/* * Copyright © 2016 Intel Corporation * * 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 #include #include #include #include #include #include "util/macros.h" #include "common/gen_decoder.h" #include "common/gen_disasm.h" #include "intel_aub.h" /* Below is the only command missing from intel_aub.h in libdrm * So, reuse intel_aub.h from libdrm and #define the * AUB_MI_BATCH_BUFFER_END as below */ #define AUB_MI_BATCH_BUFFER_END (0x0500 << 16) #define CSI "\e[" #define BLUE_HEADER CSI "0;44m" #define GREEN_HEADER CSI "1;42m" #define NORMAL CSI "0m" /* options */ static int option_full_decode = true; static int option_print_offsets = true; static int max_vbo_lines = -1; static enum { COLOR_AUTO, COLOR_ALWAYS, COLOR_NEVER } option_color; /* state */ uint16_t pci_id = 0; char *input_file = NULL, *xml_path = NULL; struct gen_device_info devinfo; struct gen_batch_decode_ctx batch_ctx; uint64_t gtt_size, gtt_end; void *gtt; uint64_t general_state_base; uint64_t surface_state_base; uint64_t dynamic_state_base; uint64_t instruction_base; uint64_t instruction_bound; FILE *outfile; struct brw_instruction; #define GEN_ENGINE_RENDER 1 #define GEN_ENGINE_BLITTER 2 static void handle_trace_block(uint32_t *p) { int operation = p[1] & AUB_TRACE_OPERATION_MASK; int type = p[1] & AUB_TRACE_TYPE_MASK; int address_space = p[1] & AUB_TRACE_ADDRESS_SPACE_MASK; uint64_t offset = p[3]; uint32_t size = p[4]; int header_length = p[0] & 0xffff; uint32_t *data = p + header_length + 2; int engine = GEN_ENGINE_RENDER; if (devinfo.gen >= 8) offset += (uint64_t) p[5] << 32; switch (operation) { case AUB_TRACE_OP_DATA_WRITE: if (address_space != AUB_TRACE_MEMTYPE_GTT) break; if (gtt_size < offset + size) { fprintf(stderr, "overflow gtt space: %s\n", strerror(errno)); exit(EXIT_FAILURE); } memcpy((char *) gtt + offset, data, size); if (gtt_end < offset + size) gtt_end = offset + size; break; case AUB_TRACE_OP_COMMAND_WRITE: switch (type) { case AUB_TRACE_TYPE_RING_PRB0: engine = GEN_ENGINE_RENDER; break; case AUB_TRACE_TYPE_RING_PRB2: engine = GEN_ENGINE_BLITTER; break; default: fprintf(outfile, "command write to unknown ring %d\n", type); break; } (void)engine; /* TODO */ gen_print_batch(&batch_ctx, data, size, 0); gtt_end = 0; break; } } static struct gen_batch_decode_bo get_gen_batch_bo(void *user_data, uint64_t address) { if (address > gtt_end) return (struct gen_batch_decode_bo) { .map = NULL }; /* We really only have one giant address range */ return (struct gen_batch_decode_bo) { .addr = 0, .map = gtt, .size = gtt_size }; } static void aubinator_init(uint16_t aub_pci_id, const char *app_name) { if (!gen_get_device_info(pci_id, &devinfo)) { fprintf(stderr, "can't find device information: pci_id=0x%x\n", pci_id); exit(EXIT_FAILURE); } enum gen_batch_decode_flags batch_flags = 0; if (option_color == COLOR_ALWAYS) batch_flags |= GEN_BATCH_DECODE_IN_COLOR; if (option_full_decode) batch_flags |= GEN_BATCH_DECODE_FULL; if (option_print_offsets) batch_flags |= GEN_BATCH_DECODE_OFFSETS; batch_flags |= GEN_BATCH_DECODE_FLOATS; gen_batch_decode_ctx_init(&batch_ctx, &devinfo, outfile, batch_flags, xml_path, get_gen_batch_bo, NULL, NULL); batch_ctx.max_vbo_decoded_lines = max_vbo_lines; char *color = GREEN_HEADER, *reset_color = NORMAL; if (option_color == COLOR_NEVER) color = reset_color = ""; fprintf(outfile, "%sAubinator: Intel AUB file decoder.%-80s%s\n", color, "", reset_color); if (input_file) fprintf(outfile, "File name: %s\n", input_file); if (aub_pci_id) fprintf(outfile, "PCI ID: 0x%x\n", aub_pci_id); fprintf(outfile, "Application name: %s\n", app_name); fprintf(outfile, "Decoding as: %s\n", gen_get_device_name(pci_id)); /* Throw in a new line before the first batch */ fprintf(outfile, "\n"); } static void handle_trace_header(uint32_t *p) { /* The intel_aubdump tool from IGT is kind enough to put a PCI-ID= tag in * the AUB header comment. If the user hasn't specified a hardware * generation, try to use the one from the AUB file. */ uint32_t *end = p + (p[0] & 0xffff) + 2; int aub_pci_id = 0; if (end > &p[12] && p[12] > 0) sscanf((char *)&p[13], "PCI-ID=%i", &aub_pci_id); if (pci_id == 0) pci_id = aub_pci_id; char app_name[33]; strncpy(app_name, (char *)&p[2], 32); app_name[32] = 0; aubinator_init(aub_pci_id, app_name); } static void handle_memtrace_version(uint32_t *p) { int header_length = p[0] & 0xffff; char app_name[64]; int app_name_len = MIN2(4 * (header_length + 1 - 5), ARRAY_SIZE(app_name) - 1); int pci_id_len = 0; int aub_pci_id = 0; strncpy(app_name, (char *)&p[5], app_name_len); app_name[app_name_len] = 0; sscanf(app_name, "PCI-ID=%i %n", &aub_pci_id, &pci_id_len); if (pci_id == 0) pci_id = aub_pci_id; aubinator_init(aub_pci_id, app_name + pci_id_len); } static void handle_memtrace_reg_write(uint32_t *p) { uint32_t offset = p[1]; uint32_t value = p[5]; int engine; static int render_elsp_writes = 0; static int blitter_elsp_writes = 0; static int render_elsq0 = 0; static int blitter_elsq0 = 0; uint8_t *pphwsp; if (offset == 0x2230) { render_elsp_writes++; engine = GEN_ENGINE_RENDER; } else if (offset == 0x22230) { blitter_elsp_writes++; engine = GEN_ENGINE_BLITTER; } else if (offset == 0x2510) { render_elsq0 = value; } else if (offset == 0x22510) { blitter_elsq0 = value; } else if (offset == 0x2550 || offset == 0x22550) { /* nothing */; } else { return; } if (render_elsp_writes > 3 || blitter_elsp_writes > 3) { render_elsp_writes = blitter_elsp_writes = 0; pphwsp = (uint8_t*)gtt + (value & 0xfffff000); } else if (offset == 0x2550) { engine = GEN_ENGINE_RENDER; pphwsp = (uint8_t*)gtt + (render_elsq0 & 0xfffff000); } else if (offset == 0x22550) { engine = GEN_ENGINE_BLITTER; pphwsp = (uint8_t*)gtt + (blitter_elsq0 & 0xfffff000); } else { return; } const uint32_t pphwsp_size = 4096; uint32_t *context = (uint32_t*)(pphwsp + pphwsp_size); uint32_t ring_buffer_head = context[5]; uint32_t ring_buffer_tail = context[7]; uint32_t ring_buffer_start = context[9]; uint32_t *commands = (uint32_t*)((uint8_t*)gtt + ring_buffer_start + ring_buffer_head); (void)engine; /* TODO */ gen_print_batch(&batch_ctx, commands, ring_buffer_tail - ring_buffer_head, 0); } static void handle_memtrace_mem_write(uint32_t *p) { uint64_t address = *(uint64_t*)&p[1]; uint32_t address_space = p[3] >> 28; uint32_t size = p[4]; uint32_t *data = p + 5; if (address_space != 1) return; if (gtt_size < address + size) { fprintf(stderr, "overflow gtt space: %s\n", strerror(errno)); exit(EXIT_FAILURE); } memcpy((char *) gtt + address, data, size); if (gtt_end < address + size) gtt_end = address + size; } struct aub_file { FILE *stream; uint32_t *map, *end, *cursor; uint32_t *mem_end; }; static struct aub_file * aub_file_open(const char *filename) { struct aub_file *file; struct stat sb; int fd; file = calloc(1, sizeof *file); fd = open(filename, O_RDONLY); if (fd == -1) { fprintf(stderr, "open %s failed: %s\n", filename, strerror(errno)); exit(EXIT_FAILURE); } if (fstat(fd, &sb) == -1) { fprintf(stderr, "stat failed: %s\n", strerror(errno)); exit(EXIT_FAILURE); } file->map = mmap(NULL, sb.st_size, PROT_READ, MAP_SHARED, fd, 0); if (file->map == MAP_FAILED) { fprintf(stderr, "mmap failed: %s\n", strerror(errno)); exit(EXIT_FAILURE); } close(fd); file->cursor = file->map; file->end = file->map + sb.st_size / 4; return file; } static struct aub_file * aub_file_stdin(void) { struct aub_file *file; file = calloc(1, sizeof *file); file->stream = stdin; return file; } #define TYPE(dw) (((dw) >> 29) & 7) #define OPCODE(dw) (((dw) >> 23) & 0x3f) #define SUBOPCODE(dw) (((dw) >> 16) & 0x7f) #define MAKE_HEADER(type, opcode, subopcode) \ (((type) << 29) | ((opcode) << 23) | ((subopcode) << 16)) #define TYPE_AUB 0x7 /* Classic AUB opcodes */ #define OPCODE_AUB 0x01 #define SUBOPCODE_HEADER 0x05 #define SUBOPCODE_BLOCK 0x41 #define SUBOPCODE_BMP 0x1e /* Newer version AUB opcode */ #define OPCODE_NEW_AUB 0x2e #define SUBOPCODE_REG_POLL 0x02 #define SUBOPCODE_REG_WRITE 0x03 #define SUBOPCODE_MEM_POLL 0x05 #define SUBOPCODE_MEM_WRITE 0x06 #define SUBOPCODE_VERSION 0x0e #define MAKE_GEN(major, minor) ( ((major) << 8) | (minor) ) enum { AUB_ITEM_DECODE_OK, AUB_ITEM_DECODE_FAILED, AUB_ITEM_DECODE_NEED_MORE_DATA, }; static int aub_file_decode_batch(struct aub_file *file) { uint32_t *p, h, *new_cursor; int header_length, bias; if (file->end - file->cursor < 1) return AUB_ITEM_DECODE_NEED_MORE_DATA; p = file->cursor; h = *p; header_length = h & 0xffff; switch (OPCODE(h)) { case OPCODE_AUB: bias = 2; break; case OPCODE_NEW_AUB: bias = 1; break; default: fprintf(outfile, "unknown opcode %d at %td/%td\n", OPCODE(h), file->cursor - file->map, file->end - file->map); return AUB_ITEM_DECODE_FAILED; } new_cursor = p + header_length + bias; if ((h & 0xffff0000) == MAKE_HEADER(TYPE_AUB, OPCODE_AUB, SUBOPCODE_BLOCK)) { if (file->end - file->cursor < 4) return AUB_ITEM_DECODE_NEED_MORE_DATA; new_cursor += p[4] / 4; } if (new_cursor > file->end) return AUB_ITEM_DECODE_NEED_MORE_DATA; switch (h & 0xffff0000) { case MAKE_HEADER(TYPE_AUB, OPCODE_AUB, SUBOPCODE_HEADER): handle_trace_header(p); break; case MAKE_HEADER(TYPE_AUB, OPCODE_AUB, SUBOPCODE_BLOCK): handle_trace_block(p); break; case MAKE_HEADER(TYPE_AUB, OPCODE_AUB, SUBOPCODE_BMP): break; case MAKE_HEADER(TYPE_AUB, OPCODE_NEW_AUB, SUBOPCODE_VERSION): handle_memtrace_version(p); break; case MAKE_HEADER(TYPE_AUB, OPCODE_NEW_AUB, SUBOPCODE_REG_WRITE): handle_memtrace_reg_write(p); break; case MAKE_HEADER(TYPE_AUB, OPCODE_NEW_AUB, SUBOPCODE_MEM_WRITE): handle_memtrace_mem_write(p); break; case MAKE_HEADER(TYPE_AUB, OPCODE_NEW_AUB, SUBOPCODE_MEM_POLL): fprintf(outfile, "memory poll block (dwords %d):\n", h & 0xffff); break; case MAKE_HEADER(TYPE_AUB, OPCODE_NEW_AUB, SUBOPCODE_REG_POLL): break; default: fprintf(outfile, "unknown block type=0x%x, opcode=0x%x, " "subopcode=0x%x (%08x)\n", TYPE(h), OPCODE(h), SUBOPCODE(h), h); break; } file->cursor = new_cursor; return AUB_ITEM_DECODE_OK; } static int aub_file_more_stuff(struct aub_file *file) { return file->cursor < file->end || (file->stream && !feof(file->stream)); } #define AUB_READ_BUFFER_SIZE (4096) #define MAX(a, b) ((a) < (b) ? (b) : (a)) static void aub_file_data_grow(struct aub_file *file) { size_t old_size = (file->mem_end - file->map) * 4; size_t new_size = MAX(old_size * 2, AUB_READ_BUFFER_SIZE); uint32_t *new_start = realloc(file->map, new_size); file->cursor = new_start + (file->cursor - file->map); file->end = new_start + (file->end - file->map); file->map = new_start; file->mem_end = file->map + (new_size / 4); } static bool aub_file_data_load(struct aub_file *file) { size_t r; if (file->stream == NULL) return false; /* First remove any consumed data */ if (file->cursor > file->map) { memmove(file->map, file->cursor, (file->end - file->cursor) * 4); file->end -= file->cursor - file->map; file->cursor = file->map; } /* Then load some new data in */ if ((file->mem_end - file->end) < (AUB_READ_BUFFER_SIZE / 4)) aub_file_data_grow(file); r = fread(file->end, 1, (file->mem_end - file->end) * 4, file->stream); file->end += r / 4; return r != 0; } static void setup_pager(void) { int fds[2]; pid_t pid; if (!isatty(1)) return; if (pipe(fds) == -1) return; pid = fork(); if (pid == -1) return; if (pid == 0) { close(fds[1]); dup2(fds[0], 0); execlp("less", "less", "-FRSi", NULL); } close(fds[0]); dup2(fds[1], 1); close(fds[1]); } static void print_help(const char *progname, FILE *file) { fprintf(file, "Usage: %s [OPTION]... [FILE]\n" "Decode aub file contents from either FILE or the standard input.\n\n" "A valid --gen option must be provided.\n\n" " --help display this help and exit\n" " --gen=platform decode for given platform (3 letter platform name)\n" " --headers decode only command headers\n" " --color[=WHEN] colorize the output; WHEN can be 'auto' (default\n" " if omitted), 'always', or 'never'\n" " --max-vbo-lines=N limit the number of decoded VBO lines\n" " --no-pager don't launch pager\n" " --no-offsets don't print instruction offsets\n" " --xml=DIR load hardware xml description from directory DIR\n", progname); } int main(int argc, char *argv[]) { struct aub_file *file; int c, i; bool help = false, pager = true; const struct option aubinator_opts[] = { { "help", no_argument, (int *) &help, true }, { "no-pager", no_argument, (int *) &pager, false }, { "no-offsets", no_argument, (int *) &option_print_offsets, false }, { "gen", required_argument, NULL, 'g' }, { "headers", no_argument, (int *) &option_full_decode, false }, { "color", required_argument, NULL, 'c' }, { "xml", required_argument, NULL, 'x' }, { "max-vbo-lines", required_argument, NULL, 'v' }, { NULL, 0, NULL, 0 } }; outfile = stdout; i = 0; while ((c = getopt_long(argc, argv, "", aubinator_opts, &i)) != -1) { switch (c) { case 'g': { const int id = gen_device_name_to_pci_device_id(optarg); if (id < 0) { fprintf(stderr, "can't parse gen: '%s', expected ivb, byt, hsw, " "bdw, chv, skl, kbl or bxt\n", optarg); exit(EXIT_FAILURE); } else { pci_id = id; } break; } case 'c': if (optarg == NULL || strcmp(optarg, "always") == 0) option_color = COLOR_ALWAYS; else if (strcmp(optarg, "never") == 0) option_color = COLOR_NEVER; else if (strcmp(optarg, "auto") == 0) option_color = COLOR_AUTO; else { fprintf(stderr, "invalid value for --color: %s", optarg); exit(EXIT_FAILURE); } break; case 'x': xml_path = strdup(optarg); break; case 'v': max_vbo_lines = atoi(optarg); break; default: break; } } if (help || argc == 1) { print_help(argv[0], stderr); exit(0); } if (optind < argc) input_file = argv[optind]; /* Do this before we redirect stdout to pager. */ if (option_color == COLOR_AUTO) option_color = isatty(1) ? COLOR_ALWAYS : COLOR_NEVER; if (isatty(1) && pager) setup_pager(); if (input_file == NULL) file = aub_file_stdin(); else file = aub_file_open(input_file); /* mmap a terabyte for our gtt space. */ gtt_size = 1ull << 40; gtt = mmap(NULL, gtt_size, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS | MAP_NORESERVE, -1, 0); if (gtt == MAP_FAILED) { fprintf(stderr, "failed to alloc gtt space: %s\n", strerror(errno)); exit(EXIT_FAILURE); } while (aub_file_more_stuff(file)) { switch (aub_file_decode_batch(file)) { case AUB_ITEM_DECODE_OK: break; case AUB_ITEM_DECODE_NEED_MORE_DATA: if (!file->stream) { file->cursor = file->end; break; } if (aub_file_more_stuff(file) && !aub_file_data_load(file)) { fprintf(stderr, "failed to load data from stdin\n"); exit(EXIT_FAILURE); } break; default: fprintf(stderr, "failed to parse aubdump data\n"); exit(EXIT_FAILURE); } } fflush(stdout); /* close the stdout which is opened to write the output */ close(1); free(xml_path); wait(NULL); return EXIT_SUCCESS; }