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/* tc-z80.c -- Assemble code for the Zilog Z80 and ASCII R800 Copyright 2005, 2006, 2007, 2008, 2009 Free Software Foundation, Inc. Contributed by Arnold Metselaar <arnold_m@operamail.com> 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 3, 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, 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */ #include "as.h" #include "safe-ctype.h" #include "subsegs.h" /* Exported constants. */ const char comment_chars[] = ";\0"; const char line_comment_chars[] = "#;\0"; const char line_separator_chars[] = "\0"; const char EXP_CHARS[] = "eE\0"; const char FLT_CHARS[] = "RrFf\0"; /* For machine specific options. */ const char * md_shortopts = ""; /* None yet. */ enum options { OPTION_MACH_Z80 = OPTION_MD_BASE, OPTION_MACH_R800, OPTION_MACH_IUD, OPTION_MACH_WUD, OPTION_MACH_FUD, OPTION_MACH_IUP, OPTION_MACH_WUP, OPTION_MACH_FUP }; #define INS_Z80 1 #define INS_UNDOC 2 #define INS_UNPORT 4 #define INS_R800 8 struct option md_longopts[] = { { "z80", no_argument, NULL, OPTION_MACH_Z80}, { "r800", no_argument, NULL, OPTION_MACH_R800}, { "ignore-undocumented-instructions", no_argument, NULL, OPTION_MACH_IUD }, { "Wnud", no_argument, NULL, OPTION_MACH_IUD }, { "warn-undocumented-instructions", no_argument, NULL, OPTION_MACH_WUD }, { "Wud", no_argument, NULL, OPTION_MACH_WUD }, { "forbid-undocumented-instructions", no_argument, NULL, OPTION_MACH_FUD }, { "Fud", no_argument, NULL, OPTION_MACH_FUD }, { "ignore-unportable-instructions", no_argument, NULL, OPTION_MACH_IUP }, { "Wnup", no_argument, NULL, OPTION_MACH_IUP }, { "warn-unportable-instructions", no_argument, NULL, OPTION_MACH_WUP }, { "Wup", no_argument, NULL, OPTION_MACH_WUP }, { "forbid-unportable-instructions", no_argument, NULL, OPTION_MACH_FUP }, { "Fup", no_argument, NULL, OPTION_MACH_FUP }, { NULL, no_argument, NULL, 0 } } ; size_t md_longopts_size = sizeof (md_longopts); extern int coff_flags; /* Instruction classes that silently assembled. */ static int ins_ok = INS_Z80 | INS_UNDOC; /* Instruction classes that generate errors. */ static int ins_err = INS_R800; /* Instruction classes actually used, determines machine type. */ static int ins_used = INS_Z80; int md_parse_option (int c, char* arg ATTRIBUTE_UNUSED) { switch (c) { default: return 0; case OPTION_MACH_Z80: ins_ok &= ~INS_R800; ins_err |= INS_R800; break; case OPTION_MACH_R800: ins_ok = INS_Z80 | INS_UNDOC | INS_R800; ins_err = INS_UNPORT; break; case OPTION_MACH_IUD: ins_ok |= INS_UNDOC; ins_err &= ~INS_UNDOC; break; case OPTION_MACH_IUP: ins_ok |= INS_UNDOC | INS_UNPORT; ins_err &= ~(INS_UNDOC | INS_UNPORT); break; case OPTION_MACH_WUD: if ((ins_ok & INS_R800) == 0) { ins_ok &= ~(INS_UNDOC|INS_UNPORT); ins_err &= ~INS_UNDOC; } break; case OPTION_MACH_WUP: ins_ok &= ~INS_UNPORT; ins_err &= ~(INS_UNDOC|INS_UNPORT); break; case OPTION_MACH_FUD: if ((ins_ok & INS_R800) == 0) { ins_ok &= (INS_UNDOC | INS_UNPORT); ins_err |= INS_UNDOC | INS_UNPORT; } break; case OPTION_MACH_FUP: ins_ok &= ~INS_UNPORT; ins_err |= INS_UNPORT; break; } return 1; } void md_show_usage (FILE * f) { fprintf (f, "\n\ CPU model/instruction set options:\n\ \n\ -z80\t\t assemble for Z80\n\ -ignore-undocumented-instructions\n\ -Wnud\n\ \tsilently assemble undocumented Z80-instructions that work on R800\n\ -ignore-unportable-instructions\n\ -Wnup\n\ \tsilently assemble all undocumented Z80-instructions\n\ -warn-undocumented-instructions\n\ -Wud\n\ \tissue warnings for undocumented Z80-instructions that work on R800\n\ -warn-unportable-instructions\n\ -Wup\n\ \tissue warnings for other undocumented Z80-instructions\n\ -forbid-undocumented-instructions\n\ -Fud\n\ \ttreat all undocumented z80-instructions as errors\n\ -forbid-unportable-instructions\n\ -Fup\n\ \ttreat undocumented z80-instructions that do not work on R800 as errors\n\ -r800\t assemble for R800\n\n\ Default: -z80 -ignore-undocument-instructions -warn-unportable-instructions.\n"); } static symbolS * zero; void md_begin (void) { expressionS nul; char * p; p = input_line_pointer; input_line_pointer = "0"; nul.X_md=0; expression (& nul); input_line_pointer = p; zero = make_expr_symbol (& nul); /* We do not use relaxation (yet). */ linkrelax = 0; } void z80_md_end (void) { int mach_type; if (ins_used & (INS_UNPORT | INS_R800)) ins_used |= INS_UNDOC; switch (ins_used) { case INS_Z80: mach_type = bfd_mach_z80strict; break; case INS_Z80|INS_UNDOC: mach_type = bfd_mach_z80; break; case INS_Z80|INS_UNDOC|INS_UNPORT: mach_type = bfd_mach_z80full; break; case INS_Z80|INS_UNDOC|INS_R800: mach_type = bfd_mach_r800; break; default: mach_type = 0; } bfd_set_arch_mach (stdoutput, TARGET_ARCH, mach_type); } static const char * skip_space (const char *s) { while (*s == ' ' || *s == '\t') ++s; return s; } /* A non-zero return-value causes a continue in the function read_a_source_file () in ../read.c. */ int z80_start_line_hook (void) { char *p, quote; char buf[4]; /* Convert one character constants. */ for (p = input_line_pointer; *p && *p != '\n'; ++p) { switch (*p) { case '\'': if (p[1] != 0 && p[1] != '\'' && p[2] == '\'') { snprintf (buf, 4, "%3d", (unsigned char)p[1]); *p++ = buf[0]; *p++ = buf[1]; *p++ = buf[2]; break; } case '"': for (quote = *p++; quote != *p && '\n' != *p; ++p) /* No escapes. */ ; if (quote != *p) { as_bad (_("-- unterminated string")); ignore_rest_of_line (); return 1; } break; } } /* Check for <label>[:] [.](EQU|DEFL) <value>. */ if (is_name_beginner (*input_line_pointer)) { char c, *rest, *line_start; int len; symbolS * symbolP; line_start = input_line_pointer; LISTING_NEWLINE (); if (ignore_input ()) return 0; c = get_symbol_end (); rest = input_line_pointer + 1; if (*rest == ':') ++rest; if (*rest == ' ' || *rest == '\t') ++rest; if (*rest == '.') ++rest; if (strncasecmp (rest, "EQU", 3) == 0) len = 3; else if (strncasecmp (rest, "DEFL", 4) == 0) len = 4; else len = 0; if (len && (rest[len] == ' ' || rest[len] == '\t')) { /* Handle assignment here. */ input_line_pointer = rest + len; if (line_start[-1] == '\n') bump_line_counters (); /* Most Z80 assemblers require the first definition of a label to use "EQU" and redefinitions to have "DEFL". */ if (len == 3 && (symbolP = symbol_find (line_start)) != NULL) { if (S_IS_DEFINED (symbolP) || symbol_equated_p (symbolP)) as_bad (_("symbol `%s' is already defined"), line_start); } equals (line_start, 1); return 1; } else { /* Restore line and pointer. */ *input_line_pointer = c; input_line_pointer = line_start; } } return 0; } symbolS * md_undefined_symbol (char *name ATTRIBUTE_UNUSED) { return NULL; } char * md_atof (int type ATTRIBUTE_UNUSED, char *litP ATTRIBUTE_UNUSED, int *sizeP ATTRIBUTE_UNUSED) { return _("floating point numbers are not implemented"); } valueT md_section_align (segT seg ATTRIBUTE_UNUSED, valueT size) { return size; } long md_pcrel_from (fixS * fixp) { return fixp->fx_where + fixp->fx_frag->fr_address + 1; } typedef const char * (asfunc)(char, char, const char*); typedef struct _table_t { char* name; char prefix; char opcode; asfunc * fp; } table_t; /* Compares the key for structs that start with a char * to the key. */ static int key_cmp (const void * a, const void * b) { const char *str_a, *str_b; str_a = *((const char**)a); str_b = *((const char**)b); return strcmp (str_a, str_b); } #define BUFLEN 8 /* Large enough for any keyword. */ char buf[BUFLEN]; const char *key = buf; #define R_STACKABLE (0x80) #define R_ARITH (0x40) #define R_IX (0x20) #define R_IY (0x10) #define R_INDEX (R_IX | R_IY) #define REG_A (7) #define REG_B (0) #define REG_C (1) #define REG_D (2) #define REG_E (3) #define REG_H (4) #define REG_L (5) #define REG_F (6 | 8) #define REG_I (9) #define REG_R (10) #define REG_AF (3 | R_STACKABLE) #define REG_BC (0 | R_STACKABLE | R_ARITH) #define REG_DE (1 | R_STACKABLE | R_ARITH) #define REG_HL (2 | R_STACKABLE | R_ARITH) #define REG_SP (3 | R_ARITH) static const struct reg_entry { char* name; int number; } regtable[] = { {"a", REG_A }, {"af", REG_AF }, {"b", REG_B }, {"bc", REG_BC }, {"c", REG_C }, {"d", REG_D }, {"de", REG_DE }, {"e", REG_E }, {"f", REG_F }, {"h", REG_H }, {"hl", REG_HL }, {"i", REG_I }, {"ix", REG_HL | R_IX }, {"ixh",REG_H | R_IX }, {"ixl",REG_L | R_IX }, {"iy", REG_HL | R_IY }, {"iyh",REG_H | R_IY }, {"iyl",REG_L | R_IY }, {"l", REG_L }, {"r", REG_R }, {"sp", REG_SP }, } ; /* Prevent an error on a line from also generating a "junk at end of line" error message. */ static char err_flag; static void error (const char * message) { as_bad ("%s", message); err_flag = 1; } static void ill_op (void) { error (_("illegal operand")); } static void wrong_mach (int ins_type) { const char *p; switch (ins_type) { case INS_UNDOC: p = "undocumented instruction"; break; case INS_UNPORT: p = "instruction does not work on R800"; break; case INS_R800: p = "instruction only works R800"; break; default: p = 0; /* Not reachable. */ } if (ins_type & ins_err) error (_(p)); else as_warn (_(p)); } static void check_mach (int ins_type) { if ((ins_type & ins_ok) == 0) wrong_mach (ins_type); ins_used |= ins_type; } /* Check whether an expression is indirect. */ static int is_indir (const char *s) { char quote; const char *p; int indir, depth; /* Indirection is indicated with parentheses. */ indir = (*s == '('); for (p = s, depth = 0; *p && *p != ','; ++p) { switch (*p) { case '"': case '\'': for (quote = *p++; quote != *p && *p != '\n'; ++p) if (*p == '\\' && p[1]) ++p; break; case '(': ++ depth; break; case ')': -- depth; if (depth == 0) { p = skip_space (p + 1); if (*p && *p != ',') indir = 0; --p; } if (depth < 0) error (_("mismatched parentheses")); break; } } if (depth != 0) error (_("mismatched parentheses")); return indir; } /* Parse general expression. */ static const char * parse_exp2 (const char *s, expressionS *op, segT *pseg) { const char *p; int indir; int i; const struct reg_entry * regp; expressionS offset; p = skip_space (s); op->X_md = indir = is_indir (p); if (indir) p = skip_space (p + 1); for (i = 0; i < BUFLEN; ++i) { if (!ISALPHA (p[i])) /* Register names consist of letters only. */ break; buf[i] = TOLOWER (p[i]); } if ((i < BUFLEN) && ((p[i] == 0) || (strchr (")+-, \t", p[i])))) { buf[i] = 0; regp = bsearch (& key, regtable, ARRAY_SIZE (regtable), sizeof (regtable[0]), key_cmp); if (regp) { *pseg = reg_section; op->X_add_symbol = op->X_op_symbol = 0; op->X_add_number = regp->number; op->X_op = O_register; p += strlen (regp->name); p = skip_space (p); if (indir) { if (*p == ')') ++p; if ((regp->number & R_INDEX) && (regp->number & R_ARITH)) { op->X_op = O_md1; if ((*p == '+') || (*p == '-')) { input_line_pointer = (char*) p; expression (& offset); p = skip_space (input_line_pointer); if (*p != ')') error (_("bad offset expression syntax")); else ++ p; op->X_add_symbol = make_expr_symbol (& offset); return p; } /* We treat (i[xy]) as (i[xy]+0), which is how it will end up anyway, unless we're processing jp (i[xy]). */ op->X_add_symbol = zero; } } p = skip_space (p); if ((*p == 0) || (*p == ',')) return p; } } /* Not an argument involving a register; use the generic parser. */ input_line_pointer = (char*) s ; *pseg = expression (op); if (op->X_op == O_absent) error (_("missing operand")); if (op->X_op == O_illegal) error (_("bad expression syntax")); return input_line_pointer; } static const char * parse_exp (const char *s, expressionS *op) { segT dummy; return parse_exp2 (s, op, & dummy); } /* Condition codes, including some synonyms provided by HiTech zas. */ static const struct reg_entry cc_tab[] = { { "age", 6 << 3 }, { "alt", 7 << 3 }, { "c", 3 << 3 }, { "di", 4 << 3 }, { "ei", 5 << 3 }, { "lge", 2 << 3 }, { "llt", 3 << 3 }, { "m", 7 << 3 }, { "nc", 2 << 3 }, { "nz", 0 << 3 }, { "p", 6 << 3 }, { "pe", 5 << 3 }, { "po", 4 << 3 }, { "z", 1 << 3 }, } ; /* Parse condition code. */ static const char * parse_cc (const char *s, char * op) { const char *p; int i; struct reg_entry * cc_p; for (i = 0; i < BUFLEN; ++i) { if (!ISALPHA (s[i])) /* Condition codes consist of letters only. */ break; buf[i] = TOLOWER (s[i]); } if ((i < BUFLEN) && ((s[i] == 0) || (s[i] == ','))) { buf[i] = 0; cc_p = bsearch (&key, cc_tab, ARRAY_SIZE (cc_tab), sizeof (cc_tab[0]), key_cmp); } else cc_p = NULL; if (cc_p) { *op = cc_p->number; p = s + i; } else p = NULL; return p; } static const char * emit_insn (char prefix, char opcode, const char * args) { char *p; if (prefix) { p = frag_more (2); *p++ = prefix; } else p = frag_more (1); *p = opcode; return args; } void z80_cons_fix_new (fragS *frag_p, int offset, int nbytes, expressionS *exp) { bfd_reloc_code_real_type r[4] = { BFD_RELOC_8, BFD_RELOC_16, BFD_RELOC_24, BFD_RELOC_32 }; if (nbytes < 1 || nbytes > 4) { as_bad (_("unsupported BFD relocation size %u"), nbytes); } else { fix_new_exp (frag_p, offset, nbytes, exp, 0, r[nbytes-1]); } } static void emit_byte (expressionS * val, bfd_reloc_code_real_type r_type) { char *p; int lo, hi; fixS * fixp; p = frag_more (1); *p = val->X_add_number; if ((r_type == BFD_RELOC_8_PCREL) && (val->X_op == O_constant)) { as_bad (_("cannot make a relative jump to an absolute location")); } else if (val->X_op == O_constant) { lo = -128; hi = (BFD_RELOC_8 == r_type) ? 255 : 127; if ((val->X_add_number < lo) || (val->X_add_number > hi)) { if (r_type == BFD_RELOC_Z80_DISP8) as_bad (_("offset too large")); else as_warn (_("overflow")); } } else { fixp = fix_new_exp (frag_now, p - frag_now->fr_literal, 1, val, (r_type == BFD_RELOC_8_PCREL) ? TRUE : FALSE, r_type); /* FIXME : Process constant offsets immediately. */ } } static void emit_word (expressionS * val) { char *p; p = frag_more (2); if ( (val->X_op == O_register) || (val->X_op == O_md1)) ill_op (); else { *p = val->X_add_number; p[1] = (val->X_add_number>>8); if (val->X_op != O_constant) fix_new_exp (frag_now, p - frag_now->fr_literal, 2, val, FALSE, BFD_RELOC_16); } } static void emit_mx (char prefix, char opcode, int shift, expressionS * arg) /* The operand m may be r, (hl), (ix+d), (iy+d), if 0 == prefix m may also be ixl, ixh, iyl, iyh. */ { char *q; int rnum; rnum = arg->X_add_number; switch (arg->X_op) { case O_register: if (arg->X_md) { if (rnum != REG_HL) { ill_op (); break; } else rnum = 6; } else { if ((prefix == 0) && (rnum & R_INDEX)) { prefix = (rnum & R_IX) ? 0xDD : 0xFD; check_mach (INS_UNDOC); rnum &= ~R_INDEX; } if (rnum > 7) { ill_op (); break; } } q = frag_more (prefix ? 2 : 1); if (prefix) * q ++ = prefix; * q ++ = opcode + (rnum << shift); break; case O_md1: q = frag_more (2); *q++ = (rnum & R_IX) ? 0xDD : 0xFD; *q = (prefix) ? prefix : (opcode + (6 << shift)); emit_byte (symbol_get_value_expression (arg->X_add_symbol), BFD_RELOC_Z80_DISP8); if (prefix) { q = frag_more (1); *q = opcode+(6<<shift); } break; default: abort (); } } /* The operand m may be r, (hl), (ix+d), (iy+d), if 0 = prefix m may also be ixl, ixh, iyl, iyh. */ static const char * emit_m (char prefix, char opcode, const char *args) { expressionS arg_m; const char *p; p = parse_exp (args, &arg_m); switch (arg_m.X_op) { case O_md1: case O_register: emit_mx (prefix, opcode, 0, &arg_m); break; default: ill_op (); } return p; } /* The operand m may be as above or one of the undocumented combinations (ix+d),r and (iy+d),r (if unportable instructions are allowed). */ static const char * emit_mr (char prefix, char opcode, const char *args) { expressionS arg_m, arg_r; const char *p; p = parse_exp (args, & arg_m); switch (arg_m.X_op) { case O_md1: if (*p == ',') { p = parse_exp (p + 1, & arg_r); if ((arg_r.X_md == 0) && (arg_r.X_op == O_register) && (arg_r.X_add_number < 8)) opcode += arg_r.X_add_number-6; /* Emit_mx () will add 6. */ else { ill_op (); break; } check_mach (INS_UNPORT); } case O_register: emit_mx (prefix, opcode, 0, & arg_m); break; default: ill_op (); } return p; } static void emit_sx (char prefix, char opcode, expressionS * arg_p) { char *q; switch (arg_p->X_op) { case O_register: case O_md1: emit_mx (prefix, opcode, 0, arg_p); break; default: if (arg_p->X_md) ill_op (); else { q = frag_more (prefix ? 2 : 1); if (prefix) *q++ = prefix; *q = opcode ^ 0x46; emit_byte (arg_p, BFD_RELOC_8); } } } /* The operand s may be r, (hl), (ix+d), (iy+d), n. */ static const char * emit_s (char prefix, char opcode, const char *args) { expressionS arg_s; const char *p; p = parse_exp (args, & arg_s); emit_sx (prefix, opcode, & arg_s); return p; } static const char * emit_call (char prefix ATTRIBUTE_UNUSED, char opcode, const char * args) { expressionS addr; const char *p; char *q; p = parse_exp (args, &addr); if (addr.X_md) ill_op (); else { q = frag_more (1); *q = opcode; emit_word (& addr); } return p; } /* Operand may be rr, r, (hl), (ix+d), (iy+d). */ static const char * emit_incdec (char prefix, char opcode, const char * args) { expressionS operand; int rnum; const char *p; char *q; p = parse_exp (args, &operand); rnum = operand.X_add_number; if ((! operand.X_md) && (operand.X_op == O_register) && (R_ARITH&rnum)) { q = frag_more ((rnum & R_INDEX) ? 2 : 1); if (rnum & R_INDEX) *q++ = (rnum & R_IX) ? 0xDD : 0xFD; *q = prefix + ((rnum & 3) << 4); } else { if ((operand.X_op == O_md1) || (operand.X_op == O_register)) emit_mx (0, opcode, 3, & operand); else ill_op (); } return p; } static const char * emit_jr (char prefix ATTRIBUTE_UNUSED, char opcode, const char * args) { expressionS addr; const char *p; char *q; p = parse_exp (args, &addr); if (addr.X_md) ill_op (); else { q = frag_more (1); *q = opcode; emit_byte (&addr, BFD_RELOC_8_PCREL); } return p; } static const char * emit_jp (char prefix, char opcode, const char * args) { expressionS addr; const char *p; char *q; int rnum; p = parse_exp (args, & addr); if (addr.X_md) { rnum = addr.X_add_number; if ((addr.X_op == O_register && (rnum & ~R_INDEX) == REG_HL) /* An operand (i[xy]) would have been rewritten to (i[xy]+0) in parse_exp (). */ || (addr.X_op == O_md1 && addr.X_add_symbol == zero)) { q = frag_more ((rnum & R_INDEX) ? 2 : 1); if (rnum & R_INDEX) *q++ = (rnum & R_IX) ? 0xDD : 0xFD; *q = prefix; } else ill_op (); } else { q = frag_more (1); *q = opcode; emit_word (& addr); } return p; } static const char * emit_im (char prefix, char opcode, const char * args) { expressionS mode; const char *p; char *q; p = parse_exp (args, & mode); if (mode.X_md || (mode.X_op != O_constant)) ill_op (); else switch (mode.X_add_number) { case 1: case 2: ++mode.X_add_number; /* Fall through. */ case 0: q = frag_more (2); *q++ = prefix; *q = opcode + 8*mode.X_add_number; break; default: ill_op (); } return p; } static const char * emit_pop (char prefix ATTRIBUTE_UNUSED, char opcode, const char * args) { expressionS regp; const char *p; char *q; p = parse_exp (args, & regp); if ((!regp.X_md) && (regp.X_op == O_register) && (regp.X_add_number & R_STACKABLE)) { int rnum; rnum = regp.X_add_number; if (rnum&R_INDEX) { q = frag_more (2); *q++ = (rnum&R_IX)?0xDD:0xFD; } else q = frag_more (1); *q = opcode + ((rnum & 3) << 4); } else ill_op (); return p; } static const char * emit_retcc (char prefix ATTRIBUTE_UNUSED, char opcode, const char * args) { char cc, *q; const char *p; p = parse_cc (args, &cc); q = frag_more (1); if (p) *q = opcode + cc; else *q = prefix; return p ? p : args; } static const char * emit_adc (char prefix, char opcode, const char * args) { expressionS term; int rnum; const char *p; char *q; p = parse_exp (args, &term); if (*p++ != ',') { error (_("bad intruction syntax")); return p; } if ((term.X_md) || (term.X_op != O_register)) ill_op (); else switch (term.X_add_number) { case REG_A: p = emit_s (0, prefix, p); break; case REG_HL: p = parse_exp (p, &term); if ((!term.X_md) && (term.X_op == O_register)) { rnum = term.X_add_number; if (R_ARITH == (rnum & (R_ARITH | R_INDEX))) { q = frag_more (2); *q++ = 0xED; *q = opcode + ((rnum & 3) << 4); break; } } /* Fall through. */ default: ill_op (); } return p; } static const char * emit_add (char prefix, char opcode, const char * args) { expressionS term; int lhs, rhs; const char *p; char *q; p = parse_exp (args, &term); if (*p++ != ',') { error (_("bad intruction syntax")); return p; } if ((term.X_md) || (term.X_op != O_register)) ill_op (); else switch (term.X_add_number & ~R_INDEX) { case REG_A: p = emit_s (0, prefix, p); break; case REG_HL: lhs = term.X_add_number; p = parse_exp (p, &term); if ((!term.X_md) && (term.X_op == O_register)) { rhs = term.X_add_number; if ((rhs & R_ARITH) && ((rhs == lhs) || ((rhs & ~R_INDEX) != REG_HL))) { q = frag_more ((lhs & R_INDEX) ? 2 : 1); if (lhs & R_INDEX) *q++ = (lhs & R_IX) ? 0xDD : 0xFD; *q = opcode + ((rhs & 3) << 4); break; } } /* Fall through. */ default: ill_op (); } return p; } static const char * emit_bit (char prefix, char opcode, const char * args) { expressionS b; int bn; const char *p; p = parse_exp (args, &b); if (*p++ != ',') error (_("bad intruction syntax")); bn = b.X_add_number; if ((!b.X_md) && (b.X_op == O_constant) && (0 <= bn) && (bn < 8)) { if (opcode == 0x40) /* Bit : no optional third operand. */ p = emit_m (prefix, opcode + (bn << 3), p); else /* Set, res : resulting byte can be copied to register. */ p = emit_mr (prefix, opcode + (bn << 3), p); } else ill_op (); return p; } static const char * emit_jpcc (char prefix, char opcode, const char * args) { char cc; const char *p; p = parse_cc (args, & cc); if (p && *p++ == ',') p = emit_call (0, opcode + cc, p); else p = (prefix == (char)0xC3) ? emit_jp (0xE9, prefix, args) : emit_call (0, prefix, args); return p; } static const char * emit_jrcc (char prefix, char opcode, const char * args) { char cc; const char *p; p = parse_cc (args, &cc); if (p && *p++ == ',') { if (cc > (3 << 3)) error (_("condition code invalid for jr")); else p = emit_jr (0, opcode + cc, p); } else p = emit_jr (0, prefix, args); return p; } static const char * emit_ex (char prefix_in ATTRIBUTE_UNUSED, char opcode_in ATTRIBUTE_UNUSED, const char * args) { expressionS op; const char * p; char prefix, opcode; p = parse_exp (args, &op); p = skip_space (p); if (*p++ != ',') { error (_("bad instruction syntax")); return p; } prefix = opcode = 0; if (op.X_op == O_register) switch (op.X_add_number | (op.X_md ? 0x8000 : 0)) { case REG_AF: if (TOLOWER (*p++) == 'a' && TOLOWER (*p++) == 'f') { /* The scrubber changes '\'' to '`' in this context. */ if (*p == '`') ++p; opcode = 0x08; } break; case REG_DE: if (TOLOWER (*p++) == 'h' && TOLOWER (*p++) == 'l') opcode = 0xEB; break; case REG_SP|0x8000: p = parse_exp (p, & op); if (op.X_op == O_register && op.X_md == 0 && (op.X_add_number & ~R_INDEX) == REG_HL) { opcode = 0xE3; if (R_INDEX & op.X_add_number) prefix = (R_IX & op.X_add_number) ? 0xDD : 0xFD; } break; } if (opcode) emit_insn (prefix, opcode, p); else ill_op (); return p; } static const char * emit_in (char prefix ATTRIBUTE_UNUSED, char opcode ATTRIBUTE_UNUSED, const char * args) { expressionS reg, port; const char *p; char *q; p = parse_exp (args, ®); if (*p++ != ',') { error (_("bad intruction syntax")); return p; } p = parse_exp (p, &port); if (reg.X_md == 0 && reg.X_op == O_register && (reg.X_add_number <= 7 || reg.X_add_number == REG_F) && (port.X_md)) { if (port.X_op != O_md1 && port.X_op != O_register) { if (REG_A == reg.X_add_number) { q = frag_more (1); *q = 0xDB; emit_byte (&port, BFD_RELOC_8); } else ill_op (); } else { if (port.X_add_number == REG_C) { if (reg.X_add_number == REG_F) check_mach (INS_UNDOC); else { q = frag_more (2); *q++ = 0xED; *q = 0x40|((reg.X_add_number&7)<<3); } } else ill_op (); } } else ill_op (); return p; } static const char * emit_out (char prefix ATTRIBUTE_UNUSED, char opcode ATTRIBUTE_UNUSED, const char * args) { expressionS reg, port; const char *p; char *q; p = parse_exp (args, & port); if (*p++ != ',') { error (_("bad intruction syntax")); return p; } p = parse_exp (p, ®); if (!port.X_md) { ill_op (); return p; } /* Allow "out (c), 0" as unportable instruction. */ if (reg.X_op == O_constant && reg.X_add_number == 0) { check_mach (INS_UNPORT); reg.X_op = O_register; reg.X_add_number = 6; } if (reg.X_md || reg.X_op != O_register || reg.X_add_number > 7) ill_op (); else if (port.X_op != O_register && port.X_op != O_md1) { if (REG_A == reg.X_add_number) { q = frag_more (1); *q = 0xD3; emit_byte (&port, BFD_RELOC_8); } else ill_op (); } else { if (REG_C == port.X_add_number) { q = frag_more (2); *q++ = 0xED; *q = 0x41 | (reg.X_add_number << 3); } else ill_op (); } return p; } static const char * emit_rst (char prefix ATTRIBUTE_UNUSED, char opcode, const char * args) { expressionS addr; const char *p; char *q; p = parse_exp (args, &addr); if (addr.X_op != O_constant) { error ("rst needs constant address"); return p; } if (addr.X_add_number & ~(7 << 3)) ill_op (); else { q = frag_more (1); *q = opcode + (addr.X_add_number & (7 << 3)); } return p; } static void emit_ldxhl (char prefix, char opcode, expressionS *src, expressionS *d) { char *q; if (src->X_md) ill_op (); else { if (src->X_op == O_register) { if (src->X_add_number>7) ill_op (); if (prefix) { q = frag_more (2); *q++ = prefix; } else q = frag_more (1); *q = opcode + src->X_add_number; if (d) emit_byte (d, BFD_RELOC_Z80_DISP8); } else { if (prefix) { q = frag_more (2); *q++ = prefix; } else q = frag_more (1); *q = opcode^0x46; if (d) emit_byte (d, BFD_RELOC_Z80_DISP8); emit_byte (src, BFD_RELOC_8); } } } static void emit_ldreg (int dest, expressionS * src) { char *q; int rnum; switch (dest) { /* 8 Bit ld group: */ case REG_I: case REG_R: if (src->X_md == 0 && src->X_op == O_register && src->X_add_number == REG_A) { q = frag_more (2); *q++ = 0xED; *q = (dest == REG_I) ? 0x47 : 0x4F; } else ill_op (); break; case REG_A: if ((src->X_md) && src->X_op != O_register && src->X_op != O_md1) { q = frag_more (1); *q = 0x3A; emit_word (src); break; } if ((src->X_md) && src->X_op == O_register && (src->X_add_number == REG_BC || src->X_add_number == REG_DE)) { q = frag_more (1); *q = 0x0A + ((src->X_add_number & 1) << 4); break; } if ((!src->X_md) && src->X_op == O_register && (src->X_add_number == REG_R || src->X_add_number == REG_I)) { q = frag_more (2); *q++ = 0xED; *q = (src->X_add_number == REG_I) ? 0x57 : 0x5F; break; } /* Fall through. */ case REG_B: case REG_C: case REG_D: case REG_E: emit_sx (0, 0x40 + (dest << 3), src); break; case REG_H: case REG_L: if ((src->X_md == 0) && (src->X_op == O_register) && (src->X_add_number & R_INDEX)) ill_op (); else emit_sx (0, 0x40 + (dest << 3), src); break; case R_IX | REG_H: case R_IX | REG_L: case R_IY | REG_H: case R_IY | REG_L: if (src->X_md) { ill_op (); break; } check_mach (INS_UNDOC); if (src-> X_op == O_register) { rnum = src->X_add_number; if ((rnum & ~R_INDEX) < 8 && ((rnum & R_INDEX) == (dest & R_INDEX) || ( (rnum & ~R_INDEX) != REG_H && (rnum & ~R_INDEX) != REG_L))) { q = frag_more (2); *q++ = (dest & R_IX) ? 0xDD : 0xFD; *q = 0x40 + ((dest & 0x07) << 3) + (rnum & 7); } else ill_op (); } else { q = frag_more (2); *q++ = (dest & R_IX) ? 0xDD : 0xFD; *q = 0x06 + ((dest & 0x07) << 3); emit_byte (src, BFD_RELOC_8); } break; /* 16 Bit ld group: */ case REG_SP: if (src->X_md == 0 && src->X_op == O_register && REG_HL == (src->X_add_number &~ R_INDEX)) { q = frag_more ((src->X_add_number & R_INDEX) ? 2 : 1); if (src->X_add_number & R_INDEX) *q++ = (src->X_add_number & R_IX) ? 0xDD : 0xFD; *q = 0xF9; break; } /* Fall through. */ case REG_BC: case REG_DE: if (src->X_op == O_register || src->X_op == O_md1) ill_op (); q = frag_more (src->X_md ? 2 : 1); if (src->X_md) { *q++ = 0xED; *q = 0x4B + ((dest & 3) << 4); } else *q = 0x01 + ((dest & 3) << 4); emit_word (src); break; case REG_HL: case REG_HL | R_IX: case REG_HL | R_IY: if (src->X_op == O_register || src->X_op == O_md1) ill_op (); q = frag_more ((dest & R_INDEX) ? 2 : 1); if (dest & R_INDEX) * q ++ = (dest & R_IX) ? 0xDD : 0xFD; *q = (src->X_md) ? 0x2A : 0x21; emit_word (src); break; case REG_AF: case REG_F: ill_op (); break; default: abort (); } } static const char * emit_ld (char prefix_in ATTRIBUTE_UNUSED, char opcode_in ATTRIBUTE_UNUSED, const char * args) { expressionS dst, src; const char *p; char *q; char prefix, opcode; p = parse_exp (args, &dst); if (*p++ != ',') error (_("bad intruction syntax")); p = parse_exp (p, &src); switch (dst.X_op) { case O_md1: emit_ldxhl ((dst.X_add_number & R_IX) ? 0xDD : 0xFD, 0x70, &src, symbol_get_value_expression (dst.X_add_symbol)); break; case O_register: if (dst.X_md) { switch (dst.X_add_number) { case REG_BC: case REG_DE: if (src.X_md == 0 && src.X_op == O_register && src.X_add_number == REG_A) { q = frag_more (1); *q = 0x02 + ( (dst.X_add_number & 1) << 4); } else ill_op (); break; case REG_HL: emit_ldxhl (0, 0x70, &src, NULL); break; default: ill_op (); } } else emit_ldreg (dst.X_add_number, &src); break; default: if (src.X_md != 0 || src.X_op != O_register) ill_op (); prefix = opcode = 0; switch (src.X_add_number) { case REG_A: opcode = 0x32; break; case REG_BC: case REG_DE: case REG_SP: prefix = 0xED; opcode = 0x43 + ((src.X_add_number&3)<<4); break; case REG_HL: opcode = 0x22; break; case REG_HL|R_IX: prefix = 0xDD; opcode = 0x22; break; case REG_HL|R_IY: prefix = 0xFD; opcode = 0x22; break; } if (opcode) { q = frag_more (prefix?2:1); if (prefix) *q++ = prefix; *q = opcode; emit_word (&dst); } else ill_op (); } return p; } static void emit_data (int size ATTRIBUTE_UNUSED) { const char *p, *q; char *u, quote; int cnt; expressionS exp; if (is_it_end_of_statement ()) { demand_empty_rest_of_line (); return; } p = skip_space (input_line_pointer); do { if (*p == '\"' || *p == '\'') { for (quote = *p, q = ++p, cnt = 0; *p && quote != *p; ++p, ++cnt) ; u = frag_more (cnt); memcpy (u, q, cnt); if (!*p) as_warn (_("unterminated string")); else p = skip_space (p+1); } else { p = parse_exp (p, &exp); if (exp.X_op == O_md1 || exp.X_op == O_register) { ill_op (); break; } if (exp.X_md) as_warn (_("parentheses ignored")); emit_byte (&exp, BFD_RELOC_8); p = skip_space (p); } } while (*p++ == ',') ; input_line_pointer = (char *)(p-1); } static const char * emit_mulub (char prefix ATTRIBUTE_UNUSED, char opcode, const char * args) { const char *p; p = skip_space (args); if (TOLOWER (*p++) != 'a' || *p++ != ',') ill_op (); else { char *q, reg; reg = TOLOWER (*p++); switch (reg) { case 'b': case 'c': case 'd': case 'e': check_mach (INS_R800); if (!*skip_space (p)) { q = frag_more (2); *q++ = prefix; *q = opcode + ((reg - 'b') << 3); break; } default: ill_op (); } } return p; } static const char * emit_muluw (char prefix ATTRIBUTE_UNUSED, char opcode, const char * args) { const char *p; p = skip_space (args); if (TOLOWER (*p++) != 'h' || TOLOWER (*p++) != 'l' || *p++ != ',') ill_op (); else { expressionS reg; char *q; p = parse_exp (p, & reg); if ((!reg.X_md) && reg.X_op == O_register) switch (reg.X_add_number) { case REG_BC: case REG_SP: check_mach (INS_R800); q = frag_more (2); *q++ = prefix; *q = opcode + ((reg.X_add_number & 3) << 4); break; default: ill_op (); } } return p; } /* Port specific pseudo ops. */ const pseudo_typeS md_pseudo_table[] = { { "db" , emit_data, 1}, { "d24", cons, 3}, { "d32", cons, 4}, { "def24", cons, 3}, { "def32", cons, 4}, { "defb", emit_data, 1}, { "defs", s_space, 1}, /* Synonym for ds on some assemblers. */ { "defw", cons, 2}, { "ds", s_space, 1}, /* Fill with bytes rather than words. */ { "dw", cons, 2}, { "psect", obj_coff_section, 0}, /* TODO: Translate attributes. */ { "set", 0, 0}, /* Real instruction on z80. */ { NULL, 0, 0 } } ; static table_t instab[] = { { "adc", 0x88, 0x4A, emit_adc }, { "add", 0x80, 0x09, emit_add }, { "and", 0x00, 0xA0, emit_s }, { "bit", 0xCB, 0x40, emit_bit }, { "call", 0xCD, 0xC4, emit_jpcc }, { "ccf", 0x00, 0x3F, emit_insn }, { "cp", 0x00, 0xB8, emit_s }, { "cpd", 0xED, 0xA9, emit_insn }, { "cpdr", 0xED, 0xB9, emit_insn }, { "cpi", 0xED, 0xA1, emit_insn }, { "cpir", 0xED, 0xB1, emit_insn }, { "cpl", 0x00, 0x2F, emit_insn }, { "daa", 0x00, 0x27, emit_insn }, { "dec", 0x0B, 0x05, emit_incdec }, { "di", 0x00, 0xF3, emit_insn }, { "djnz", 0x00, 0x10, emit_jr }, { "ei", 0x00, 0xFB, emit_insn }, { "ex", 0x00, 0x00, emit_ex}, { "exx", 0x00, 0xD9, emit_insn }, { "halt", 0x00, 0x76, emit_insn }, { "im", 0xED, 0x46, emit_im }, { "in", 0x00, 0x00, emit_in }, { "inc", 0x03, 0x04, emit_incdec }, { "ind", 0xED, 0xAA, emit_insn }, { "indr", 0xED, 0xBA, emit_insn }, { "ini", 0xED, 0xA2, emit_insn }, { "inir", 0xED, 0xB2, emit_insn }, { "jp", 0xC3, 0xC2, emit_jpcc }, { "jr", 0x18, 0x20, emit_jrcc }, { "ld", 0x00, 0x00, emit_ld }, { "ldd", 0xED, 0xA8, emit_insn }, { "lddr", 0xED, 0xB8, emit_insn }, { "ldi", 0xED, 0xA0, emit_insn }, { "ldir", 0xED, 0xB0, emit_insn }, { "mulub", 0xED, 0xC5, emit_mulub }, /* R800 only. */ { "muluw", 0xED, 0xC3, emit_muluw }, /* R800 only. */ { "neg", 0xed, 0x44, emit_insn }, { "nop", 0x00, 0x00, emit_insn }, { "or", 0x00, 0xB0, emit_s }, { "otdr", 0xED, 0xBB, emit_insn }, { "otir", 0xED, 0xB3, emit_insn }, { "out", 0x00, 0x00, emit_out }, { "outd", 0xED, 0xAB, emit_insn }, { "outi", 0xED, 0xA3, emit_insn }, { "pop", 0x00, 0xC1, emit_pop }, { "push", 0x00, 0xC5, emit_pop }, { "res", 0xCB, 0x80, emit_bit }, { "ret", 0xC9, 0xC0, emit_retcc }, { "reti", 0xED, 0x4D, emit_insn }, { "retn", 0xED, 0x45, emit_insn }, { "rl", 0xCB, 0x10, emit_mr }, { "rla", 0x00, 0x17, emit_insn }, { "rlc", 0xCB, 0x00, emit_mr }, { "rlca", 0x00, 0x07, emit_insn }, { "rld", 0xED, 0x6F, emit_insn }, { "rr", 0xCB, 0x18, emit_mr }, { "rra", 0x00, 0x1F, emit_insn }, { "rrc", 0xCB, 0x08, emit_mr }, { "rrca", 0x00, 0x0F, emit_insn }, { "rrd", 0xED, 0x67, emit_insn }, { "rst", 0x00, 0xC7, emit_rst}, { "sbc", 0x98, 0x42, emit_adc }, { "scf", 0x00, 0x37, emit_insn }, { "set", 0xCB, 0xC0, emit_bit }, { "sla", 0xCB, 0x20, emit_mr }, { "sli", 0xCB, 0x30, emit_mr }, { "sll", 0xCB, 0x30, emit_mr }, { "sra", 0xCB, 0x28, emit_mr }, { "srl", 0xCB, 0x38, emit_mr }, { "sub", 0x00, 0x90, emit_s }, { "xor", 0x00, 0xA8, emit_s }, } ; void md_assemble (char* str) { const char *p; char * old_ptr; int i; table_t *insp; err_flag = 0; old_ptr = input_line_pointer; p = skip_space (str); for (i = 0; (i < BUFLEN) && (ISALPHA (*p));) buf[i++] = TOLOWER (*p++); if (i == BUFLEN) { buf[BUFLEN-3] = buf[BUFLEN-2] = '.'; /* Mark opcode as abbreviated. */ buf[BUFLEN-1] = 0; as_bad (_("Unknown instruction '%s'"), buf); } else if ((*p) && (!ISSPACE (*p))) as_bad (_("syntax error")); else { buf[i] = 0; p = skip_space (p); key = buf; insp = bsearch (&key, instab, ARRAY_SIZE (instab), sizeof (instab[0]), key_cmp); if (!insp) as_bad (_("Unknown instruction '%s'"), buf); else { p = insp->fp (insp->prefix, insp->opcode, p); p = skip_space (p); if ((!err_flag) && *p) as_bad (_("junk at end of line, first unrecognized character is `%c'"), *p); } } input_line_pointer = old_ptr; } void md_apply_fix (fixS * fixP, valueT* valP, segT seg ATTRIBUTE_UNUSED) { long val = * (long *) valP; char *buf = fixP->fx_where + fixP->fx_frag->fr_literal; switch (fixP->fx_r_type) { case BFD_RELOC_8_PCREL: if (fixP->fx_addsy) { fixP->fx_no_overflow = 1; fixP->fx_done = 0; } else { fixP->fx_no_overflow = (-128 <= val && val < 128); if (!fixP->fx_no_overflow) as_bad_where (fixP->fx_file, fixP->fx_line, _("relative jump out of range")); *buf++ = val; fixP->fx_done = 1; } break; case BFD_RELOC_Z80_DISP8: if (fixP->fx_addsy) { fixP->fx_no_overflow = 1; fixP->fx_done = 0; } else { fixP->fx_no_overflow = (-128 <= val && val < 128); if (!fixP->fx_no_overflow) as_bad_where (fixP->fx_file, fixP->fx_line, _("index offset out of range")); *buf++ = val; fixP->fx_done = 1; } break; case BFD_RELOC_8: if (val > 255 || val < -128) as_warn_where (fixP->fx_file, fixP->fx_line, _("overflow")); *buf++ = val; fixP->fx_no_overflow = 1; if (fixP->fx_addsy == NULL) fixP->fx_done = 1; break; case BFD_RELOC_16: *buf++ = val; *buf++ = (val >> 8); fixP->fx_no_overflow = 1; if (fixP->fx_addsy == NULL) fixP->fx_done = 1; break; case BFD_RELOC_24: /* Def24 may produce this. */ *buf++ = val; *buf++ = (val >> 8); *buf++ = (val >> 16); fixP->fx_no_overflow = 1; if (fixP->fx_addsy == NULL) fixP->fx_done = 1; break; case BFD_RELOC_32: /* Def32 and .long may produce this. */ *buf++ = val; *buf++ = (val >> 8); *buf++ = (val >> 16); *buf++ = (val >> 24); if (fixP->fx_addsy == NULL) fixP->fx_done = 1; break; default: printf (_("md_apply_fix: unknown r_type 0x%x\n"), fixP->fx_r_type); abort (); } } /* GAS will call this to generate a reloc. GAS will pass the resulting reloc to `bfd_install_relocation'. This currently works poorly, as `bfd_install_relocation' often does the wrong thing, and instances of `tc_gen_reloc' have been written to work around the problems, which in turns makes it difficult to fix `bfd_install_relocation'. */ /* If while processing a fixup, a reloc really needs to be created then it is done here. */ arelent * tc_gen_reloc (asection *seg ATTRIBUTE_UNUSED , fixS *fixp) { arelent *reloc; if (! bfd_reloc_type_lookup (stdoutput, fixp->fx_r_type)) { as_bad_where (fixp->fx_file, fixp->fx_line, _("reloc %d not supported by object file format"), (int) fixp->fx_r_type); return NULL; } reloc = xmalloc (sizeof (arelent)); reloc->sym_ptr_ptr = xmalloc (sizeof (asymbol *)); *reloc->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy); reloc->address = fixp->fx_frag->fr_address + fixp->fx_where; reloc->howto = bfd_reloc_type_lookup (stdoutput, fixp->fx_r_type); reloc->addend = fixp->fx_offset; return reloc; }
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