Mercurial > hg-old > index.cgi
view src/insn_indexed.c @ 235:aa0056ca7319
Added a padding value for the ALIGN directive
author | lost |
---|---|
date | Fri, 12 Jun 2009 05:25:41 +0000 |
parents | f59c0916753d |
children |
line wrap: on
line source
/* insn_indexed.c Copyright © 2009 William Astle This file is part of LWASM. LWASM 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 <http://www.gnu.org/licenses/>. */ /* for handling indexed mode instructions */ #define __insn_indexed_c_seen__ #include <ctype.h> #include <string.h> #include "lwasm.h" #include "instab.h" #include "expr.h" void insn_indexed_aux(asmstate_t *as, lwasm_line_t *l, const char **p, int *b1, int *b2, int *b3) { static const char *regs = "X Y U S W PCRPC "; static const struct { char *opstr; int pb; } simpleindex[] = { {",x", 0x84}, {",y", 0xa4}, {",u", 0xc4}, {",s", 0xe4}, {",x+", 0x80}, {",y+", 0xa0}, {",u+", 0xc0}, {",s+", 0xe0}, {",x++", 0x81}, {",y++", 0xa1}, {",u++", 0xc1}, {",s++", 0xe1}, {",-x", 0x82}, {",-y", 0xa2}, {",-u", 0xc2}, {",-s", 0xe2}, {",--x", 0x83}, {",--y", 0xa3}, {",--u", 0xc3}, {",--s", 0xe3}, {"a,x", 0x86}, {"a,y", 0xa6}, {"a,u", 0xc6}, {"a,s", 0xe6}, {"b,x", 0x85}, {"b,y", 0xa5}, {"b,u", 0xc5}, {"b,s", 0xe5}, {"e,x", 0x87}, {"e,y", 0xa7}, {"e,u", 0xc7}, {"e,s", 0xe7}, {"f,x", 0x8a}, {"f,y", 0xaa}, {"f,u", 0xca}, {"f,s", 0xea}, {"d,x", 0x8b}, {"d,y", 0xab}, {"d,u", 0xcb}, {"d,s", 0xed}, {"w,x", 0x8e}, {"w,y", 0xae}, {"w,u", 0xce}, {"w,s", 0xee}, {",w", 0x8f}, {",w++", 0xcf}, {",--w", 0xef}, {"[,x]", 0x94}, {"[,y]", 0xb4}, {"[,u", 0xd4}, {"[,s]", 0xf4}, {"[,x++]", 0x91}, {"[,y++]", 0xb1}, {"[,u++]", 0xd1}, {"[,s++]", 0xf1}, {"[,--x]", 0x93}, {"[,--y]", 0xb3}, {"[,--u]", 0xd3}, {"[,--s]", 0xf3}, {"[a,x]", 0x96}, {"[a,y]", 0xb6}, {"[a,u]", 0xd6}, {"[a,s]", 0xf6}, {"[b,x]", 0x95}, {"[b,y]", 0xb5}, {"[b,u]", 0xd5}, {"[b,s]", 0xf5}, {"[e,x]", 0x97}, {"[e,y]", 0xb7}, {"[e,u]", 0xd7}, {"[e,s]", 0xf7}, {"[f,x]", 0x9a}, {"[f,y]", 0xba}, {"[f,u]", 0xda}, {"[f,s]", 0xfa}, {"[d,x]", 0x9b}, {"[d,y]", 0xbb}, {"[d,u]", 0xdb}, {"[d,s]", 0xfd}, {"[w,x]", 0x9e}, {"[w,y]", 0xbe}, {"[w,u]", 0xde}, {"[w,s]", 0xfe}, {"[,w]", 0x90}, {"[,w++]", 0xd0}, {"[,--w]", 0xf0}, { "", -1 } }; char stbuf[25]; int i, j, rn; int f8 = 0, f16 = 0, f0 = 0; int r, v; int indir = 0; int fs8 = 0, fs16 = 0; // initialize output bytes *b1 = *b2 = *b3 = -1; // fetch out operand for lookup for (i = 0; i < 24; i++) { if (*((*p) + i) && !isspace(*((*p) + i))) stbuf[i] = *((*p) + i); else break; } stbuf[i] = '\0'; // now look up operand in "simple" table if (!*((*p) + i) || isspace(*((*p) + i))) { // do simple lookup for (j = 0; simpleindex[j].opstr[0]; j++) { if (!strcasecmp(stbuf, simpleindex[j].opstr)) break; } if (simpleindex[j].opstr[0]) { *b1 = simpleindex[j].pb; (*p) += i; return; } } // now do the "hard" ones // is it indirect? if (**p == '[') { indir = 1; (*p)++; } // look for a "," - all indexed modes have a "," except extended indir rn = 0; for (i = 0; (*p)[i] && !isspace((*p)[i]); i++) { if ((*p)[i] == ',') { rn = 1; break; } } // if no "," and indirect, do extended indir if (!rn && indir) { // extended indir *b1 = 0x9f; *b2 = 0; *b3 = 0; r = lwasm_expr_result2(as, l, (char **)p, 0, &v, 0); if (r < 0) { return; } if (**p != ']') { register_error(as, l, 1, "Bad operand"); return; } (*p)++; if (r == 1 && as -> passnum == 2) { l -> relocoff = as -> addr - l -> codeaddr + 1; } *b2 = (v >> 8) & 0xff; *b3 = v & 0xff; return; } // if we've previously forced the offset size, make a note of it if (l -> fsize == 1) f8 = 1; else if (l -> fsize == 2) f16 = 1; if (**p == '<') { fs8 = 1; (*p)++; } else if (**p == '>') { fs16 = 1; (*p)++; } if (**p == '0' && *(*p+1) == ',') { f0 = 1; } // now we have to evaluate the expression r = lwasm_expr_result2(as, l, (char **)p, 0, &v, 0); if (r < 0) { return; } // now look for a comma; if not present, explode if (*(*p)++ != ',') { // syntax error; force 0 bit *b1 = 00; l -> fsize = 0; return; } // now get the register rn = lwasm_lookupreg3(regs, p); if (rn < 0) { *b1 = 0; l -> fsize = 0; register_error(as, l, 1, "Bad register"); return; } if (indir) { if (**p != ']') { register_error(as, l, 1, "Bad operand"); l -> fsize = 0; *b1 = 0; return; } else (*p)++; } // incomplete reference on pass 1 forces 16 bit if (r == 1 && as -> passnum == 1) { f16 = 1; l -> fsize = 2; } // incomplete reference on pass 2 needs relocoff set if (r == 1 && as -> passnum == 2) { l -> relocoff = as -> addr - l -> codeaddr + 1; } // nnnn,W is only 16 bit (or 0 bit) if (rn == 4) { if (f8) { register_error(as, l, 1, "n,W cannot be 8 bit"); l -> fsize = 0; *b1 = 0; return; } // note: set f16 above for incomplete references // also set reloc offset if (!f16 && !f0 && !(as -> pragmas & PRAGMA_NOINDEX0TONONE) && v == 0) { if (indir) *b1 = 0x90; else *b1 = 0x8f; return; } if (indir) *b1 = 0xb0; else *b1 = 0xcf; *b2 = (v >> 8) & 0xff; *b3 = v & 0xff; return; } // set indir to correct bit value if (indir) indir = 0x10; // PCR? then we have PC relative addressing (like B??, LB??) if (rn == 5) { lwasm_expr_term_t *t; // external references are handled exactly the same as for // relative addressing modes // on pass 1, adjust the expression for a subtraction of the // current address // need to re-evaluate the expression with "SECTCONST"... r = lwasm_expr_result2(as, l, (char **)p, EXPR_SECTCONST | EXPR_REEVAL, &v, 0); if (r != 0) v = 0; if (as -> passnum == 1) { l -> fsize = 0; } f8 = f16 = 0; if (r == 1 && as -> passnum == 1 && !fs8) { l -> fsize = 2; f16 = 1; } if (fs8) f8 = 1; if (fs16) f16 = 1; if (l -> fsize == 2) f16 = 1; else if (l -> fsize == 1) f8 = 1; if (as -> passnum == 1) v -= as -> addr; // we have a slight problem here // PCR based on current insn loc is really // -125 <= offset <= +130 (8 bit offset) // NOTE: when we are called, we already have the opcode emitted // so we only need to worry about the size of the operand // hence the 2 and 3 magic numbers below instead of 3 and 4 // (and that also avoids errors with two byte opcodes, etc) if (f8 || (!f16 && v >= -125 && v <= 130)) { f8 = 1; l -> fsize = 1; *b1 = indir | 0x8C; if (as -> passnum == 1) v -= 2; if (v < -128 || v > 127) register_error(as, l, 2, "Byte overflow"); *b2 = v & 0xff; if (r != 0 && as -> passnum == 2) { register_error(as, l, 2, "Illegal incomplete reference"); } goto finpcr; } // anything else is 16 bit offset // need 16 bit l -> fsize = 2; *b1 = indir | 0x8D; if (as -> passnum == 1) v -= 3; *b2 = (v >> 8) & 0xff; *b3 = v & 0xff; if (as -> passnum == 2 && r == 1) { t = lwasm_expr_term_create_secbase(); lwasm_expr_stack_push(l -> exprs[0], t); lwasm_expr_term_free(t); t = lwasm_expr_term_create_oper(LWASM_OPER_MINUS); lwasm_expr_stack_push(l -> exprs[0], t); lwasm_expr_term_free(t); } finpcr: if (as -> passnum == 1) { // need to adjust the expression if (l -> exprs[0]) { t = lwasm_expr_term_create_int(as -> addr + (f8 ? 2 : 3)); lwasm_expr_stack_push(l -> exprs[0], t); lwasm_expr_term_free(t); t = lwasm_expr_term_create_oper(LWASM_OPER_MINUS); lwasm_expr_stack_push(l -> exprs[0], t); lwasm_expr_term_free(t); } else { l -> exprvals[0] -= as -> addr + (f8 ? 2 : 3); } } return; } if (fs16) f16 = 1; if (fs8) f8 = 1; if (f8 && r != 0) { register_error(as, l, 2, "Illegal external or inter-section reference"); r = 0; v = 0; } // constant offset from PC (using PC as regular register :) ) // FIXME: handle external references intelligently if (rn == 6) { if (f8 || (!f16 && v >= -128 && v <= 127)) { *b1 = indir | 0x8C; if (v < -128 || v > 127) register_error(as, l, 2, "Byte overflow"); *b2 = v & 0xff; return; } // everything else must be 16 bit // need 16 bit *b1 = indir | 0x8D; *b2 = (v >> 8) & 0xff; *b3 = v & 0xff; return; } // we only have to deal with x,y,u,s here if (!f8 && !f16 && v >= -16 && v <= 15) { // zero offset going to ,R? if (v == 0 && !f0 && !(as -> pragmas & PRAGMA_NOINDEX0TONONE)) { *b1 = rn << 5 | indir | 0x80 | 0x04; return; } // no 5 bit on indirect if (indir) { f8 = 1; l -> fsize = 1; goto no5bit; } // 5 bit addressing *b1 = rn << 5 | (v & 0x1F); return; } no5bit: if (f16 || (!f8 && (v < -128 || v > 127))) { // must be a 16 bit offset here *b1 = rn << 5 | indir | 0x80 | 0x09; *b2 = (v >> 8) & 0xff; *b3 = v & 0xff; return; } // if we're here, we have an 8 bit offset // note: cannot get here if incomplete reference detected above *b1 = rn << 5 | indir | 0x80 | 0x08; if (v < -128 || v > 127) register_error(as, l, 2, "Byte overflow"); *b2 = v & 0xff; return; } OPFUNC(insn_indexed) { int b1, b2, b3; lwasm_emitop(as, l, instab[opnum].ops[0]); insn_indexed_aux(as, l, (const char **)p, &b1, &b2, &b3); if (b1 != -1) lwasm_emit(as, l, b1); if (b2 != -1) lwasm_emit(as, l, b2); if (b3 != -1) lwasm_emit(as, l, b3); }