/* Author(s): * Connor Abbott * Alyssa Rosenzweig * * Copyright (c) 2013 Connor Abbott (connor@abbott.cx) * Copyright (c) 2018 Alyssa Rosenzweig (alyssa@rosenzweig.io) * * 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 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 "midgard.h" #include "midgard-parse.h" #include "midgard_ops.h" #include "disassemble.h" #include "helpers.h" #include "util/half_float.h" #include "util/u_math.h" #define DEFINE_CASE(define, str) case define: { printf(str); break; } static bool is_instruction_int = false; /* Stats */ static struct midgard_disasm_stats midg_stats; /* Prints a short form of the tag for branching, the minimum needed to be * legible and unambiguous */ static void print_tag_short(unsigned tag) { switch (midgard_word_types[tag]) { case midgard_word_type_texture: printf("tex/%X", tag); break; case midgard_word_type_load_store: printf("ldst"); break; case midgard_word_type_alu: printf("alu%u/%X", midgard_word_size[tag], tag); break; default: printf("%s%X", (tag > 0) ? "" : "unk", tag); break; } } static void print_alu_opcode(midgard_alu_op op) { bool int_op = false; if (alu_opcode_props[op].name) { printf("%s", alu_opcode_props[op].name); int_op = midgard_is_integer_op(op); } else printf("alu_op_%02X", op); /* For constant analysis */ is_instruction_int = int_op; } static void print_ld_st_opcode(midgard_load_store_op op) { if (load_store_opcode_names[op]) printf("%s", load_store_opcode_names[op]); else printf("ldst_op_%02X", op); } static bool is_embedded_constant_half = false; static bool is_embedded_constant_int = false; static char prefix_for_bits(unsigned bits) { switch (bits) { case 8: return 'q'; case 16: return 'h'; case 64: return 'd'; default: return 0; } } /* For static analysis to ensure all registers are written at least once before * use along the source code path (TODO: does this break done for complex CF?) */ uint16_t midg_ever_written = 0; static void print_reg(unsigned reg, unsigned bits) { /* Perform basic static analysis for expanding constants correctly */ if (reg == 26) { is_embedded_constant_int = is_instruction_int; is_embedded_constant_half = (bits < 32); } unsigned uniform_reg = 23 - reg; bool is_uniform = false; /* For r8-r15, it could be a work or uniform. We distinguish based on * the fact work registers are ALWAYS written before use, but uniform * registers are NEVER written before use. */ if ((reg >= 8 && reg < 16) && !(midg_ever_written & (1 << reg))) is_uniform = true; /* r16-r23 are always uniform */ if (reg >= 16 && reg <= 23) is_uniform = true; /* Update the uniform count appropriately */ if (is_uniform) midg_stats.uniform_count = MAX2(uniform_reg + 1, midg_stats.uniform_count); char prefix = prefix_for_bits(bits); if (prefix) putchar(prefix); printf("r%u", reg); } static char *outmod_names_float[4] = { "", ".pos", ".unk2", ".sat" }; static char *outmod_names_int[4] = { ".isat", ".usat", "", ".hi" }; static char *srcmod_names_int[4] = { "sext(", "zext(", "", "(" }; static void print_outmod(unsigned outmod, bool is_int) { printf("%s", is_int ? outmod_names_int[outmod] : outmod_names_float[outmod]); } static void print_quad_word(uint32_t *words, unsigned tabs) { unsigned i; for (i = 0; i < 4; i++) printf("0x%08X%s ", words[i], i == 3 ? "" : ","); printf("\n"); } static const char components[16] = "xyzwefghijklmnop"; /* Helper to print 4 chars of a swizzle */ static void print_swizzle_helper(unsigned swizzle, bool upper) { for (unsigned i = 0; i < 4; ++i) { unsigned c = (swizzle >> (i * 2)) & 3; c += upper*4; printf("%c", components[c]); } } /* Helper to print 8 chars of a swizzle, duplicating over */ static void print_swizzle_helper_8(unsigned swizzle, bool upper) { for (unsigned i = 0; i < 4; ++i) { unsigned c = (swizzle >> (i * 2)) & 3; c *= 2; c += upper*8; printf("%c%c", components[c], components[c+1]); } } static void print_swizzle_vec16(unsigned swizzle, bool rep_high, bool rep_low, midgard_dest_override override) { printf("."); if (override == midgard_dest_override_upper) { if (rep_high) printf(" /* rep_high */ "); if (rep_low) printf(" /* rep_low */ "); if (!rep_high && rep_low) print_swizzle_helper_8(swizzle, true); else print_swizzle_helper_8(swizzle, false); } else { print_swizzle_helper_8(swizzle, rep_high & 1); print_swizzle_helper_8(swizzle, !(rep_low & 1)); } } static void print_swizzle_vec8(unsigned swizzle, bool rep_high, bool rep_low) { printf("."); print_swizzle_helper(swizzle, rep_high & 1); print_swizzle_helper(swizzle, !(rep_low & 1)); } static void print_swizzle_vec4(unsigned swizzle, bool rep_high, bool rep_low) { if (rep_high) printf(" /* rep_high */ "); if (rep_low) printf(" /* rep_low */ "); if (swizzle == 0xE4) return; /* xyzw */ printf("."); print_swizzle_helper(swizzle, 0); } static void print_swizzle_vec2(unsigned swizzle, bool rep_high, bool rep_low) { if (rep_high) printf(" /* rep_high */ "); if (rep_low) printf(" /* rep_low */ "); if (swizzle == 0xE4) return; /* XY */ printf("."); for (unsigned i = 0; i < 4; i += 2) { unsigned a = (swizzle >> (i * 2)) & 3; unsigned b = (swizzle >> ((i+1) * 2)) & 3; /* Normally we're adjacent, but if there's an issue, don't make * it ambiguous */ if (a & 0x1) printf("[%c%c]", components[a], components[b]); else if (a == b) printf("%c", components[a >> 1]); else if (b == (a + 1)) printf("%c", "XY"[a >> 1]); else printf("[%c%c]", components[a], components[b]); } } static int bits_for_mode(midgard_reg_mode mode) { switch (mode) { case midgard_reg_mode_8: return 8; case midgard_reg_mode_16: return 16; case midgard_reg_mode_32: return 32; case midgard_reg_mode_64: return 64; default: unreachable("Invalid reg mode"); return 0; } } static int bits_for_mode_halved(midgard_reg_mode mode, bool half) { unsigned bits = bits_for_mode(mode); if (half) bits >>= 1; return bits; } static void print_vector_src(unsigned src_binary, midgard_reg_mode mode, unsigned reg, midgard_dest_override override, bool is_int) { midgard_vector_alu_src *src = (midgard_vector_alu_src *)&src_binary; /* Modifiers change meaning depending on the op's context */ midgard_int_mod int_mod = src->mod; if (is_int) { printf("%s", srcmod_names_int[int_mod]); } else { if (src->mod & MIDGARD_FLOAT_MOD_NEG) printf("-"); if (src->mod & MIDGARD_FLOAT_MOD_ABS) printf("abs("); } //register unsigned bits = bits_for_mode_halved(mode, src->half); print_reg(reg, bits); //swizzle if (bits == 16) print_swizzle_vec8(src->swizzle, src->rep_high, src->rep_low); else if (bits == 8) print_swizzle_vec16(src->swizzle, src->rep_high, src->rep_low, override); else if (bits == 32) print_swizzle_vec4(src->swizzle, src->rep_high, src->rep_low); else if (bits == 64) print_swizzle_vec2(src->swizzle, src->rep_high, src->rep_low); /* Since we wrapped with a function-looking thing */ if (is_int && int_mod == midgard_int_shift) printf(") << %u", bits); else if ((is_int && (int_mod != midgard_int_normal)) || (!is_int && src->mod & MIDGARD_FLOAT_MOD_ABS)) printf(")"); } static uint16_t decode_vector_imm(unsigned src2_reg, unsigned imm) { uint16_t ret; ret = src2_reg << 11; ret |= (imm & 0x7) << 8; ret |= (imm >> 3) & 0xFF; return ret; } static void print_immediate(uint16_t imm) { if (is_instruction_int) printf("#%u", imm); else printf("#%g", _mesa_half_to_float(imm)); } static void update_dest(unsigned reg) { /* We should record writes as marking this as a work register. Store * the max register in work_count; we'll add one at the end */ if (reg < 16) { midg_stats.work_count = MAX2(reg, midg_stats.work_count); midg_ever_written |= (1 << reg); } } static unsigned print_dest(unsigned reg, midgard_reg_mode mode, midgard_dest_override override) { /* Depending on the mode and override, we determine the type of * destination addressed. Absent an override, we address just the * type of the operation itself */ unsigned bits = bits_for_mode(mode); if (override != midgard_dest_override_none) bits /= 2; update_dest(reg); print_reg(reg, bits); return bits; } static void print_mask_vec16(uint8_t mask, midgard_dest_override override) { printf("."); if (override == midgard_dest_override_none) { for (unsigned i = 0; i < 8; i++) { if (mask & (1 << i)) printf("%c%c", components[i*2 + 0], components[i*2 + 1]); } } else { bool upper = (override == midgard_dest_override_upper); for (unsigned i = 0; i < 8; i++) { if (mask & (1 << i)) printf("%c", components[i + (upper ? 8 : 0)]); } } } /* For 16-bit+ masks, we read off from the 8-bit mask field. For 16-bit (vec8), * it's just one bit per channel, easy peasy. For 32-bit (vec4), it's one bit * per channel with one duplicate bit in the middle. For 64-bit (vec2), it's * one-bit per channel with _3_ duplicate bits in the middle. Basically, just * subdividing the 128-bit word in 16-bit increments. For 64-bit, we uppercase * the mask to make it obvious what happened */ static void print_mask(uint8_t mask, unsigned bits, midgard_dest_override override) { if (bits == 8) { print_mask_vec16(mask, override); return; } if (bits < 16) { /* Shouldn't happen but with junk / out-of-spec shaders it * would cause an infinite loop */ printf("/* XXX: bits = %u */", bits); return; } /* Skip 'complete' masks */ if (bits >= 32 && mask == 0xFF) return; if (bits == 16) { if (mask == 0x0F) return; else if (mask == 0xF0) { printf("'"); return; } } printf("."); unsigned skip = (bits / 16); bool uppercase = bits > 32; bool tripped = false; for (unsigned i = 0; i < 8; i += skip) { bool a = (mask & (1 << i)) != 0; for (unsigned j = 1; j < skip; ++j) { bool dupe = (mask & (1 << (i + j))) != 0; tripped |= (dupe != a); } if (a) { char c = components[i / skip]; if (uppercase) c = toupper(c); printf("%c", c); } } if (tripped) printf(" /* %X */", mask); } /* Prints the 4-bit masks found in texture and load/store ops, as opposed to * the 8-bit masks found in (vector) ALU ops */ static void print_mask_4(unsigned mask) { if (mask == 0xF) return; printf("."); for (unsigned i = 0; i < 4; ++i) { bool a = (mask & (1 << i)) != 0; if (a) printf("%c", components[i]); } } static void print_vector_field(const char *name, uint16_t *words, uint16_t reg_word, unsigned tabs) { midgard_reg_info *reg_info = (midgard_reg_info *)®_word; midgard_vector_alu *alu_field = (midgard_vector_alu *) words; midgard_reg_mode mode = alu_field->reg_mode; unsigned override = alu_field->dest_override; /* For now, prefix instruction names with their unit, until we * understand how this works on a deeper level */ printf("%s.", name); print_alu_opcode(alu_field->op); /* Postfix with the size to disambiguate if necessary */ char postfix = prefix_for_bits(bits_for_mode(mode)); bool size_ambiguous = override != midgard_dest_override_none; if (size_ambiguous) printf("%c", postfix ? postfix : 'r'); /* Print the outmod, if there is one */ print_outmod(alu_field->outmod, midgard_is_integer_out_op(alu_field->op)); printf(" "); /* Mask denoting status of 8-lanes */ uint8_t mask = alu_field->mask; /* First, print the destination */ unsigned dest_size = print_dest(reg_info->out_reg, mode, alu_field->dest_override); /* Apply the destination override to the mask */ if (mode == midgard_reg_mode_32 || mode == midgard_reg_mode_64) { if (override == midgard_dest_override_lower) mask &= 0x0F; else if (override == midgard_dest_override_upper) mask &= 0xF0; } else if (mode == midgard_reg_mode_16 && override == midgard_dest_override_lower) { /* stub */ } if (override != midgard_dest_override_none) { bool modeable = (mode != midgard_reg_mode_8); bool known = override != 0x3; /* Unused value */ if (!(modeable && known)) printf("/* do%u */ ", override); } print_mask(mask, dest_size, override); printf(", "); bool is_int = midgard_is_integer_op(alu_field->op); print_vector_src(alu_field->src1, mode, reg_info->src1_reg, override, is_int); printf(", "); if (reg_info->src2_imm) { uint16_t imm = decode_vector_imm(reg_info->src2_reg, alu_field->src2 >> 2); print_immediate(imm); } else { print_vector_src(alu_field->src2, mode, reg_info->src2_reg, override, is_int); } midg_stats.instruction_count++; printf("\n"); } static void print_scalar_src(unsigned src_binary, unsigned reg) { midgard_scalar_alu_src *src = (midgard_scalar_alu_src *)&src_binary; if (src->negate) printf("-"); if (src->abs) printf("abs("); print_reg(reg, src->full ? 32 : 16); unsigned c = src->component; if (src->full) { assert((c & 1) == 0); c >>= 1; } printf(".%c", components[c]); if (src->abs) printf(")"); } static uint16_t decode_scalar_imm(unsigned src2_reg, unsigned imm) { uint16_t ret; ret = src2_reg << 11; ret |= (imm & 3) << 9; ret |= (imm & 4) << 6; ret |= (imm & 0x38) << 2; ret |= imm >> 6; return ret; } static void print_scalar_field(const char *name, uint16_t *words, uint16_t reg_word, unsigned tabs) { midgard_reg_info *reg_info = (midgard_reg_info *)®_word; midgard_scalar_alu *alu_field = (midgard_scalar_alu *) words; if (alu_field->unknown) printf("scalar ALU unknown bit set\n"); printf("%s.", name); print_alu_opcode(alu_field->op); print_outmod(alu_field->outmod, midgard_is_integer_out_op(alu_field->op)); printf(" "); bool full = alu_field->output_full; update_dest(reg_info->out_reg); print_reg(reg_info->out_reg, full ? 32 : 16); unsigned c = alu_field->output_component; if (full) { assert((c & 1) == 0); c >>= 1; } printf(".%c, ", components[c]); print_scalar_src(alu_field->src1, reg_info->src1_reg); printf(", "); if (reg_info->src2_imm) { uint16_t imm = decode_scalar_imm(reg_info->src2_reg, alu_field->src2); print_immediate(imm); } else print_scalar_src(alu_field->src2, reg_info->src2_reg); midg_stats.instruction_count++; printf("\n"); } static void print_branch_op(unsigned op) { switch (op) { case midgard_jmp_writeout_op_branch_uncond: printf("uncond."); break; case midgard_jmp_writeout_op_branch_cond: printf("cond."); break; case midgard_jmp_writeout_op_writeout: printf("write."); break; case midgard_jmp_writeout_op_tilebuffer_pending: printf("tilebuffer."); break; case midgard_jmp_writeout_op_discard: printf("discard."); break; default: printf("unk%u.", op); break; } } static void print_branch_cond(int cond) { switch (cond) { case midgard_condition_write0: printf("write0"); break; case midgard_condition_false: printf("false"); break; case midgard_condition_true: printf("true"); break; case midgard_condition_always: printf("always"); break; default: printf("unk%X", cond); break; } } static void print_compact_branch_writeout_field(uint16_t word) { midgard_jmp_writeout_op op = word & 0x7; switch (op) { case midgard_jmp_writeout_op_branch_uncond: { midgard_branch_uncond br_uncond; memcpy((char *) &br_uncond, (char *) &word, sizeof(br_uncond)); printf("br.uncond "); if (br_uncond.unknown != 1) printf("unknown:%u, ", br_uncond.unknown); if (br_uncond.offset >= 0) printf("+"); printf("%d -> ", br_uncond.offset); print_tag_short(br_uncond.dest_tag); printf("\n"); break; } case midgard_jmp_writeout_op_branch_cond: case midgard_jmp_writeout_op_writeout: case midgard_jmp_writeout_op_discard: default: { midgard_branch_cond br_cond; memcpy((char *) &br_cond, (char *) &word, sizeof(br_cond)); printf("br."); print_branch_op(br_cond.op); print_branch_cond(br_cond.cond); printf(" "); if (br_cond.offset >= 0) printf("+"); printf("%d -> ", br_cond.offset); print_tag_short(br_cond.dest_tag); printf("\n"); break; } } midg_stats.instruction_count++; } static void print_extended_branch_writeout_field(uint8_t *words) { midgard_branch_extended br; memcpy((char *) &br, (char *) words, sizeof(br)); printf("brx."); print_branch_op(br.op); /* Condition codes are a LUT in the general case, but simply repeated 8 times for single-channel conditions.. Check this. */ bool single_channel = true; for (unsigned i = 0; i < 16; i += 2) { single_channel &= (((br.cond >> i) & 0x3) == (br.cond & 0x3)); } if (single_channel) print_branch_cond(br.cond & 0x3); else printf("lut%X", br.cond); if (br.unknown) printf(".unknown%u", br.unknown); printf(" "); if (br.offset >= 0) printf("+"); printf("%d -> ", br.offset); print_tag_short(br.dest_tag); printf("\n"); midg_stats.instruction_count++; } static unsigned num_alu_fields_enabled(uint32_t control_word) { unsigned ret = 0; if ((control_word >> 17) & 1) ret++; if ((control_word >> 19) & 1) ret++; if ((control_word >> 21) & 1) ret++; if ((control_word >> 23) & 1) ret++; if ((control_word >> 25) & 1) ret++; return ret; } static float float_bitcast(uint32_t integer) { union { uint32_t i; float f; } v; v.i = integer; return v.f; } static void print_alu_word(uint32_t *words, unsigned num_quad_words, unsigned tabs) { uint32_t control_word = words[0]; uint16_t *beginning_ptr = (uint16_t *)(words + 1); unsigned num_fields = num_alu_fields_enabled(control_word); uint16_t *word_ptr = beginning_ptr + num_fields; unsigned num_words = 2 + num_fields; if ((control_word >> 16) & 1) printf("unknown bit 16 enabled\n"); if ((control_word >> 17) & 1) { print_vector_field("vmul", word_ptr, *beginning_ptr, tabs); beginning_ptr += 1; word_ptr += 3; num_words += 3; } if ((control_word >> 18) & 1) printf("unknown bit 18 enabled\n"); if ((control_word >> 19) & 1) { print_scalar_field("sadd", word_ptr, *beginning_ptr, tabs); beginning_ptr += 1; word_ptr += 2; num_words += 2; } if ((control_word >> 20) & 1) printf("unknown bit 20 enabled\n"); if ((control_word >> 21) & 1) { print_vector_field("vadd", word_ptr, *beginning_ptr, tabs); beginning_ptr += 1; word_ptr += 3; num_words += 3; } if ((control_word >> 22) & 1) printf("unknown bit 22 enabled\n"); if ((control_word >> 23) & 1) { print_scalar_field("smul", word_ptr, *beginning_ptr, tabs); beginning_ptr += 1; word_ptr += 2; num_words += 2; } if ((control_word >> 24) & 1) printf("unknown bit 24 enabled\n"); if ((control_word >> 25) & 1) { print_vector_field("lut", word_ptr, *beginning_ptr, tabs); word_ptr += 3; num_words += 3; } if ((control_word >> 26) & 1) { print_compact_branch_writeout_field(*word_ptr); word_ptr += 1; num_words += 1; } if ((control_word >> 27) & 1) { print_extended_branch_writeout_field((uint8_t *) word_ptr); word_ptr += 3; num_words += 3; } if (num_quad_words > (num_words + 7) / 8) { assert(num_quad_words == (num_words + 15) / 8); //Assume that the extra quadword is constants void *consts = words + (4 * num_quad_words - 4); if (is_embedded_constant_int) { if (is_embedded_constant_half) { int16_t *sconsts = (int16_t *) consts; printf("sconstants %d, %d, %d, %d\n", sconsts[0], sconsts[1], sconsts[2], sconsts[3]); } else { uint32_t *iconsts = (uint32_t *) consts; printf("iconstants 0x%X, 0x%X, 0x%X, 0x%X\n", iconsts[0], iconsts[1], iconsts[2], iconsts[3]); } } else { if (is_embedded_constant_half) { uint16_t *hconsts = (uint16_t *) consts; printf("hconstants %g, %g, %g, %g\n", _mesa_half_to_float(hconsts[0]), _mesa_half_to_float(hconsts[1]), _mesa_half_to_float(hconsts[2]), _mesa_half_to_float(hconsts[3])); } else { uint32_t *fconsts = (uint32_t *) consts; printf("fconstants %g, %g, %g, %g\n", float_bitcast(fconsts[0]), float_bitcast(fconsts[1]), float_bitcast(fconsts[2]), float_bitcast(fconsts[3])); } } } } static void print_varying_parameters(midgard_load_store_word *word) { midgard_varying_parameter param; unsigned v = word->varying_parameters; memcpy(¶m, &v, sizeof(param)); if (param.is_varying) { /* If a varying, there are qualifiers */ if (param.flat) printf(".flat"); if (param.interpolation != midgard_interp_default) { if (param.interpolation == midgard_interp_centroid) printf(".centroid"); else printf(".interp%d", param.interpolation); } if (param.modifier != midgard_varying_mod_none) { if (param.modifier == midgard_varying_mod_perspective_w) printf(".perspectivew"); else if (param.modifier == midgard_varying_mod_perspective_z) printf(".perspectivez"); else printf(".mod%d", param.modifier); } } else if (param.flat || param.interpolation || param.modifier) { printf(" /* is_varying not set but varying metadata attached */"); } if (param.zero0 || param.zero1 || param.zero2) printf(" /* zero tripped, %u %u %u */ ", param.zero0, param.zero1, param.zero2); } static bool is_op_varying(unsigned op) { switch (op) { case midgard_op_st_vary_16: case midgard_op_st_vary_32: case midgard_op_st_vary_32i: case midgard_op_st_vary_32u: case midgard_op_ld_vary_16: case midgard_op_ld_vary_32: case midgard_op_ld_vary_32i: case midgard_op_ld_vary_32u: return true; } return false; } static bool is_op_attribute(unsigned op) { switch (op) { case midgard_op_ld_attr_16: case midgard_op_ld_attr_32: case midgard_op_ld_attr_32i: case midgard_op_ld_attr_32u: return true; } return false; } static void print_load_store_arg(uint8_t arg, unsigned index) { /* Try to interpret as a register */ midgard_ldst_register_select sel; memcpy(&sel, &arg, sizeof(arg)); /* If unknown is set, we're not sure what this is or how to * interpret it. But if it's zero, we get it. */ if (sel.unknown) { printf("0x%02X", arg); return; } unsigned reg = REGISTER_LDST_BASE + sel.select; char comp = components[sel.component]; printf("r%u.%c", reg, comp); /* Only print a shift if it's non-zero. Shifts only make sense for the * second index. For the first, we're not sure what it means yet */ if (index == 1) { if (sel.shift) printf(" << %u", sel.shift); } else { printf(" /* %X */", sel.shift); } } static void update_stats(signed *stat, unsigned address) { if (*stat >= 0) *stat = MAX2(*stat, address + 1); } static void print_load_store_instr(uint64_t data, unsigned tabs) { midgard_load_store_word *word = (midgard_load_store_word *) &data; print_ld_st_opcode(word->op); unsigned address = word->address; if (is_op_varying(word->op)) { print_varying_parameters(word); /* Do some analysis: check if direct cacess */ if ((word->arg_2 == 0x1E) && midg_stats.varying_count >= 0) update_stats(&midg_stats.varying_count, address); else midg_stats.varying_count = -16; } else if (is_op_attribute(word->op)) { if ((word->arg_2 == 0x1E) && midg_stats.attribute_count >= 0) update_stats(&midg_stats.attribute_count, address); else midg_stats.attribute_count = -16; } printf(" r%u", word->reg); print_mask_4(word->mask); if (!OP_IS_STORE(word->op)) update_dest(word->reg); bool is_ubo = OP_IS_UBO_READ(word->op); if (is_ubo) { /* UBOs use their own addressing scheme */ int lo = word->varying_parameters >> 7; int hi = word->address; /* TODO: Combine fields logically */ address = (hi << 3) | lo; } printf(", %u", address); print_swizzle_vec4(word->swizzle, false, false); printf(", "); if (is_ubo) { printf("ubo%u", word->arg_1); update_stats(&midg_stats.uniform_buffer_count, word->arg_1); } else print_load_store_arg(word->arg_1, 0); printf(", "); print_load_store_arg(word->arg_2, 1); printf(" /* %X */\n", word->varying_parameters); midg_stats.instruction_count++; } static void print_load_store_word(uint32_t *word, unsigned tabs) { midgard_load_store *load_store = (midgard_load_store *) word; if (load_store->word1 != 3) { print_load_store_instr(load_store->word1, tabs); } if (load_store->word2 != 3) { print_load_store_instr(load_store->word2, tabs); } } static void print_texture_reg(bool full, bool select, bool upper) { if (full) printf("r%d", REG_TEX_BASE + select); else printf("hr%d", (REG_TEX_BASE + select) * 2 + upper); if (full && upper) printf("// error: out full / upper mutually exclusive\n"); } static void print_texture_reg_triple(unsigned triple) { bool full = triple & 1; bool select = triple & 2; bool upper = triple & 4; print_texture_reg(full, select, upper); } static void print_texture_reg_select(uint8_t u) { midgard_tex_register_select sel; memcpy(&sel, &u, sizeof(u)); if (!sel.full) printf("h"); printf("r%u", REG_TEX_BASE + sel.select); unsigned component = sel.component; /* Use the upper half in half-reg mode */ if (sel.upper) { assert(!sel.full); component += 4; } printf(".%c", components[component]); assert(sel.zero == 0); } static void print_texture_format(int format) { /* Act like a modifier */ printf("."); switch (format) { DEFINE_CASE(MALI_TEX_1D, "1d"); DEFINE_CASE(MALI_TEX_2D, "2d"); DEFINE_CASE(MALI_TEX_3D, "3d"); DEFINE_CASE(MALI_TEX_CUBE, "cube"); default: unreachable("Bad format"); } } static bool midgard_op_has_helpers(unsigned op, bool gather) { if (gather) return true; switch (op) { case TEXTURE_OP_NORMAL: case TEXTURE_OP_DFDX: case TEXTURE_OP_DFDY: return true; default: return false; } } static void print_texture_op(unsigned op, bool gather) { /* Act like a bare name, like ESSL functions */ if (gather) { printf("textureGather"); unsigned component = op >> 4; unsigned bottom = op & 0xF; if (bottom != 0x2) printf("_unk%u", bottom); printf(".%c", components[component]); return; } switch (op) { DEFINE_CASE(TEXTURE_OP_NORMAL, "texture"); DEFINE_CASE(TEXTURE_OP_LOD, "textureLod"); DEFINE_CASE(TEXTURE_OP_TEXEL_FETCH, "texelFetch"); DEFINE_CASE(TEXTURE_OP_DFDX, "dFdx"); DEFINE_CASE(TEXTURE_OP_DFDY, "dFdy"); default: printf("tex_%X", op); break; } } static bool texture_op_takes_bias(unsigned op) { return op == TEXTURE_OP_NORMAL; } static char sampler_type_name(enum mali_sampler_type t) { switch (t) { case MALI_SAMPLER_FLOAT: return 'f'; case MALI_SAMPLER_UNSIGNED: return 'u'; case MALI_SAMPLER_SIGNED: return 'i'; default: return '?'; } } #undef DEFINE_CASE static void print_texture_word(uint32_t *word, unsigned tabs) { midgard_texture_word *texture = (midgard_texture_word *) word; midg_stats.helper_invocations |= midgard_op_has_helpers(texture->op, texture->is_gather); /* Broad category of texture operation in question */ print_texture_op(texture->op, texture->is_gather); /* Specific format in question */ print_texture_format(texture->format); /* Instruction "modifiers" parallel the ALU instructions. */ if (texture->shadow) printf(".shadow"); if (texture->cont) printf(".cont"); if (texture->last) printf(".last"); /* Output modifiers are always interpreted floatly */ print_outmod(texture->outmod, false); printf(" "); print_texture_reg(texture->out_full, texture->out_reg_select, texture->out_upper); print_mask_4(texture->mask); printf(", "); /* Depending on whether we read from textures directly or indirectly, * we may be able to update our analysis */ if (texture->texture_register) { printf("texture["); print_texture_reg_select(texture->texture_handle); printf("], "); /* Indirect, tut tut */ midg_stats.texture_count = -16; } else { printf("texture%u, ", texture->texture_handle); update_stats(&midg_stats.texture_count, texture->texture_handle); } /* Print the type, GL style */ printf("%csampler", sampler_type_name(texture->sampler_type)); if (texture->sampler_register) { printf("["); print_texture_reg_select(texture->sampler_handle); printf("]"); midg_stats.sampler_count = -16; } else { printf("%u", texture->sampler_handle); update_stats(&midg_stats.sampler_count, texture->sampler_handle); } print_swizzle_vec4(texture->swizzle, false, false); printf(", "); print_texture_reg(texture->in_reg_full, texture->in_reg_select, texture->in_reg_upper); print_swizzle_vec4(texture->in_reg_swizzle, false, false); /* There is *always* an offset attached. Of * course, that offset is just immediate #0 for a * GLES call that doesn't take an offset. If there * is a non-negative non-zero offset, this is * specified in immediate offset mode, with the * values in the offset_* fields as immediates. If * this is a negative offset, we instead switch to * a register offset mode, where the offset_* * fields become register triplets */ if (texture->offset_register) { printf(" + "); print_texture_reg_triple(texture->offset_x); /* The less questions you ask, the better. */ unsigned swizzle_lo, swizzle_hi; unsigned orig_y = texture->offset_y; unsigned orig_z = texture->offset_z; memcpy(&swizzle_lo, &orig_y, sizeof(unsigned)); memcpy(&swizzle_hi, &orig_z, sizeof(unsigned)); /* Duplicate hi swizzle over */ assert(swizzle_hi < 4); swizzle_hi = (swizzle_hi << 2) | swizzle_hi; unsigned swiz = (swizzle_lo << 4) | swizzle_hi; unsigned reversed = util_bitreverse(swiz) >> 24; print_swizzle_vec4(reversed, false, false); printf(", "); } else if (texture->offset_x || texture->offset_y || texture->offset_z) { /* Only select ops allow negative immediate offsets, verify */ bool neg_x = texture->offset_x < 0; bool neg_y = texture->offset_y < 0; bool neg_z = texture->offset_z < 0; bool any_neg = neg_x || neg_y || neg_z; if (any_neg && texture->op != TEXTURE_OP_TEXEL_FETCH) printf("/* invalid negative */ "); /* Regardless, just print the immediate offset */ printf(" + <%d, %d, %d>, ", texture->offset_x, texture->offset_y, texture->offset_z); } else { printf(", "); } char lod_operand = texture_op_takes_bias(texture->op) ? '+' : '='; if (texture->lod_register) { printf("lod %c ", lod_operand); print_texture_reg_select(texture->bias); printf(", "); if (texture->bias_int) printf(" /* bias_int = 0x%X */", texture->bias_int); } else if (texture->op == TEXTURE_OP_TEXEL_FETCH) { /* For texel fetch, the int LOD is in the fractional place and * there is no fraction / possibility of bias. We *always* have * an explicit LOD, even if it's zero. */ if (texture->bias_int) printf(" /* bias_int = 0x%X */ ", texture->bias_int); printf("lod = %u, ", texture->bias); } else if (texture->bias || texture->bias_int) { signed bias_int = texture->bias_int; float bias_frac = texture->bias / 256.0f; float bias = bias_int + bias_frac; bool is_bias = texture_op_takes_bias(texture->op); char sign = (bias >= 0.0) ? '+' : '-'; char operand = is_bias ? sign : '='; printf("lod %c %f, ", operand, fabsf(bias)); } printf("\n"); /* While not zero in general, for these simple instructions the * following unknowns are zero, so we don't include them */ if (texture->unknown4 || texture->unknownA || texture->unknown8) { printf("// unknown4 = 0x%x\n", texture->unknown4); printf("// unknownA = 0x%x\n", texture->unknownA); printf("// unknown8 = 0x%x\n", texture->unknown8); } midg_stats.instruction_count++; } struct midgard_disasm_stats disassemble_midgard(uint8_t *code, size_t size) { uint32_t *words = (uint32_t *) code; unsigned num_words = size / 4; int tabs = 0; bool prefetch_flag = false; int last_next_tag = -1; unsigned i = 0; /* Stats for shader-db */ memset(&midg_stats, 0, sizeof(midg_stats)); midg_ever_written = 0; while (i < num_words) { unsigned tag = words[i] & 0xF; unsigned next_tag = (words[i] >> 4) & 0xF; unsigned num_quad_words = midgard_word_size[tag]; /* Check the tag */ if (last_next_tag > 1) { if (last_next_tag != tag) { printf("/* TAG ERROR got "); print_tag_short(tag); printf(" expected "); print_tag_short(last_next_tag); printf(" */ "); } } else { /* TODO: Check ALU case */ } last_next_tag = next_tag; switch (midgard_word_types[tag]) { case midgard_word_type_texture: print_texture_word(&words[i], tabs); break; case midgard_word_type_load_store: print_load_store_word(&words[i], tabs); break; case midgard_word_type_alu: print_alu_word(&words[i], num_quad_words, tabs); /* Reset word static analysis state */ is_embedded_constant_half = false; is_embedded_constant_int = false; break; default: printf("Unknown word type %u:\n", words[i] & 0xF); num_quad_words = 1; print_quad_word(&words[i], tabs); printf("\n"); break; } if (prefetch_flag && midgard_word_types[tag] == midgard_word_type_alu) break; printf("\n"); unsigned next = (words[i] & 0xF0) >> 4; /* We are parsing per bundle anyway */ midg_stats.bundle_count++; midg_stats.quadword_count += num_quad_words; /* Break based on instruction prefetch flag */ if (i < num_words && next == 1) { prefetch_flag = true; if (midgard_word_types[words[i] & 0xF] != midgard_word_type_alu) break; } i += 4 * num_quad_words; } /* We computed work_count as max_work_registers, so add one to get the * count. If no work registers are written, you still have one work * reported, which is exactly what the hardware expects */ midg_stats.work_count++; return midg_stats; }