/**************************************************************** * * * Copyright 2001, 2009 Fidelity Information Services, Inc * * * * This source code contains the intellectual property * * of its copyright holder(s), and is made available * * under a license. If you do not know the terms of * * the license, please stop and do not read further. * * * ****************************************************************/ #include "mdef.h" #include "compiler.h" #include #include "stack_frame.h" #include "opcode.h" #include "xfer_enum.h" #include "mdq.h" #include "vxi.h" #include "vxt.h" #include "cgp.h" #include "obj_gen.h" #include "i386.h" #include "obj_file.h" #include #include "hashtab_mname.h" #include "stddef.h" #define BUFFERED_CODE_SIZE 50 #define LONG_JUMP_OFFSET (0x7ffffffc) #define XFER_BYTE_INST_SIZE 3 #define XFER_LONG_INST_SIZE 6 #define BRB_INST_SIZE 2 #define JMP_LONG_INST_SIZE 5 /* index in ttt from start of call[sp] and forlcldo to xfer_table index */ #define CALL_4LCLDO_XFER 2 typedef enum { CLEAR, COMPARE, INCREMENT, JUMP, LOAD, LOAD_ADDRESS, PUSH, PUSH_ADDRESS, STORE, TEST } generic_op; void emit_pcrel(generic_op op, unsigned char use_reg); void emit_trip(generic_op op, oprtype *opr, bool val_output, unsigned char use_reg); void emit_op_base_offset(generic_op op, short base_reg, int offset, short use_reg); void emit_op_alit (generic_op op, unsigned char use_reg); void emit_jmp(short vax_in, short **instp); unsigned char i386_reg(unsigned char vax_reg); union { ModR_M modrm; unsigned char byte; } modrm_byte; union { SIB sib; unsigned char byte; } sib_byte; LITREF octabstruct oc_tab[]; /* op-code table */ LITREF short ttt[]; /* triple templates */ static unsigned char code_buf[BUFFERED_CODE_SIZE]; static unsigned short code_idx; static int4 jmp_offset, code_reference; static int force_32; static int call_4lcldo_variant; /* used in emit_jmp for call[sp] and forlcldo */ GBLREF int4 curr_addr; GBLREF char cg_phase; /* code generation phase */ GBLDEF uint4 txtrel_cnt; /* count of text relocation records */ /* its referenced in ind_code.c */ GBLDEF int calculated_code_size, generated_code_size; void trip_gen(triple *ct) { oprtype **sopr, *opr; /* triple operand */ oprtype *saved_opr[MAX_ARGS]; unsigned short oct; short tp; /* template pointer */ short *tsp; /* template short pointer */ triple *ttp; /* temp triple pointer */ short irep_index; oprtype *irep_opr; short *repl, repcnt; /* temp irep ptr */ int4 off; error_def (ERR_UNIMPLOP); error_def (ERR_MAXARGCNT); tp = ttt[ct->opcode]; if (tp <= 0) { stx_error(ERR_UNIMPLOP); return; } code_idx = 0; code_reference = ct->rtaddr; oct = oc_tab[ct->opcode].octype; sopr = &saved_opr[0]; *sopr++ = &ct->destination; for (ttp = ct, opr = ttp->operand ; opr < ARRAYTOP(ttp->operand); ) { if (opr->oprclass) { if (opr->oprclass == TRIP_REF && opr->oprval.tref->opcode == OC_PARAMETER) { ttp = opr->oprval.tref; opr = ttp->operand; continue; } *sopr++ = opr; if (sopr >= ARRAYTOP(saved_opr)) rts_error(VARLSTCNT(3) ERR_MAXARGCNT, 1, MAX_ARGS); } opr++; } *sopr=0; jmp_offset = 0; call_4lcldo_variant = 0; if (oct & OCT_JUMP || ct->opcode == OC_LDADDR || ct->opcode == OC_FORLOOP) { if (ct->operand[0].oprval.tref->rtaddr == 0) /* forward reference */ { jmp_offset = LONG_JUMP_OFFSET; assert(cg_phase == CGP_APPROX_ADDR); } else jmp_offset = ct->operand[0].oprval.tref->rtaddr - ct->rtaddr; switch (ct->opcode) { case OC_CALL: case OC_FORLCLDO: case OC_CALLSP: /* Changes to emit_xfer, emit_base_offset, or emit_jmp may require changes here since we try to predict how big the call into the xfer_table and the following jump will be. There is also an assumption that both the word and long variants of the opcode will be followed by a jmp with 32 bit offset while the -BYTE variants will be followed by a BRB with an 8 bit offset. */ tsp = (short *)&ttt[ttt[tp]]; if (-128 <= tsp[CALL_4LCLDO_XFER] && 127 >= tsp[CALL_4LCLDO_XFER]) off = jmp_offset - XFER_BYTE_INST_SIZE; else off = jmp_offset - XFER_LONG_INST_SIZE; if (-128 <= (off - BRB_INST_SIZE) && 127 >= (off - BRB_INST_SIZE)) call_4lcldo_variant = BRB_INST_SIZE; /* used by emit_jmp */ else { call_4lcldo_variant = JMP_LONG_INST_SIZE; /* used by emit_jmp */ tsp = (short *)&ttt[ttt[tp + 1]]; if (-128 <= tsp[CALL_4LCLDO_XFER] && 127 >= tsp[CALL_4LCLDO_XFER]) off = jmp_offset - XFER_BYTE_INST_SIZE; else off = jmp_offset - XFER_LONG_INST_SIZE; if (-32768 > (off - JMP_LONG_INST_SIZE) && 32767 < (off - JMP_LONG_INST_SIZE)) tsp = (short *)&ttt[ttt[tp + 2]]; } break; case OC_JMP: case OC_JMPEQU: case OC_JMPGEQ: case OC_JMPGTR: case OC_JMPLEQ: case OC_JMPNEQ: case OC_JMPLSS: case OC_JMPTSET: case OC_JMPTCLR: case OC_LDADDR: case OC_FORLOOP: tsp = (short *)&ttt[ttt[tp]]; break; default: GTMASSERT; break; } } else if (oct & OCT_COERCE) { switch (oc_tab[ct->operand[0].oprval.tref->opcode].octype & (OCT_VALUE | OCT_BOOL)) { case OCT_MVAL: tp = ttt[tp]; break; case OCT_MINT: tp = ttt[tp + 3]; break; case OCT_BOOL: tp = ttt[tp + 4]; break; default: GTMASSERT; break; } tsp = (short *)&ttt[tp]; } else tsp = (short *)&ttt[tp]; for (; *tsp != VXT_END; ) { if (*tsp == VXT_IREPAB || *tsp == VXT_IREPL) { repl = tsp; repl += 2; repcnt = *repl++; assert(repcnt != 1); for (irep_index = repcnt, irep_opr = &ct->operand[1]; irep_index > 2; --irep_index) { assert (irep_opr->oprclass == TRIP_REF); irep_opr = &irep_opr->oprval.tref->operand[1]; } if (irep_opr->oprclass == TRIP_REF) { repl = tsp; do { tsp = repl; tsp = emit_vax_inst(tsp, &saved_opr[0], --sopr); } while (sopr > &saved_opr[repcnt]); } else { sopr = &saved_opr[repcnt]; tsp = repl; } } else { assert(*tsp > 0 && *tsp <= 511); tsp = emit_vax_inst(tsp, &saved_opr[0], sopr); }/* else */ }/* for */ } short *emit_vax_inst(short *inst, oprtype **fst_opr, oprtype **lst_opr) /* fst_opr and lst_opr are triple operands */ { short sav_in; bool oc_int; int4 cnt; oprtype *opr; triple *ct; code_idx = 0; force_32 = 0; switch (cg_phase) { case CGP_ADDR_OPT: case CGP_APPROX_ADDR: case CGP_MACHINE: switch ((sav_in = *inst++)) { case VXI_BEQL: case VXI_BGEQ: case VXI_BGTR: case VXI_BLEQ: case VXI_BLSS: case VXI_BNEQ: case VXI_BRB: case VXI_BRW: emit_jmp(sav_in, &inst); break; case VXI_BLBC: case VXI_BLBS: assert (*inst == VXT_REG); inst++; inst++; emit_xfer(4*xf_dt_get); code_buf[code_idx++] = I386_INS_CMP_eAX_Iv; *((int4 *)&code_buf[code_idx]) = 0; code_idx += SIZEOF(int4); if (sav_in == VXI_BLBC) emit_jmp(VXI_BEQL, &inst); else { assert (sav_in == VXI_BLBS); emit_jmp(VXI_BNEQ, &inst); } break; case VXI_BICB2: case VXI_BISB2: assert (*inst == VXT_LIT); inst++; assert (*inst == 1); inst++; assert (*inst == VXT_REG); inst++; inst++; if (sav_in == VXI_BICB2) emit_xfer(4*xf_dt_false); else { assert (sav_in == VXI_BISB2); emit_xfer(4*xf_dt_true); } break; case VXI_CALLS: oc_int = TRUE; if (*inst == VXT_LIT) { inst++; cnt = (int4) *inst++; } else { assert(*inst == VXT_VAL); inst++; opr = *(fst_opr + *inst); assert (opr->oprclass == TRIP_REF); ct = opr->oprval.tref; if (ct->destination.oprclass) { opr = &ct->destination; } if (opr->oprclass == TRIP_REF) { assert(ct->opcode == OC_ILIT); cnt = ct->operand[0].oprval.ilit; if (cnt >= -128 && cnt <= 127) { code_buf[code_idx++] = I386_INS_PUSH_Ib; code_buf[code_idx++] = cnt & 0xff; } else { code_buf[code_idx++] = I386_INS_PUSH_Iv; *((int4 *)&code_buf[code_idx]) = cnt; code_idx += SIZEOF(int4); } cnt++; inst++; } else { assert(opr->oprclass == TINT_REF); oc_int = FALSE; opr = *(fst_opr + *inst++); emit_trip(PUSH, opr, TRUE, 0); } } assert (*inst == VXT_XFER); inst++; emit_xfer(*inst++); if (oc_int) { if (cnt) { code_buf[code_idx++] = I386_INS_LEA_Gv_M; emit_base_offset(I386_REG_ESP, I386_REG_ESP, 4*cnt); } } else { emit_trip(LOAD, opr, TRUE, I386_REG_EDX); code_buf[code_idx++] = I386_INS_LEA_Gv_M; emit_base_offset(I386_REG_ESP, I386_REG_ESP, 4); } break; case VXI_CLRL: assert (*inst == VXT_VAL); inst++; emit_trip(CLEAR, *(fst_opr + *inst++), TRUE, 0); break; case VXI_CMPL: assert (*inst == VXT_VAL); inst++; emit_trip(LOAD, *(fst_opr + *inst++), TRUE, I386_REG_EDX); assert (*inst == VXT_VAL); inst++; emit_trip(COMPARE, *(fst_opr + *inst++), TRUE, I386_REG_EDX); break; case VXI_INCL: assert (*inst == VXT_VAL); inst++; emit_trip(INCREMENT, *(fst_opr + *inst++), TRUE, 0); break; case VXI_JMP: if (*inst == VXT_VAL) { inst++; emit_trip(JUMP, *(fst_opr + *inst++), FALSE, 0); } else { emit_jmp(sav_in, &inst); } break; case VXI_JSB: assert (*inst == VXT_XFER); inst++; emit_xfer(*inst++); break; case VXI_MOVAB: if (*inst == VXT_JMP) { inst += 2; emit_pcrel(LOAD_ADDRESS, I386_REG_EAX); assert (*inst == VXT_ADDR); inst++; emit_trip(STORE, *(fst_opr + *inst++), FALSE, I386_REG_EAX); } else if (*inst == VXT_ADDR || *inst == VXT_VAL) { bool addr; unsigned char reg; short save_inst; addr = (*inst == VXT_VAL); inst++; save_inst = *inst++; assert (*inst == VXT_REG); inst++; reg = ((*inst++ & 0x01) ? I386_REG_EDX : I386_REG_EAX); /* r0 and r1 are only ones used */ emit_trip(LOAD_ADDRESS, *(fst_opr + save_inst), addr, reg); } else GTMASSERT; break; case VXI_MOVC3: assert (*inst == VXT_LIT); inst += 2; assert(*inst == VXT_VAL); inst++; code_buf[code_idx++] = I386_INS_PUSH_eSI; code_buf[code_idx++] = I386_INS_PUSH_eDI; emit_trip(LOAD_ADDRESS, *(fst_opr + *inst++), TRUE, I386_REG_ECX); assert(*inst == VXT_VAL); inst++; emit_trip(LOAD_ADDRESS, *(fst_opr + *inst++), TRUE, I386_REG_EDI); code_buf[code_idx++] = I386_INS_MOV_Gv_Ev; modrm_byte.modrm.reg_opcode = I386_REG_ESI; modrm_byte.modrm.mod = I386_MOD32_REGISTER; modrm_byte.modrm.r_m = I386_REG_ECX; code_buf[code_idx++] = modrm_byte.byte; code_buf[code_idx++] = I386_INS_MOV_eCX; *((int4 *)&code_buf[code_idx]) = (int4)SIZEOF(mval); code_idx += SIZEOF(int4); code_buf[code_idx++] = I386_INS_REP_E_Prefix; code_buf[code_idx++] = I386_INS_MOVSB_Xb_Yb; code_buf[code_idx++] = I386_INS_POP_eDI; code_buf[code_idx++] = I386_INS_POP_eSI; break; case VXI_MOVL: if (*inst == VXT_REG) { inst++; if (*inst > 0x5f) /* OC_CURRHD */ /* any mode >= 6 (deferred), any register */ { inst++; assert (*inst == VXT_ADDR); inst++; emit_xfer(4*xf_get_msf); emit_op_base_offset(LOAD, I386_REG_EAX, 0, I386_REG_EAX); emit_trip(STORE, *(fst_opr + *inst++), FALSE, I386_REG_EAX); } else { bool addr; assert (*inst == 0x50); /* register mode: R0 */ inst++; if (*inst == VXT_VAL || *inst == VXT_ADDR) { addr = (*inst == VXT_VAL); inst++; emit_trip(STORE, *(fst_opr + *inst++), addr, I386_REG_EAX); } else if (*inst == VXT_REG) { unsigned char reg; inst++; if ((*inst & 0x0f) == 10) /* VAX $TEST */ { code_buf[code_idx++] = I386_INS_PUSH_eAX; emit_xfer(4*xf_dt_store); code_buf[code_idx++] = I386_INS_POP_eAX; } else { code_buf[code_idx++] = I386_INS_MOV_Ev_Gv; modrm_byte.modrm.reg_opcode = I386_REG_EAX; modrm_byte.modrm.mod = I386_MOD32_REGISTER; modrm_byte.modrm.r_m = i386_reg(*inst); code_buf[code_idx++] = modrm_byte.byte; } inst++; } else GTMASSERT; } } else if (*inst == VXT_VAL) { inst++; emit_trip(LOAD, *(fst_opr + *inst++), TRUE, I386_REG_EDX); assert (*inst == VXT_REG); inst++; assert (*inst == 0x51); /* register mode: R1 */ inst++; } else GTMASSERT; break; case VXT_IREPAB: assert (*inst == VXT_VAL); inst += 2; emit_trip(PUSH_ADDRESS, *lst_opr, TRUE, 0); break; case VXI_PUSHAB: if (*inst == VXT_JMP) { inst += 2; emit_pcrel(PUSH_ADDRESS, 0); } else if (*inst == VXT_VAL) { inst++; emit_trip(PUSH_ADDRESS, *(fst_opr + *inst++), TRUE, 0); } else GTMASSERT; break; case VXT_IREPL: assert (*inst == VXT_VAL); inst += 2; emit_trip(PUSH, *lst_opr, TRUE, 0); break; case VXI_PUSHL: if (*inst == VXT_LIT) { int4 lit; inst++; lit = *inst++; if (lit >= -128 && lit <= 127) { code_buf[code_idx++] = I386_INS_PUSH_Ib; code_buf[code_idx++] = lit & 0xff; } else { code_buf[code_idx++] = I386_INS_PUSH_Iv; *((int4 *)&code_buf[code_idx]) = lit; code_idx += SIZEOF(int4); } } else if (*inst == VXT_ADDR) { inst++; emit_trip(PUSH, *(fst_opr + *inst++), FALSE, 0); } else if (*inst == VXT_VAL) { inst++; emit_trip(PUSH, *(fst_opr + *inst++), TRUE, 0); } else GTMASSERT; break; case VXI_TSTL: if (*inst == VXT_VAL) { inst++; emit_trip(TEST, *(fst_opr + *inst++), TRUE, 0); } else if (VXT_REG == *inst) { inst++; code_buf[code_idx++] = I386_INS_CMP_eAX_Iv; assert(I386_REG_EAX == i386_reg(*inst)); /* VAX R0 */ inst++; *((int4 *)&code_buf[code_idx]) = 0; /* 32 bit immediate 0 */ code_idx += SIZEOF(int4); } else GTMASSERT; break; default: GTMASSERT; } break; default: GTMASSERT; break; } assert (code_idx < BUFFERED_CODE_SIZE); if (cg_phase == CGP_MACHINE) { generated_code_size += code_idx; emit_immed ((char *)&code_buf[0], SIZEOF(unsigned char) * code_idx); } else if (cg_phase != CGP_ASSEMBLY) { if (cg_phase == CGP_APPROX_ADDR) { calculated_code_size += code_idx; } curr_addr += SIZEOF(unsigned char) * code_idx; } code_reference += SIZEOF(unsigned char) * code_idx; jmp_offset -= SIZEOF(unsigned char) * code_idx; return inst; } /* Changes here or emit_xfer may require changes in trip_gen case for OC_CALL[SP] and FORLCLDO */ void emit_jmp(short vax_in, short **instp) { assert (jmp_offset != 0); jmp_offset -= code_idx * SIZEOF(code_buf[0]); /* size of this particular instruction */ assert (**instp == VXT_JMP); *instp += 1; assert (**instp == 1); *instp += 1; if (jmp_offset == 0) { code_buf[code_idx++] = I386_INS_NOP__; } else if ((jmp_offset - 2) >= -128 && (jmp_offset - 2) <= 127 && JMP_LONG_INST_SIZE != call_4lcldo_variant) { jmp_offset -= 2; switch (vax_in) { case VXI_BEQL: code_buf[code_idx++] = I386_INS_JZ_Jb; break; case VXI_BGEQ: code_buf[code_idx++] = I386_INS_JNL_Jb; break; case VXI_BGTR: code_buf[code_idx++] = I386_INS_JNLE_Jb; break; case VXI_BLEQ: code_buf[code_idx++] = I386_INS_JLE_Jb; break; case VXI_BLSS: code_buf[code_idx++] = I386_INS_JL_Jb; break; case VXI_BNEQ: code_buf[code_idx++] = I386_INS_JNZ_Jb; break; case VXI_BRB: case VXI_BRW: case VXI_JMP: assert(0 == call_4lcldo_variant || BRB_INST_SIZE == call_4lcldo_variant); code_buf[code_idx++] = I386_INS_JMP_Jb; break; default: GTMASSERT; break; } code_buf[code_idx++] = jmp_offset & 0xff; } else { if (vax_in == VXI_BRB || vax_in == VXI_BRW || vax_in == VXI_JMP) { assert(0 == call_4lcldo_variant || JMP_LONG_INST_SIZE == call_4lcldo_variant); jmp_offset -= SIZEOF(int4) + 1; code_buf[code_idx++] = I386_INS_JMP_Jv; } else { jmp_offset -= SIZEOF(int4) + 2; code_buf[code_idx++] = I386_INS_Two_Byte_Escape_Prefix; switch (vax_in) { case VXI_BEQL: code_buf[code_idx++] = I386_INS_JZ_Jv; break; case VXI_BGEQ: code_buf[code_idx++] = I386_INS_JNL_Jv; break; case VXI_BGTR: code_buf[code_idx++] = I386_INS_JNLE_Jv; break; case VXI_BLEQ: code_buf[code_idx++] = I386_INS_JLE_Jv; break; case VXI_BLSS: code_buf[code_idx++] = I386_INS_JL_Jv; break; case VXI_BNEQ: code_buf[code_idx++] = I386_INS_JNZ_Jv; break; default: GTMASSERT; break; } } *((int4 *)&code_buf[code_idx]) = jmp_offset; code_idx += SIZEOF(int4); } } void emit_pcrel(generic_op op, unsigned char use_reg) { code_buf[code_idx++] = I386_INS_CALL_Jv; *((int4 *)&code_buf[code_idx]) = 0; code_idx += SIZEOF(int4); jmp_offset -= code_idx; code_buf[code_idx++] = I386_INS_POP_eAX; emit_op_base_offset(op, I386_REG_EAX, jmp_offset, use_reg); } GBLREF boolean_t run_time; GBLREF int4 sa_temps_offset[]; GBLREF int4 sa_temps[]; LITREF int4 sa_class_sizes[]; void emit_trip(generic_op op, oprtype *opr, bool val_output, unsigned char use_reg) { unsigned char base_reg, temp_reg; int4 offset, literal; triple *ct; error_def (ERR_UNIMPLOP); if (opr->oprclass == TRIP_REF) { ct = opr->oprval.tref; if (ct->destination.oprclass) { opr = &ct->destination; } /* else lit or error */ } switch (cg_phase) { case CGP_ADDR_OPT: case CGP_APPROX_ADDR: switch (opr->oprclass) { case TRIP_REF: assert(ct->destination.oprclass == 0); assert(val_output); switch (ct->opcode) { case OC_LIT: if (run_time) { int4 pc_value_idx; switch (op) { case LOAD_ADDRESS: temp_reg = use_reg; break; case PUSH: case PUSH_ADDRESS: temp_reg = I386_REG_ECX; break; default: rts_error(VARLSTCNT(1) ERR_UNIMPLOP); break; } pc_value_idx = code_idx + 5; code_idx += 1 + SIZEOF(int4) + 1; emit_addr(0, (int4)ct->operand[0].oprval.mlit->rt_addr, &offset); offset -= pc_value_idx; force_32 = 1; emit_op_base_offset(op, temp_reg, offset, temp_reg); force_32 = 0; } else { emit_op_alit(op, use_reg); code_idx += SIZEOF(int4); } if (cg_phase == CGP_APPROX_ADDR) txtrel_cnt++; break; case OC_CDLIT: if (cg_phase == CGP_APPROX_ADDR) define_symbol(GTM_LITERALS, ct->operand[0].oprval.cdlt, 0); emit_op_alit(op, use_reg); code_idx += SIZEOF(int4); break; case OC_ILIT: literal = ct->operand[0].oprval.ilit; switch(op) { case COMPARE: /* 1byte(opcode) + 1byte(ModR/M) + 4byte(literal) */ code_idx += 2 + SIZEOF(int4); break; case LOAD: code_idx += 1 + SIZEOF(int4); break; case PUSH: if (literal >= -128 && literal <= 127) code_idx += 2; else code_idx += 1 + SIZEOF(int4); break; default: rts_error(VARLSTCNT(1) ERR_UNIMPLOP); break; } break; default: GTMASSERT; break; } break; case TINT_REF: case TVAL_REF: assert(val_output); offset = sa_temps_offset[opr->oprclass]; offset -= (sa_temps[opr->oprclass] - opr->oprval.temp) * sa_class_sizes[opr->oprclass]; if (offset < 0 && offset > 65535) GTMASSERT; emit_op_base_offset(op, I386_REG_EDI, offset, use_reg); break; case TCAD_REF: case TVAD_REF: case TVAR_REF: offset = sa_temps_offset[opr->oprclass]; offset -= (sa_temps[opr->oprclass] - opr->oprval.temp) * sa_class_sizes[opr->oprclass]; if (offset < 0 && offset > 65535) GTMASSERT; if (opr->oprclass == TVAR_REF) base_reg = I386_REG_ESI; else base_reg = I386_REG_EDI; switch (op) { case JUMP: if (val_output) { code_idx++; emit_base_offset(I386_REG_EAX, base_reg, offset); } code_idx++; if (val_output) emit_base_offset(I386_INS_JMP_Ev, I386_REG_EAX, 0); else emit_base_offset(I386_INS_JMP_Ev, base_reg, offset); break; case LOAD_ADDRESS: code_idx++; emit_base_offset(use_reg, base_reg, offset); if (opr->oprclass == TVAR_REF) { code_idx++; emit_base_offset(use_reg, use_reg, offsetof(ht_ent_mname, value)); } break; case PUSH: if (!val_output) { code_idx++; emit_base_offset(I386_INS_PUSH_Ev, base_reg, offset); } else { code_idx++; emit_base_offset(I386_REG_ECX, base_reg, offset); code_idx++; emit_base_offset(I386_INS_PUSH_Ev, I386_REG_ECX, 0); } break; case PUSH_ADDRESS: if (val_output) { if (opr->oprclass == TVAR_REF) { code_idx++; emit_base_offset(use_reg, base_reg, offset); code_idx++; emit_base_offset(I386_INS_PUSH_Ev, use_reg, offsetof(ht_ent_mname, value)); } else { code_idx++; emit_base_offset(I386_INS_PUSH_Ev, base_reg, offset); } } else { code_idx++; emit_base_offset(I386_REG_ECX, base_reg, offset); code_idx++; } break; case STORE: if (val_output) { if (use_reg == I386_REG_EAX) temp_reg = I386_REG_EDX; else temp_reg = I386_REG_EAX; code_idx++; emit_base_offset(temp_reg, base_reg, offset); } code_idx++; if (val_output) emit_base_offset(use_reg, temp_reg, 0); else emit_base_offset(use_reg, base_reg, offset); break; default: rts_error(VARLSTCNT(1) ERR_UNIMPLOP); break; } break; } break; case CGP_MACHINE: switch (opr->oprclass) { case TRIP_REF: assert(ct->destination.oprclass == 0); assert(val_output); switch (ct->opcode) { case OC_LIT: assert(ct->operand[0].oprclass == MLIT_REF); if (run_time) { int4 pc_value_idx; switch(op) { case LOAD_ADDRESS: temp_reg = use_reg; break; case PUSH: case PUSH_ADDRESS: temp_reg = I386_REG_ECX; break; default: rts_error(VARLSTCNT(1) ERR_UNIMPLOP); break; } code_buf[code_idx++] = I386_INS_CALL_Jv; *((int4 *)&code_buf[code_idx]) = 0; code_idx += SIZEOF(int4); pc_value_idx = code_idx; code_buf[code_idx++] = I386_INS_POP_eAX + temp_reg; emit_addr(0, (int4)ct->operand[0].oprval.mlit->rt_addr, &offset); offset -= pc_value_idx; force_32 = 1; emit_op_base_offset(op, temp_reg, offset, temp_reg); force_32 = 0; } else { emit_op_alit(op, use_reg); emit_addr(code_reference + (code_idx * SIZEOF(unsigned char)), (int4)ct->operand[0].oprval.mlit->rt_addr, (int4 *)&code_buf[code_idx]); code_idx += SIZEOF(int4); } break; case OC_CDLIT: emit_op_alit(op, use_reg); emit_reference(code_reference + (code_idx * SIZEOF(unsigned char)), ct->operand[0].oprval.cdlt, (uint4 *)&code_buf[code_idx]); code_idx += SIZEOF(int4); break; case OC_ILIT: literal = ct->operand[0].oprval.ilit; switch (op) { case COMPARE: /* cmpl $literal,use_reg - 1byte(opcode) + 1byte(ModR/M) + 4byte(literal) */ code_buf[code_idx++] = I386_INS_Grp1_Ev_Iv_Prefix; modrm_byte.modrm.reg_opcode = I386_INS_CMP__; modrm_byte.modrm.mod = I386_MOD32_REGISTER; modrm_byte.modrm.r_m = use_reg; code_buf[code_idx++] = modrm_byte.byte; *((int4 *)&code_buf[code_idx]) = literal; code_idx += SIZEOF(int4); break; case LOAD: code_buf[code_idx++] = I386_INS_MOV_eAX + use_reg; *((int4 *)&code_buf[code_idx]) = literal; code_idx += SIZEOF(int4); break; case PUSH: if (literal >= -128 && literal <= 127) { code_buf[code_idx++] = I386_INS_PUSH_Ib; code_buf[code_idx++] = literal & 0xff; } else { code_buf[code_idx++] = I386_INS_PUSH_Iv; *((int4 *)&code_buf[code_idx]) = literal; code_idx += SIZEOF(int4); } break; default: rts_error(VARLSTCNT(1) ERR_UNIMPLOP); break; } break; default: GTMASSERT; break; } break; case TINT_REF: case TVAL_REF: assert(val_output); offset = sa_temps_offset[opr->oprclass]; offset -= (sa_temps[opr->oprclass] - opr->oprval.temp) * sa_class_sizes[opr->oprclass]; if (offset < 0 && offset > 65535) GTMASSERT; emit_op_base_offset(op, I386_REG_EDI, offset, use_reg); break; case TCAD_REF: case TVAD_REF: case TVAR_REF: offset = sa_temps_offset[opr->oprclass]; offset -= (sa_temps[opr->oprclass] - opr->oprval.temp) * sa_class_sizes[opr->oprclass]; if (offset < 0 && offset > 65535) GTMASSERT; if (opr->oprclass == TVAR_REF) base_reg = I386_REG_ESI; else base_reg = I386_REG_EDI; switch (op) { case JUMP: assert (use_reg == 0); if (val_output) { code_buf[code_idx++] = I386_INS_MOV_Gv_Ev; emit_base_offset(I386_REG_EAX, base_reg, offset); } code_buf[code_idx++] = I386_INS_Grp5_Prefix; if (val_output) emit_base_offset(I386_INS_JMP_Ev, I386_REG_EAX, 0); else emit_base_offset(I386_INS_JMP_Ev, base_reg, offset); break; case LOAD_ADDRESS: if (val_output) code_buf[code_idx++] = I386_INS_MOV_Gv_Ev; else code_buf[code_idx++] = I386_INS_LEA_Gv_M; emit_base_offset(use_reg, base_reg, offset); if (opr->oprclass == TVAR_REF) { code_buf[code_idx++] = I386_INS_MOV_Gv_Ev; emit_base_offset(use_reg, use_reg, offsetof(ht_ent_mname, value)); } break; case PUSH: if (val_output) { code_buf[code_idx++] = I386_INS_MOV_Gv_Ev; emit_base_offset(I386_REG_ECX, base_reg, offset); code_buf[code_idx++] = I386_INS_Grp5_Prefix; emit_base_offset(I386_INS_PUSH_Ev, I386_REG_ECX, 0); } else { code_buf[code_idx++] = I386_INS_Grp5_Prefix; emit_base_offset(I386_INS_PUSH_Ev, base_reg, offset); } break; case PUSH_ADDRESS: if (val_output) { if (opr->oprclass == TVAR_REF) { code_buf[code_idx++] = I386_INS_MOV_Gv_Ev; emit_base_offset(use_reg, base_reg, offset); code_buf[code_idx++] = I386_INS_Grp5_Prefix; emit_base_offset(I386_INS_PUSH_Ev, use_reg, offsetof(ht_ent_mname, value)); } else { code_buf[code_idx++] = I386_INS_Grp5_Prefix; emit_base_offset(I386_INS_PUSH_Ev, base_reg, offset); } } else { code_buf[code_idx++] = I386_INS_LEA_Gv_M; emit_base_offset(I386_REG_ECX, base_reg, offset); code_buf[code_idx++] = I386_INS_PUSH_eCX; } break; case STORE: if (val_output) { if (use_reg == I386_REG_EAX) temp_reg = I386_REG_EDX; else temp_reg = I386_REG_EAX; assert(temp_reg != use_reg); code_buf[code_idx++] = I386_INS_MOV_Gv_Ev; emit_base_offset(temp_reg, base_reg, offset); } code_buf[code_idx++] = I386_INS_MOV_Ev_Gv; if (val_output) emit_base_offset(use_reg, temp_reg, 0); else emit_base_offset(use_reg, base_reg, offset); break; default: rts_error(VARLSTCNT(1) ERR_UNIMPLOP); break; } break; default: GTMASSERT; break; } break; default: GTMASSERT; break; } } /* Changes here, emit_base_offset, or emit_jmp may require changes in trip_gen case for OC_CALL[SP] and FORLCLDO */ void emit_xfer(short xfer) { code_buf[code_idx++] = I386_INS_Grp5_Prefix; emit_base_offset(I386_INS_CALL_Ev, I386_REG_EBX, (int4)xfer); } void emit_op_base_offset(generic_op op, short base_reg, int offset, short use_reg) { error_def (ERR_UNIMPLOP); switch (op) { case CLEAR: code_buf[code_idx++] = I386_INS_MOV_Ev_Iv; emit_base_offset(0, base_reg, offset); *((int4 *)&code_buf[code_idx]) = 0; code_idx += SIZEOF(int4); break; case COMPARE: code_buf[code_idx++] = I386_INS_CMP_Gv_Ev; emit_base_offset(use_reg, base_reg, offset); break; case INCREMENT: code_buf[code_idx++] = I386_INS_Grp5_Prefix; emit_base_offset(I386_INS_INC_Ev, base_reg, offset); break; case LOAD: code_buf[code_idx++] = I386_INS_MOV_Gv_Ev; emit_base_offset(use_reg, base_reg, offset); break; case LOAD_ADDRESS: code_buf[code_idx++] = I386_INS_LEA_Gv_M; emit_base_offset(use_reg, base_reg, offset); break; case PUSH: code_buf[code_idx++] = I386_INS_Grp5_Prefix; emit_base_offset(I386_INS_PUSH_Ev, base_reg, offset); break; case PUSH_ADDRESS: code_buf[code_idx++] = I386_INS_LEA_Gv_M; emit_base_offset(use_reg, base_reg, offset); code_buf[code_idx++] = I386_INS_PUSH_eAX + use_reg; break; case STORE: code_buf[code_idx++] = I386_INS_MOV_Ev_Gv; emit_base_offset(use_reg, base_reg, offset); break; case TEST: code_buf[code_idx++] = I386_INS_Grp1_Ev_Ib_Prefix; emit_base_offset(I386_INS_CMP__, base_reg, offset); code_buf[code_idx++] = 0; break; default: rts_error(VARLSTCNT(1) ERR_UNIMPLOP); break; } } /* Changes here, emit_base_offset, or emit_jmp may require changes in trip_gen case for OC_CALL[SP] and FORLCLDO */ void emit_base_offset (short reg_opcode, short base_reg, int4 offset) { modrm_byte.modrm.reg_opcode = reg_opcode; if (offset == 0) modrm_byte.modrm.mod = I386_MOD32_BASE; else if ((offset >= -128 && offset <= 127) && force_32 == 0) modrm_byte.modrm.mod = I386_MOD32_BASE_DISP_8; else modrm_byte.modrm.mod = I386_MOD32_BASE_DISP_32; if (base_reg == I386_REG_ESP || (base_reg == I386_REG_EBP && offset == 0)) { modrm_byte.modrm.r_m = I386_REG_SIB_FOLLOWS; code_buf[code_idx++] = modrm_byte.byte; sib_byte.sib.base = base_reg; sib_byte.sib.ss = I386_SS_TIMES_1; sib_byte.sib.index = I386_REG_NO_INDEX; code_buf[code_idx++] = sib_byte.byte; } else { modrm_byte.modrm.r_m = base_reg; code_buf[code_idx++] = modrm_byte.byte; } if (offset == 0) ; else if ((offset >= -128 && offset <= 127) && force_32 == 0) code_buf[code_idx++] = offset & 0xff; else { *((int4 *)&code_buf[code_idx]) = offset; code_idx += SIZEOF(int4); } } void emit_op_alit (generic_op op, unsigned char use_reg) { error_def (ERR_UNIMPLOP); switch (op) { case LOAD_ADDRESS: code_buf[code_idx++] = I386_INS_MOV_eAX + use_reg; break; case PUSH: code_buf[code_idx++] = I386_INS_Grp5_Prefix; modrm_byte.modrm.reg_opcode = I386_INS_PUSH_Ev; modrm_byte.modrm.mod = I386_MOD32_BASE; modrm_byte.modrm.r_m = I386_REG_disp32_NO_BASE; code_buf[code_idx++] = modrm_byte.byte; break; case PUSH_ADDRESS: code_buf[code_idx++] = I386_INS_PUSH_Iv; break; default: rts_error(VARLSTCNT(1) ERR_UNIMPLOP); break; } } unsigned char i386_reg(unsigned char vax_reg) { unsigned char reg; switch (vax_reg & 0xf) /* mask out VAX register mode field */ { case 0: reg = I386_REG_EAX; break; case 1: reg = I386_REG_EDX; break; case 8: reg = I386_REG_ESI; break; case 9: reg = I386_REG_EDI; break; case 11: reg = I386_REG_EBX; break; default: GTMASSERT; break; } return reg; }