; if (byte_order_for_code == BFD_ENDIAN_BIG) return mips16_big_breakpoint; else return mips16_little_breakpoint; } case MIPS_BP_KIND_MICROMIPS16: { static gdb_byte micromips16_big_breakpoint[] = { 0x46, 0x85 }; static gdb_byte micromips16_little_breakpoint[] = { 0x85, 0x46 }; *size = 2; if (byte_order_for_code == BFD_ENDIAN_BIG) return micromips16_big_breakpoint; else return micromips16_little_breakpoint; } case MIPS_BP_KIND_MICROMIPS32: { static gdb_byte micromips32_big_breakpoint[] = { 0, 0x5, 0, 0x7 }; static gdb_byte micromips32_little_breakpoint[] = { 0x5, 0, 0x7, 0 }; *size = 4; if (byte_order_for_code == BFD_ENDIAN_BIG) return micromips32_big_breakpoint; else return micromips32_little_breakpoint; } case MIPS_BP_KIND_MIPS32: { static gdb_byte big_breakpoint[] = { 0, 0x5, 0, 0xd }; static gdb_byte little_breakpoint[] = { 0xd, 0, 0x5, 0 }; *size = 4; if (byte_order_for_code == BFD_ENDIAN_BIG) return big_breakpoint; else return little_breakpoint; } default: gdb_assert_not_reached ("unexpected mips breakpoint kind"); }; } /* Return non-zero if the standard MIPS instruction INST has a branch delay slot (i.e. it is a jump or branch instruction). This function is based on mips32_next_pc. */ static int mips32_instruction_has_delay_slot (struct gdbarch *gdbarch, ULONGEST inst) { int op; int rs; int rt; op = itype_op (inst); if ((inst & 0xe0000000) != 0) { rs = itype_rs (inst); rt = itype_rt (inst); return (is_octeon_bbit_op (op, gdbarch) || op >> 2 == 5 /* BEQL, BNEL, BLEZL, BGTZL: bits 0101xx */ || op == 29 /* JALX: bits 011101 */ || (op == 17 && (rs == 8 /* BC1F, BC1FL, BC1T, BC1TL: 010001 01000 */ || (rs == 9 && (rt & 0x2) == 0) /* BC1ANY2F, BC1ANY2T: bits 010001 01001 */ || (rs == 10 && (rt & 0x2) == 0)))); /* BC1ANY4F, BC1ANY4T: bits 010001 01010 */ } else switch (op & 0x07) /* extract bits 28,27,26 */ { case 0: /* SPECIAL */ op = rtype_funct (inst); return (op == 8 /* JR */ || op == 9); /* JALR */ break; /* end SPECIAL */ case 1: /* REGIMM */ rs = itype_rs (inst); rt = itype_rt (inst); /* branch condition */ return ((rt & 0xc) == 0 /* BLTZ, BLTZL, BGEZ, BGEZL: bits 000xx */ /* BLTZAL, BLTZALL, BGEZAL, BGEZALL: 100xx */ || ((rt & 0x1e) == 0x1c && rs == 0)); /* BPOSGE32, BPOSGE64: bits 1110x */ break; /* end REGIMM */ default: /* J, JAL, BEQ, BNE, BLEZ, BGTZ */ return 1; break; } } /* Return non-zero if a standard MIPS instruction at ADDR has a branch delay slot (i.e. it is a jump or branch instruction). */ static int mips32_insn_at_pc_has_delay_slot (struct gdbarch *gdbarch, CORE_ADDR addr) { ULONGEST insn; int status; insn = mips_fetch_instruction (gdbarch, ISA_MIPS, addr, &status); if (status) return 0; return mips32_instruction_has_delay_slot (gdbarch, insn); } /* Return non-zero if the microMIPS instruction INSN, comprising the 16-bit major opcode word in the high 16 bits and any second word in the low 16 bits, has a branch delay slot (i.e. it is a non-compact jump or branch instruction). The instruction must be 32-bit if MUSTBE32 is set or can be any instruction otherwise. */ static int micromips_instruction_has_delay_slot (ULONGEST insn, int mustbe32) { ULONGEST major = insn >> 16; switch (micromips_op (major)) { /* 16-bit instructions. */ case 0x33: /* B16: bits 110011 */ case 0x2b: /* BNEZ16: bits 101011 */ case 0x23: /* BEQZ16: bits 100011 */ return !mustbe32; case 0x11: /* POOL16C: bits 010001 */ return (!mustbe32 && ((b5s5_op (major) == 0xc /* JR16: bits 010001 01100 */ || (b5s5_op (major) & 0x1e) == 0xe))); /* JALR16, JALRS16: bits 010001 0111x */ /* 32-bit instructions. */ case 0x3d: /* JAL: bits 111101 */ case 0x3c: /* JALX: bits 111100 */ case 0x35: /* J: bits 110101 */ case 0x2d: /* BNE: bits 101101 */ case 0x25: /* BEQ: bits 100101 */ case 0x1d: /* JALS: bits 011101 */ return 1; case 0x10: /* POOL32I: bits 010000 */ return ((b5s5_op (major) & 0x1c) == 0x0 /* BLTZ, BLTZAL, BGEZ, BGEZAL: 010000 000xx */ || (b5s5_op (major) & 0x1d) == 0x4 /* BLEZ, BGTZ: bits 010000 001x0 */ || (b5s5_op (major) & 0x1d) == 0x11 /* BLTZALS, BGEZALS: bits 010000 100x1 */ || ((b5s5_op (major) & 0x1e) == 0x14 && (major & 0x3) == 0x0) /* BC2F, BC2T: bits 010000 1010x xxx00 */ || (b5s5_op (major) & 0x1e) == 0x1a /* BPOSGE64, BPOSGE32: bits 010000 1101x */ || ((b5s5_op (major) & 0x1e) == 0x1c && (major & 0x3) == 0x0) /* BC1F, BC1T: bits 010000 1110x xxx00 */ || ((b5s5_op (major) & 0x1c) == 0x1c && (major & 0x3) == 0x1)); /* BC1ANY*: bits 010000 111xx xxx01 */ case 0x0: /* POOL32A: bits 000000 */ return (b0s6_op (insn) == 0x3c /* POOL32Axf: bits 000000 ... 111100 */ && (b6s10_ext (insn) & 0x2bf) == 0x3c); /* JALR, JALR.HB: 000000 000x111100 111100 */ /* JALRS, JALRS.HB: 000000 010x111100 111100 */ default: return 0; } } /* Return non-zero if a microMIPS instruction at ADDR has a branch delay slot (i.e. it is a non-compact jump instruction). The instruction must be 32-bit if MUSTBE32 is set or can be any instruction otherwise. */ static int micromips_insn_at_pc_has_delay_slot (struct gdbarch *gdbarch, CORE_ADDR addr, int mustbe32) { ULONGEST insn; int status; int size; insn = mips_fetch_instruction (gdbarch, ISA_MICROMIPS, addr, &status); if (status) return 0; size = mips_insn_size (ISA_MICROMIPS, insn); insn <<= 16; if (size == 2 * MIPS_INSN16_SIZE) { insn |= mips_fetch_instruction (gdbarch, ISA_MICROMIPS, addr, &status); if (status) return 0; } return micromips_instruction_has_delay_slot (insn, mustbe32); } /* Return non-zero if the MIPS16 instruction INST, which must be a 32-bit instruction if MUSTBE32 is set or can be any instruction otherwise, has a branch delay slot (i.e. it is a non-compact jump instruction). This function is based on mips16_next_pc. */ static int mips16_instruction_has_delay_slot (unsigned short inst, int mustbe32) { if ((inst & 0xf89f) == 0xe800) /* JR/JALR (16-bit instruction) */ return !mustbe32; return (inst & 0xf800) == 0x1800; /* JAL/JALX (32-bit instruction) */ } /* Return non-zero if a MIPS16 instruction at ADDR has a branch delay slot (i.e. it is a non-compact jump instruction). The instruction must be 32-bit if MUSTBE32 is set or can be any instruction otherwise. */ static int mips16_insn_at_pc_has_delay_slot (struct gdbarch *gdbarch, CORE_ADDR addr, int mustbe32) { unsigned short insn; int status; insn = mips_fetch_instruction (gdbarch, ISA_MIPS16, addr, &status); if (status) return 0; return mips16_instruction_has_delay_slot (insn, mustbe32); } /* Calculate the starting address of the MIPS memory segment BPADDR is in. This assumes KSSEG exists. */ static CORE_ADDR mips_segment_boundary (CORE_ADDR bpaddr) { CORE_ADDR mask = CORE_ADDR_MAX; int segsize; if (sizeof (CORE_ADDR) == 8) /* Get the topmost two bits of bpaddr in a 32-bit safe manner (avoid a compiler warning produced where CORE_ADDR is a 32-bit type even though in that case this is dead code). */ switch (bpaddr >> ((sizeof (CORE_ADDR) << 3) - 2) & 3) { case 3: if (bpaddr == (bfd_signed_vma) (int32_t) bpaddr) segsize = 29; /* 32-bit compatibility segment */ else segsize = 62; /* xkseg */ break; case 2: /* xkphys */ segsize = 59; break; default: /* xksseg (1), xkuseg/kuseg (0) */ segsize = 62; break; } else if (bpaddr & 0x80000000) /* kernel segment */ segsize = 29; else segsize = 31; /* user segment */ mask <<= segsize; return bpaddr & mask; } /* Move the breakpoint at BPADDR out of any branch delay slot by shifting it backwards if necessary. Return the address of the new location. */ static CORE_ADDR mips_adjust_breakpoint_address (struct gdbarch *gdbarch, CORE_ADDR bpaddr) { CORE_ADDR prev_addr; CORE_ADDR boundary; CORE_ADDR func_addr; /* If a breakpoint is set on the instruction in a branch delay slot, GDB gets confused. When the breakpoint is hit, the PC isn't on the instruction in the branch delay slot, the PC will point to the branch instruction. Since the PC doesn't match any known breakpoints, GDB reports a trap exception. There are two possible fixes for this problem. 1) When the breakpoint gets hit, see if the BD bit is set in the Cause register (which indicates the last exception occurred in a branch delay slot). If the BD bit is set, fix the PC to point to the instruction in the branch delay slot. 2) When the user sets the breakpoint, don't allow him to set the breakpoint on the instruction in the branch delay slot. Instead move the breakpoint to the branch instruction (which will have the same result). The problem with the first solution is that if the user then single-steps the processor, the branch instruction will get skipped (since GDB thinks the PC is on the instruction in the branch delay slot). So, we'll use the second solution. To do this we need to know if the instruction we're trying to set the breakpoint on is in the branch delay slot. */ boundary = mips_segment_boundary (bpaddr); /* Make sure we don't scan back before the beginning of the current function, since we may fetch constant data or insns that look like a jump. Of course we might do that anyway if the compiler has moved constants inline. :-( */ if (find_pc_partial_function (bpaddr, NULL, &func_addr, NULL) && func_addr > boundary && func_addr <= bpaddr) boundary = func_addr; if (mips_pc_is_mips (bpaddr)) { if (bpaddr == boundary) return bpaddr; /* If the previous instruction has a branch delay slot, we have to move the breakpoint to the branch instruction. */ prev_addr = bpaddr - 4; if (mips32_insn_at_pc_has_delay_slot (gdbarch, prev_addr)) bpaddr = prev_addr; } else { int (*insn_at_pc_has_delay_slot) (struct gdbarch *, CORE_ADDR, int); CORE_ADDR addr, jmpaddr; int i; boundary = unmake_compact_addr (boundary); /* The only MIPS16 instructions with delay slots are JAL, JALX, JALR and JR. An absolute JAL/JALX is always 4 bytes long, so try for that first, then try the 2 byte JALR/JR. The microMIPS ASE has a whole range of jumps and branches with delay slots, some of which take 4 bytes and some take 2 bytes, so the idea is the same. FIXME: We have to assume that bpaddr is not the second half of an extended instruction. */ insn_at_pc_has_delay_slot = (mips_pc_is_micromips (gdbarch, bpaddr) ? micromips_insn_at_pc_has_delay_slot : mips16_insn_at_pc_has_delay_slot); jmpaddr = 0; addr = bpaddr; for (i = 1; i < 4; i++) { if (unmake_compact_addr (addr) == boundary) break; addr -= MIPS_INSN16_SIZE; if (i == 1 && insn_at_pc_has_delay_slot (gdbarch, addr, 0)) /* Looks like a JR/JALR at [target-1], but it could be the second word of a previous JAL/JALX, so record it and check back one more. */ jmpaddr = addr; else if (i > 1 && insn_at_pc_has_delay_slot (gdbarch, addr, 1)) { if (i == 2) /* Looks like a JAL/JALX at [target-2], but it could also be the second word of a previous JAL/JALX, record it, and check back one more. */ jmpaddr = addr; else /* Looks like a JAL/JALX at [target-3], so any previously recorded JAL/JALX or JR/JALR must be wrong, because: >-3: JAL -2: JAL-ext (can't be JAL/JALX) -1: bdslot (can't be JR/JALR) 0: target insn Of course it could be another JAL-ext which looks like a JAL, but in that case we'd have broken out of this loop at [target-2]: -4: JAL >-3: JAL-ext -2: bdslot (can't be jmp) -1: JR/JALR 0: target insn */ jmpaddr = 0; } else { /* Not a jump instruction: if we're at [target-1] this could be the second word of a JAL/JALX, so continue; otherwise we're done. */ if (i > 1) break; } } if (jmpaddr) bpaddr = jmpaddr; } return bpaddr; } /* Return non-zero if SUFFIX is one of the numeric suffixes used for MIPS16 call stubs, one of 1, 2, 5, 6, 9, 10, or, if ZERO is non-zero, also 0. */ static int mips_is_stub_suffix (const char *suffix, int zero) { switch (suffix[0]) { case '0': return zero && suffix[1] == '\0'; case '1': return suffix[1] == '\0' || (suffix[1] == '0' && suffix[2] == '\0'); case '2': case '5': case '6': case '9': return suffix[1] == '\0'; default: return 0; } } /* Return non-zero if MODE is one of the mode infixes used for MIPS16 call stubs, one of sf, df, sc, or dc. */ static int mips_is_stub_mode (const char *mode) { return ((mode[0] == 's' || mode[0] == 'd') && (mode[1] == 'f' || mode[1] == 'c')); } /* Code at PC is a compiler-generated stub. Such a stub for a function bar might have a name like __fn_stub_bar, and might look like this: mfc1 $4, $f13 mfc1 $5, $f12 mfc1 $6, $f15 mfc1 $7, $f14 followed by (or interspersed with): j bar or: lui $25, %hi(bar) addiu $25, $25, %lo(bar) jr $25 ($1 may be used in old code; for robustness we accept any register) or, in PIC code: lui $28, %hi(_gp_disp) addiu $28, $28, %lo(_gp_disp) addu $28, $28, $25 lw $25, %got(bar) addiu $25, $25, %lo(bar) jr $25 In the case of a __call_stub_bar stub, the sequence to set up arguments might look like this: mtc1 $4, $f13 mtc1 $5, $f12 mtc1 $6, $f15 mtc1 $7, $f14 followed by (or interspersed with) one of the jump sequences above. In the case of a __call_stub_fp_bar stub, JAL or JALR is used instead of J or JR, respectively, followed by: mfc1 $2, $f0 mfc1 $3, $f1 jr $18 We are at the beginning of the stub here, and scan down and extract the target address from the jump immediate instruction or, if a jump register instruction is used, from the register referred. Return the value of PC calculated or 0 if inconclusive. The limit on the search is arbitrarily set to 20 instructions. FIXME. */ static CORE_ADDR mips_get_mips16_fn_stub_pc (struct frame_info *frame, CORE_ADDR pc) { struct gdbarch *gdbarch = get_frame_arch (frame); enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); int addrreg = MIPS_ZERO_REGNUM; CORE_ADDR start_pc = pc; CORE_ADDR target_pc = 0; CORE_ADDR addr = 0; CORE_ADDR gp = 0; int status = 0; int i; for (i = 0; status == 0 && target_pc == 0 && i < 20; i++, pc += MIPS_INSN32_SIZE) { ULONGEST inst = mips_fetch_instruction (gdbarch, ISA_MIPS, pc, NULL); CORE_ADDR imm; int rt; int rs; int rd; switch (itype_op (inst)) { case 0: /* SPECIAL */ switch (rtype_funct (inst)) { case 8: /* JR */ case 9: /* JALR */ rs = rtype_rs (inst); if (rs == MIPS_GP_REGNUM) target_pc = gp; /* Hmm... */ else if (rs == addrreg) target_pc = addr; break; case 0x21: /* ADDU */ rt = rtype_rt (inst); rs = rtype_rs (inst); rd = rtype_rd (inst); if (rd == MIPS_GP_REGNUM && ((rs == MIPS_GP_REGNUM && rt == MIPS_T9_REGNUM) || (rs == MIPS_T9_REGNUM && rt == MIPS_GP_REGNUM))) gp += start_pc; break; } break; case 2: /* J */ case 3: /* JAL */ target_pc = jtype_target (inst) << 2; target_pc += ((pc + 4) & ~(CORE_ADDR) 0x0fffffff); break; case 9: /* ADDIU */ rt = itype_rt (inst); rs = itype_rs (inst); if (rt == rs) { imm = (itype_immediate (inst) ^ 0x8000) - 0x8000; if (rt == MIPS_GP_REGNUM) gp += imm; else if (rt == addrreg) addr += imm; } break; case 0xf: /* LUI */ rt = itype_rt (inst); imm = ((itype_immediate (inst) ^ 0x8000) - 0x8000) << 16; if (rt == MIPS_GP_REGNUM) gp = imm; else if (rt != MIPS_ZERO_REGNUM) { addrreg = rt; addr = imm; } break; case 0x23: /* LW */ rt = itype_rt (inst); rs = itype_rs (inst); imm = (itype_immediate (inst) ^ 0x8000) - 0x8000; if (gp != 0 && rs == MIPS_GP_REGNUM) { gdb_byte buf[4]; memset (buf, 0, sizeof (buf)); status = target_read_memory (gp + imm, buf, sizeof (buf)); addrreg = rt; addr = extract_signed_integer (buf, sizeof (buf), byte_order); } break; } } return target_pc; } /* If PC is in a MIPS16 call or return stub, return the address of the target PC, which is either the callee or the caller. There are several cases which must be handled: * If the PC is in __mips16_ret_{d,s}{f,c}, this is a return stub and the target PC is in $31 ($ra). * If the PC is in __mips16_call_stub_{1..10}, this is a call stub and the target PC is in $2. * If the PC at the start of __mips16_call_stub_{s,d}{f,c}_{0..10}, i.e. before the JALR instruction, this is effectively a call stub and the target PC is in $2. Otherwise this is effectively a return stub and the target PC is in $18. * If the PC is at the start of __call_stub_fp_*, i.e. before the JAL or JALR instruction, this is effectively a call stub and the target PC is buried in the instruction stream. Otherwise this is effectively a return stub and the target PC is in $18. * If the PC is in __call_stub_* or in __fn_stub_*, this is a call stub and the target PC is buried in the instruction stream. See the source code for the stubs in gcc/config/mips/mips16.S, or the stub builder in gcc/config/mips/mips.c (mips16_build_call_stub) for the gory details. */ static CORE_ADDR mips_skip_mips16_trampoline_code (struct frame_info *frame, CORE_ADDR pc) { struct gdbarch *gdbarch = get_frame_arch (frame); CORE_ADDR start_addr; const char *name; size_t prefixlen; /* Find the starting address and name of the function containing the PC. */ if (find_pc_partial_function (pc, &name, &start_addr, NULL) == 0) return 0; /* If the PC is in __mips16_ret_{d,s}{f,c}, this is a return stub and the target PC is in $31 ($ra). */ prefixlen = strlen (mips_str_mips16_ret_stub); if (strncmp (name, mips_str_mips16_ret_stub, prefixlen) == 0 && mips_is_stub_mode (name + prefixlen) && name[prefixlen + 2] == '\0') return get_frame_register_signed (frame, gdbarch_num_regs (gdbarch) + MIPS_RA_REGNUM); /* If the PC is in __mips16_call_stub_*, this is one of the call call/return stubs. */ prefixlen = strlen (mips_str_mips16_call_stub); if (strncmp (name, mips_str_mips16_call_stub, prefixlen) == 0) { /* If the PC is in __mips16_call_stub_{1..10}, this is a call stub and the target PC is in $2. */ if (mips_is_stub_suffix (name + prefixlen, 0)) return get_frame_register_signed (frame, gdbarch_num_regs (gdbarch) + MIPS_V0_REGNUM); /* If the PC at the start of __mips16_call_stub_{s,d}{f,c}_{0..10}, i.e. before the JALR instruction, this is effectively a call stub and the target PC is in $2. Otherwise this is effectively a return stub and the target PC is in $18. */ else if (mips_is_stub_mode (name + prefixlen) && name[prefixlen + 2] == '_' && mips_is_stub_suffix (name + prefixlen + 3, 0)) { if (pc == start_addr) /* This is the 'call' part of a call stub. The return address is in $2. */ return get_frame_register_signed (frame, gdbarch_num_regs (gdbarch) + MIPS_V0_REGNUM); else /* This is the 'return' part of a call stub. The return address is in $18. */ return get_frame_register_signed (frame, gdbarch_num_regs (gdbarch) + MIPS_S2_REGNUM); } else return 0; /* Not a stub. */ } /* If the PC is in __call_stub_* or __fn_stub*, this is one of the compiler-generated call or call/return stubs. */ if (startswith (name, mips_str_fn_stub) || startswith (name, mips_str_call_stub)) { if (pc == start_addr) /* This is the 'call' part of a call stub. Call this helper to scan through this code for interesting instructions and determine the final PC. */ return mips_get_mips16_fn_stub_pc (frame, pc); else /* This is the 'return' part of a call stub. The return address is in $18. */ return get_frame_register_signed (frame, gdbarch_num_regs (gdbarch) + MIPS_S2_REGNUM); } return 0; /* Not a stub. */ } /* Return non-zero if the PC is inside a return thunk (aka stub or trampoline). This implements the IN_SOLIB_RETURN_TRAMPOLINE macro. */ static int mips_in_return_stub (struct gdbarch *gdbarch, CORE_ADDR pc, const char *name) { CORE_ADDR start_addr; size_t prefixlen; /* Find the starting address of the function containing the PC. */ if (find_pc_partial_function (pc, NULL, &start_addr, NULL) == 0) return 0; /* If the PC is in __mips16_call_stub_{s,d}{f,c}_{0..10} but not at the start, i.e. after the JALR instruction, this is effectively a return stub. */ prefixlen = strlen (mips_str_mips16_call_stub); if (pc != start_addr && strncmp (name, mips_str_mips16_call_stub, prefixlen) == 0 && mips_is_stub_mode (name + prefixlen) && name[prefixlen + 2] == '_' && mips_is_stub_suffix (name + prefixlen + 3, 1)) return 1; /* If the PC is in __call_stub_fp_* but not at the start, i.e. after the JAL or JALR instruction, this is effectively a return stub. */ prefixlen = strlen (mips_str_call_fp_stub); if (pc != start_addr && strncmp (name, mips_str_call_fp_stub, prefixlen) == 0) return 1; /* Consume the .pic. prefix of any PIC stub, this function must return true when the PC is in a PIC stub of a __mips16_ret_{d,s}{f,c} stub or the call stub path will trigger in handle_inferior_event causing it to go astray. */ prefixlen = strlen (mips_str_pic); if (strncmp (name, mips_str_pic, prefixlen) == 0) name += prefixlen; /* If the PC is in __mips16_ret_{d,s}{f,c}, this is a return stub. */ prefixlen = strlen (mips_str_mips16_ret_stub); if (strncmp (name, mips_str_mips16_ret_stub, prefixlen) == 0 && mips_is_stub_mode (name + prefixlen) && name[prefixlen + 2] == '\0') return 1; return 0; /* Not a stub. */ } /* If the current PC is the start of a non-PIC-to-PIC stub, return the PC of the stub target. The stub just loads $t9 and jumps to it, so that $t9 has the correct value at function entry. */ static CORE_ADDR mips_skip_pic_trampoline_code (struct frame_info *frame, CORE_ADDR pc) { struct gdbarch *gdbarch = get_frame_arch (frame); enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); struct bound_minimal_symbol msym; int i; gdb_byte stub_code[16]; int32_t stub_words[4]; /* The stub for foo is named ".pic.foo", and is either two instructions inserted before foo or a three instruction sequence which jumps to foo. */ msym = lookup_minimal_symbol_by_pc (pc); if (msym.minsym == NULL || BMSYMBOL_VALUE_ADDRESS (msym) != pc || msym.minsym->linkage_name () == NULL || !startswith (msym.minsym->linkage_name (), ".pic.")) return 0; /* A two-instruction header. */ if (MSYMBOL_SIZE (msym.minsym) == 8) return pc + 8; /* A three-instruction (plus delay slot) trampoline. */ if (MSYMBOL_SIZE (msym.minsym) == 16) { if (target_read_memory (pc, stub_code, 16) != 0) return 0; for (i = 0; i < 4; i++) stub_words[i] = extract_unsigned_integer (stub_code + i * 4, 4, byte_order); /* A stub contains these instructions: lui t9, %hi(target) j target addiu t9, t9, %lo(target) nop This works even for N64, since stubs are only generated with -msym32. */ if ((stub_words[0] & 0xffff0000U) == 0x3c190000 && (stub_words[1] & 0xfc000000U) == 0x08000000 && (stub_words[2] & 0xffff0000U) == 0x27390000 && stub_words[3] == 0x00000000) return ((((stub_words[0] & 0x0000ffff) << 16) + (stub_words[2] & 0x0000ffff)) ^ 0x8000) - 0x8000; } /* Not a recognized stub. */ return 0; } static CORE_ADDR mips_skip_trampoline_code (struct frame_info *frame, CORE_ADDR pc) { CORE_ADDR requested_pc = pc; CORE_ADDR target_pc; CORE_ADDR new_pc; do { target_pc = pc; new_pc = mips_skip_mips16_trampoline_code (frame, pc); if (new_pc) pc = new_pc; new_pc = find_solib_trampoline_target (frame, pc); if (new_pc) pc = new_pc; new_pc = mips_skip_pic_trampoline_code (frame, pc); if (new_pc) pc = new_pc; } while (pc != target_pc); return pc != requested_pc ? pc : 0; } /* Convert a dbx stab register number (from `r' declaration) to a GDB [1 * gdbarch_num_regs .. 2 * gdbarch_num_regs) REGNUM. */ static int mips_stab_reg_to_regnum (struct gdbarch *gdbarch, int num) { int regnum; if (num >= 0 && num < 32) regnum = num; else if (num >= 38 && num < 70) regnum = num + mips_regnum (gdbarch)->fp0 - 38; else if (num == 70) regnum = mips_regnum (gdbarch)->hi; else if (num == 71) regnum = mips_regnum (gdbarch)->lo; else if (mips_regnum (gdbarch)->dspacc != -1 && num >= 72 && num < 78) regnum = num + mips_regnum (gdbarch)->dspacc - 72; else return -1; return gdbarch_num_regs (gdbarch) + regnum; } /* Convert a dwarf, dwarf2, or ecoff register number to a GDB [1 * gdbarch_num_regs .. 2 * gdbarch_num_regs) REGNUM. */ static int mips_dwarf_dwarf2_ecoff_reg_to_regnum (struct gdbarch *gdbarch, int num) { int regnum; if (num >= 0 && num < 32) regnum = num; else if (num >= 32 && num < 64) regnum = num + mips_regnum (gdbarch)->fp0 - 32; else if (num == 64) regnum = mips_regnum (gdbarch)->hi; else if (num == 65) regnum = mips_regnum (gdbarch)->lo; else if (mips_regnum (gdbarch)->dspacc != -1 && num >= 66 && num < 72) regnum = num + mips_regnum (gdbarch)->dspacc - 66; else return -1; return gdbarch_num_regs (gdbarch) + regnum; } static int mips_register_sim_regno (struct gdbarch *gdbarch, int regnum) { /* Only makes sense to supply raw registers. */ gdb_assert (regnum >= 0 && regnum < gdbarch_num_regs (gdbarch)); /* FIXME: cagney/2002-05-13: Need to look at the pseudo register to decide if it is valid. Should instead define a standard sim/gdb register numbering scheme. */ if (gdbarch_register_name (gdbarch, gdbarch_num_regs (gdbarch) + regnum) != NULL && gdbarch_register_name (gdbarch, gdbarch_num_regs (gdbarch) + regnum)[0] != '\0') return regnum; else return LEGACY_SIM_REGNO_IGNORE; } /* Convert an integer into an address. Extracting the value signed guarantees a correctly sign extended address. */ static CORE_ADDR mips_integer_to_address (struct gdbarch *gdbarch, struct type *type, const gdb_byte *buf) { enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); return extract_signed_integer (buf, TYPE_LENGTH (type), byte_order); } /* Dummy virtual frame pointer method. This is no more or less accurate than most other architectures; we just need to be explicit about it, because the pseudo-register gdbarch_sp_regnum will otherwise lead to an assertion failure. */ static void mips_virtual_frame_pointer (struct gdbarch *gdbarch, CORE_ADDR pc, int *reg, LONGEST *offset) { *reg = MIPS_SP_REGNUM; *offset = 0; } static void mips_find_abi_section (bfd *abfd, asection *sect, void *obj) { enum mips_abi *abip = (enum mips_abi *) obj; const char *name = bfd_section_name (sect); if (*abip != MIPS_ABI_UNKNOWN) return; if (!startswith (name, ".mdebug.")) return; if (strcmp (name, ".mdebug.abi32") == 0) *abip = MIPS_ABI_O32; else if (strcmp (name, ".mdebug.abiN32") == 0) *abip = MIPS_ABI_N32; else if (strcmp (name, ".mdebug.abi64") == 0) *abip = MIPS_ABI_N64; else if (strcmp (name, ".mdebug.abiO64") == 0) *abip = MIPS_ABI_O64; else if (strcmp (name, ".mdebug.eabi32") == 0) *abip = MIPS_ABI_EABI32; else if (strcmp (name, ".mdebug.eabi64") == 0) *abip = MIPS_ABI_EABI64; else warning (_("unsupported ABI %s."), name + 8); } static void mips_find_long_section (bfd *abfd, asection *sect, void *obj) { int *lbp = (int *) obj; const char *name = bfd_section_name (sect); if (startswith (name, ".gcc_compiled_long32")) *lbp = 32; else if (startswith (name, ".gcc_compiled_long64")) *lbp = 64; else if (startswith (name, ".gcc_compiled_long")) warning (_("unrecognized .gcc_compiled_longXX")); } static enum mips_abi global_mips_abi (void) { int i; for (i = 0; mips_abi_strings[i] != NULL; i++) if (mips_abi_strings[i] == mips_abi_string) return (enum mips_abi) i; internal_error (__FILE__, __LINE__, _("unknown ABI string")); } /* Return the default compressed instruction set, either of MIPS16 or microMIPS, selected when none could have been determined from the ELF header of the binary being executed (or no binary has been selected. */ static enum mips_isa global_mips_compression (void) { int i; for (i = 0; mips_compression_strings[i] != NULL; i++) if (mips_compression_strings[i] == mips_compression_string) return (enum mips_isa) i; internal_error (__FILE__, __LINE__, _("unknown compressed ISA string")); } static void mips_register_g_packet_guesses (struct gdbarch *gdbarch) { /* If the size matches the set of 32-bit or 64-bit integer registers, assume that's what we've got. */ register_remote_g_packet_guess (gdbarch, 38 * 4, mips_tdesc_gp32); register_remote_g_packet_guess (gdbarch, 38 * 8, mips_tdesc_gp64); /* If the size matches the full set of registers GDB traditionally knows about, including floating point, for either 32-bit or 64-bit, assume that's what we've got. */ register_remote_g_packet_guess (gdbarch, 90 * 4, mips_tdesc_gp32); register_remote_g_packet_guess (gdbarch, 90 * 8, mips_tdesc_gp64); /* Otherwise we don't have a useful guess. */ } static struct value * value_of_mips_user_reg (struct frame_info *frame, const void *baton) { const int *reg_p = (const int *) baton; return value_of_register (*reg_p, frame); } static struct gdbarch * mips_gdbarch_init (struct gdbarch_info info, struct gdbarch_list *arches) { struct gdbarch *gdbarch; struct gdbarch_tdep *tdep; int elf_flags; enum mips_abi mips_abi, found_abi, wanted_abi; int i, num_regs; enum mips_fpu_type fpu_type; struct tdesc_arch_data *tdesc_data = NULL; int elf_fpu_type = Val_GNU_MIPS_ABI_FP_ANY; const char **reg_names; struct mips_regnum mips_regnum, *regnum; enum mips_isa mips_isa; int dspacc; int dspctl; /* First of all, extract the elf_flags, if available. */ if (info.abfd && bfd_get_flavour (info.abfd) == bfd_target_elf_flavour) elf_flags = elf_elfheader (info.abfd)->e_flags; else if (arches != NULL) elf_flags = gdbarch_tdep (arches->gdbarch)->elf_flags; else elf_flags = 0; if (gdbarch_debug) fprintf_unfiltered (gdb_stdlog, "mips_gdbarch_init: elf_flags = 0x%08x\n", elf_flags); /* Check ELF_FLAGS to see if it specifies the ABI being used. */ switch ((elf_flags & EF_MIPS_ABI)) { case E_MIPS_ABI_O32: found_abi = MIPS_ABI_O32; break; case E_MIPS_ABI_O64: found_abi = MIPS_ABI_O64; break; case E_MIPS_ABI_EABI32: found_abi = MIPS_ABI_EABI32; break; case E_MIPS_ABI_EABI64: found_abi = MIPS_ABI_EABI64; break; default: if ((elf_flags & EF_MIPS_ABI2)) found_abi = MIPS_ABI_N32; else found_abi = MIPS_ABI_UNKNOWN; break; } /* GCC creates a pseudo-section whose name describes the ABI. */ if (found_abi == MIPS_ABI_UNKNOWN && info.abfd != NULL) bfd_map_over_sections (info.abfd, mips_find_abi_section, &found_abi); /* If we have no useful BFD information, use the ABI from the last MIPS architecture (if there is one). */ if (found_abi == MIPS_ABI_UNKNOWN && info.abfd == NULL && arches != NULL) found_abi = gdbarch_tdep (arches->gdbarch)->found_abi; /* Try the architecture for any hint of the correct ABI. */ if (found_abi == MIPS_ABI_UNKNOWN && info.bfd_arch_info != NULL && info.bfd_arch_info->arch == bfd_arch_mips) { switch (info.bfd_arch_info->mach) { case bfd_mach_mips3900: found_abi = MIPS_ABI_EABI32; break; case bfd_mach_mips4100: case bfd_mach_mips5000: found_abi = MIPS_ABI_EABI64; break; case bfd_mach_mips8000: case bfd_mach_mips10000: /* On Irix, ELF64 executables use the N64 ABI. The pseudo-sections which describe the ABI aren't present on IRIX. (Even for executables created by gcc.) */ if (info.abfd != NULL && bfd_get_flavour (info.abfd) == bfd_target_elf_flavour && elf_elfheader (info.abfd)->e_ident[EI_CLASS] == ELFCLASS64) found_abi = MIPS_ABI_N64; else found_abi = MIPS_ABI_N32; break; } } /* Default 64-bit objects to N64 instead of O32. */ if (found_abi == MIPS_ABI_UNKNOWN && info.abfd != NULL && bfd_get_flavour (info.abfd) == bfd_target_elf_flavour && elf_elfheader (info.abfd)->e_ident[EI_CLASS] == ELFCLASS64) found_abi = MIPS_ABI_N64; if (gdbarch_debug) fprintf_unfiltered (gdb_stdlog, "mips_gdbarch_init: found_abi = %d\n", found_abi); /* What has the user specified from the command line? */ wanted_abi = global_mips_abi (); if (gdbarch_debug) fprintf_unfiltered (gdb_stdlog, "mips_gdbarch_init: wanted_abi = %d\n", wanted_abi); /* Now that we have found what the ABI for this binary would be, check whether the user is overriding it. */ if (wanted_abi != MIPS_ABI_UNKNOWN) mips_abi = wanted_abi; else if (found_abi != MIPS_ABI_UNKNOWN) mips_abi = found_abi; else mips_abi = MIPS_ABI_O32; if (gdbarch_debug) fprintf_unfiltered (gdb_stdlog, "mips_gdbarch_init: mips_abi = %d\n", mips_abi); /* Make sure we don't use a 32-bit architecture with a 64-bit ABI. */ if (mips_abi != MIPS_ABI_EABI32 && mips_abi != MIPS_ABI_O32 && info.bfd_arch_info != NULL && info.bfd_arch_info->arch == bfd_arch_mips && info.bfd_arch_info->bits_per_word < 64) info.bfd_arch_info = bfd_lookup_arch (bfd_arch_mips, bfd_mach_mips4000); /* Determine the default compressed ISA. */ if ((elf_flags & EF_MIPS_ARCH_ASE_MICROMIPS) != 0 && (elf_flags & EF_MIPS_ARCH_ASE_M16) == 0) mips_isa = ISA_MICROMIPS; else if ((elf_flags & EF_MIPS_ARCH_ASE_M16) != 0 && (elf_flags & EF_MIPS_ARCH_ASE_MICROMIPS) == 0) mips_isa = ISA_MIPS16; else mips_isa = global_mips_compression (); mips_compression_string = mips_compression_strings[mips_isa]; /* Also used when doing an architecture lookup. */ if (gdbarch_debug) fprintf_unfiltered (gdb_stdlog, "mips_gdbarch_init: " "mips64_transfers_32bit_regs_p = %d\n", mips64_transfers_32bit_regs_p); /* Determine the MIPS FPU type. */ #ifdef HAVE_ELF if (info.abfd && bfd_get_flavour (info.abfd) == bfd_target_elf_flavour) elf_fpu_type = bfd_elf_get_obj_attr_int (info.abfd, OBJ_ATTR_GNU, Tag_GNU_MIPS_ABI_FP); #endif /* HAVE_ELF */ if (!mips_fpu_type_auto) fpu_type = mips_fpu_type; else if (elf_fpu_type != Val_GNU_MIPS_ABI_FP_ANY) { switch (elf_fpu_type) { case Val_GNU_MIPS_ABI_FP_DOUBLE: fpu_type = MIPS_FPU_DOUBLE; break; case Val_GNU_MIPS_ABI_FP_SINGLE: fpu_type = MIPS_FPU_SINGLE; break; case Val_GNU_MIPS_ABI_FP_SOFT: default: /* Soft float or unknown. */ fpu_type = MIPS_FPU_NONE; break; } } else if (info.bfd_arch_info != NULL && info.bfd_arch_info->arch == bfd_arch_mips) switch (info.bfd_arch_info->mach) { case bfd_mach_mips3900: case bfd_mach_mips4100: case bfd_mach_mips4111: case bfd_mach_mips4120: fpu_type = MIPS_FPU_NONE; break; case bfd_mach_mips4650: fpu_type = MIPS_FPU_SINGLE; break; default: fpu_type = MIPS_FPU_DOUBLE; break; } else if (arches != NULL) fpu_type = MIPS_FPU_TYPE (arches->gdbarch); else fpu_type = MIPS_FPU_DOUBLE; if (gdbarch_debug) fprintf_unfiltered (gdb_stdlog, "mips_gdbarch_init: fpu_type = %d\n", fpu_type); /* Check for blatant incompatibilities. */ /* If we have only 32-bit registers, then we can't debug a 64-bit ABI. */ if (info.target_desc && tdesc_property (info.target_desc, PROPERTY_GP32) != NULL && mips_abi != MIPS_ABI_EABI32 && mips_abi != MIPS_ABI_O32) return NULL; /* Fill in the OS dependent register numbers and names. */ if (info.osabi == GDB_OSABI_LINUX) { mips_regnum.fp0 = 38; mips_regnum.pc = 37; mips_regnum.cause = 36; mips_regnum.badvaddr = 35; mips_regnum.hi = 34; mips_regnum.lo = 33; mips_regnum.fp_control_status = 70; mips_regnum.fp_implementation_revision = 71; mips_regnum.dspacc = -1; mips_regnum.dspctl = -1; dspacc = 72; dspctl = 78; num_regs = 90; reg_names = mips_linux_reg_names; } else { mips_regnum.lo = MIPS_EMBED_LO_REGNUM; mips_regnum.hi = MIPS_EMBED_HI_REGNUM; mips_regnum.badvaddr = MIPS_EMBED_BADVADDR_REGNUM; mips_regnum.cause = MIPS_EMBED_CAUSE_REGNUM; mips_regnum.pc = MIPS_EMBED_PC_REGNUM; mips_regnum.fp0 = MIPS_EMBED_FP0_REGNUM; mips_regnum.fp_control_status = 70; mips_regnum.fp_implementation_revision = 71; mips_regnum.dspacc = dspacc = -1; mips_regnum.dspctl = dspctl = -1; num_regs = MIPS_LAST_EMBED_REGNUM + 1; if (info.bfd_arch_info != NULL && info.bfd_arch_info->mach == bfd_mach_mips3900) reg_names = mips_tx39_reg_names; else reg_names = mips_generic_reg_names; } /* Check any target description for validity. */ if (tdesc_has_registers (info.target_desc)) { static const char *const mips_gprs[] = { "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15", "r16", "r17", "r18", "r19", "r20", "r21", "r22", "r23", "r24", "r25", "r26", "r27", "r28", "r29", "r30", "r31" }; static const char *const mips_fprs[] = { "f0", "f1", "f2", "f3", "f4", "f5", "f6", "f7", "f8", "f9", "f10", "f11", "f12", "f13", "f14", "f15", "f16", "f17", "f18", "f19", "f20", "f21", "f22", "f23", "f24", "f25", "f26", "f27", "f28", "f29", "f30", "f31", }; const struct tdesc_feature *feature; int valid_p; feature = tdesc_find_feature (info.target_desc, "org.gnu.gdb.mips.cpu"); if (feature == NULL) return NULL; tdesc_data = tdesc_data_alloc (); valid_p = 1; for (i = MIPS_ZERO_REGNUM; i <= MIPS_RA_REGNUM; i++) valid_p &= tdesc_numbered_register (feature, tdesc_data, i, mips_gprs[i]); valid_p &= tdesc_numbered_register (feature, tdesc_data, mips_regnum.lo, "lo"); valid_p &= tdesc_numbered_register (feature, tdesc_data, mips_regnum.hi, "hi"); valid_p &= tdesc_numbered_register (feature, tdesc_data, mips_regnum.pc, "pc"); if (!valid_p) { tdesc_data_cleanup (tdesc_data); return NULL; } feature = tdesc_find_feature (info.target_desc, "org.gnu.gdb.mips.cp0"); if (feature == NULL) { tdesc_data_cleanup (tdesc_data); return NULL; } valid_p = 1; valid_p &= tdesc_numbered_register (feature, tdesc_data, mips_regnum.badvaddr, "badvaddr"); valid_p &= tdesc_numbered_register (feature, tdesc_data, MIPS_PS_REGNUM, "status"); valid_p &= tdesc_numbered_register (feature, tdesc_data, mips_regnum.cause, "cause"); if (!valid_p) { tdesc_data_cleanup (tdesc_data); return NULL; } /* FIXME drow/2007-05-17: The FPU should be optional. The MIPS backend is not prepared for that, though. */ feature = tdesc_find_feature (info.target_desc, "org.gnu.gdb.mips.fpu"); if (feature == NULL) { tdesc_data_cleanup (tdesc_data); return NULL; } valid_p = 1; for (i = 0; i < 32; i++) valid_p &= tdesc_numbered_register (feature, tdesc_data, i + mips_regnum.fp0, mips_fprs[i]); valid_p &= tdesc_numbered_register (feature, tdesc_data, mips_regnum.fp_control_status, "fcsr"); valid_p &= tdesc_numbered_register (feature, tdesc_data, mips_regnum.fp_implementation_revision, "fir"); if (!valid_p) { tdesc_data_cleanup (tdesc_data); return NULL; } num_regs = mips_regnum.fp_implementation_revision + 1; if (dspacc >= 0) { feature = tdesc_find_feature (info.target_desc, "org.gnu.gdb.mips.dsp"); /* The DSP registers are optional; it's OK if they are absent. */ if (feature != NULL) { i = 0; valid_p = 1; valid_p &= tdesc_numbered_register (feature, tdesc_data, dspacc + i++, "hi1"); valid_p &= tdesc_numbered_register (feature, tdesc_data, dspacc + i++, "lo1"); valid_p &= tdesc_numbered_register (feature, tdesc_data, dspacc + i++, "hi2"); valid_p &= tdesc_numbered_register (feature, tdesc_data, dspacc + i++, "lo2"); valid_p &= tdesc_numbered_register (feature, tdesc_data, dspacc + i++, "hi3"); valid_p &= tdesc_numbered_register (feature, tdesc_data, dspacc + i++, "lo3"); valid_p &= tdesc_numbered_register (feature, tdesc_data, dspctl, "dspctl"); if (!valid_p) { tdesc_data_cleanup (tdesc_data); return NULL; } mips_regnum.dspacc = dspacc; mips_regnum.dspctl = dspctl; num_regs = mips_regnum.dspctl + 1; } } /* It would be nice to detect an attempt to use a 64-bit ABI when only 32-bit registers are provided. */ reg_names = NULL; } /* Try to find a pre-existing architecture. */ for (arches = gdbarch_list_lookup_by_info (arches, &info); arches != NULL; arches = gdbarch_list_lookup_by_info (arches->next, &info)) { /* MIPS needs to be pedantic about which ABI and the compressed ISA variation the object is using. */ if (gdbarch_tdep (arches->gdbarch)->elf_flags != elf_flags) continue; if (gdbarch_tdep (arches->gdbarch)->mips_abi != mips_abi) continue; if (gdbarch_tdep (arches->gdbarch)->mips_isa != mips_isa) continue; /* Need to be pedantic about which register virtual size is used. */ if (gdbarch_tdep (arches->gdbarch)->mips64_transfers_32bit_regs_p != mips64_transfers_32bit_regs_p) continue; /* Be pedantic about which FPU is selected. */ if (MIPS_FPU_TYPE (arches->gdbarch) != fpu_type) continue; if (tdesc_data != NULL) tdesc_data_cleanup (tdesc_data); return arches->gdbarch; } /* Need a new architecture. Fill in a target specific vector. */ tdep = XCNEW (struct gdbarch_tdep); gdbarch = gdbarch_alloc (&info, tdep); tdep->elf_flags = elf_flags; tdep->mips64_transfers_32bit_regs_p = mips64_transfers_32bit_regs_p; tdep->found_abi = found_abi; tdep->mips_abi = mips_abi; tdep->mips_isa = mips_isa; tdep->mips_fpu_type = fpu_type; tdep->register_size_valid_p = 0; tdep->register_size = 0; if (info.target_desc) { /* Some useful properties can be inferred from the target. */ if (tdesc_property (info.target_desc, PROPERTY_GP32) != NULL) { tdep->register_size_valid_p = 1; tdep->register_size = 4; } else if (tdesc_property (info.target_desc, PROPERTY_GP64) != NULL) { tdep->register_size_valid_p = 1; tdep->register_size = 8; } } /* Initially set everything according to the default ABI/ISA. */ set_gdbarch_short_bit (gdbarch, 16); set_gdbarch_int_bit (gdbarch, 32); set_gdbarch_float_bit (gdbarch, 32); set_gdbarch_double_bit (gdbarch, 64); set_gdbarch_long_double_bit (gdbarch, 64); set_gdbarch_register_reggroup_p (gdbarch, mips_register_reggroup_p); set_gdbarch_pseudo_register_read (gdbarch, mips_pseudo_register_read); set_gdbarch_pseudo_register_write (gdbarch, mips_pseudo_register_write); set_gdbarch_ax_pseudo_register_collect (gdbarch, mips_ax_pseudo_register_collect); set_gdbarch_ax_pseudo_register_push_stack (gdbarch, mips_ax_pseudo_register_push_stack); set_gdbarch_elf_make_msymbol_special (gdbarch, mips_elf_make_msymbol_special); set_gdbarch_make_symbol_special (gdbarch, mips_make_symbol_special); set_gdbarch_adjust_dwarf2_addr (gdbarch, mips_adjust_dwarf2_addr); set_gdbarch_adjust_dwarf2_line (gdbarch, mips_adjust_dwarf2_line); regnum = GDBARCH_OBSTACK_ZALLOC (gdbarch, struct mips_regnum); *regnum = mips_regnum; set_gdbarch_fp0_regnum (gdbarch, regnum->fp0); set_gdbarch_num_regs (gdbarch, num_regs); set_gdbarch_num_pseudo_regs (gdbarch, num_regs); set_gdbarch_register_name (gdbarch, mips_register_name); set_gdbarch_virtual_frame_pointer (gdbarch, mips_virtual_frame_pointer); tdep->mips_processor_reg_names = reg_names; tdep->regnum = regnum; switch (mips_abi) { case MIPS_ABI_O32: set_gdbarch_push_dummy_call (gdbarch, mips_o32_push_dummy_call); set_gdbarch_return_value (gdbarch, mips_o32_return_value); tdep->mips_last_arg_regnum = MIPS_A0_REGNUM + 4 - 1; tdep->mips_last_fp_arg_regnum = tdep->regnum->fp0 + 12 + 4 - 1; tdep->default_mask_address_p = 0; set_gdbarch_long_bit (gdbarch, 32); set_gdbarch_ptr_bit (gdbarch, 32); set_gdbarch_long_long_bit (gdbarch, 64); break; case MIPS_ABI_O64: set_gdbarch_push_dummy_call (gdbarch, mips_o64_push_dummy_call); set_gdbarch_return_value (gdbarch, mips_o64_return_value); tdep->mips_last_arg_regnum = MIPS_A0_REGNUM + 4 - 1; tdep->mips_last_fp_arg_regnum = tdep->regnum->fp0 + 12 + 4 - 1; tdep->default_mask_address_p = 0; set_gdbarch_long_bit (gdbarch, 32); set_gdbarch_ptr_bit (gdbarch, 32); set_gdbarch_long_long_bit (gdbarch, 64); break; case MIPS_ABI_EABI32: set_gdbarch_push_dummy_call (gdbarch, mips_eabi_push_dummy_call); set_gdbarch_return_value (gdbarch, mips_eabi_return_value); tdep->mips_last_arg_regnum = MIPS_A0_REGNUM + 8 - 1; tdep->mips_last_fp_arg_regnum = tdep->regnum->fp0 + 12 + 8 - 1; tdep->default_mask_address_p = 0; set_gdbarch_long_bit (gdbarch, 32); set_gdbarch_ptr_bit (gdbarch, 32); set_gdbarch_long_long_bit (gdbarch, 64); break; case MIPS_ABI_EABI64: set_gdbarch_push_dummy_call (gdbarch, mips_eabi_push_dummy_call); set_gdbarch_return_value (gdbarch, mips_eabi_return_value); tdep->mips_last_arg_regnum = MIPS_A0_REGNUM + 8 - 1; tdep->mips_last_fp_arg_regnum = tdep->regnum->fp0 + 12 + 8 - 1; tdep->default_mask_address_p = 0; set_gdbarch_long_bit (gdbarch, 64); set_gdbarch_ptr_bit (gdbarch, 64); set_gdbarch_long_long_bit (gdbarch, 64); break; case MIPS_ABI_N32: set_gdbarch_push_dummy_call (gdbarch, mips_n32n64_push_dummy_call); set_gdbarch_return_value (gdbarch, mips_n32n64_return_value); tdep->mips_last_arg_regnum = MIPS_A0_REGNUM + 8 - 1; tdep->mips_last_fp_arg_regnum = tdep->regnum->fp0 + 12 + 8 - 1; tdep->default_mask_address_p = 0; set_gdbarch_long_bit (gdbarch, 32); set_gdbarch_ptr_bit (gdbarch, 32); set_gdbarch_long_long_bit (gdbarch, 64); set_gdbarch_long_double_bit (gdbarch, 128); set_gdbarch_long_double_format (gdbarch, floatformats_ibm_long_double); break; case MIPS_ABI_N64: set_gdbarch_push_dummy_call (gdbarch, mips_n32n64_push_dummy_call); set_gdbarch_return_value (gdbarch, mips_n32n64_return_value); tdep->mips_last_arg_regnum = MIPS_A0_REGNUM + 8 - 1; tdep->mips_last_fp_arg_regnum = tdep->regnum->fp0 + 12 + 8 - 1; tdep->default_mask_address_p = 0; set_gdbarch_long_bit (gdbarch, 64); set_gdbarch_ptr_bit (gdbarch, 64); set_gdbarch_long_long_bit (gdbarch, 64); set_gdbarch_long_double_bit (gdbarch, 128); set_gdbarch_long_double_format (gdbarch, floatformats_ibm_long_double); break; default: internal_error (__FILE__, __LINE__, _("unknown ABI in switch")); } /* GCC creates a pseudo-section whose name specifies the size of longs, since -mlong32 or -mlong64 may be used independent of other options. How those options affect pointer sizes is ABI and architecture dependent, so use them to override the default sizes set by the ABI. This table shows the relationship between ABI, -mlongXX, and size of pointers: ABI -mlongXX ptr bits --- -------- -------- o32 32 32 o32 64 32 n32 32 32 n32 64 64 o64 32 32 o64 64 64 n64 32 32 n64 64 64 eabi32 32 32 eabi32 64 32 eabi64 32 32 eabi64 64 64 Note that for o32 and eabi32, pointers are always 32 bits regardless of any -mlongXX option. For all others, pointers and longs are the same, as set by -mlongXX or set by defaults. */ if (info.abfd != NULL) { int long_bit = 0; bfd_map_over_sections (info.abfd, mips_find_long_section, &long_bit); if (long_bit) { set_gdbarch_long_bit (gdbarch, long_bit); switch (mips_abi) { case MIPS_ABI_O32: case MIPS_ABI_EABI32: break; case MIPS_ABI_N32: case MIPS_ABI_O64: case MIPS_ABI_N64: case MIPS_ABI_EABI64: set_gdbarch_ptr_bit (gdbarch, long_bit); break; default: internal_error (__FILE__, __LINE__, _("unknown ABI in switch")); } } } /* FIXME: jlarmour/2000-04-07: There *is* a flag EF_MIPS_32BIT_MODE that could indicate -gp32 BUT gas/config/tc-mips.c contains the comment: ``We deliberately don't allow "-gp32" to set the MIPS_32BITMODE flag in object files because to do so would make it impossible to link with libraries compiled without "-gp32". This is unnecessarily restrictive. We could solve this problem by adding "-gp32" multilibs to gcc, but to set this flag before gcc is built with such multilibs will break too many systems.'' But even more unhelpfully, the default linker output target for mips64-elf is elf32-bigmips, and has EF_MIPS_32BIT_MODE set, even for 64-bit programs - you need to change the ABI to change this, and not all gcc targets support that currently. Therefore using this flag to detect 32-bit mode would do the wrong thing given the current gcc - it would make GDB treat these 64-bit programs as 32-bit programs by default. */ set_gdbarch_read_pc (gdbarch, mips_read_pc); set_gdbarch_write_pc (gdbarch, mips_write_pc); /* Add/remove bits from an address. The MIPS needs be careful to ensure that all 32 bit addresses are sign extended to 64 bits. */ set_gdbarch_addr_bits_remove (gdbarch, mips_addr_bits_remove); /* Unwind the frame. */ set_gdbarch_unwind_pc (gdbarch, mips_unwind_pc); set_gdbarch_unwind_sp (gdbarch, mips_unwind_sp); set_gdbarch_dummy_id (gdbarch, mips_dummy_id); /* Map debug register numbers onto internal register numbers. */ set_gdbarch_stab_reg_to_regnum (gdbarch, mips_stab_reg_to_regnum); set_gdbarch_ecoff_reg_to_regnum (gdbarch, mips_dwarf_dwarf2_ecoff_reg_to_regnum); set_gdbarch_dwarf2_reg_to_regnum (gdbarch, mips_dwarf_dwarf2_ecoff_reg_to_regnum); set_gdbarch_register_sim_regno (gdbarch, mips_register_sim_regno); /* MIPS version of CALL_DUMMY. */ set_gdbarch_call_dummy_location (gdbarch, ON_STACK); set_gdbarch_push_dummy_code (gdbarch, mips_push_dummy_code); set_gdbarch_frame_align (gdbarch, mips_frame_align); set_gdbarch_print_float_info (gdbarch, mips_print_float_info); set_gdbarch_convert_register_p (gdbarch, mips_convert_register_p); set_gdbarch_register_to_value (gdbarch, mips_register_to_value); set_gdbarch_value_to_register (gdbarch, mips_value_to_register); set_gdbarch_inner_than (gdbarch, core_addr_lessthan); set_gdbarch_breakpoint_kind_from_pc (gdbarch, mips_breakpoint_kind_from_pc); set_gdbarch_sw_breakpoint_from_kind (gdbarch, mips_sw_breakpoint_from_kind); set_gdbarch_adjust_breakpoint_address (gdbarch, mips_adjust_breakpoint_address); set_gdbarch_skip_prologue (gdbarch, mips_skip_prologue); set_gdbarch_stack_frame_destroyed_p (gdbarch, mips_stack_frame_destroyed_p); set_gdbarch_pointer_to_address (gdbarch, signed_pointer_to_address); set_gdbarch_address_to_pointer (gdbarch, address_to_signed_pointer); set_gdbarch_integer_to_address (gdbarch, mips_integer_to_address); set_gdbarch_register_type (gdbarch, mips_register_type); set_gdbarch_print_registers_info (gdbarch, mips_print_registers_info); set_gdbarch_print_insn (gdbarch, gdb_print_insn_mips); if (mips_abi == MIPS_ABI_N64) set_gdbarch_disassembler_options_implicit (gdbarch, (const char *) mips_disassembler_options_n64); else if (mips_abi == MIPS_ABI_N32) set_gdbarch_disassembler_options_implicit (gdbarch, (const char *) mips_disassembler_options_n32); else set_gdbarch_disassembler_options_implicit (gdbarch, (const char *) mips_disassembler_options_o32); set_gdbarch_disassembler_options (gdbarch, &mips_disassembler_options); set_gdbarch_valid_disassembler_options (gdbarch, disassembler_options_mips ()); /* FIXME: cagney/2003-08-29: The macros target_have_steppable_watchpoint, HAVE_NONSTEPPABLE_WATCHPOINT, and target_have_continuable_watchpoint need to all be folded into the target vector. Since they are being used as guards for target_stopped_by_watchpoint, why not have target_stopped_by_watchpoint return the type of watchpoint that the code is sitting on? */ set_gdbarch_have_nonsteppable_watchpoint (gdbarch, 1); set_gdbarch_skip_trampoline_code (gdbarch, mips_skip_trampoline_code); /* NOTE drow/2012-04-25: We overload the core solib trampoline code to support MIPS16. This is a bad thing. Make sure not to do it if we have an OS ABI that actually supports shared libraries, since shared library support is more important. If we have an OS someday that supports both shared libraries and MIPS16, we'll have to find a better place for these. macro/2012-04-25: But that applies to return trampolines only and currently no MIPS OS ABI uses shared libraries that have them. */ set_gdbarch_in_solib_return_trampoline (gdbarch, mips_in_return_stub); set_gdbarch_single_step_through_delay (gdbarch, mips_single_step_through_delay); /* Virtual tables. */ set_gdbarch_vbit_in_delta (gdbarch, 1); mips_register_g_packet_guesses (gdbarch); /* Hook in OS ABI-specific overrides, if they have been registered. */ info.tdesc_data = tdesc_data; gdbarch_init_osabi (info, gdbarch); /* The hook may have adjusted num_regs, fetch the final value and set pc_regnum and sp_regnum now that it has been fixed. */ num_regs = gdbarch_num_regs (gdbarch); set_gdbarch_pc_regnum (gdbarch, regnum->pc + num_regs); set_gdbarch_sp_regnum (gdbarch, MIPS_SP_REGNUM + num_regs); /* Unwind the frame. */ dwarf2_append_unwinders (gdbarch); frame_unwind_append_unwinder (gdbarch, &mips_stub_frame_unwind); frame_unwind_append_unwinder (gdbarch, &mips_insn16_frame_unwind); frame_unwind_append_unwinder (gdbarch, &mips_micro_frame_unwind); frame_unwind_append_unwinder (gdbarch, &mips_insn32_frame_unwind); frame_base_append_sniffer (gdbarch, dwarf2_frame_base_sniffer); frame_base_append_sniffer (gdbarch, mips_stub_frame_base_sniffer); frame_base_append_sniffer (gdbarch, mips_insn16_frame_base_sniffer); frame_base_append_sniffer (gdbarch, mips_micro_frame_base_sniffer); frame_base_append_sniffer (gdbarch, mips_insn32_frame_base_sniffer); if (tdesc_data) { set_tdesc_pseudo_register_type (gdbarch, mips_pseudo_register_type); tdesc_use_registers (gdbarch, info.target_desc, tdesc_data); /* Override the normal target description methods to handle our dual real and pseudo registers. */ set_gdbarch_register_name (gdbarch, mips_register_name); set_gdbarch_register_reggroup_p (gdbarch, mips_tdesc_register_reggroup_p); num_regs = gdbarch_num_regs (gdbarch); set_gdbarch_num_pseudo_regs (gdbarch, num_regs); set_gdbarch_pc_regnum (gdbarch, tdep->regnum->pc + num_regs); set_gdbarch_sp_regnum (gdbarch, MIPS_SP_REGNUM + num_regs); } /* Add ABI-specific aliases for the registers. */ if (mips_abi == MIPS_ABI_N32 || mips_abi == MIPS_ABI_N64) for (i = 0; i < ARRAY_SIZE (mips_n32_n64_aliases); i++) user_reg_add (gdbarch, mips_n32_n64_aliases[i].name, value_of_mips_user_reg, &mips_n32_n64_aliases[i].regnum); else for (i = 0; i < ARRAY_SIZE (mips_o32_aliases); i++) user_reg_add (gdbarch, mips_o32_aliases[i].name, value_of_mips_user_reg, &mips_o32_aliases[i].regnum); /* Add some other standard aliases. */ for (i = 0; i < ARRAY_SIZE (mips_register_aliases); i++) user_reg_add (gdbarch, mips_register_aliases[i].name, value_of_mips_user_reg, &mips_register_aliases[i].regnum); for (i = 0; i < ARRAY_SIZE (mips_numeric_register_aliases); i++) user_reg_add (gdbarch, mips_numeric_register_aliases[i].name, value_of_mips_user_reg, &mips_numeric_register_aliases[i].regnum); return gdbarch; } static void mips_abi_update (const char *ignore_args, int from_tty, struct cmd_list_element *c) { struct gdbarch_info info; /* Force the architecture to update, and (if it's a MIPS architecture) mips_gdbarch_init will take care of the rest. */ gdbarch_info_init (&info); gdbarch_update_p (info); } /* Print out which MIPS ABI is in use. */ static void show_mips_abi (struct ui_file *file, int from_tty, struct cmd_list_element *ignored_cmd, const char *ignored_value) { if (gdbarch_bfd_arch_info (target_gdbarch ())->arch != bfd_arch_mips) fprintf_filtered (file, "The MIPS ABI is unknown because the current architecture " "is not MIPS.\n"); else { enum mips_abi global_abi = global_mips_abi (); enum mips_abi actual_abi = mips_abi (target_gdbarch ()); const char *actual_abi_str = mips_abi_strings[actual_abi]; if (global_abi == MIPS_ABI_UNKNOWN) fprintf_filtered (file, "The MIPS ABI is set automatically (currently \"%s\").\n", actual_abi_str); else if (global_abi == actual_abi) fprintf_filtered (file, "The MIPS ABI is assumed to be \"%s\" (due to user setting).\n", actual_abi_str); else { /* Probably shouldn't happen... */ fprintf_filtered (file, "The (auto detected) MIPS ABI \"%s\" is in use " "even though the user setting was \"%s\".\n", actual_abi_str, mips_abi_strings[global_abi]); } } } /* Print out which MIPS compressed ISA encoding is used. */ static void show_mips_compression (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("The compressed ISA encoding used is %s.\n"), value); } /* Return a textual name for MIPS FPU type FPU_TYPE. */ static const char * mips_fpu_type_str (enum mips_fpu_type fpu_type) { switch (fpu_type) { case MIPS_FPU_NONE: return "none"; case MIPS_FPU_SINGLE: return "single"; case MIPS_FPU_DOUBLE: return "double"; default: return "???"; } } static void mips_dump_tdep (struct gdbarch *gdbarch, struct ui_file *file) { struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch); if (tdep != NULL) { int ef_mips_arch; int ef_mips_32bitmode; /* Determine the ISA. */ switch (tdep->elf_flags & EF_MIPS_ARCH) { case E_MIPS_ARCH_1: ef_mips_arch = 1; break; case E_MIPS_ARCH_2: ef_mips_arch = 2; break; case E_MIPS_ARCH_3: ef_mips_arch = 3; break; case E_MIPS_ARCH_4: ef_mips_arch = 4; break; default: ef_mips_arch = 0; break; } /* Determine the size of a pointer. */ ef_mips_32bitmode = (tdep->elf_flags & EF_MIPS_32BITMODE); fprintf_unfiltered (file, "mips_dump_tdep: tdep->elf_flags = 0x%x\n", tdep->elf_flags); fprintf_unfiltered (file, "mips_dump_tdep: ef_mips_32bitmode = %d\n", ef_mips_32bitmode); fprintf_unfiltered (file, "mips_dump_tdep: ef_mips_arch = %d\n", ef_mips_arch); fprintf_unfiltered (file, "mips_dump_tdep: tdep->mips_abi = %d (%s)\n", tdep->mips_abi, mips_abi_strings[tdep->mips_abi]); fprintf_unfiltered (file, "mips_dump_tdep: " "mips_mask_address_p() %d (default %d)\n", mips_mask_address_p (tdep), tdep->default_mask_address_p); } fprintf_unfiltered (file, "mips_dump_tdep: MIPS_DEFAULT_FPU_TYPE = %d (%s)\n", MIPS_DEFAULT_FPU_TYPE, mips_fpu_type_str (MIPS_DEFAULT_FPU_TYPE)); fprintf_unfiltered (file, "mips_dump_tdep: MIPS_EABI = %d\n", MIPS_EABI (gdbarch)); fprintf_unfiltered (file, "mips_dump_tdep: MIPS_FPU_TYPE = %d (%s)\n", MIPS_FPU_TYPE (gdbarch), mips_fpu_type_str (MIPS_FPU_TYPE (gdbarch))); } void _initialize_mips_tdep (void) { static struct cmd_list_element *mipsfpulist = NULL; mips_abi_string = mips_abi_strings[MIPS_ABI_UNKNOWN]; if (MIPS_ABI_LAST + 1 != sizeof (mips_abi_strings) / sizeof (mips_abi_strings[0])) internal_error (__FILE__, __LINE__, _("mips_abi_strings out of sync")); gdbarch_register (bfd_arch_mips, mips_gdbarch_init, mips_dump_tdep); /* Create feature sets with the appropriate properties. The values are not important. */ mips_tdesc_gp32 = allocate_target_description (); set_tdesc_property (mips_tdesc_gp32, PROPERTY_GP32, ""); mips_tdesc_gp64 = allocate_target_description (); set_tdesc_property (mips_tdesc_gp64, PROPERTY_GP64, ""); /* Add root prefix command for all "set mips"/"show mips" commands. */ add_prefix_cmd ("mips", no_class, set_mips_command, _("Various MIPS specific commands."), &setmipscmdlist, "set mips ", 0, &setlist); add_prefix_cmd ("mips", no_class, show_mips_command, _("Various MIPS specific commands."), &showmipscmdlist, "show mips ", 0, &showlist); /* Allow the user to override the ABI. */ add_setshow_enum_cmd ("abi", class_obscure, mips_abi_strings, &mips_abi_string, _("\ Set the MIPS ABI used by this program."), _("\ Show the MIPS ABI used by this program."), _("\ This option can be set to one of:\n\ auto - the default ABI associated with the current binary\n\ o32\n\ o64\n\ n32\n\ n64\n\ eabi32\n\ eabi64"), mips_abi_update, show_mips_abi, &setmipscmdlist, &showmipscmdlist); /* Allow the user to set the ISA to assume for compressed code if ELF file flags don't tell or there is no program file selected. This setting is updated whenever unambiguous ELF file flags are interpreted, and carried over to subsequent sessions. */ add_setshow_enum_cmd ("compression", class_obscure, mips_compression_strings, &mips_compression_string, _("\ Set the compressed ISA encoding used by MIPS code."), _("\ Show the compressed ISA encoding used by MIPS code."), _("\ Select the compressed ISA encoding used in functions that have no symbol\n\ information available. The encoding can be set to either of:\n\ mips16\n\ micromips\n\ and is updated automatically from ELF file flags if available."), mips_abi_update, show_mips_compression, &setmipscmdlist, &showmipscmdlist); /* Let the user turn off floating point and set the fence post for heuristic_proc_start. */ add_prefix_cmd ("mipsfpu", class_support, set_mipsfpu_command, _("Set use of MIPS floating-point coprocessor."), &mipsfpulist, "set mipsfpu ", 0, &setlist); add_cmd ("single", class_support, set_mipsfpu_single_command, _("Select single-precision MIPS floating-point coprocessor."), &mipsfpulist); add_cmd ("double", class_support, set_mipsfpu_double_command, _("Select double-precision MIPS floating-point coprocessor."), &mipsfpulist); add_alias_cmd ("on", "double", class_support, 1, &mipsfpulist); add_alias_cmd ("yes", "double", class_support, 1, &mipsfpulist); add_alias_cmd ("1", "double", class_support, 1, &mipsfpulist); add_cmd ("none", class_support, set_mipsfpu_none_command, _("Select no MIPS floating-point coprocessor."), &mipsfpulist); add_alias_cmd ("off", "none", class_support, 1, &mipsfpulist); add_alias_cmd ("no", "none", class_support, 1, &mipsfpulist); add_alias_cmd ("0", "none", class_support, 1, &mipsfpulist); add_cmd ("auto", class_support, set_mipsfpu_auto_command, _("Select MIPS floating-point coprocessor automatically."), &mipsfpulist); add_cmd ("mipsfpu", class_support, show_mipsfpu_command, _("Show current use of MIPS floating-point coprocessor target."), &showlist); /* We really would like to have both "0" and "unlimited" work, but command.c doesn't deal with that. So make it a var_zinteger because the user can always use "999999" or some such for unlimited. */ add_setshow_zinteger_cmd ("heuristic-fence-post", class_support, &heuristic_fence_post, _("\ Set the distance searched for the start of a function."), _("\ Show the distance searched for the start of a function."), _("\ If you are debugging a stripped executable, GDB needs to search through the\n\ program for the start of a function. This command sets the distance of the\n\ search. The only need to set it is when debugging a stripped executable."), reinit_frame_cache_sfunc, NULL, /* FIXME: i18n: The distance searched for the start of a function is %s. */ &setlist, &showlist); /* Allow the user to control whether the upper bits of 64-bit addresses should be zeroed. */ add_setshow_auto_boolean_cmd ("mask-address", no_class, &mask_address_var, _("\ Set zeroing of upper 32 bits of 64-bit addresses."), _("\ Show zeroing of upper 32 bits of 64-bit addresses."), _("\ Use \"on\" to enable the masking, \"off\" to disable it and \"auto\" to\n\ allow GDB to determine the correct value."), NULL, show_mask_address, &setmipscmdlist, &showmipscmdlist); /* Allow the user to control the size of 32 bit registers within the raw remote packet. */ add_setshow_boolean_cmd ("remote-mips64-transfers-32bit-regs", class_obscure, &mips64_transfers_32bit_regs_p, _("\ Set compatibility with 64-bit MIPS target that transfers 32-bit quantities."), _("\ Show compatibility with 64-bit MIPS target that transfers 32-bit quantities."), _("\ Use \"on\" to enable backward compatibility with older MIPS 64 GDB+target\n\ that would transfer 32 bits for some registers (e.g. SR, FSR) and\n\ 64 bits for others. Use \"off\" to disable compatibility mode"), set_mips64_transfers_32bit_regs, NULL, /* FIXME: i18n: Compatibility with 64-bit MIPS target that transfers 32-bit quantities is %s. */ &setlist, &showlist); /* Debug this files internals. */ add_setshow_zuinteger_cmd ("mips", class_maintenance, &mips_debug, _("\ Set mips debugging."), _("\ Show mips debugging."), _("\ When non-zero, mips specific debugging is enabled."), NULL, NULL, /* FIXME: i18n: Mips debugging is currently %s. */ &setdebuglist, &showdebuglist); }