/* * Copyright (c) 2013 Rob Clark * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #include #include #include #include #include #include #include #include "instr-a3xx.h" /* bitmask of debug flags */ enum debug_t { PRINT_RAW = 0x1, /* dump raw hexdump */ PRINT_VERBOSE = 0x2, EXPAND_REPEAT = 0x4, }; static enum debug_t debug; #define printf debug_printf static const char *levels[] = { "", "\t", "\t\t", "\t\t\t", "\t\t\t\t", "\t\t\t\t\t", "\t\t\t\t\t\t", "\t\t\t\t\t\t\t", "\t\t\t\t\t\t\t\t", "\t\t\t\t\t\t\t\t\t", "x", "x", "x", "x", "x", "x", }; static const char *component = "xyzw"; static const char *type[] = { [TYPE_F16] = "f16", [TYPE_F32] = "f32", [TYPE_U16] = "u16", [TYPE_U32] = "u32", [TYPE_S16] = "s16", [TYPE_S32] = "s32", [TYPE_U8] = "u8", [TYPE_S8] = "s8", }; struct disasm_ctx { FILE *out; int level; unsigned gpu_id; /* current instruction repeat flag: */ unsigned repeat; /* current instruction repeat indx/offset (for --expand): */ unsigned repeatidx; }; static void print_reg(struct disasm_ctx *ctx, reg_t reg, bool full, bool r, bool c, bool im, bool neg, bool abs, bool addr_rel) { const char type = c ? 'c' : 'r'; // XXX I prefer - and || for neg/abs, but preserving format used // by libllvm-a3xx for easy diffing.. if (abs && neg) fprintf(ctx->out, "(absneg)"); else if (neg) fprintf(ctx->out, "(neg)"); else if (abs) fprintf(ctx->out, "(abs)"); if (r) fprintf(ctx->out, "(r)"); if (im) { fprintf(ctx->out, "%d", reg.iim_val); } else if (addr_rel) { /* I would just use %+d but trying to make it diff'able with * libllvm-a3xx... */ if (reg.iim_val < 0) fprintf(ctx->out, "%s%c", full ? "" : "h", type, -reg.iim_val); else if (reg.iim_val > 0) fprintf(ctx->out, "%s%c", full ? "" : "h", type, reg.iim_val); else fprintf(ctx->out, "%s%c", full ? "" : "h", type); } else if ((reg.num == REG_A0) && !c) { fprintf(ctx->out, "a0.%c", component[reg.comp]); } else if ((reg.num == REG_P0) && !c) { fprintf(ctx->out, "p0.%c", component[reg.comp]); } else { fprintf(ctx->out, "%s%c%d.%c", full ? "" : "h", type, reg.num, component[reg.comp]); } } static unsigned regidx(reg_t reg) { return (4 * reg.num) + reg.comp; } static reg_t idxreg(unsigned idx) { return (reg_t){ .comp = idx & 0x3, .num = idx >> 2, }; } static void print_reg_dst(struct disasm_ctx *ctx, reg_t reg, bool full, bool addr_rel) { reg = idxreg(regidx(reg) + ctx->repeatidx); print_reg(ctx, reg, full, false, false, false, false, false, addr_rel); } static void print_reg_src(struct disasm_ctx *ctx, reg_t reg, bool full, bool r, bool c, bool im, bool neg, bool abs, bool addr_rel) { if (r) reg = idxreg(regidx(reg) + ctx->repeatidx); print_reg(ctx, reg, full, r, c, im, neg, abs, addr_rel); } /* TODO switch to using reginfo struct everywhere, since more readable * than passing a bunch of bools to print_reg_src */ struct reginfo { reg_t reg; bool full; bool r; bool c; bool im; bool neg; bool abs; bool addr_rel; }; static void print_src(struct disasm_ctx *ctx, struct reginfo *info) { print_reg_src(ctx, info->reg, info->full, info->r, info->c, info->im, info->neg, info->abs, info->addr_rel); } //static void print_dst(struct disasm_ctx *ctx, struct reginfo *info) //{ // print_reg_dst(ctx, info->reg, info->full, info->addr_rel); //} static void print_instr_cat0(struct disasm_ctx *ctx, instr_t *instr) { instr_cat0_t *cat0 = &instr->cat0; switch (cat0->opc) { case OPC_KILL: case OPC_IF: fprintf(ctx->out, " %sp0.%c", cat0->inv ? "!" : "", component[cat0->comp]); break; case OPC_BR: fprintf(ctx->out, " %sp0.%c, #%d", cat0->inv ? "!" : "", component[cat0->comp], cat0->a3xx.immed); break; case OPC_JUMP: case OPC_CALL: fprintf(ctx->out, " #%d", cat0->a3xx.immed); break; } if ((debug & PRINT_VERBOSE) && (cat0->dummy2|cat0->dummy3|cat0->dummy4)) fprintf(ctx->out, "\t{0: %x,%x,%x}", cat0->dummy2, cat0->dummy3, cat0->dummy4); } static void print_instr_cat1(struct disasm_ctx *ctx, instr_t *instr) { instr_cat1_t *cat1 = &instr->cat1; if (cat1->ul) fprintf(ctx->out, "(ul)"); if (cat1->src_type == cat1->dst_type) { if ((cat1->src_type == TYPE_S16) && (((reg_t)cat1->dst).num == REG_A0)) { /* special case (nmemonic?): */ fprintf(ctx->out, "mova"); } else { fprintf(ctx->out, "mov.%s%s", type[cat1->src_type], type[cat1->dst_type]); } } else { fprintf(ctx->out, "cov.%s%s", type[cat1->src_type], type[cat1->dst_type]); } fprintf(ctx->out, " "); if (cat1->even) fprintf(ctx->out, "(even)"); if (cat1->pos_inf) fprintf(ctx->out, "(pos_infinity)"); print_reg_dst(ctx, (reg_t)(cat1->dst), type_size(cat1->dst_type) == 32, cat1->dst_rel); fprintf(ctx->out, ", "); /* ugg, have to special case this.. vs print_reg().. */ if (cat1->src_im) { if (type_float(cat1->src_type)) fprintf(ctx->out, "(%f)", cat1->fim_val); else if (type_uint(cat1->src_type)) fprintf(ctx->out, "0x%08x", cat1->uim_val); else fprintf(ctx->out, "%d", cat1->iim_val); } else if (cat1->src_rel && !cat1->src_c) { /* I would just use %+d but trying to make it diff'able with * libllvm-a3xx... */ char type = cat1->src_rel_c ? 'c' : 'r'; if (cat1->off < 0) fprintf(ctx->out, "%c", type, -cat1->off); else if (cat1->off > 0) fprintf(ctx->out, "%c", type, cat1->off); else fprintf(ctx->out, "%c", type); } else { print_reg_src(ctx, (reg_t)(cat1->src), type_size(cat1->src_type) == 32, cat1->src_r, cat1->src_c, cat1->src_im, false, false, false); } if ((debug & PRINT_VERBOSE) && (cat1->must_be_0)) fprintf(ctx->out, "\t{1: %x}", cat1->must_be_0); } static void print_instr_cat2(struct disasm_ctx *ctx, instr_t *instr) { instr_cat2_t *cat2 = &instr->cat2; static const char *cond[] = { "lt", "le", "gt", "ge", "eq", "ne", "?6?", }; switch (_OPC(2, cat2->opc)) { case OPC_CMPS_F: case OPC_CMPS_U: case OPC_CMPS_S: case OPC_CMPV_F: case OPC_CMPV_U: case OPC_CMPV_S: fprintf(ctx->out, ".%s", cond[cat2->cond]); break; } fprintf(ctx->out, " "); if (cat2->ei) fprintf(ctx->out, "(ei)"); print_reg_dst(ctx, (reg_t)(cat2->dst), cat2->full ^ cat2->dst_half, false); fprintf(ctx->out, ", "); unsigned src1_r = cat2->repeat ? cat2->src1_r : 0; if (cat2->c1.src1_c) { print_reg_src(ctx, (reg_t)(cat2->c1.src1), cat2->full, src1_r, cat2->c1.src1_c, cat2->src1_im, cat2->src1_neg, cat2->src1_abs, false); } else if (cat2->rel1.src1_rel) { print_reg_src(ctx, (reg_t)(cat2->rel1.src1), cat2->full, src1_r, cat2->rel1.src1_c, cat2->src1_im, cat2->src1_neg, cat2->src1_abs, cat2->rel1.src1_rel); } else { print_reg_src(ctx, (reg_t)(cat2->src1), cat2->full, src1_r, false, cat2->src1_im, cat2->src1_neg, cat2->src1_abs, false); } unsigned src2_r = cat2->repeat ? cat2->src2_r : 0; switch (_OPC(2, cat2->opc)) { case OPC_ABSNEG_F: case OPC_ABSNEG_S: case OPC_CLZ_B: case OPC_CLZ_S: case OPC_SIGN_F: case OPC_FLOOR_F: case OPC_CEIL_F: case OPC_RNDNE_F: case OPC_RNDAZ_F: case OPC_TRUNC_F: case OPC_NOT_B: case OPC_BFREV_B: case OPC_SETRM: case OPC_CBITS_B: /* these only have one src reg */ break; default: fprintf(ctx->out, ", "); if (cat2->c2.src2_c) { print_reg_src(ctx, (reg_t)(cat2->c2.src2), cat2->full, src2_r, cat2->c2.src2_c, cat2->src2_im, cat2->src2_neg, cat2->src2_abs, false); } else if (cat2->rel2.src2_rel) { print_reg_src(ctx, (reg_t)(cat2->rel2.src2), cat2->full, src2_r, cat2->rel2.src2_c, cat2->src2_im, cat2->src2_neg, cat2->src2_abs, cat2->rel2.src2_rel); } else { print_reg_src(ctx, (reg_t)(cat2->src2), cat2->full, src2_r, false, cat2->src2_im, cat2->src2_neg, cat2->src2_abs, false); } break; } } static void print_instr_cat3(struct disasm_ctx *ctx, instr_t *instr) { instr_cat3_t *cat3 = &instr->cat3; bool full = instr_cat3_full(cat3); fprintf(ctx->out, " "); print_reg_dst(ctx, (reg_t)(cat3->dst), full ^ cat3->dst_half, false); fprintf(ctx->out, ", "); unsigned src1_r = cat3->repeat ? cat3->src1_r : 0; if (cat3->c1.src1_c) { print_reg_src(ctx, (reg_t)(cat3->c1.src1), full, src1_r, cat3->c1.src1_c, false, cat3->src1_neg, false, false); } else if (cat3->rel1.src1_rel) { print_reg_src(ctx, (reg_t)(cat3->rel1.src1), full, src1_r, cat3->rel1.src1_c, false, cat3->src1_neg, false, cat3->rel1.src1_rel); } else { print_reg_src(ctx, (reg_t)(cat3->src1), full, src1_r, false, false, cat3->src1_neg, false, false); } fprintf(ctx->out, ", "); unsigned src2_r = cat3->repeat ? cat3->src2_r : 0; print_reg_src(ctx, (reg_t)cat3->src2, full, src2_r, cat3->src2_c, false, cat3->src2_neg, false, false); fprintf(ctx->out, ", "); if (cat3->c2.src3_c) { print_reg_src(ctx, (reg_t)(cat3->c2.src3), full, cat3->src3_r, cat3->c2.src3_c, false, cat3->src3_neg, false, false); } else if (cat3->rel2.src3_rel) { print_reg_src(ctx, (reg_t)(cat3->rel2.src3), full, cat3->src3_r, cat3->rel2.src3_c, false, cat3->src3_neg, false, cat3->rel2.src3_rel); } else { print_reg_src(ctx, (reg_t)(cat3->src3), full, cat3->src3_r, false, false, cat3->src3_neg, false, false); } } static void print_instr_cat4(struct disasm_ctx *ctx, instr_t *instr) { instr_cat4_t *cat4 = &instr->cat4; fprintf(ctx->out, " "); print_reg_dst(ctx, (reg_t)(cat4->dst), cat4->full ^ cat4->dst_half, false); fprintf(ctx->out, ", "); if (cat4->c.src_c) { print_reg_src(ctx, (reg_t)(cat4->c.src), cat4->full, cat4->src_r, cat4->c.src_c, cat4->src_im, cat4->src_neg, cat4->src_abs, false); } else if (cat4->rel.src_rel) { print_reg_src(ctx, (reg_t)(cat4->rel.src), cat4->full, cat4->src_r, cat4->rel.src_c, cat4->src_im, cat4->src_neg, cat4->src_abs, cat4->rel.src_rel); } else { print_reg_src(ctx, (reg_t)(cat4->src), cat4->full, cat4->src_r, false, cat4->src_im, cat4->src_neg, cat4->src_abs, false); } if ((debug & PRINT_VERBOSE) && (cat4->dummy1|cat4->dummy2)) fprintf(ctx->out, "\t{4: %x,%x}", cat4->dummy1, cat4->dummy2); } static void print_instr_cat5(struct disasm_ctx *ctx, instr_t *instr) { static const struct { bool src1, src2, samp, tex; } info[0x1f] = { [opc_op(OPC_ISAM)] = { true, false, true, true, }, [opc_op(OPC_ISAML)] = { true, true, true, true, }, [opc_op(OPC_ISAMM)] = { true, false, true, true, }, [opc_op(OPC_SAM)] = { true, false, true, true, }, [opc_op(OPC_SAMB)] = { true, true, true, true, }, [opc_op(OPC_SAML)] = { true, true, true, true, }, [opc_op(OPC_SAMGQ)] = { true, false, true, true, }, [opc_op(OPC_GETLOD)] = { true, false, true, true, }, [opc_op(OPC_CONV)] = { true, true, true, true, }, [opc_op(OPC_CONVM)] = { true, true, true, true, }, [opc_op(OPC_GETSIZE)] = { true, false, false, true, }, [opc_op(OPC_GETBUF)] = { false, false, false, true, }, [opc_op(OPC_GETPOS)] = { true, false, false, true, }, [opc_op(OPC_GETINFO)] = { false, false, false, true, }, [opc_op(OPC_DSX)] = { true, false, false, false, }, [opc_op(OPC_DSY)] = { true, false, false, false, }, [opc_op(OPC_GATHER4R)] = { true, false, true, true, }, [opc_op(OPC_GATHER4G)] = { true, false, true, true, }, [opc_op(OPC_GATHER4B)] = { true, false, true, true, }, [opc_op(OPC_GATHER4A)] = { true, false, true, true, }, [opc_op(OPC_SAMGP0)] = { true, false, true, true, }, [opc_op(OPC_SAMGP1)] = { true, false, true, true, }, [opc_op(OPC_SAMGP2)] = { true, false, true, true, }, [opc_op(OPC_SAMGP3)] = { true, false, true, true, }, [opc_op(OPC_DSXPP_1)] = { true, false, false, false, }, [opc_op(OPC_DSYPP_1)] = { true, false, false, false, }, [opc_op(OPC_RGETPOS)] = { true, false, false, false, }, [opc_op(OPC_RGETINFO)] = { false, false, false, false, }, }; instr_cat5_t *cat5 = &instr->cat5; int i; if (cat5->is_3d) fprintf(ctx->out, ".3d"); if (cat5->is_a) fprintf(ctx->out, ".a"); if (cat5->is_o) fprintf(ctx->out, ".o"); if (cat5->is_p) fprintf(ctx->out, ".p"); if (cat5->is_s) fprintf(ctx->out, ".s"); if (cat5->is_s2en) fprintf(ctx->out, ".s2en"); fprintf(ctx->out, " "); switch (_OPC(5, cat5->opc)) { case OPC_DSXPP_1: case OPC_DSYPP_1: break; default: fprintf(ctx->out, "(%s)", type[cat5->type]); break; } fprintf(ctx->out, "("); for (i = 0; i < 4; i++) if (cat5->wrmask & (1 << i)) fprintf(ctx->out, "%c", "xyzw"[i]); fprintf(ctx->out, ")"); print_reg_dst(ctx, (reg_t)(cat5->dst), type_size(cat5->type) == 32, false); if (info[cat5->opc].src1) { fprintf(ctx->out, ", "); print_reg_src(ctx, (reg_t)(cat5->src1), cat5->full, false, false, false, false, false, false); } if (cat5->is_s2en) { if (cat5->is_o || info[cat5->opc].src2) { fprintf(ctx->out, ", "); print_reg_src(ctx, (reg_t)(cat5->s2en.src2), cat5->full, false, false, false, false, false, false); } fprintf(ctx->out, ", "); print_reg_src(ctx, (reg_t)(cat5->s2en.src3), false, false, false, false, false, false, false); } else { if (cat5->is_o || info[cat5->opc].src2) { fprintf(ctx->out, ", "); print_reg_src(ctx, (reg_t)(cat5->norm.src2), cat5->full, false, false, false, false, false, false); } if (info[cat5->opc].samp) fprintf(ctx->out, ", s#%d", cat5->norm.samp); if (info[cat5->opc].tex) fprintf(ctx->out, ", t#%d", cat5->norm.tex); } if (debug & PRINT_VERBOSE) { if (cat5->is_s2en) { if ((debug & PRINT_VERBOSE) && (cat5->s2en.dummy1|cat5->s2en.dummy2|cat5->dummy2)) fprintf(ctx->out, "\t{5: %x,%x,%x}", cat5->s2en.dummy1, cat5->s2en.dummy2, cat5->dummy2); } else { if ((debug & PRINT_VERBOSE) && (cat5->norm.dummy1|cat5->dummy2)) fprintf(ctx->out, "\t{5: %x,%x}", cat5->norm.dummy1, cat5->dummy2); } } } static void print_instr_cat6_a3xx(struct disasm_ctx *ctx, instr_t *instr) { instr_cat6_t *cat6 = &instr->cat6; char sd = 0, ss = 0; /* dst/src address space */ bool nodst = false; struct reginfo dst, src1, src2; int src1off = 0, dstoff = 0; memset(&dst, 0, sizeof(dst)); memset(&src1, 0, sizeof(src1)); memset(&src2, 0, sizeof(src2)); switch (_OPC(6, cat6->opc)) { case OPC_RESINFO: case OPC_RESFMT: dst.full = type_size(cat6->type) == 32; src1.full = type_size(cat6->type) == 32; src2.full = type_size(cat6->type) == 32; break; case OPC_L2G: case OPC_G2L: dst.full = true; src1.full = true; src2.full = true; break; case OPC_STG: case OPC_STL: case OPC_STP: case OPC_STLW: case OPC_STIB: dst.full = true; src1.full = type_size(cat6->type) == 32; src2.full = type_size(cat6->type) == 32; break; default: dst.full = type_size(cat6->type) == 32; src1.full = true; src2.full = true; break; } switch (_OPC(6, cat6->opc)) { case OPC_PREFETCH: break; case OPC_RESINFO: fprintf(ctx->out, ".%dd", cat6->ldgb.d + 1); break; case OPC_LDGB: fprintf(ctx->out, ".%s", cat6->ldgb.typed ? "typed" : "untyped"); fprintf(ctx->out, ".%dd", cat6->ldgb.d + 1); fprintf(ctx->out, ".%s", type[cat6->type]); fprintf(ctx->out, ".%d", cat6->ldgb.type_size + 1); break; case OPC_STGB: case OPC_STIB: fprintf(ctx->out, ".%s", cat6->stgb.typed ? "typed" : "untyped"); fprintf(ctx->out, ".%dd", cat6->stgb.d + 1); fprintf(ctx->out, ".%s", type[cat6->type]); fprintf(ctx->out, ".%d", cat6->stgb.type_size + 1); break; case OPC_ATOMIC_ADD: case OPC_ATOMIC_SUB: case OPC_ATOMIC_XCHG: case OPC_ATOMIC_INC: case OPC_ATOMIC_DEC: case OPC_ATOMIC_CMPXCHG: case OPC_ATOMIC_MIN: case OPC_ATOMIC_MAX: case OPC_ATOMIC_AND: case OPC_ATOMIC_OR: case OPC_ATOMIC_XOR: ss = cat6->g ? 'g' : 'l'; fprintf(ctx->out, ".%s", cat6->ldgb.typed ? "typed" : "untyped"); fprintf(ctx->out, ".%dd", cat6->ldgb.d + 1); fprintf(ctx->out, ".%s", type[cat6->type]); fprintf(ctx->out, ".%d", cat6->ldgb.type_size + 1); fprintf(ctx->out, ".%c", ss); break; default: dst.im = cat6->g && !cat6->dst_off; fprintf(ctx->out, ".%s", type[cat6->type]); break; } fprintf(ctx->out, " "); switch (_OPC(6, cat6->opc)) { case OPC_STG: sd = 'g'; break; case OPC_STP: sd = 'p'; break; case OPC_STL: case OPC_STLW: sd = 'l'; break; case OPC_LDG: case OPC_LDC: ss = 'g'; break; case OPC_LDP: ss = 'p'; break; case OPC_LDL: case OPC_LDLW: case OPC_LDLV: ss = 'l'; break; case OPC_L2G: ss = 'l'; sd = 'g'; break; case OPC_G2L: ss = 'g'; sd = 'l'; break; case OPC_PREFETCH: ss = 'g'; nodst = true; break; } if ((_OPC(6, cat6->opc) == OPC_STGB) || (_OPC(6, cat6->opc) == OPC_STIB)) { struct reginfo src3; memset(&src3, 0, sizeof(src3)); src1.reg = (reg_t)(cat6->stgb.src1); src2.reg = (reg_t)(cat6->stgb.src2); src2.im = cat6->stgb.src2_im; src3.reg = (reg_t)(cat6->stgb.src3); src3.im = cat6->stgb.src3_im; src3.full = true; fprintf(ctx->out, "g[%u], ", cat6->stgb.dst_ssbo); print_src(ctx, &src1); fprintf(ctx->out, ", "); print_src(ctx, &src2); fprintf(ctx->out, ", "); print_src(ctx, &src3); if (debug & PRINT_VERBOSE) fprintf(ctx->out, " (pad0=%x, pad3=%x)", cat6->stgb.pad0, cat6->stgb.pad3); return; } if (is_atomic(_OPC(6, cat6->opc))) { src1.reg = (reg_t)(cat6->ldgb.src1); src1.im = cat6->ldgb.src1_im; src2.reg = (reg_t)(cat6->ldgb.src2); src2.im = cat6->ldgb.src2_im; dst.reg = (reg_t)(cat6->ldgb.dst); print_src(ctx, &dst); fprintf(ctx->out, ", "); if (ss == 'g') { struct reginfo src3; memset(&src3, 0, sizeof(src3)); src3.reg = (reg_t)(cat6->ldgb.src3); src3.full = true; /* For images, the ".typed" variant is used and src2 is * the ivecN coordinates, ie ivec2 for 2d. * * For SSBOs, the ".untyped" variant is used and src2 is * a simple dword offset.. src3 appears to be * uvec2(offset * 4, 0). Not sure the point of that. */ fprintf(ctx->out, "g[%u], ", cat6->ldgb.src_ssbo); print_src(ctx, &src1); /* value */ fprintf(ctx->out, ", "); print_src(ctx, &src2); /* offset/coords */ fprintf(ctx->out, ", "); print_src(ctx, &src3); /* 64b byte offset.. */ if (debug & PRINT_VERBOSE) { fprintf(ctx->out, " (pad0=%x, pad3=%x, mustbe0=%x)", cat6->ldgb.pad0, cat6->ldgb.pad3, cat6->ldgb.mustbe0); } } else { /* ss == 'l' */ fprintf(ctx->out, "l["); print_src(ctx, &src1); /* simple byte offset */ fprintf(ctx->out, "], "); print_src(ctx, &src2); /* value */ if (debug & PRINT_VERBOSE) { fprintf(ctx->out, " (src3=%x, pad0=%x, pad3=%x, mustbe0=%x)", cat6->ldgb.src3, cat6->ldgb.pad0, cat6->ldgb.pad3, cat6->ldgb.mustbe0); } } return; } else if (_OPC(6, cat6->opc) == OPC_RESINFO) { dst.reg = (reg_t)(cat6->ldgb.dst); print_src(ctx, &dst); fprintf(ctx->out, ", "); fprintf(ctx->out, "g[%u]", cat6->ldgb.src_ssbo); return; } else if (_OPC(6, cat6->opc) == OPC_LDGB) { src1.reg = (reg_t)(cat6->ldgb.src1); src1.im = cat6->ldgb.src1_im; src2.reg = (reg_t)(cat6->ldgb.src2); src2.im = cat6->ldgb.src2_im; dst.reg = (reg_t)(cat6->ldgb.dst); print_src(ctx, &dst); fprintf(ctx->out, ", "); fprintf(ctx->out, "g[%u], ", cat6->ldgb.src_ssbo); print_src(ctx, &src1); fprintf(ctx->out, ", "); print_src(ctx, &src2); if (debug & PRINT_VERBOSE) fprintf(ctx->out, " (pad0=%x, pad3=%x, mustbe0=%x)", cat6->ldgb.pad0, cat6->ldgb.pad3, cat6->ldgb.mustbe0); return; } else if (_OPC(6, cat6->opc) == OPC_LDG && cat6->a.src1_im && cat6->a.src2_im) { struct reginfo src3; memset(&src3, 0, sizeof(src3)); src1.reg = (reg_t)(cat6->a.src1); src2.reg = (reg_t)(cat6->a.src2); src2.im = cat6->a.src2_im; src3.reg = (reg_t)(cat6->a.off); src3.full = true; dst.reg = (reg_t)(cat6->d.dst); print_src(ctx, &dst); fprintf(ctx->out, ", g["); print_src(ctx, &src1); fprintf(ctx->out, "+"); print_src(ctx, &src3); fprintf(ctx->out, "], "); print_src(ctx, &src2); return; } if (cat6->dst_off) { dst.reg = (reg_t)(cat6->c.dst); dstoff = cat6->c.off; } else { dst.reg = (reg_t)(cat6->d.dst); } if (cat6->src_off) { src1.reg = (reg_t)(cat6->a.src1); src1.im = cat6->a.src1_im; src2.reg = (reg_t)(cat6->a.src2); src2.im = cat6->a.src2_im; src1off = cat6->a.off; } else { src1.reg = (reg_t)(cat6->b.src1); src1.im = cat6->b.src1_im; src2.reg = (reg_t)(cat6->b.src2); src2.im = cat6->b.src2_im; } if (!nodst) { if (sd) fprintf(ctx->out, "%c[", sd); /* note: dst might actually be a src (ie. address to store to) */ print_src(ctx, &dst); if (cat6->dst_off && cat6->g) { struct reginfo dstoff_reg = {0}; dstoff_reg.reg = (reg_t) cat6->c.off; dstoff_reg.full = true; fprintf(ctx->out, "+"); print_src(ctx, &dstoff_reg); } else if (dstoff) fprintf(ctx->out, "%+d", dstoff); if (sd) fprintf(ctx->out, "]"); fprintf(ctx->out, ", "); } if (ss) fprintf(ctx->out, "%c[", ss); /* can have a larger than normal immed, so hack: */ if (src1.im) { fprintf(ctx->out, "%u", src1.reg.dummy13); } else { print_src(ctx, &src1); } if (cat6->src_off && cat6->g) print_src(ctx, &src2); else if (src1off) fprintf(ctx->out, "%+d", src1off); if (ss) fprintf(ctx->out, "]"); switch (_OPC(6, cat6->opc)) { case OPC_RESINFO: case OPC_RESFMT: break; default: fprintf(ctx->out, ", "); print_src(ctx, &src2); break; } } static void print_instr_cat6_a6xx(struct disasm_ctx *ctx, instr_t *instr) { instr_cat6_a6xx_t *cat6 = &instr->cat6_a6xx; struct reginfo src1, src2; bool has_dest = _OPC(6, cat6->opc) == OPC_LDIB; char ss = 0; memset(&src1, 0, sizeof(src1)); memset(&src2, 0, sizeof(src2)); fprintf(ctx->out, ".%s", cat6->typed ? "typed" : "untyped"); fprintf(ctx->out, ".%dd", cat6->d + 1); fprintf(ctx->out, ".%s", type[cat6->type]); fprintf(ctx->out, ".%u ", cat6->type_size + 1); if (has_dest) { src2.reg = (reg_t)(cat6->src2); src2.full = true; // XXX print_src(ctx, &src2); fprintf(ctx->out, ", "); } /* NOTE: blob seems to use old encoding for ldl/stl (local memory) */ ss = 'g'; fprintf(ctx->out, "%c[%u", ss, cat6->ssbo); fprintf(ctx->out, "] + "); src1.reg = (reg_t)(cat6->src1); src1.full = true; // XXX print_src(ctx, &src1); if (!has_dest) { fprintf(ctx->out, ", "); src2.reg = (reg_t)(cat6->src2); src2.full = true; // XXX print_src(ctx, &src2); } if (debug & PRINT_VERBOSE) { fprintf(ctx->out, " (pad1=%x, pad2=%x, pad3=%x, pad4=%x)", cat6->pad1, cat6->pad2, cat6->pad3, cat6->pad4); } } static void print_instr_cat6(struct disasm_ctx *ctx, instr_t *instr) { if (!is_cat6_legacy(instr, ctx->gpu_id)) { print_instr_cat6_a6xx(ctx, instr); if (debug & PRINT_VERBOSE) fprintf(ctx->out, " NEW"); } else { print_instr_cat6_a3xx(ctx, instr); if (debug & PRINT_VERBOSE) fprintf(ctx->out, " LEGACY"); } } static void print_instr_cat7(struct disasm_ctx *ctx, instr_t *instr) { instr_cat7_t *cat7 = &instr->cat7; if (cat7->g) fprintf(ctx->out, ".g"); if (cat7->l) fprintf(ctx->out, ".l"); if (_OPC(7, cat7->opc) == OPC_FENCE) { if (cat7->r) fprintf(ctx->out, ".r"); if (cat7->w) fprintf(ctx->out, ".w"); } } /* size of largest OPC field of all the instruction categories: */ #define NOPC_BITS 6 static const struct opc_info { uint16_t cat; uint16_t opc; const char *name; void (*print)(struct disasm_ctx *ctx, instr_t *instr); } opcs[1 << (3+NOPC_BITS)] = { #define OPC(cat, opc, name) [(opc)] = { (cat), (opc), #name, print_instr_cat##cat } /* category 0: */ OPC(0, OPC_NOP, nop), OPC(0, OPC_BR, br), OPC(0, OPC_JUMP, jump), OPC(0, OPC_CALL, call), OPC(0, OPC_RET, ret), OPC(0, OPC_KILL, kill), OPC(0, OPC_END, end), OPC(0, OPC_EMIT, emit), OPC(0, OPC_CUT, cut), OPC(0, OPC_CHMASK, chmask), OPC(0, OPC_CHSH, chsh), OPC(0, OPC_FLOW_REV, flow_rev), OPC(0, OPC_IF, if), OPC(0, OPC_ELSE, else), OPC(0, OPC_ENDIF, endif), /* category 1: */ OPC(1, OPC_MOV, ), /* category 2: */ OPC(2, OPC_ADD_F, add.f), OPC(2, OPC_MIN_F, min.f), OPC(2, OPC_MAX_F, max.f), OPC(2, OPC_MUL_F, mul.f), OPC(2, OPC_SIGN_F, sign.f), OPC(2, OPC_CMPS_F, cmps.f), OPC(2, OPC_ABSNEG_F, absneg.f), OPC(2, OPC_CMPV_F, cmpv.f), OPC(2, OPC_FLOOR_F, floor.f), OPC(2, OPC_CEIL_F, ceil.f), OPC(2, OPC_RNDNE_F, rndne.f), OPC(2, OPC_RNDAZ_F, rndaz.f), OPC(2, OPC_TRUNC_F, trunc.f), OPC(2, OPC_ADD_U, add.u), OPC(2, OPC_ADD_S, add.s), OPC(2, OPC_SUB_U, sub.u), OPC(2, OPC_SUB_S, sub.s), OPC(2, OPC_CMPS_U, cmps.u), OPC(2, OPC_CMPS_S, cmps.s), OPC(2, OPC_MIN_U, min.u), OPC(2, OPC_MIN_S, min.s), OPC(2, OPC_MAX_U, max.u), OPC(2, OPC_MAX_S, max.s), OPC(2, OPC_ABSNEG_S, absneg.s), OPC(2, OPC_AND_B, and.b), OPC(2, OPC_OR_B, or.b), OPC(2, OPC_NOT_B, not.b), OPC(2, OPC_XOR_B, xor.b), OPC(2, OPC_CMPV_U, cmpv.u), OPC(2, OPC_CMPV_S, cmpv.s), OPC(2, OPC_MUL_U24, mul.u24), OPC(2, OPC_MUL_S24, mul.s24), OPC(2, OPC_MULL_U, mull.u), OPC(2, OPC_BFREV_B, bfrev.b), OPC(2, OPC_CLZ_S, clz.s), OPC(2, OPC_CLZ_B, clz.b), OPC(2, OPC_SHL_B, shl.b), OPC(2, OPC_SHR_B, shr.b), OPC(2, OPC_ASHR_B, ashr.b), OPC(2, OPC_BARY_F, bary.f), OPC(2, OPC_MGEN_B, mgen.b), OPC(2, OPC_GETBIT_B, getbit.b), OPC(2, OPC_SETRM, setrm), OPC(2, OPC_CBITS_B, cbits.b), OPC(2, OPC_SHB, shb), OPC(2, OPC_MSAD, msad), /* category 3: */ OPC(3, OPC_MAD_U16, mad.u16), OPC(3, OPC_MADSH_U16, madsh.u16), OPC(3, OPC_MAD_S16, mad.s16), OPC(3, OPC_MADSH_M16, madsh.m16), OPC(3, OPC_MAD_U24, mad.u24), OPC(3, OPC_MAD_S24, mad.s24), OPC(3, OPC_MAD_F16, mad.f16), OPC(3, OPC_MAD_F32, mad.f32), OPC(3, OPC_SEL_B16, sel.b16), OPC(3, OPC_SEL_B32, sel.b32), OPC(3, OPC_SEL_S16, sel.s16), OPC(3, OPC_SEL_S32, sel.s32), OPC(3, OPC_SEL_F16, sel.f16), OPC(3, OPC_SEL_F32, sel.f32), OPC(3, OPC_SAD_S16, sad.s16), OPC(3, OPC_SAD_S32, sad.s32), /* category 4: */ OPC(4, OPC_RCP, rcp), OPC(4, OPC_RSQ, rsq), OPC(4, OPC_LOG2, log2), OPC(4, OPC_EXP2, exp2), OPC(4, OPC_SIN, sin), OPC(4, OPC_COS, cos), OPC(4, OPC_SQRT, sqrt), OPC(4, OPC_HRSQ, hrsq), OPC(4, OPC_HLOG2, hlog2), OPC(4, OPC_HEXP2, hexp2), /* category 5: */ OPC(5, OPC_ISAM, isam), OPC(5, OPC_ISAML, isaml), OPC(5, OPC_ISAMM, isamm), OPC(5, OPC_SAM, sam), OPC(5, OPC_SAMB, samb), OPC(5, OPC_SAML, saml), OPC(5, OPC_SAMGQ, samgq), OPC(5, OPC_GETLOD, getlod), OPC(5, OPC_CONV, conv), OPC(5, OPC_CONVM, convm), OPC(5, OPC_GETSIZE, getsize), OPC(5, OPC_GETBUF, getbuf), OPC(5, OPC_GETPOS, getpos), OPC(5, OPC_GETINFO, getinfo), OPC(5, OPC_DSX, dsx), OPC(5, OPC_DSY, dsy), OPC(5, OPC_GATHER4R, gather4r), OPC(5, OPC_GATHER4G, gather4g), OPC(5, OPC_GATHER4B, gather4b), OPC(5, OPC_GATHER4A, gather4a), OPC(5, OPC_SAMGP0, samgp0), OPC(5, OPC_SAMGP1, samgp1), OPC(5, OPC_SAMGP2, samgp2), OPC(5, OPC_SAMGP3, samgp3), OPC(5, OPC_DSXPP_1, dsxpp.1), OPC(5, OPC_DSYPP_1, dsypp.1), OPC(5, OPC_RGETPOS, rgetpos), OPC(5, OPC_RGETINFO, rgetinfo), /* category 6: */ OPC(6, OPC_LDG, ldg), OPC(6, OPC_LDL, ldl), OPC(6, OPC_LDP, ldp), OPC(6, OPC_STG, stg), OPC(6, OPC_STL, stl), OPC(6, OPC_STP, stp), OPC(6, OPC_LDIB, ldib), OPC(6, OPC_G2L, g2l), OPC(6, OPC_L2G, l2g), OPC(6, OPC_PREFETCH, prefetch), OPC(6, OPC_LDLW, ldlw), OPC(6, OPC_STLW, stlw), OPC(6, OPC_RESFMT, resfmt), OPC(6, OPC_RESINFO, resinfo), OPC(6, OPC_ATOMIC_ADD, atomic.add), OPC(6, OPC_ATOMIC_SUB, atomic.sub), OPC(6, OPC_ATOMIC_XCHG, atomic.xchg), OPC(6, OPC_ATOMIC_INC, atomic.inc), OPC(6, OPC_ATOMIC_DEC, atomic.dec), OPC(6, OPC_ATOMIC_CMPXCHG, atomic.cmpxchg), OPC(6, OPC_ATOMIC_MIN, atomic.min), OPC(6, OPC_ATOMIC_MAX, atomic.max), OPC(6, OPC_ATOMIC_AND, atomic.and), OPC(6, OPC_ATOMIC_OR, atomic.or), OPC(6, OPC_ATOMIC_XOR, atomic.xor), OPC(6, OPC_LDGB, ldgb), OPC(6, OPC_STGB, stgb), OPC(6, OPC_STIB, stib), OPC(6, OPC_LDC, ldc), OPC(6, OPC_LDLV, ldlv), OPC(7, OPC_BAR, bar), OPC(7, OPC_FENCE, fence), #undef OPC }; #define GETINFO(instr) (&(opcs[((instr)->opc_cat << NOPC_BITS) | instr_opc(instr, ctx->gpu_id)])) // XXX hack.. probably should move this table somewhere common: #include "ir3.h" const char *ir3_instr_name(struct ir3_instruction *instr) { if (opc_cat(instr->opc) == -1) return "??meta??"; return opcs[instr->opc].name; } static void print_single_instr(struct disasm_ctx *ctx, instr_t *instr) { const char *name = GETINFO(instr)->name; uint32_t opc = instr_opc(instr, ctx->gpu_id); if (name) { fprintf(ctx->out, "%s", name); GETINFO(instr)->print(ctx, instr); } else { fprintf(ctx->out, "unknown(%d,%d)", instr->opc_cat, opc); switch (instr->opc_cat) { case 0: print_instr_cat0(ctx, instr); break; case 1: print_instr_cat1(ctx, instr); break; case 2: print_instr_cat2(ctx, instr); break; case 3: print_instr_cat3(ctx, instr); break; case 4: print_instr_cat4(ctx, instr); break; case 5: print_instr_cat5(ctx, instr); break; case 6: print_instr_cat6(ctx, instr); break; case 7: print_instr_cat7(ctx, instr); break; } } } static bool print_instr(struct disasm_ctx *ctx, uint32_t *dwords, int n) { instr_t *instr = (instr_t *)dwords; uint32_t opc = instr_opc(instr, ctx->gpu_id); unsigned nop = 0; if (debug & PRINT_VERBOSE) fprintf(ctx->out, "%s%04d[%08xx_%08xx] ", levels[ctx->level], n, dwords[1], dwords[0]); /* NOTE: order flags are printed is a bit fugly.. but for now I * try to match the order in llvm-a3xx disassembler for easy * diff'ing.. */ ctx->repeat = instr_repeat(instr); if (instr->sync) { fprintf(ctx->out, "(sy)"); } if (instr->ss && ((instr->opc_cat <= 4) || (instr->opc_cat == 7))) { fprintf(ctx->out, "(ss)"); } if (instr->jmp_tgt) fprintf(ctx->out, "(jp)"); if (instr_sat(instr)) fprintf(ctx->out, "(sat)"); if (ctx->repeat) fprintf(ctx->out, "(rpt%d)", ctx->repeat); else if ((instr->opc_cat == 2) && (instr->cat2.src1_r || instr->cat2.src2_r)) nop = (instr->cat2.src2_r * 2) + instr->cat2.src1_r; else if ((instr->opc_cat == 3) && (instr->cat3.src1_r || instr->cat3.src2_r)) nop = (instr->cat3.src2_r * 2) + instr->cat3.src1_r; if (nop) fprintf(ctx->out, "(nop%d)", nop); if (instr->ul && ((2 <= instr->opc_cat) && (instr->opc_cat <= 4))) fprintf(ctx->out, "(ul)"); print_single_instr(ctx, instr); fprintf(ctx->out, "\n"); if ((instr->opc_cat <= 4) && (debug & EXPAND_REPEAT)) { int i; for (i = 0; i < nop; i++) { fprintf(ctx->out, "%s%04d[ ] ", levels[ctx->level], n); fprintf(ctx->out, "nop\n"); } for (i = 0; i < ctx->repeat; i++) { ctx->repeatidx = i + 1; fprintf(ctx->out, "%s%04d[ ] ", levels[ctx->level], n); print_single_instr(ctx, instr); fprintf(ctx->out, "\n"); } ctx->repeatidx = 0; } return (instr->opc_cat == 0) && (opc == OPC_END); } int disasm_a3xx(uint32_t *dwords, int sizedwords, int level, FILE *out, unsigned gpu_id) { struct disasm_ctx ctx; int i; int nop_count = 0; assert((sizedwords % 2) == 0); memset(&ctx, 0, sizeof(ctx)); ctx.out = out; ctx.level = level; ctx.gpu_id = gpu_id; for (i = 0; i < sizedwords; i += 2) { print_instr(&ctx, &dwords[i], i/2); if (dwords[i] == 0 && dwords[i + 1] == 0) nop_count++; else nop_count = 0; if (nop_count > 3) break; } return 0; }