/* tc-dvp.c -- Assembler for the DVP Copyright (C) 1997, 1998 Free Software Foundation. This file is part of GAS, the GNU Assembler. GAS 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 2, or (at your option) any later version. GAS 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 GAS; see the file COPYING. If not, write to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include #include #include "sysdep.h" #include "as.h" #include "subsegs.h" /* Needed by opcode/dvp.h. */ #include "dis-asm.h" #include "opcode/dvp.h" #include "elf/mips.h" #ifdef USE_STDARG #include #else #include #endif /* Compute DMA operand index number of OP. */ #define DMA_OPERAND_INDEX(op) ((op) - dma_operands) /* Our local label prefix. */ #define LOCAL_LABEL_PREFIX ".L" /* Label prefix for end markers used in autocounts. */ #define END_LABEL_PREFIX ".L.end." /* Label to use for unique labels. */ #define UNIQUE_LABEL_PREFIX ".L.dvptmp." static long parse_float PARAMS ((char **, const char **)); static symbolS * create_label PARAMS ((const char *, const char *)); static symbolS * create_colon_label PARAMS ((int, const char *, const char *)); static char * unique_name PARAMS ((const char *)); static long eval_expr PARAMS ((int, int, const char *, ...)); static long parse_dma_addr_autocount (); static void inline_dma_data PARAMS ((int, DVP_INSN *)); static void setup_dma_autocount PARAMS ((const char *, DVP_INSN *, int)); static void insert_operand PARAMS ((dvp_cpu, const dvp_opcode *, const dvp_operand *, int, DVP_INSN *, offsetT, const char **)); static void insert_operand_final PARAMS ((dvp_cpu, const dvp_operand *, int, DVP_INSN *, offsetT, char *, unsigned int)); static int insert_file PARAMS ((const char *)); static int cur_vif_insn_length PARAMS ((void)); static void install_vif_length PARAMS ((char *, int)); const char comment_chars[] = ";"; const char line_comment_chars[] = "#"; const char line_separator_chars[] = "!"; const char EXP_CHARS[] = "eE"; const char FLT_CHARS[] = "dD"; /* Current assembler state. Instructions like mpg and direct are followed by a restricted set of instructions. In the case of a '*' length argument an end marker must be provided. (e.g. mpg is followed by vu insns until a .EndMpg is seen). Allowed state transitions: ASM_INIT -> ASM_MPG ASM_DIRECT -> ASM_GIF ASM_UNPACK ASM_VU */ typedef enum { ASM_INIT, ASM_DIRECT, ASM_MPG, ASM_UNPACK, ASM_VU, ASM_GIF } asm_state; /* We need to maintain a stack of the current and previous status to handle such things as "direct ...; gifpacked ... ; .endgif ; .enddirect". */ #define MAX_STATE_DEPTH 2 static asm_state asm_state_stack[MAX_STATE_DEPTH]; /* Current state's index in the stack. */ static int cur_state_index; /* Macro to fetch the current state. */ #define CUR_ASM_STATE (asm_state_stack[cur_state_index]) /* Functions to push/pop the state stack. */ static void push_asm_state PARAMS ((asm_state)); static void pop_asm_state PARAMS ((int)); static void set_asm_state PARAMS ((asm_state)); /* Current cpu (machine variant) type state. We copy the mips16 way of recording what the current machine type is in the code. A label is created whenever necessary and has an "other" value the denotes the machine type. */ static dvp_cpu cur_cpu; /* Record the current mach type. */ static void record_mach PARAMS ((dvp_cpu, int)); /* Given a dvp_cpu value, return the STO_DVP value to use. */ static int cpu_sto PARAMS ((dvp_cpu, const char **)); /* Nonzero if inside .DmaData. */ static int dma_data_state = 0; /* Label of .DmaData (internally generated for inline data). */ static const char *dma_data_name; /* Type of gif tag. */ static gif_type gif_insn_type; /* Name of label of current gif insn's data. */ static const char *gif_data_name; /* Pointer to current gif insn in fragment. */ static char *gif_insn_frag; /* For variable length instructions, pointer to the initial frag and pointer into that frag. These only hold valid values if CUR_ASM_STATE is one of ASM_MPG, ASM_DIRECT, ASM_UNPACK. */ static fragS *cur_varlen_frag; static char *cur_varlen_insn; /* The length value specified in the insn, or -1 if '*'. */ static int cur_varlen_value; /* Count of vu insns seen since the last mpg. Set to -1 to disable automatic mpg insertion. */ static int vu_count; /* Non-zero if packing vif instructions in dma tags. */ static int dma_pack_vif_p; /* Non-zero if dma insns are to be included in the output. This is the default, but writing "if (! no_dma)" is klunky. */ static int output_dma = 1; /* Non-zero if vif insns are to be included in the output. */ static int output_vif = 1; const char *md_shortopts = ""; struct option md_longopts[] = { #define OPTION_NO_DMA (OPTION_MD_BASE + 1) { "no-dma", no_argument, NULL, OPTION_NO_DMA }, #define OPTION_NO_DMA_VIF (OPTION_NO_DMA + 1) { "no-dma-vif", no_argument, NULL, OPTION_NO_DMA_VIF }, {NULL, no_argument, NULL, 0} }; size_t md_longopts_size = sizeof(md_longopts); int md_parse_option (c, arg) int c; char *arg; { switch (c) { case OPTION_NO_DMA : output_dma = 0; break; case OPTION_NO_DMA_VIF : output_dma = 0; output_vif = 0; break; default : return 0; } return 1; } void md_show_usage (stream) FILE *stream; { fprintf (stream, "\ DVP options:\n\ -no-dma do not include DMA instructions in the output\n\ -no-dma-vif do not include DMA or VIF instructions in the output\n\ "); } /* Set by md_assemble for use by dvp_fill_insn. */ static subsegT prev_subseg; static segT prev_seg; static void s_dmadata PARAMS ((int)); static void s_enddmadata PARAMS ((int)); static void s_dmapackvif PARAMS ((int)); static void s_enddirect PARAMS ((int)); static void s_endmpg PARAMS ((int)); static void s_endunpack PARAMS ((int)); static void s_endgif PARAMS ((int)); static void s_state PARAMS ((int)); /* The target specific pseudo-ops which we support. */ const pseudo_typeS md_pseudo_table[] = { { "word", cons, 4 }, { "dmadata", s_dmadata, 0 }, { "dmapackvif", s_dmapackvif, 0 }, { "enddirect", s_enddirect, 0 }, { "enddmadata", s_enddmadata, 0 }, { "endmpg", s_endmpg, 0 }, { "endunpack", s_endunpack, 0 }, { "endgif", s_endgif, 0 }, /* .vu added to simplify debugging and creation of input files */ { "vu", s_state, ASM_VU }, { NULL, NULL, 0 } }; void md_begin () { /* Initialize the opcode tables. This involves computing the hash chains. */ dvp_opcode_init_tables (0); /* Set the current mach to an illegal value to force a label for the first insn. */ cur_cpu = DVP_UNKNOWN; /* Initialize the parsing state. */ cur_state_index = 0; set_asm_state (ASM_INIT); dma_pack_vif_p = 0; /* Disable automatic mpg insertion. */ vu_count = -1; } /* We need to keep a list of fixups. We can't simply generate them as we go, because that would require us to first create the frag, and that would screw up references to ``.''. */ struct dvp_fixup { /* index into `dvp_operands' */ int opindex; /* byte offset from beginning of instruction */ int offset; expressionS exp; }; #define MAX_FIXUPS 5 static int fixup_count; static struct dvp_fixup fixups[MAX_FIXUPS]; /* Given a cpu type and operand number, return a temporary reloc type for use in generating the fixup that encodes the cpu type and operand. */ static int encode_fixup_reloc_type PARAMS ((dvp_cpu, int)); /* Given an encoded fixup reloc type, decode it into cpu and operand. */ static void decode_fixup_reloc_type PARAMS ((int, dvp_cpu *, const dvp_operand **)); static void assemble_dma PARAMS ((char *)); static void assemble_gif PARAMS ((char *)); static void assemble_vif PARAMS ((char *)); static void assemble_vu PARAMS ((char *)); static const dvp_opcode * assemble_vu_insn PARAMS ((dvp_cpu, const dvp_opcode *, const dvp_operand *, char **, char *)); static const dvp_opcode * assemble_one_insn PARAMS ((dvp_cpu, const dvp_opcode *, const dvp_operand *, char **, DVP_INSN *)); /* Main entry point for assembling an instruction. */ void md_assemble (str) char *str; { /* Skip leading white space. */ while (isspace (*str)) str++; /* After a gif tag, no insns can appear until a .endgif is seen. */ if (CUR_ASM_STATE == ASM_GIF) { as_bad ("missing .endgif"); pop_asm_state (1); } /* Ditto for unpack. */ if (CUR_ASM_STATE == ASM_UNPACK) { as_bad ("missing .endunpack"); pop_asm_state (1); } #if 0 /* this doesn't work of course as gif insns may follow */ /* Ditto for direct. */ if (CUR_ASM_STATE == ASM_DIRECT) { as_bad ("missing .enddirect"); pop_asm_state (1); } #endif if (CUR_ASM_STATE == ASM_INIT) { if (strncasecmp (str, "dma", 3) == 0) assemble_dma (str); else if (strncasecmp (str, "gif", 3) == 0) assemble_gif (str); else assemble_vif (str); } else if (CUR_ASM_STATE == ASM_DIRECT) assemble_gif (str); else if (CUR_ASM_STATE == ASM_VU || CUR_ASM_STATE == ASM_MPG) assemble_vu (str); else as_fatal ("unknown parse state"); } /* Subroutine of md_assemble to assemble DMA instructions. */ static void assemble_dma (str) char *str; { DVP_INSN insn_buf[4]; /* Insn's length, in 32 bit words. */ int len; /* Pointer to allocated frag. */ char *f; int i; const dvp_opcode *opcode; if (output_dma) { /* Do an implicit alignment to a 16 byte boundary. Do it now so that inline dma data labels are at the right place. */ frag_align (4, 0, 0); record_alignment (now_seg, 4); } /* This is the DMA tag. */ insn_buf[0] = 0; insn_buf[1] = 0; /* These are VIF NOPs. They may be over-written later if DmaPackPke is on. initialize the remainder with zeros. */ insn_buf[2] = 0; insn_buf[3] = 0; opcode = assemble_one_insn (DVP_DMA, dma_opcode_lookup_asm (str), dma_operands, &str, insn_buf); if (opcode == NULL) return; if (!output_dma) return; record_mach (DVP_DMA, 0); len = 4; f = frag_more (len * 4); /* Write out the DMA instruction. */ for (i = 0; i < len; ++i) md_number_to_chars (f + i * 4, insn_buf[i], 4); /* Create any fixups. */ /* FIXME: It might eventually be possible to combine all the various copies of this bit of code. */ for (i = 0; i < fixup_count; ++i) { int op_type, reloc_type, offset; const dvp_operand *operand; /* Create a fixup for this operand. At this point we do not use a bfd_reloc_code_real_type for operands residing in the insn, but instead just use the operand index. This lets us easily handle fixups for any operand type, although that is admittedly not a very exciting feature. We pick a BFD reloc type in md_apply_fix. */ op_type = fixups[i].opindex; offset = fixups[i].offset; reloc_type = encode_fixup_reloc_type (DVP_DMA, op_type); operand = &dma_operands[op_type]; fix_new_exp (frag_now, f + offset - frag_now->fr_literal, 4, &fixups[i].exp, (operand->flags & DVP_OPERAND_RELATIVE_BRANCH) != 0, (bfd_reloc_code_real_type) reloc_type); } } /* Subroutine of md_assemble to assemble VIF instructions. */ static void assemble_vif (str) char *str; { /* Space for the instruction. The variable length insns can require much more space than this. It is allocated later, when we know we have such an insn. */ DVP_INSN insn_buf[5]; /* Insn's length, in 32 bit words. */ int len; /* Pointer to allocated frag. */ char *f; int i; const dvp_opcode *opcode; opcode = assemble_one_insn (DVP_VIF, vif_opcode_lookup_asm (str), vif_operands, &str, insn_buf); if (opcode == NULL) return; if (opcode->flags & VIF_OPCODE_LENVAR) len = 1; /* actual data follows later */ else if (opcode->flags & VIF_OPCODE_LEN2) len = 2; else if (opcode->flags & VIF_OPCODE_LEN5) len = 5; else len = 1; /* We still have to switch modes (if mpg for example) so we can't exit early if -no-vif. */ if (output_vif) { /* Record the mach before doing the alignment so that we properly disassemble any inserted vifnop's. For variable length insns force the recording of the mach type for the next insn. A label may be embedded in it to compute the length and this will cause the disassembler to wrongly disassemble the next insn. */ if (opcode->flags & VIF_OPCODE_LENVAR) record_mach (DVP_VIF, 1); else record_mach (DVP_VIF, 0); if (opcode->flags & VIF_OPCODE_MPG) { frag_align (3, 0, 0); record_alignment (now_seg, 3); /* FIXME: The data must be aligned on a 64 bit boundary. Not sure how to do this yet so punt by making the mpg insn 8 bytes (vifnop,mpg). */ f = frag_more (4); memset (f, 0, 4); } else if (opcode->flags & VIF_OPCODE_DIRECT) { frag_align (4, 0, 0); record_alignment (now_seg, 4); /* FIXME: revisit */ f = frag_more (12); memset (f, 0, 12); } /* Reminder: it is important to fetch enough space in one call to `frag_more'. We use (f - frag_now->fr_literal) to compute where we are and we don't want frag_now to change between calls. */ f = frag_more (len * 4); /* Write out the instruction. */ for (i = 0; i < len; ++i) md_number_to_chars (f + i * 4, insn_buf[i], 4); /* Create any fixups. */ /* FIXME: It might eventually be possible to combine all the various copies of this bit of code. */ for (i = 0; i < fixup_count; ++i) { int op_type, reloc_type, offset; const dvp_operand *operand; /* Create a fixup for this operand. At this point we do not use a bfd_reloc_code_real_type for operands residing in the insn, but instead just use the operand index. This lets us easily handle fixups for any operand type, although that is admittedly not a very exciting feature. We pick a BFD reloc type in md_apply_fix. */ op_type = fixups[i].opindex; offset = fixups[i].offset; reloc_type = encode_fixup_reloc_type (DVP_VIF, op_type); operand = &vif_operands[op_type]; fix_new_exp (frag_now, f + offset - frag_now->fr_literal, 4, &fixups[i].exp, (operand->flags & DVP_OPERAND_RELATIVE_BRANCH) != 0, (bfd_reloc_code_real_type) reloc_type); } } /* Handle variable length insns. */ if (opcode->flags & VIF_OPCODE_LENVAR) { /* Name of file to read data from. */ char *file; /* Length in 32 bit words. */ int data_len; file = NULL; data_len = 0; vif_get_var_data (&file, &data_len); if (file) { int byte_len = insert_file (file); if (output_vif) install_vif_length (f, byte_len); /* Update $.MpgLoc. */ vif_set_mpgloc (vif_get_mpgloc () + byte_len); } else { /* data_len == -1 means the value must be computed from the data. */ if (data_len == 0 || data_len < -2) as_bad ("invalid data length"); cur_varlen_frag = frag_now; cur_varlen_insn = f; cur_varlen_value = data_len; if (opcode->flags & VIF_OPCODE_MPG) { set_asm_state (ASM_MPG); /* Enable automatic mpg insertion every 256 insns. */ vu_count = 0; } else if (opcode->flags & VIF_OPCODE_DIRECT) set_asm_state (ASM_DIRECT); else if (opcode->flags & VIF_OPCODE_UNPACK) set_asm_state (ASM_UNPACK); } } } /* Subroutine of md_assemble to assemble GIF instructions. */ static void assemble_gif (str) char *str; { DVP_INSN insn_buf[4]; const dvp_opcode *opcode; char *f; int i; insn_buf[0] = insn_buf[1] = insn_buf[2] = insn_buf[3] = 0; opcode = assemble_one_insn (DVP_GIF, gif_opcode_lookup_asm (str), gif_operands, &str, insn_buf); if (opcode == NULL) return; /* Do an implicit alignment to a 16 byte boundary. */ frag_align (4, 0, 0); record_alignment (now_seg, 4); /* Insert a label so we can compute the number of quadwords when the .endgif is seen. This is put before the mach type label because gif insns are followed by data and we don't want the disassembler to try to disassemble them as mips insns (since it uses the st_other field) of the closest label to choose the mach type and since we don't have a special st_other value for "data". */ gif_data_name = S_GET_NAME (create_colon_label (0, "", unique_name (NULL))); record_mach (DVP_GIF, 1); gif_insn_frag = f = frag_more (16); for (i = 0; i < 4; ++i) md_number_to_chars (f + i * 4, insn_buf[i], 4); /* Record the type of the gif tag so we know how to compute nloop in s_endgif. */ if (strcmp (opcode->mnemonic, "gifpacked") == 0) gif_insn_type = GIF_PACKED; else if (strcmp (opcode->mnemonic, "gifreglist") == 0) gif_insn_type = GIF_REGLIST; else if (strcmp (opcode->mnemonic, "gifimage") == 0) gif_insn_type = GIF_IMAGE; else abort (); push_asm_state (ASM_GIF); } /* Subroutine of md_assemble to assemble VU instructions. */ static void assemble_vu (str) char *str; { char *f; const dvp_opcode *opcode; /* Handle automatic mpg insertion if enabled. */ if (CUR_ASM_STATE == ASM_MPG && vu_count == 256) { s_endmpg (1); md_assemble ("mpg *,*"); } /* Do an implicit alignment to a 8 byte boundary. */ frag_align (3, 0, 0); record_alignment (now_seg, 3); record_mach (DVP_VUUP, 0); /* The lower instruction has the lower address. Handle this by grabbing 8 bytes now, and then filling each word as appropriate. */ f = frag_more (8); #ifdef VERTICAL_BAR_SEPARATOR char *p = strchr (str, '|'); if (p == NULL) { as_bad ("lower slot missing in `%s'", str); return; } *p = 0; opcode = assemble_vu_insn (DVP_VUUP, vu_upper_opcode_lookup_asm (str), vu_operands, &str, f + 4); *p = '|'; str = p + 1; #else opcode = assemble_vu_insn (DVP_VUUP, vu_upper_opcode_lookup_asm (str), vu_operands, &str, f + 4); #endif /* Don't assemble next one if we couldn't assemble the first. */ if (opcode == NULL) return; opcode = assemble_vu_insn (DVP_VULO, vu_lower_opcode_lookup_asm (str), vu_operands, &str, f); /* If this was the "loi" pseudo-insn, we need to set the `i' bit. */ if (opcode != NULL) { if (strcmp (opcode->mnemonic, "loi") == 0) f[7] |= 0x80; } /* Increment the vu insn counter. If get reach 256 we need to insert an `mpg'. */ ++vu_count; } static const dvp_opcode * assemble_vu_insn (cpu, opcode, operand_table, pstr, buf) dvp_cpu cpu; const dvp_opcode *opcode; const dvp_operand *operand_table; char **pstr; char *buf; { int i; DVP_INSN insn; opcode = assemble_one_insn (cpu, opcode, operand_table, pstr, &insn); if (opcode == NULL) return NULL; /* Write out the instruction. Reminder: it is important to fetch enough space in one call to `frag_more'. We use (f - frag_now->fr_literal) to compute where we are and we don't want frag_now to change between calls. */ md_number_to_chars (buf, insn, 4); /* Create any fixups. */ for (i = 0; i < fixup_count; ++i) { int op_type, reloc_type; const dvp_operand *operand; /* Create a fixup for this operand. At this point we do not use a bfd_reloc_code_real_type for operands residing in the insn, but instead just use the operand index. This lets us easily handle fixups for any operand type, although that is admittedly not a very exciting feature. We pick a BFD reloc type in md_apply_fix. */ op_type = fixups[i].opindex; reloc_type = encode_fixup_reloc_type (cpu, op_type); operand = &vu_operands[op_type]; fix_new_exp (frag_now, buf - frag_now->fr_literal, 4, &fixups[i].exp, (operand->flags & DVP_OPERAND_RELATIVE_BRANCH) != 0, (bfd_reloc_code_real_type) reloc_type); } /* All done. */ return opcode; } /* Assemble one instruction at *PSTR. CPU indicates what component we're assembling for. The assembled instruction is stored in INSN_BUF. OPCODE is a pointer to the head of the hash chain. *PSTR is updated to point passed the parsed instruction. If the insn is successfully parsed the result is a pointer to the opcode entry that successfully matched and *PSTR is updated to point passed the parsed insn. If an error occurs the result is NULL and *PSTR is left at some random point in the string (??? may wish to leave it pointing where the error occured). */ static const dvp_opcode * assemble_one_insn (cpu, opcode, operand_table, pstr, insn_buf) dvp_cpu cpu; const dvp_opcode *opcode; const dvp_operand *operand_table; char **pstr; DVP_INSN *insn_buf; { char *start, *str; /* Keep looking until we find a match. */ start = str = *pstr; for ( ; opcode != NULL; opcode = DVP_OPCODE_NEXT_ASM (opcode)) { int past_opcode_p, num_suffixes; const unsigned char *syn; /* Ensure the mnemonic part matches. */ for (str = start, syn = opcode->mnemonic; *syn != '\0'; ++str, ++syn) if (tolower (*str) != tolower (*syn)) break; if (*syn != '\0') continue; /* Scan the syntax string. If it doesn't match, try the next one. */ dvp_opcode_init_parse (); insn_buf[opcode->opcode_word] = opcode->value; fixup_count = 0; past_opcode_p = 0; num_suffixes = 0; /* We don't check for (*str != '\0') here because we want to parse any trailing fake arguments in the syntax string. */ for (/*str = start, */ syn = opcode->syntax; *syn != '\0'; ) { int mods,index; const dvp_operand *operand; const char *errmsg; /* Non operand chars must match exactly. Operand chars that are letters are not part of symbols and are case insensitive. */ if (*syn < 128) { if (tolower (*str) == tolower (*syn)) { if (*syn == ' ') past_opcode_p = 1; ++syn; ++str; } else break; continue; } /* We have a suffix or an operand. Pick out any modifiers. */ mods = 0; index = DVP_OPERAND_INDEX (*syn); while (DVP_MOD_P (operand_table[index].flags)) { mods |= operand_table[index].flags & DVP_MOD_BITS; ++syn; index = DVP_OPERAND_INDEX (*syn); } operand = operand_table + index; if (operand->flags & DVP_OPERAND_FAKE) { long value = 0; if (operand->flags & DVP_OPERAND_DMA_INLINE) { inline_dma_data ((mods & DVP_OPERAND_AUTOCOUNT) != 0, insn_buf); ++syn; continue; } if (operand->parse) { errmsg = NULL; value = (*operand->parse) (opcode, operand, mods, &str, &errmsg); if (errmsg) break; } if (operand->insert) { errmsg = NULL; (*operand->insert) (opcode, operand, mods, insn_buf, (offsetT) value, &errmsg); /* If we get an error, go on to try the next insn. */ if (errmsg) break; } ++syn; } /* Are we finished with suffixes? */ else if (!past_opcode_p) { long suf_value; if (!(operand->flags & DVP_OPERAND_SUFFIX)) as_fatal ("bad opcode table, missing suffix flag"); /* If we're at a space in the input string, we want to skip the remaining suffixes. There may be some fake ones though, so just go on to try the next one. */ if (*str == ' ') { ++syn; continue; } /* Parse the suffix. */ errmsg = NULL; suf_value = (*operand->parse) (opcode, operand, mods, &str, &errmsg); if (errmsg) { /* This can happen, for example, in ARC's in "blle foo" and we're currently using the template "b%q%.n %j". The "bl" insn occurs later in the table so "lle" isn't an illegal suffix. */ break; } /* Insert the suffix's value into the insn. */ insert_operand (cpu, opcode, operand, mods, insn_buf, (offsetT) suf_value, &errmsg); ++syn; } else /* This is an operand, either a register or an expression of some kind. */ { char c; char *hold; long value = 0; expressionS exp; if (operand->flags & DVP_OPERAND_SUFFIX) as_fatal ("bad opcode table, suffix wrong"); /* Is there anything left to parse? We don't check for this at the top because we want to parse any trailing fake arguments in the syntax string. */ /* ??? This doesn't allow operands with a legal value of "". */ if (*str == '\0') break; /* Parse the operand. */ if (operand->flags & DVP_OPERAND_FLOAT) { errmsg = 0; value = parse_float (&str, &errmsg); if (errmsg) break; } else if ((operand->flags & DVP_OPERAND_DMA_ADDR) && (mods & DVP_OPERAND_AUTOCOUNT)) { errmsg = 0; value = parse_dma_addr_autocount (opcode, operand, mods, insn_buf, &str, &errmsg); if (errmsg) break; } else if (operand->parse) { errmsg = NULL; value = (*operand->parse) (opcode, operand, mods, &str, &errmsg); if (errmsg) break; } else { hold = input_line_pointer; input_line_pointer = str; expression (&exp); str = input_line_pointer; input_line_pointer = hold; if (exp.X_op == O_illegal || exp.X_op == O_absent) break; else if (exp.X_op == O_constant) value = exp.X_add_number; else if (exp.X_op == O_register) as_fatal ("got O_register"); else { /* We need to generate a fixup for this expression. */ if (fixup_count >= MAX_FIXUPS) as_fatal ("too many fixups"); fixups[fixup_count].exp = exp; fixups[fixup_count].opindex = index; /* FIXME: Revisit. Do we really need operand->word? The endianness of a 128 bit DMAtag is rather twisted. How about defining word 0 as the word with the lowest address and basing operand-shift off that. operand->word could then be deleted. */ if (operand->word != 0) fixups[fixup_count].offset = operand->word * 4; else fixups[fixup_count].offset = (operand->shift / 32) * 4; ++fixup_count; value = 0; } } /* Insert the register or expression into the instruction. */ errmsg = NULL; insert_operand (cpu, opcode, operand, mods, insn_buf, (offsetT) value, &errmsg); if (errmsg != (const char *) NULL) break; ++syn; } } /* If we're at the end of the syntax string, we're done. */ if (*syn == '\0') { int i; /* For the moment we assume a valid `str' can only contain blanks now. IE: We needn't try again with a longer version of the insn and it is assumed that longer versions of insns appear before shorter ones (eg: lsr r2,r3,1 vs lsr r2,r3). */ while (isspace (*str)) ++str; if (*str != '\0' #ifndef VERTICAL_BAR_SEPARATOR && cpu != DVP_VUUP #endif ) as_bad ("junk at end of line: `%s'", str); /* It's now up to the caller to emit the instruction and any relocations. */ *pstr = str; return opcode; } /* Try the next entry. */ } as_bad ("bad instruction `%s'", start); return 0; } /* Given a dvp cpu type, return it's STO_DVP value. The section name prefix to use is stored in *PNAME. */ static int cpu_sto (cpu, pname) dvp_cpu cpu; const char **pname; { switch (cpu) { case DVP_DMA : *pname = ".dma."; return STO_DVP_DMA; case DVP_VIF : *pname = ".vif."; return STO_DVP_VIF; case DVP_GIF : *pname = ".gif."; return STO_DVP_GIF; case DVP_VUUP : *pname = ".vu."; return STO_DVP_VU; } abort (); } /* Record the current mach type in the object file. If FORCE_NEXT_P is non-zero, force a label to be emitted the next time we're called. This is useful for variable length instructions that can have labels embedded within them. */ static void record_mach (cpu, force_next_p) dvp_cpu cpu; int force_next_p; { symbolS *label; const char *name; int sto; if (cpu == cur_cpu) return; sto = cpu_sto (cpu, &name); label = create_colon_label (sto, "", unique_name (name)); if (force_next_p) cur_cpu = DVP_UNKNOWN; else cur_cpu = cpu; } /* Push/pop the current parsing state. */ static void push_asm_state (new_state) asm_state new_state; { ++cur_state_index; if (cur_state_index == MAX_STATE_DEPTH) as_fatal ("unexpected state push"); asm_state_stack[cur_state_index] = new_state; } /* TOP_OK_P is non-zero if it's ok that we're at the top of the stack. This happens if there are errors in the assembler code. We just reset the stack to its "init" state. */ static void pop_asm_state (top_ok_p) int top_ok_p; { if (cur_state_index == 0) { if (top_ok_p) asm_state_stack[cur_state_index] = ASM_INIT; else as_fatal ("unexpected state pop"); } else --cur_state_index; } static void set_asm_state (state) asm_state state; { CUR_ASM_STATE = state; } void md_operand (expressionP) expressionS *expressionP; { } valueT md_section_align (segment, size) segT segment; valueT size; { int align = bfd_get_section_alignment (stdoutput, segment); return ((size + (1 << align) - 1) & (-1 << align)); } symbolS * md_undefined_symbol (name) char *name; { return 0; } /* Called after parsing the file via md_after_pass_hook. */ void dvp_after_pass_hook () { #if 0 /* ??? Doesn't work unless we keep track of the nested include file level. */ /* Check for missing .EndMpg, and supply one if necessary. */ if (CUR_ASM_STATE == ASM_MPG) s_endmpg (1); else if (CUR_ASM_STATE == ASM_DIRECT) s_enddirect (0); else if (CUR_ASM_STATE == ASM_UNPACK) s_endunpack (0); #endif } /* Called when a label is defined via tc_frob_label. */ void dvp_frob_label (sym) symbolS *sym; { /* All labels in vu code must be specially marked for the disassembler. The disassembler ignores all previous information at each new label (that has a higher address than the last one). */ if (CUR_ASM_STATE == ASM_MPG || CUR_ASM_STATE == ASM_VU) S_SET_OTHER (sym, STO_DVP_VU); } /* Functions concerning relocs. */ /* Spacing between each cpu type's operand numbers. Should be at least as bit as any operand table. */ #define RELOC_SPACING 256 /* Given a cpu type and operand number, return a temporary reloc type for use in generating the fixup that encodes the cpu type and operand number. */ static int encode_fixup_reloc_type (cpu, opnum) dvp_cpu cpu; int opnum; { return (int) BFD_RELOC_UNUSED + ((int) cpu * RELOC_SPACING) + opnum; } /* Given a fixup reloc type, decode it into cpu type and operand. */ static void decode_fixup_reloc_type (fixup_reloc, cpuP, operandP) int fixup_reloc; dvp_cpu *cpuP; const dvp_operand **operandP; { dvp_cpu cpu = (fixup_reloc - (int) BFD_RELOC_UNUSED) / RELOC_SPACING; int opnum = (fixup_reloc - (int) BFD_RELOC_UNUSED) % RELOC_SPACING; *cpuP = cpu; switch (cpu) { case DVP_VUUP : *operandP = &vu_operands[opnum]; break; case DVP_VULO : *operandP = &vu_operands[opnum]; break; case DVP_DMA : *operandP = &dma_operands[opnum]; break; case DVP_VIF : *operandP = &vif_operands[opnum]; break; case DVP_GIF : *operandP = &gif_operands[opnum]; break; default : as_fatal ("bad fixup encoding"); } } /* Given a fixup reloc type, return a pointer to the operand /* The location from which a PC relative jump should be calculated, given a PC relative reloc. */ long md_pcrel_from_section (fixP, sec) fixS *fixP; segT sec; { if (fixP->fx_addsy != (symbolS *) NULL && (! S_IS_DEFINED (fixP->fx_addsy) || S_GET_SEGMENT (fixP->fx_addsy) != sec)) { /* The symbol is undefined (or is defined but not in this section). Let the linker figure it out. +8: branch offsets are relative to the delay slot. */ return 8; } /* We assume this is a vu branch. Offsets are calculated based on the address of the next insn. */ return ((fixP->fx_frag->fr_address + fixP->fx_where) & -8L) + 8; } /* Apply a fixup to the object code. This is called for all the fixups we generated by calls to fix_new_exp. At this point all symbol values should be fully resolved, and we attempt to completely resolve the reloc. If we can not do that, we determine the correct reloc code and put it back in the fixup. */ int md_apply_fix3 (fixP, valueP, seg) fixS *fixP; valueT *valueP; segT seg; { char *where = fixP->fx_frag->fr_literal + fixP->fx_where; valueT value; /* FIXME FIXME FIXME: The value we are passed in *valueP includes the symbol values. Since we are using BFD_ASSEMBLER, if we are doing this relocation the code in write.c is going to call bfd_perform_relocation, which is also going to use the symbol value. That means that if the reloc is fully resolved we want to use *valueP since bfd_perform_relocation is not being used. However, if the reloc is not fully resolved we do not want to use *valueP, and must use fx_offset instead. However, if the reloc is PC relative, we do want to use *valueP since it includes the result of md_pcrel_from. This is confusing. */ if (fixP->fx_addsy == (symbolS *) NULL) { value = *valueP; fixP->fx_done = 1; } else if (fixP->fx_pcrel) { value = *valueP; } else { value = fixP->fx_offset; if (fixP->fx_subsy != (symbolS *) NULL) { if (S_GET_SEGMENT (fixP->fx_subsy) == absolute_section) value -= S_GET_VALUE (fixP->fx_subsy); else { /* We can't actually support subtracting a symbol. */ as_bad_where (fixP->fx_file, fixP->fx_line, "expression too complex"); } } } /* Check for dvp operands. These are indicated with a reloc value >= BFD_RELOC_UNUSED. */ if ((int) fixP->fx_r_type >= (int) BFD_RELOC_UNUSED) { dvp_cpu cpu; const dvp_operand *operand; DVP_INSN insn; decode_fixup_reloc_type ((int) fixP->fx_r_type, & cpu, & operand); /* Fetch the instruction, insert the fully resolved operand value, and stuff the instruction back again. The fixup is recorded at the appropriate word so pass DVP_MOD_THIS_WORD so any offset specified in the tables is ignored. */ insn = bfd_getl32 ((unsigned char *) where); insert_operand_final (cpu, operand, DVP_MOD_THIS_WORD, &insn, (offsetT) value, fixP->fx_file, fixP->fx_line); bfd_putl32 ((bfd_vma) insn, (unsigned char *) where); if (fixP->fx_done) { /* Nothing else to do here. */ return 1; } /* Determine a BFD reloc value based on the operand information. We are only prepared to turn a few of the operands into relocs. */ /* FIXME: This test is a hack. */ if ((operand->flags & DVP_OPERAND_RELATIVE_BRANCH) != 0) { assert (operand->bits == 11 && operand->shift == 0); fixP->fx_r_type = BFD_RELOC_MIPS_DVP_11_PCREL; } else if ((operand->flags & DVP_OPERAND_DMA_ADDR) != 0 || (operand->flags & DVP_OPERAND_DMA_NEXT) != 0) { assert (operand->bits == 27 && operand->shift == 4); fixP->fx_r_type = BFD_RELOC_MIPS_DVP_27_S4; } else { as_bad_where (fixP->fx_file, fixP->fx_line, "unresolved expression that must be resolved"); fixP->fx_done = 1; return 1; } } else { switch (fixP->fx_r_type) { case BFD_RELOC_8: md_number_to_chars (where, value, 1); break; case BFD_RELOC_16: md_number_to_chars (where, value, 2); break; case BFD_RELOC_32: md_number_to_chars (where, value, 4); break; default: abort (); } } fixP->fx_addnumber = value; return 1; } /* Translate internal representation of relocation info to BFD target format. */ arelent * tc_gen_reloc (section, fixP) asection *section; fixS *fixP; { arelent *reloc; reloc = (arelent *) xmalloc (sizeof (arelent)); reloc->sym_ptr_ptr = &fixP->fx_addsy->bsym; reloc->address = fixP->fx_frag->fr_address + fixP->fx_where; reloc->howto = bfd_reloc_type_lookup (stdoutput, fixP->fx_r_type); if (reloc->howto == (reloc_howto_type *) NULL) { as_bad_where (fixP->fx_file, fixP->fx_line, "internal error: can't export reloc type %d (`%s')", fixP->fx_r_type, bfd_get_reloc_code_name (fixP->fx_r_type)); return NULL; } assert (!fixP->fx_pcrel == !reloc->howto->pc_relative); reloc->addend = fixP->fx_addnumber; return reloc; } /* Write a value out to the object file, using the appropriate endianness. */ void md_number_to_chars (buf, val, n) char *buf; valueT val; int n; { if (target_big_endian) number_to_chars_bigendian (buf, val, n); else number_to_chars_littleendian (buf, val, n); } /* Turn a string in input_line_pointer into a floating point constant of type type, and store the appropriate bytes in *litP. The number of LITTLENUMS emitted is stored in *sizeP . An error message is returned, or NULL on OK. */ /* Equal to MAX_PRECISION in atof-ieee.c */ #define MAX_LITTLENUMS 6 char * md_atof (type, litP, sizeP) char type; char *litP; int *sizeP; { int i,prec; LITTLENUM_TYPE words[MAX_LITTLENUMS]; LITTLENUM_TYPE *wordP; char *t; char *atof_ieee (); switch (type) { case 'f': case 'F': case 's': case 'S': prec = 2; break; case 'd': case 'D': case 'r': case 'R': prec = 4; break; /* FIXME: Some targets allow other format chars for bigger sizes here. */ default: *sizeP = 0; return "Bad call to md_atof()"; } t = atof_ieee (input_line_pointer, type, words); if (t) input_line_pointer = t; *sizeP = prec * sizeof (LITTLENUM_TYPE); if (target_big_endian) { for (i = 0; i < prec; i++) { md_number_to_chars (litP, (valueT) words[i], sizeof (LITTLENUM_TYPE)); litP += sizeof (LITTLENUM_TYPE); } } else { for (i = prec - 1; i >= 0; i--) { md_number_to_chars (litP, (valueT) words[i], sizeof (LITTLENUM_TYPE)); litP += sizeof (LITTLENUM_TYPE); } } return 0; } /* Miscellaneous utilities. */ /* Parse a 32 bit floating point number. The result is those 32 bits as an integer. */ static long parse_float (pstr, errmsg) char **pstr; const char **errmsg; { LITTLENUM_TYPE words[MAX_LITTLENUMS]; char *p; p = atof_ieee (*pstr, 'f', words); *pstr = p; return (words[0] << 16) | words[1]; } /* Scan a symbol and return a pointer to one past the end. */ #define issymchar(ch) (isalnum(ch) || ch == '_') static char * scan_symbol (sym) char *sym; { while (*sym && issymchar (*sym)) ++sym; return sym; } /* Evaluate an expression. The result is the value of the expression if it can be evaluated, or 0 if it cannot (say because some symbols haven't been defined yet) in which case a fixup is queued. If OPINDEX is 0, don't queue any fixups, just return 0. */ static long #ifdef USE_STDARG eval_expr (int opindex, int offset, const char *fmt, ...) #else eval_expr (opindex, offset, fmt, va_alist) int opindex,offset; const char *fmt; va_dcl #endif { long value; va_list ap; char *str,*save_input; expressionS exp; #ifdef USE_STDARG va_start (ap, fmt); #else va_start (ap); #endif vasprintf (&str, fmt, ap); va_end (ap); save_input = input_line_pointer; input_line_pointer = str; expression (&exp); input_line_pointer = save_input; free (str); if (exp.X_op == O_constant) value = exp.X_add_number; else { if (opindex != 0) { fixups[fixup_count].exp = exp; fixups[fixup_count].opindex = opindex; fixups[fixup_count].offset = offset; ++fixup_count; } value = 0; } return value; } /* Create a label named by concatenating PREFIX to NAME. */ static symbolS * create_label (prefix, name) const char *prefix, *name; { int namelen = strlen (name); int prefixlen = strlen (prefix); char *fullname; symbolS *result; fullname = xmalloc (prefixlen + namelen + 1); strcpy (fullname, prefix); strcat (fullname, name); result = symbol_find_or_make (fullname); free (fullname); return result; } /* Create a label named by concatenating PREFIX to NAME, and define it as `.'. STO, if non-zero, is the st_other value to assign to this label. If STO is zero `cur_cpu' is set to DVP_UNKNOWN to force record_mach to emit a cpu label. Otherwise the disassembler gets confused. */ static symbolS * create_colon_label (sto, prefix, name) int sto; const char *prefix, *name; { int namelen = strlen (name); int prefixlen = strlen (prefix); char *fullname; symbolS *result; fullname = xmalloc (prefixlen + namelen + 1); strcpy (fullname, prefix); strcat (fullname, name); result = colon (fullname); if (sto) S_SET_OTHER (result, sto); else cur_cpu = DVP_UNKNOWN; free (fullname); return result; } /* Return a malloc'd string useful in creating unique labels. PREFIX is the prefix to use or NULL if we're to pick one. */ /* ??? Presumably such a routine already exists somewhere [but a first pass at finding it didn't turn up anything]. */ static char * unique_name (prefix) const char *prefix; { static int counter; char *result; if (prefix == NULL) prefix = UNIQUE_LABEL_PREFIX; asprintf (&result, "%s%d", prefix, counter); ++counter; return result; } /* Compute the auto-count value for a DMA tag. INLINE_P is non-zero if the dma data is inline. */ static void setup_dma_autocount (name, insn_buf, inline_p) const char *name; DVP_INSN *insn_buf; int inline_p; { long count; if (inline_p) { /* -1: The count is the number of following quadwords, so skip the one containing the dma tag. */ count = eval_expr (dma_operand_count, 0, "((%s%s - %s) >> 4) - 1", END_LABEL_PREFIX, name, name); } else { /* We don't want to subtract 1 here as the begin and end labels properly surround the data we want to compute the length of. */ count = eval_expr (dma_operand_count, 0, "(%s%s - %s) >> 4", END_LABEL_PREFIX, name, name); } /* Store the count field. */ insn_buf[0] &= 0xffff0000; insn_buf[0] |= count & 0x0000ffff; } /* Record that inline data follows. */ static void inline_dma_data (autocount_p, insn_buf) int autocount_p; DVP_INSN *insn_buf; { if (dma_data_state != 0 ) { as_bad ("DmaData blocks cannot be nested."); return; } dma_data_state = 1; if (autocount_p) { dma_data_name = S_GET_NAME (create_colon_label (0, "", unique_name (NULL))); setup_dma_autocount (dma_data_name, insn_buf, 1); } else dma_data_name = 0; } /* Compute the auto-count value for a DMA tag with out-of-line data. */ static long parse_dma_addr_autocount (opcode, operand, mods, insn_buf, pstr, errmsg) const dvp_opcode *opcode; const dvp_operand *operand; int mods; DVP_INSN *insn_buf; char **pstr; const char **errmsg; { char *start = *pstr; char *end = start; long retval; /* Data reference must be a .DmaData label. */ symbolS *label, *label2, *endlabel; const char *name; char c; label = label2 = 0; if (! is_name_beginner (*start)) { *errmsg = "invalid .DmaData label"; return 0; } name = start; end = scan_symbol (name); c = *end; *end = 0; label = symbol_find_or_make (name); *end = c; label2 = create_label ("_$", name); endlabel = create_label (END_LABEL_PREFIX, name); retval = eval_expr (dma_operand_addr, 4, name); setup_dma_autocount (name, insn_buf, 0); *pstr = end; return retval; } /* Return length in bytes of the variable length VIF insn currently being assembled. */ static int cur_vif_insn_length () { int byte_len; fragS *f; if (cur_varlen_frag == frag_now) byte_len = frag_more (0) - cur_varlen_insn - 4; /* -4 for mpg itself */ else { byte_len = (cur_varlen_frag->fr_fix /*+ cur_varlen_frag->fr_offset + cur_varlen_frag->fr_var*/ - (cur_varlen_insn - cur_varlen_frag->fr_literal)) - 4; for (f = cur_varlen_frag->fr_next; f != frag_now; f = f->fr_next) byte_len += f->fr_fix /*+ f->fr_offset + f->fr_var*/; byte_len += frag_now_fix (); } return byte_len; } /* Install length LEN, in bytes, in the vif insn at BUF. The bytes in BUF are in target order. */ static void install_vif_length (buf, len) char *buf; int len; { char cmd = buf[3]; if ((cmd & 0x70) == 0x40) { /* mpg */ len /= 8; /* ??? Worry about data /= 8 cuts off? */ if (len > 256) as_bad ("`mpg' data length must be between 1 and 256"); buf[2] = len == 256 ? 0 : len; } else if ((cmd & 0x70) == 0x50) { /* direct/directhl */ /* ??? Worry about data /= 16 cuts off? */ len /= 16; if (len > 65536) as_bad ("`direct' data length must be between 1 and 65536"); len = len == 65536 ? 0 : len; buf[0] = len; buf[1] = len >> 8; } else if ((cmd & 0x60) == 0x60) { /* unpack */ /* FIXME: revisit */ /* ??? Worry about data /= 16 cuts off? */ len /= 16; if (len > 256) as_bad ("`direct' data length must be between 1 and 256"); len = len == 256 ? 0 : len; buf[2] = len; } else as_fatal ("bad call to install_vif_length"); } /* Insert a file into the output. -I is used to specify where to find the file. The result is the number of bytes inserted. If an error occurs an error message is printed and zero is returned. */ static int insert_file (file) const char *file; { FILE *f; char buf[256]; int i, n, total; char *path; path = xmalloc (strlen (file) + include_dir_maxlen + 5 /*slop*/); f = NULL; for (i = 0; i < include_dir_count; i++) { strcpy (path, include_dirs[i]); strcat (path, "/"); strcat (path, file); if ((f = fopen (path, FOPEN_RB)) != NULL) break; } free (path); if (f == NULL) f = fopen (file, FOPEN_RB); if (f == NULL) { as_bad ("unable to read file `%s'", file); return 0; } total = 0; do { n = fread (buf, 1, sizeof (buf), f); if (n > 0) { char *fr = frag_more (n); memcpy (fr, buf, n); total += n; } } while (n > 0); fclose (f); /* We assume the file is smaller than 2^31 bytes. Ok, we shouldn't make any assumptions. Later. */ return total; } /* Insert an operand value into an instruction. */ static void insert_operand (cpu, opcode, operand, mods, insn_buf, val, errmsg) dvp_cpu cpu; const dvp_opcode *opcode; const dvp_operand *operand; int mods; DVP_INSN *insn_buf; offsetT val; const char **errmsg; { if (operand->insert) { (*operand->insert) (opcode, operand, mods, insn_buf, (long) val, errmsg); } else { /* We currently assume a field does not cross a word boundary. */ int shift = ((mods & DVP_MOD_THIS_WORD) ? (operand->shift & 31) : operand->shift); /* FIXME: revisit */ if (operand->word == 0) { int word = (mods & DVP_MOD_THIS_WORD) ? 0 : (shift / 32); if (operand->bits == 32) insn_buf[word] = val; else { shift = shift % 32; insn_buf[word] |= ((long) val & ((1 << operand->bits) - 1)) << shift; } } else { int word = (mods & DVP_MOD_THIS_WORD) ? 0 : operand->word; if (operand->bits == 32) insn_buf[word] = val; else { long temp = (long) val & ((1 << operand->bits) - 1); insn_buf[word] |= temp << operand->shift; } } } } /* Insert an operand's final value into an instruction. Here we can give warning messages about operand values if we want to. */ static void insert_operand_final (cpu, operand, mods, insn_buf, val, file, line) dvp_cpu cpu; const dvp_operand *operand; int mods; DVP_INSN *insn_buf; offsetT val; char *file; unsigned int line; { if (operand->bits != 32) { offsetT min, max, test; if ((operand->flags & DVP_OPERAND_RELATIVE_BRANCH) != 0) { if ((val & 7) != 0) { if (file == (char *) NULL) as_warn ("branch to misaligned address"); else as_warn_where (file, line, "branch to misaligned address"); } val >>= 3; } if ((operand->flags & DVP_OPERAND_SIGNED) != 0) { if ((operand->flags & DVP_OPERAND_SIGNOPT) != 0) max = (1 << operand->bits) - 1; else max = (1 << (operand->bits - 1)) - 1; min = - (1 << (operand->bits - 1)); } else { max = (1 << operand->bits) - 1; min = 0; } if ((operand->flags & DVP_OPERAND_NEGATIVE) != 0) test = - val; else test = val; if (test < (offsetT) min || test > (offsetT) max) { const char *err = "operand out of range (%s not between %ld and %ld)"; char buf[100]; sprint_value (buf, test); if (file == (char *) NULL) as_warn (err, buf, min, max); else as_warn_where (file, line, err, buf, min, max); } } { const char *errmsg = NULL; insert_operand (cpu, NULL, operand, mods, insn_buf, val, &errmsg); if (errmsg != NULL) as_warn_where (file, line, errmsg); } } /* DVP pseudo ops. */ static void s_dmadata (ignore) int ignore; { char *name, c; dma_data_name = 0; if (dma_data_state != 0) { as_bad ("DmaData blocks cannot be nested."); ignore_rest_of_line (); return; } dma_data_state = 1; SKIP_WHITESPACE (); /* Leading whitespace is part of operand. */ name = input_line_pointer; if (!is_name_beginner (*name)) { as_bad ("invalid identifier for \".DmaData\""); ignore_rest_of_line (); return; } c = get_symbol_end (); line_label = colon (name); /* user-defined label */ dma_data_name = S_GET_NAME (line_label); *input_line_pointer = c; demand_empty_rest_of_line (); } static void s_enddmadata (ignore) int ignore; { if (dma_data_state != 1) { as_warn (".EndDmaData encountered outside a DmaData block -- ignored."); ignore_rest_of_line (); dma_data_name = 0; } dma_data_state = 0; demand_empty_rest_of_line (); /* If count provided, verify it is correct. */ /* ... */ /* "label" points to beginning of block. Create a name for the final label like _$. */ if (dma_data_name) { /* Fill the data out to a multiple of 16 bytes. */ /* FIXME: Are the fill contents right? */ frag_align (4, 0, 0); create_colon_label (0, END_LABEL_PREFIX, dma_data_name); } } static void s_dmapackvif (ignore) int ignore; { /* Syntax: .dmapackvif 0|1 */ symbolS *label; /* Points to symbol */ char *name; /* points to name of symbol */ /* Leading whitespace is part of operand. */ SKIP_WHITESPACE (); switch (*input_line_pointer++) { case '0': dma_pack_vif_p = 0; break; case '1': dma_pack_vif_p = 1; break; default: as_bad ("illegal argument to `.DmaPackPke'"); } demand_empty_rest_of_line (); } static void s_enddirect (ignore) int ignore; { int byte_len; if (CUR_ASM_STATE != ASM_DIRECT) { as_bad ("`.enddirect' has no matching `direct' instruction"); return; } byte_len = cur_vif_insn_length (); if (cur_varlen_value != -1 && cur_varlen_value * 16 != byte_len) as_warn ("length in `direct' instruction does not match length of data"); if (output_vif) install_vif_length (cur_varlen_insn, byte_len); set_asm_state (ASM_INIT); /* These needn't be reset, but to catch bugs they are. */ cur_varlen_frag = NULL; cur_varlen_insn = NULL; cur_varlen_value = 0; demand_empty_rest_of_line (); } /* INTERNAL_P is non-zero if invoked internally by this file rather than by the user. In this case we don't touch the input stream. */ static void s_endmpg (internal_p) int internal_p; { int byte_len; if (CUR_ASM_STATE != ASM_MPG) { as_bad ("`.endmpg' has no matching `mpg' instruction"); return; } byte_len = cur_vif_insn_length (); if (cur_varlen_value != -1 && cur_varlen_value * 8 != byte_len) as_warn ("length in `mpg' instruction does not match length of data"); if (output_vif) install_vif_length (cur_varlen_insn, byte_len); set_asm_state (ASM_INIT); /* These needn't be reset, but to catch bugs they are. */ cur_varlen_frag = NULL; cur_varlen_insn = NULL; cur_varlen_value = 0; /* Reset the vu insn counter. */ vu_count = -1; /* Update $.MpgLoc. */ vif_set_mpgloc (vif_get_mpgloc () + byte_len); if (! internal_p) demand_empty_rest_of_line (); } static void s_endunpack (ignore) int ignore; { int byte_len; if (CUR_ASM_STATE != ASM_UNPACK) { as_bad ("`.endunpack' has no matching `unpack' instruction"); return; } byte_len = cur_vif_insn_length (); #if 0 /* unpack doesn't support prespecifying a length */ if (cur_varlen_value * 16 != bytelen) as_warn ("length in `direct' instruction does not match length of data"); #endif if (output_vif) install_vif_length (cur_varlen_insn, byte_len); set_asm_state (ASM_INIT); /* These needn't be reset, but to catch bugs they are. */ cur_varlen_frag = NULL; cur_varlen_insn = NULL; cur_varlen_value = 0; /* Update $.UnpackLoc. */ vif_set_unpackloc (vif_get_unpackloc () + byte_len); demand_empty_rest_of_line (); } static void s_endgif (ignore) int ignore; { long count; int nloop = gif_nloop (); if (CUR_ASM_STATE != ASM_GIF) { as_bad (".endgif doesn't follow a gif tag"); return; } pop_asm_state (0); /* The -16 is because the `gif_data_name' label is emitted at the start of the gif tag. */ if (gif_insn_type == GIF_REGLIST) count = eval_expr (0, 0, "(. - %s - 16) >> 3", gif_data_name); else count = eval_expr (0, 0, "(. - %s - 16) >> 4", gif_data_name); if (count < 0 || fixup_count != 0) { as_warn ("bad data count"); return; } /* Validate nloop if specified. Otherwise write the computed value into the insn. */ if (nloop != -1) { int ok_p; switch (gif_insn_type) { case GIF_PACKED : case GIF_REGLIST : ok_p = count == nloop * gif_nregs (); break; case GIF_IMAGE : ok_p = count == nloop; break; } if (! ok_p) { as_warn ("nloop value does not match size of data"); return; } } else { DVP_INSN insn = bfd_getl32 (gif_insn_frag + 12); char *file; unsigned int line; as_where (&file, &line); insert_operand_final (DVP_GIF, &gif_operands[gif_operand_nloop], DVP_MOD_THIS_WORD, &insn, (offsetT) nloop, file, line); bfd_putl32 ((bfd_vma) insn, gif_insn_frag + 12); } gif_data_name = NULL; demand_empty_rest_of_line (); } static void s_state (state) int state; { /* If in MPG state and the user requests to change to VU state, leave the state as MPG. This happens when we see an mpg followed by a .include that has .vu. */ if (CUR_ASM_STATE == ASM_MPG && state == ASM_VU) return; set_asm_state (state); demand_empty_rest_of_line (); }