ref: e9e9983ebccd77f991af91b1010b179f556148ff
dir: /src/cmd/as/target/x86/ins.c/
#include <stdlib.h> #include <string.h> #include <scc/scc.h> #include "../../as.h" #include "proc.h" #define addrbyte(mod, reg, rm) ((mod) << 6 | (reg) << 3 | (rm)) /* * This implementation is based in: * - x86 Opcode Structure and Instruction Overview - Fraunhofer-Institut * fÜr kommunikation, informationsverarbeitung und ergonomie fkie. * - Intel® 64 and IA-32 Architectures Software Developer’s Manual. * - Encoding Real x86 Instructions - CIS-77 lectures. */ enum addr_mode { MEM_MODE = 0, MEM8_MODE = 1, MEM16_MODE = 2, REG_MODE = 3, }; static int getclass(Node *np) { if (np->addr != AREG) return 0; switch (np->sym->value) { case AREG_AL: case AREG_AH: case AREG_BL: case AREG_BH: case AREG_CL: case AREG_CH: case AREG_DL: case AREG_DH: return R8CLASS; case AREG_AX: case AREG_BX: case AREG_CX: case AREG_DX: case AREG_DI: case AREG_SI: case AREG_SP: case AREG_BP: return R16CLASS; case AREG_CS: case AREG_DS: case AREG_SS: case AREG_ES: case AREG_FS: case AREG_GS: case AREG_EFLAGS: case AREG_CF: case AREG_PF: case AREG_AF: case AREG_ZF: case AREG_SF: case AREG_TF: case AREG_IF: case AREG_DF: case AREG_OF: case AREG_IOPL: case AREG_NT: case AREG_RF: case AREG_VM: case AREG_AC: case AREG_VIF: case AREG_VIP: case AREG_ID: case AREG_EAX: case AREG_RAX: case AREG_EBX: case AREG_RBX: case AREG_ECX: case AREG_RCX: case AREG_EDX: case AREG_RDX: case AREG_SIL: case AREG_ESI: case AREG_RSI: case AREG_DIL: case AREG_EDI: case AREG_RDI: case AREG_SPL: case AREG_ESP: case AREG_RSP: case AREG_BPL: case AREG_EBP: case AREG_RBP: case AREG_R0: case AREG_MM0: case AREG_R1: case AREG_MM1: case AREG_R2: case AREG_MM2: case AREG_R3: case AREG_MM3: case AREG_R4: case AREG_MM4: case AREG_R5: case AREG_MM5: case AREG_R6: case AREG_MM6: case AREG_R7: case AREG_MM7: case AREG_R8: case AREG_R8L: case AREG_R8W: case AREG_R9: case AREG_R9L: case AREG_R9W: case AREG_R10: case AREG_R10L: case AREG_R10W: case AREG_R11: case AREG_R11L: case AREG_R11W: case AREG_R12: case AREG_R12L: case AREG_R12W: case AREG_R13: case AREG_R13L: case AREG_R13W: case AREG_R14: case AREG_R14L: case AREG_R14W: case AREG_R15: case AREG_R15L: case AREG_R15W: case AREG_XMM0: case AREG_XMM1: case AREG_XMM2: case AREG_XMM3: case AREG_XMM4: case AREG_XMM5: case AREG_XMM6: case AREG_XMM7: case AREG_XMM8: case AREG_XMM9: case AREG_XMM10: case AREG_XMM11: case AREG_XMM12: case AREG_XMM13: case AREG_XMM14: case AREG_XMM15: case AREG_YMM0: case AREG_YMM1: case AREG_YMM2: case AREG_YMM3: case AREG_YMM4: case AREG_YMM5: case AREG_YMM6: case AREG_YMM7: case AREG_YMM8: case AREG_YMM9: case AREG_YMM10: case AREG_YMM11: case AREG_YMM12: case AREG_YMM13: case AREG_YMM14: case AREG_YMM15: case AREG_MXCSR: return 0; default: abort(); } } int match(Op *op, Node **args) { unsigned char *p; int arg, class, rep, opt; Node *np; if (!op->args) return args == NULL; opt = rep = 0; for (p = op->args; arg = *p; ++p) { if (rep) --p; if ((np = *args++) == NULL) return (rep|opt) != 0; switch (arg) { case AOPT: opt = 1; break; case AREP: rep = 1; break; case AREG_R8CLASS: class = R8CLASS; goto check_class; case AREG_R16CLASS: class = R16CLASS; check_class: if ((getclass(np) & class) == 0) return 0; break; case AIMM8: case AIMM16: case AIMM32: case AIMM64: if (np->addr != AIMM) return 0; if (toobig(np, arg)) error("overflow in immediate operand"); break; case ASYM: if (np->addr != AIMM || np->op != IDEN) return 0; break; case ADIRECT: case ASTR: if (np->addr != arg) return 0; break; default: abort(); } } return *args == NULL; } Node * moperand(void) { } static int reg8toint(Node *np) { switch (np->sym->value) { case AREG_AL: return 0; case AREG_CL: return 1; case AREG_DL: return 2; case AREG_BL: return 3; case AREG_AH: return 4; case AREG_CH: return 5; case AREG_DH: return 6; case AREG_BH: return 7; default: abort(); } } static int reg16toint(Node *np) { switch (np->sym->value) { case AREG_AX: return 0; case AREG_CX: return 1; case AREG_DX: return 2; case AREG_BX: return 3; case AREG_SP: return 4; case AREG_BP: return 5; case AREG_SI: return 6; case AREG_DI: return 7; default: abort(); } } static int reg32toint(Node *np) { switch (np->sym->value) { case AREG_EAX: return 0; case AREG_ECX: return 1; case AREG_EDX: return 2; case AREG_EBX: return 3; case AREG_ESP: return 4; case AREG_EBP: return 5; case AREG_ESI: return 6; case AREG_EDI: return 7; default: abort(); } } void reg8_reg8(Op *op, Node **args) { int src, dst; char buf[op->size]; src = reg8toint(args[0]); dst = reg8toint(args[1]); memcpy(buf, op->bytes, op->size - 1); buf[op->size - 1] = addrbyte(REG_MODE, src, dst); emit(buf, op->size); } void imm8_reg8(Op *op, Node **args) { int src, dst; char buf[op->size]; src = (*args)->sym->value; dst = reg8toint(args[1]); memcpy(buf, op->bytes, op->size - 2); buf[op->size - 2] = addrbyte(REG_MODE, 0, dst); buf[op->size - 1] = src; emit(buf, op->size); } void reg16_reg16(Op *op, Node **args) { int src, dst; char buf[op->size]; src = reg16toint(args[0]); dst = reg16toint(args[1]); memcpy(buf, op->bytes, op->size - 1); buf[op->size - 1] = addrbyte(REG_MODE, src, dst); emit(buf, op->size); } void reg32_reg32(Op *op, Node **args) { int src, dst; char buf[op->size]; src = reg32toint(args[0]); dst = reg32toint(args[1]); memcpy(buf, op->bytes, op->size - 1); buf[op->size - 1] = addrbyte(REG_MODE, src, dst); emit(buf, op->size); }