/* * Copyright (C) 2017-2019 Alyssa Rosenzweig * Copyright (C) 2017-2019 Connor Abbott * Copyright (C) 2019 Collabora, Ltd. * * 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 #include "decode.h" #include "io.h" #include "hexdump.h" static const char *agx_alloc_types[AGX_NUM_ALLOC] = { "mem", "map", "cmd" }; static void agx_disassemble(void *_code, size_t maxlen, FILE *fp) { /* stub */ } FILE *agxdecode_dump_stream; #define MAX_MAPPINGS 4096 struct agx_bo mmap_array[MAX_MAPPINGS]; unsigned mmap_count = 0; struct agx_bo *ro_mappings[MAX_MAPPINGS]; unsigned ro_mapping_count = 0; static struct agx_bo * agxdecode_find_mapped_gpu_mem_containing_rw(uint64_t addr) { for (unsigned i = 0; i < mmap_count; ++i) { if (mmap_array[i].type == AGX_ALLOC_REGULAR && addr >= mmap_array[i].ptr.gpu && (addr - mmap_array[i].ptr.gpu) < mmap_array[i].size) return mmap_array + i; } return NULL; } static struct agx_bo * agxdecode_find_mapped_gpu_mem_containing(uint64_t addr) { struct agx_bo *mem = agxdecode_find_mapped_gpu_mem_containing_rw(addr); if (mem && mem->ptr.cpu && !mem->ro) { mprotect(mem->ptr.cpu, mem->size, PROT_READ); mem->ro = true; ro_mappings[ro_mapping_count++] = mem; assert(ro_mapping_count < MAX_MAPPINGS); } if (mem && !mem->mapped) { fprintf(stderr, "[ERROR] access to memory not mapped (GPU %" PRIx64 ", handle %u)\n", mem->ptr.gpu, mem->handle); } return mem; } static struct agx_bo * agxdecode_find_handle(unsigned handle, unsigned type) { for (unsigned i = 0; i < mmap_count; ++i) { if (mmap_array[i].type != type) continue; if (mmap_array[i].handle != handle) continue; return &mmap_array[i]; } return NULL; } static void agxdecode_mark_mapped(unsigned handle) { struct agx_bo *bo = agxdecode_find_handle(handle, AGX_ALLOC_REGULAR); if (!bo) { fprintf(stderr, "ERROR - unknown BO mapped with handle %u\n", handle); return; } /* Mark mapped for future consumption */ bo->mapped = true; } static void agxdecode_decode_segment_list(void *segment_list) { unsigned nr_handles = 0; /* First, mark everything unmapped */ for (unsigned i = 0; i < mmap_count; ++i) mmap_array[i].mapped = false; /* Check the header */ struct agx_map_header *hdr = segment_list; if (hdr->resource_group_count == 0) { fprintf(agxdecode_dump_stream, "ERROR - empty map\n"); return; } if (hdr->segment_count != 1) { fprintf(agxdecode_dump_stream, "ERROR - can't handle segment count %u\n", hdr->segment_count); } fprintf(agxdecode_dump_stream, "Segment list:\n"); fprintf(agxdecode_dump_stream, " Command buffer shmem ID: %" PRIx64 "\n", hdr->cmdbuf_id); fprintf(agxdecode_dump_stream, " Encoder ID: %" PRIx64 "\n", hdr->encoder_id); fprintf(agxdecode_dump_stream, " Kernel commands start offset: %u\n", hdr->kernel_commands_start_offset); fprintf(agxdecode_dump_stream, " Kernel commands end offset: %u\n", hdr->kernel_commands_end_offset); fprintf(agxdecode_dump_stream, " Unknown: 0x%X\n", hdr->unk); /* Expected structure: header followed by resource groups */ size_t length = sizeof(struct agx_map_header); length += sizeof(struct agx_map_entry) * hdr->resource_group_count; if (length != hdr->length) { fprintf(agxdecode_dump_stream, "ERROR: expected length %zu, got %u\n", length, hdr->length); } if (hdr->padding[0] || hdr->padding[1]) fprintf(agxdecode_dump_stream, "ERROR - padding tripped\n"); /* Check the entries */ struct agx_map_entry *groups = ((void *) hdr) + sizeof(*hdr); for (unsigned i = 0; i < hdr->resource_group_count; ++i) { struct agx_map_entry group = groups[i]; unsigned count = group.resource_count; STATIC_ASSERT(ARRAY_SIZE(group.resource_id) == 6); STATIC_ASSERT(ARRAY_SIZE(group.resource_unk) == 6); STATIC_ASSERT(ARRAY_SIZE(group.resource_flags) == 6); if ((count < 1) || (count > 6)) { fprintf(agxdecode_dump_stream, "ERROR - invalid count %u\n", count); continue; } for (unsigned j = 0; j < count; ++j) { unsigned handle = group.resource_id[j]; unsigned unk = group.resource_unk[j]; unsigned flags = group.resource_flags[j]; if (!handle) { fprintf(agxdecode_dump_stream, "ERROR - invalid handle %u\n", handle); continue; } agxdecode_mark_mapped(handle); nr_handles++; fprintf(agxdecode_dump_stream, "%u (0x%X, 0x%X)\n", handle, unk, flags); } if (group.unka) fprintf(agxdecode_dump_stream, "ERROR - unknown 0x%X\n", group.unka); /* Visual separator for resource groups */ fprintf(agxdecode_dump_stream, "\n"); } /* Check the handle count */ if (nr_handles != hdr->total_resources) { fprintf(agxdecode_dump_stream, "ERROR - wrong handle count, got %u, expected %u (%u entries)\n", nr_handles, hdr->total_resources, hdr->resource_group_count); } } static inline void * __agxdecode_fetch_gpu_mem(const struct agx_bo *mem, uint64_t gpu_va, size_t size, int line, const char *filename) { if (!mem) mem = agxdecode_find_mapped_gpu_mem_containing(gpu_va); if (!mem) { fprintf(stderr, "Access to unknown memory %" PRIx64 " in %s:%d\n", gpu_va, filename, line); fflush(agxdecode_dump_stream); assert(0); } assert(mem); assert(size + (gpu_va - mem->ptr.gpu) <= mem->size); return mem->ptr.cpu + gpu_va - mem->ptr.gpu; } #define agxdecode_fetch_gpu_mem(gpu_va, size) \ __agxdecode_fetch_gpu_mem(NULL, gpu_va, size, __LINE__, __FILE__) static void agxdecode_map_read_write(void) { for (unsigned i = 0; i < ro_mapping_count; ++i) { ro_mappings[i]->ro = false; mprotect(ro_mappings[i]->ptr.cpu, ro_mappings[i]->size, PROT_READ | PROT_WRITE); } ro_mapping_count = 0; } /* Helpers for parsing the cmdstream */ #define DUMP_UNPACKED(T, var, str) { \ agxdecode_log(str); \ agx_print(agxdecode_dump_stream, T, var, (agxdecode_indent + 1) * 2); \ } #define DUMP_CL(T, cl, str) {\ agx_unpack(agxdecode_dump_stream, cl, T, temp); \ DUMP_UNPACKED(T, temp, str "\n"); \ } #define agxdecode_log(str) fputs(str, agxdecode_dump_stream) #define agxdecode_msg(str) fprintf(agxdecode_dump_stream, "// %s", str) unsigned agxdecode_indent = 0; static void agxdecode_dump_bo(struct agx_bo *bo, const char *name) { fprintf(agxdecode_dump_stream, "%s %s (%u)\n", name, bo->name ?: "", bo->handle); hexdump(agxdecode_dump_stream, bo->ptr.cpu, bo->size, false); } /* Abstraction for command stream parsing */ typedef unsigned (*decode_cmd)(const uint8_t *map, bool verbose); #define STATE_DONE (0xFFFFFFFFu) static void agxdecode_stateful(uint64_t va, const char *label, decode_cmd decoder, bool verbose) { struct agx_bo *alloc = agxdecode_find_mapped_gpu_mem_containing(va); assert(alloc != NULL && "nonexistant object"); fprintf(agxdecode_dump_stream, "%s (%" PRIx64 ", handle %u)\n", label, va, alloc->handle); fflush(agxdecode_dump_stream); uint8_t *map = agxdecode_fetch_gpu_mem(va, 64); uint8_t *end = (uint8_t *) alloc->ptr.cpu + alloc->size; if (verbose) agxdecode_dump_bo(alloc, label); fflush(agxdecode_dump_stream); while (map < end) { unsigned count = decoder(map, verbose); /* If we fail to decode, default to a hexdump (don't hang) */ if (count == 0) { hexdump(agxdecode_dump_stream, map, 8, false); count = 8; } map += count; fflush(agxdecode_dump_stream); if (count == STATE_DONE) break; } } unsigned COUNTER = 0; static unsigned agxdecode_pipeline(const uint8_t *map, UNUSED bool verbose) { uint8_t zeroes[16] = { 0 }; if (map[0] == 0x4D && (map[11] & BITFIELD_BIT(5))) { agx_unpack(agxdecode_dump_stream, map, SET_SHADER_EXTENDED, cmd); DUMP_UNPACKED(SET_SHADER_EXTENDED, cmd, "Set shader\n"); if (cmd.preshader_mode == AGX_PRESHADER_MODE_PRESHADER) { agxdecode_log("Preshader\n"); agx_disassemble(agxdecode_fetch_gpu_mem(cmd.preshader_code, 2048), 2048, agxdecode_dump_stream); agxdecode_log("\n---\n"); } agxdecode_log("\n"); agx_disassemble(agxdecode_fetch_gpu_mem(cmd.code, 2048), 2048, agxdecode_dump_stream); agxdecode_log("\n"); char *name; asprintf(&name, "file%u.bin", COUNTER++); FILE *fp = fopen(name, "wb"); fwrite(agxdecode_fetch_gpu_mem(cmd.code, 2048), 1, 2048, fp); fclose(fp); free(name); agxdecode_log("\n"); return AGX_SET_SHADER_EXTENDED_LENGTH; } else if (map[0] == 0x4D) { agx_unpack(agxdecode_dump_stream, map, SET_SHADER, cmd); DUMP_UNPACKED(SET_SHADER, cmd, "Set shader\n"); fflush(agxdecode_dump_stream); if (cmd.preshader_mode == AGX_PRESHADER_MODE_PRESHADER) { agxdecode_log("Preshader\n"); agx_disassemble(agxdecode_fetch_gpu_mem(cmd.preshader_code, 2048), 2048, agxdecode_dump_stream); agxdecode_log("\n---\n"); } agxdecode_log("\n"); agx_disassemble(agxdecode_fetch_gpu_mem(cmd.code, 2048), 2048, agxdecode_dump_stream); char *name; asprintf(&name, "file%u.bin", COUNTER++); FILE *fp = fopen(name, "wb"); fwrite(agxdecode_fetch_gpu_mem(cmd.code, 2048), 1, 2048, fp); fclose(fp); free(name); agxdecode_log("\n"); return AGX_SET_SHADER_LENGTH; } else if (map[0] == 0xDD) { agx_unpack(agxdecode_dump_stream, map, BIND_TEXTURE, temp); DUMP_UNPACKED(BIND_TEXTURE, temp, "Bind texture\n"); uint8_t *tex = agxdecode_fetch_gpu_mem(temp.buffer, AGX_TEXTURE_LENGTH * temp.count); /* Note: samplers only need 8 byte alignment? */ for (unsigned i = 0; i < temp.count; ++i) { agx_unpack(agxdecode_dump_stream, tex, TEXTURE, t); DUMP_CL(TEXTURE, tex, "Texture"); DUMP_CL(RENDER_TARGET, tex, "Render target"); tex += AGX_TEXTURE_LENGTH; } return AGX_BIND_TEXTURE_LENGTH; } else if (map[0] == 0x9D) { agx_unpack(agxdecode_dump_stream, map, BIND_SAMPLER, temp); DUMP_UNPACKED(BIND_SAMPLER, temp, "Bind sampler\n"); uint8_t *samp = agxdecode_fetch_gpu_mem(temp.buffer, AGX_SAMPLER_LENGTH * temp.count); for (unsigned i = 0; i < temp.count; ++i) { DUMP_CL(SAMPLER, samp, "Sampler"); samp += AGX_SAMPLER_LENGTH; } return AGX_BIND_SAMPLER_LENGTH; } else if (map[0] == 0x1D) { DUMP_CL(BIND_UNIFORM, map, "Bind uniform"); return AGX_BIND_UNIFORM_LENGTH; } else if (memcmp(map, zeroes, 16) == 0) { /* TODO: Termination */ return STATE_DONE; } else { return 0; } } #define PPP_PRINT(map, header_name, struct_name, human) \ if (hdr.header_name) { \ assert(((map + AGX_##struct_name##_LENGTH) <= (base + size)) && \ "buffer overrun in PPP update"); \ DUMP_CL(struct_name, map, human); \ map += AGX_##struct_name##_LENGTH; \ } static void agxdecode_record(uint64_t va, size_t size, bool verbose) { uint8_t *base = agxdecode_fetch_gpu_mem(va, size); uint8_t *map = base; agx_unpack(agxdecode_dump_stream, map, PPP_HEADER, hdr); map += AGX_PPP_HEADER_LENGTH; PPP_PRINT(map, fragment_control, FRAGMENT_CONTROL, "Fragment control"); PPP_PRINT(map, fragment_control_2, FRAGMENT_CONTROL_2, "Fragment control 2"); PPP_PRINT(map, fragment_front_face, FRAGMENT_FACE, "Front face"); PPP_PRINT(map, fragment_front_face_2, FRAGMENT_FACE_2, "Front face 2"); PPP_PRINT(map, fragment_front_stencil, FRAGMENT_STENCIL, "Front stencil"); PPP_PRINT(map, fragment_back_face, FRAGMENT_FACE, "Back face"); PPP_PRINT(map, fragment_back_face_2, FRAGMENT_FACE_2, "Back face 2"); PPP_PRINT(map, fragment_back_stencil, FRAGMENT_STENCIL, "Back stencil"); PPP_PRINT(map, depth_bias_scissor, DEPTH_BIAS_SCISSOR, "Depth bias/scissor"); PPP_PRINT(map, region_clip, REGION_CLIP, "Region clip"); PPP_PRINT(map, viewport, VIEWPORT, "Viewport"); PPP_PRINT(map, w_clamp, W_CLAMP, "W clamp"); PPP_PRINT(map, output_select, OUTPUT_SELECT, "Output select"); PPP_PRINT(map, varying_word_0, VARYING_0, "Varying word 0"); PPP_PRINT(map, varying_word_1, VARYING_1, "Varying word 1"); PPP_PRINT(map, cull, CULL, "Cull"); PPP_PRINT(map, cull_2, CULL_2, "Cull 2"); if (hdr.fragment_shader) { agx_unpack(agxdecode_dump_stream, map, FRAGMENT_SHADER, frag); agxdecode_stateful(frag.pipeline, "Fragment pipeline", agxdecode_pipeline, verbose); if (frag.cf_bindings) { uint8_t *cf = agxdecode_fetch_gpu_mem(frag.cf_bindings, 128); hexdump(agxdecode_dump_stream, cf, 128, false); DUMP_CL(CF_BINDING_HEADER, cf, "Coefficient binding header:"); cf += AGX_CF_BINDING_HEADER_LENGTH; for (unsigned i = 0; i < frag.cf_binding_count; ++i) { DUMP_CL(CF_BINDING, cf, "Coefficient binding:"); cf += AGX_CF_BINDING_LENGTH; } } DUMP_UNPACKED(FRAGMENT_SHADER, frag, "Fragment shader\n"); map += AGX_FRAGMENT_SHADER_LENGTH; } PPP_PRINT(map, occlusion_query, FRAGMENT_OCCLUSION_QUERY, "Occlusion query"); PPP_PRINT(map, occlusion_query_2, FRAGMENT_OCCLUSION_QUERY_2, "Occlusion query 2"); PPP_PRINT(map, output_unknown, OUTPUT_UNKNOWN, "Output unknown"); PPP_PRINT(map, output_size, OUTPUT_SIZE, "Output size"); PPP_PRINT(map, varying_word_2, VARYING_2, "Varying word 2"); /* PPP print checks we don't read too much, now check we read enough */ assert(map == (base + size) && "invalid size of PPP update"); } static unsigned agxdecode_cmd(const uint8_t *map, bool verbose) { if (map[0] == 0x02 && map[1] == 0x10 && map[2] == 0x00 && map[3] == 0x00) { /* XXX: This is a CDM command not a VDM one */ agx_unpack(agxdecode_dump_stream, map, LAUNCH, cmd); agxdecode_stateful(cmd.pipeline, "Pipeline", agxdecode_pipeline, verbose); DUMP_UNPACKED(LAUNCH, cmd, "Launch\n"); return AGX_LAUNCH_LENGTH; } /* Bits 29-31 contain the block type */ enum agx_vdm_block_type block_type = (map[3] >> 5); switch (block_type) { case AGX_VDM_BLOCK_TYPE_PPP_STATE_UPDATE: { agx_unpack(agxdecode_dump_stream, map, PPP_STATE, cmd); uint64_t address = (((uint64_t) cmd.pointer_hi) << 32) | cmd.pointer_lo; struct agx_bo *mem = agxdecode_find_mapped_gpu_mem_containing(address); if (mem) agxdecode_record(address, cmd.size_words * 4, verbose); else DUMP_UNPACKED(PPP_STATE, cmd, "Non-existant record (XXX)\n"); return AGX_PPP_STATE_LENGTH; } case AGX_VDM_BLOCK_TYPE_VDM_STATE_UPDATE: { size_t length = AGX_VDM_STATE_LENGTH; agx_unpack(agxdecode_dump_stream, map, VDM_STATE, hdr); map += AGX_VDM_STATE_LENGTH; #define VDM_PRINT(header_name, STRUCT_NAME, human) \ if (hdr.header_name##_present) { \ DUMP_CL(VDM_STATE_##STRUCT_NAME, map, human); \ map += AGX_VDM_STATE_##STRUCT_NAME##_LENGTH; \ length += AGX_VDM_STATE_##STRUCT_NAME##_LENGTH; \ } VDM_PRINT(restart_index, RESTART_INDEX, "Restart index"); VDM_PRINT(vertex_shader_word_0, VERTEX_SHADER_WORD_0, "Vertex shader word 0"); if (hdr.vertex_shader_word_1_present) { agx_unpack(agxdecode_dump_stream, map, VDM_STATE_VERTEX_SHADER_WORD_1, word_1); fprintf(agxdecode_dump_stream, "Pipeline %X\n", (uint32_t) word_1.pipeline); agxdecode_stateful(word_1.pipeline, "Pipeline", agxdecode_pipeline, verbose); } VDM_PRINT(vertex_shader_word_1, VERTEX_SHADER_WORD_1, "Vertex shader word 1"); VDM_PRINT(vertex_outputs, VERTEX_OUTPUTS, "Vertex outputs"); VDM_PRINT(vertex_unknown, VERTEX_UNKNOWN, "Vertex unknown"); #undef VDM_PRINT return ALIGN_POT(length, 8); } case AGX_VDM_BLOCK_TYPE_INDEX_LIST: { size_t length = AGX_INDEX_LIST_LENGTH; agx_unpack(agxdecode_dump_stream, map, INDEX_LIST, hdr); DUMP_UNPACKED(INDEX_LIST, hdr, "Index List\n"); map += AGX_INDEX_LIST_LENGTH; #define IDX_PRINT(header_name, STRUCT_NAME, human) \ if (hdr.header_name##_present) { \ DUMP_CL(INDEX_LIST_##STRUCT_NAME, map, human); \ map += AGX_INDEX_LIST_##STRUCT_NAME##_LENGTH; \ length += AGX_INDEX_LIST_##STRUCT_NAME##_LENGTH; \ } IDX_PRINT(index_buffer, BUFFER_LO, "Index buffer"); IDX_PRINT(index_buffer_size, BUFFER_SIZE, "Index buffer size"); IDX_PRINT(index_count, COUNT, "Index count"); IDX_PRINT(instance_count, INSTANCES, "Instance count"); IDX_PRINT(start, START, "Start"); #undef IDX_PRINT return ALIGN_POT(length, 8); } case AGX_VDM_BLOCK_TYPE_STREAM_TERMINATE: { DUMP_CL(STREAM_TERMINATE, map, "Stream Terminate"); return STATE_DONE; } default: fprintf(agxdecode_dump_stream, "Unknown VDM block type: %u\n", block_type); hexdump(agxdecode_dump_stream, map, 8, false); return 8; } } void agxdecode_cmdstream(unsigned cmdbuf_handle, unsigned map_handle, bool verbose) { agxdecode_dump_file_open(); struct agx_bo *cmdbuf = agxdecode_find_handle(cmdbuf_handle, AGX_ALLOC_CMDBUF); struct agx_bo *map = agxdecode_find_handle(map_handle, AGX_ALLOC_MEMMAP); assert(cmdbuf != NULL && "nonexistant command buffer"); assert(map != NULL && "nonexistant mapping"); /* Before decoding anything, validate the map. Set bo->mapped fields */ agxdecode_decode_segment_list(map->ptr.cpu); /* Print the IOGPU stuff */ agx_unpack(agxdecode_dump_stream, cmdbuf->ptr.cpu, IOGPU_HEADER, cmd); DUMP_UNPACKED(IOGPU_HEADER, cmd, "IOGPU Header\n"); agx_unpack(agxdecode_dump_stream, ((uint32_t *) cmdbuf->ptr.cpu) + 160, IOGPU_INTERNAL_PIPELINES, pip); DUMP_CL(IOGPU_INTERNAL_PIPELINES, ((uint32_t *) cmdbuf->ptr.cpu) + 160, "Internal pipelines"); DUMP_CL(IOGPU_AUX_FRAMEBUFFER, ((uint32_t *) cmdbuf->ptr.cpu) + 228, "Aux Framebuffer"); agx_unpack(agxdecode_dump_stream, ((uint32_t *) cmdbuf->ptr.cpu) + 292, IOGPU_CLEAR_Z_S, clearzs); DUMP_UNPACKED(IOGPU_CLEAR_Z_S, clearzs, "Clear Z/S"); /* Guard against changes */ uint32_t zeroes[356 - 344] = { 0 }; assert(memcmp(((uint32_t *) cmdbuf->ptr.cpu) + 344, zeroes, 4 * (356 - 344)) == 0); DUMP_CL(IOGPU_MISC, ((uint32_t *) cmdbuf->ptr.cpu) + 356, "Misc"); /* Should be unused, we think */ for (unsigned i = (0x6B0 / 4); i < (cmd.attachment_offset / 4); ++i) { assert(((uint32_t *) cmdbuf->ptr.cpu)[i] == 0); } DUMP_CL(IOGPU_ATTACHMENT_COUNT, ((uint8_t *) cmdbuf->ptr.cpu + cmd.attachment_offset), "Attachment count"); uint32_t *attachments = (uint32_t *) ((uint8_t *) cmdbuf->ptr.cpu + cmd.attachment_offset); unsigned attachment_count = attachments[3]; for (unsigned i = 0; i < attachment_count; ++i) { uint32_t *ptr = attachments + 4 + (i * AGX_IOGPU_ATTACHMENT_LENGTH / 4); DUMP_CL(IOGPU_ATTACHMENT, ptr, "Attachment"); } uint64_t *encoder = ((uint64_t *) cmdbuf->ptr.cpu) + 7; agxdecode_stateful(*encoder, "Encoder", agxdecode_cmd, verbose); if (pip.clear_pipeline_unk) { fprintf(agxdecode_dump_stream, "Unk: %X\n", pip.clear_pipeline_unk); agxdecode_stateful(pip.clear_pipeline, "Clear pipeline", agxdecode_pipeline, verbose); } if (pip.store_pipeline_unk) { assert(pip.store_pipeline_unk == 0x4); agxdecode_stateful(pip.store_pipeline, "Store pipeline", agxdecode_pipeline, verbose); } assert((clearzs.partial_reload_pipeline_unk & 0xF) == 0x4); if (clearzs.partial_reload_pipeline) { agxdecode_stateful(clearzs.partial_reload_pipeline, "Partial reload pipeline", agxdecode_pipeline, verbose); } if (clearzs.partial_store_pipeline) { agxdecode_stateful(clearzs.partial_store_pipeline, "Partial store pipeline", agxdecode_pipeline, verbose); } agxdecode_map_read_write(); } void agxdecode_dump_mappings(unsigned map_handle) { agxdecode_dump_file_open(); struct agx_bo *map = agxdecode_find_handle(map_handle, AGX_ALLOC_MEMMAP); assert(map != NULL && "nonexistant mapping"); agxdecode_decode_segment_list(map->ptr.cpu); for (unsigned i = 0; i < mmap_count; ++i) { if (!mmap_array[i].ptr.cpu || !mmap_array[i].size || !mmap_array[i].mapped) continue; assert(mmap_array[i].type < AGX_NUM_ALLOC); fprintf(agxdecode_dump_stream, "Buffer: type %s, gpu %" PRIx64 ", handle %u.bin:\n\n", agx_alloc_types[mmap_array[i].type], mmap_array[i].ptr.gpu, mmap_array[i].handle); hexdump(agxdecode_dump_stream, mmap_array[i].ptr.cpu, mmap_array[i].size, false); fprintf(agxdecode_dump_stream, "\n"); } } void agxdecode_track_alloc(struct agx_bo *alloc) { assert((mmap_count + 1) < MAX_MAPPINGS); for (unsigned i = 0; i < mmap_count; ++i) { struct agx_bo *bo = &mmap_array[i]; bool match = (bo->handle == alloc->handle && bo->type == alloc->type); assert(!match && "tried to alloc already allocated BO"); } mmap_array[mmap_count++] = *alloc; } void agxdecode_track_free(struct agx_bo *bo) { bool found = false; for (unsigned i = 0; i < mmap_count; ++i) { if (mmap_array[i].handle == bo->handle && mmap_array[i].type == bo->type) { assert(!found && "mapped multiple times!"); found = true; memset(&mmap_array[i], 0, sizeof(mmap_array[i])); } } assert(found && "freed unmapped memory"); } static int agxdecode_dump_frame_count = 0; void agxdecode_dump_file_open(void) { if (agxdecode_dump_stream) return; /* This does a getenv every frame, so it is possible to use * setenv to change the base at runtime. */ const char *dump_file_base = getenv("AGXDECODE_DUMP_FILE") ?: "agxdecode.dump"; if (!strcmp(dump_file_base, "stderr")) agxdecode_dump_stream = stderr; else { char buffer[1024]; snprintf(buffer, sizeof(buffer), "%s.%04d", dump_file_base, agxdecode_dump_frame_count); printf("agxdecode: dump command stream to file %s\n", buffer); agxdecode_dump_stream = fopen(buffer, "w"); if (!agxdecode_dump_stream) fprintf(stderr, "agxdecode: failed to open command stream log file %s\n", buffer); } } static void agxdecode_dump_file_close(void) { if (agxdecode_dump_stream && agxdecode_dump_stream != stderr) { fclose(agxdecode_dump_stream); agxdecode_dump_stream = NULL; } } void agxdecode_next_frame(void) { agxdecode_dump_file_close(); agxdecode_dump_frame_count++; } void agxdecode_close(void) { agxdecode_dump_file_close(); }