/* * AVR disassembler * * Copyright (c) 2019-2020 Richard Henderson * Copyright (c) 2019-2020 Michael Rolnik * * This program 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 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 . */ #include "qemu/osdep.h" #include "cpu.h" typedef struct { disassemble_info *info; uint16_t next_word; bool next_word_used; } DisasContext; static int to_regs_16_31_by_one(DisasContext *ctx, int indx) { return 16 + (indx % 16); } static int to_regs_16_23_by_one(DisasContext *ctx, int indx) { return 16 + (indx % 8); } static int to_regs_24_30_by_two(DisasContext *ctx, int indx) { return 24 + (indx % 4) * 2; } static int to_regs_00_30_by_two(DisasContext *ctx, int indx) { return (indx % 16) * 2; } static uint16_t next_word(DisasContext *ctx) { ctx->next_word_used = true; return ctx->next_word; } static int append_16(DisasContext *ctx, int x) { return x << 16 | next_word(ctx); } /* Include the auto-generated decoder. */ static bool decode_insn(DisasContext *ctx, uint16_t insn); #include "decode_insn.inc.c" #define output(mnemonic, format, ...) \ (pctx->info->fprintf_func(pctx->info->stream, "%-9s " format, \ mnemonic, ##__VA_ARGS__)) int avr_print_insn(bfd_vma addr, disassemble_info *info) { DisasContext ctx; DisasContext *pctx = &ctx; bfd_byte buffer[4]; uint16_t insn; int status; ctx.info = info; status = info->read_memory_func(addr, buffer, 4, info); if (status != 0) { info->memory_error_func(status, addr, info); return -1; } insn = bfd_getl16(buffer); ctx.next_word = bfd_getl16(buffer + 2); ctx.next_word_used = false; if (!decode_insn(&ctx, insn)) { output(".db", "0x%02x, 0x%02x", buffer[0], buffer[1]); } return ctx.next_word_used ? 4 : 2; } #define INSN(opcode, format, ...) \ static bool trans_##opcode(DisasContext *pctx, arg_##opcode * a) \ { \ output(#opcode, format, ##__VA_ARGS__); \ return true; \ } #define INSN_MNEMONIC(opcode, mnemonic, format, ...) \ static bool trans_##opcode(DisasContext *pctx, arg_##opcode * a) \ { \ output(mnemonic, format, ##__VA_ARGS__); \ return true; \ } /* * C Z N V S H T I * 0 1 2 3 4 5 6 7 */ static const char brbc[][5] = { "BRCC", "BRNE", "BRPL", "BRVC", "BRGE", "BRHC", "BRTC", "BRID" }; static const char brbs[][5] = { "BRCS", "BREQ", "BRMI", "BRVS", "BRLT", "BRHS", "BRTS", "BRIE" }; static const char bset[][4] = { "SEC", "SEZ", "SEN", "SEZ", "SES", "SEH", "SET", "SEI" }; static const char bclr[][4] = { "CLC", "CLZ", "CLN", "CLZ", "CLS", "CLH", "CLT", "CLI" }; /* * Arithmetic Instructions */ INSN(ADD, "r%d, r%d", a->rd, a->rr) INSN(ADC, "r%d, r%d", a->rd, a->rr) INSN(ADIW, "r%d:r%d, %d", a->rd + 1, a->rd, a->imm) INSN(SUB, "r%d, r%d", a->rd, a->rr) INSN(SUBI, "r%d, %d", a->rd, a->imm) INSN(SBC, "r%d, r%d", a->rd, a->rr) INSN(SBCI, "r%d, %d", a->rd, a->imm) INSN(SBIW, "r%d:r%d, %d", a->rd + 1, a->rd, a->imm) INSN(AND, "r%d, r%d", a->rd, a->rr) INSN(ANDI, "r%d, %d", a->rd, a->imm) INSN(OR, "r%d, r%d", a->rd, a->rr) INSN(ORI, "r%d, %d", a->rd, a->imm) INSN(EOR, "r%d, r%d", a->rd, a->rr) INSN(COM, "r%d", a->rd) INSN(NEG, "r%d", a->rd) INSN(INC, "r%d", a->rd) INSN(DEC, "r%d", a->rd) INSN(MUL, "r%d, r%d", a->rd, a->rr) INSN(MULS, "r%d, r%d", a->rd, a->rr) INSN(MULSU, "r%d, r%d", a->rd, a->rr) INSN(FMUL, "r%d, r%d", a->rd, a->rr) INSN(FMULS, "r%d, r%d", a->rd, a->rr) INSN(FMULSU, "r%d, r%d", a->rd, a->rr) INSN(DES, "%d", a->imm) /* * Branch Instructions */ INSN(RJMP, ".%+d", a->imm * 2) INSN(IJMP, "") INSN(EIJMP, "") INSN(JMP, "0x%x", a->imm * 2) INSN(RCALL, ".%+d", a->imm * 2) INSN(ICALL, "") INSN(EICALL, "") INSN(CALL, "0x%x", a->imm * 2) INSN(RET, "") INSN(RETI, "") INSN(CPSE, "r%d, r%d", a->rd, a->rr) INSN(CP, "r%d, r%d", a->rd, a->rr) INSN(CPC, "r%d, r%d", a->rd, a->rr) INSN(CPI, "r%d, %d", a->rd, a->imm) INSN(SBRC, "r%d, %d", a->rr, a->bit) INSN(SBRS, "r%d, %d", a->rr, a->bit) INSN(SBIC, "$%d, %d", a->reg, a->bit) INSN(SBIS, "$%d, %d", a->reg, a->bit) INSN_MNEMONIC(BRBS, brbs[a->bit], ".%+d", a->imm * 2) INSN_MNEMONIC(BRBC, brbc[a->bit], ".%+d", a->imm * 2) /* * Data Transfer Instructions */ INSN(MOV, "r%d, r%d", a->rd, a->rr) INSN(MOVW, "r%d:r%d, r%d:r%d", a->rd + 1, a->rd, a->rr + 1, a->rr) INSN(LDI, "r%d, %d", a->rd, a->imm) INSN(LDS, "r%d, %d", a->rd, a->imm) INSN(LDX1, "r%d, X", a->rd) INSN(LDX2, "r%d, X+", a->rd) INSN(LDX3, "r%d, -X", a->rd) INSN(LDY2, "r%d, Y+", a->rd) INSN(LDY3, "r%d, -Y", a->rd) INSN(LDZ2, "r%d, Z+", a->rd) INSN(LDZ3, "r%d, -Z", a->rd) INSN(LDDY, "r%d, Y+%d", a->rd, a->imm) INSN(LDDZ, "r%d, Z+%d", a->rd, a->imm) INSN(STS, "%d, r%d", a->imm, a->rd) INSN(STX1, "X, r%d", a->rr) INSN(STX2, "X+, r%d", a->rr) INSN(STX3, "-X, r%d", a->rr) INSN(STY2, "Y+, r%d", a->rd) INSN(STY3, "-Y, r%d", a->rd) INSN(STZ2, "Z+, r%d", a->rd) INSN(STZ3, "-Z, r%d", a->rd) INSN(STDY, "Y+%d, r%d", a->imm, a->rd) INSN(STDZ, "Z+%d, r%d", a->imm, a->rd) INSN(LPM1, "") INSN(LPM2, "r%d, Z", a->rd) INSN(LPMX, "r%d, Z+", a->rd) INSN(ELPM1, "") INSN(ELPM2, "r%d, Z", a->rd) INSN(ELPMX, "r%d, Z+", a->rd) INSN(SPM, "") INSN(SPMX, "Z+") INSN(IN, "r%d, $%d", a->rd, a->imm) INSN(OUT, "$%d, r%d", a->imm, a->rd) INSN(PUSH, "r%d", a->rd) INSN(POP, "r%d", a->rd) INSN(XCH, "Z, r%d", a->rd) INSN(LAC, "Z, r%d", a->rd) INSN(LAS, "Z, r%d", a->rd) INSN(LAT, "Z, r%d", a->rd) /* * Bit and Bit-test Instructions */ INSN(LSR, "r%d", a->rd) INSN(ROR, "r%d", a->rd) INSN(ASR, "r%d", a->rd) INSN(SWAP, "r%d", a->rd) INSN(SBI, "$%d, %d", a->reg, a->bit) INSN(CBI, "%d, %d", a->reg, a->bit) INSN(BST, "r%d, %d", a->rd, a->bit) INSN(BLD, "r%d, %d", a->rd, a->bit) INSN_MNEMONIC(BSET, bset[a->bit], "") INSN_MNEMONIC(BCLR, bclr[a->bit], "") /* * MCU Control Instructions */ INSN(BREAK, "") INSN(NOP, "") INSN(SLEEP, "") INSN(WDR, "")