/* * 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 "decoder.h" #define XML_BUFFER_SIZE 4096 #define MAKE_GEN(major, minor) ( ((major) << 8) | (minor) ) struct gen_spec { uint32_t gen; int ncommands; struct gen_group *commands[256]; int nstructs; struct gen_group *structs[256]; int nregisters; struct gen_group *registers[256]; }; struct location { const char *filename; int line_number; }; struct parser_context { XML_Parser parser; int foo; struct location loc; const char *platform; struct gen_group *group; int nfields; struct gen_field *fields[128]; struct gen_spec *spec; }; const char * gen_group_get_name(struct gen_group *group) { return group->name; } uint32_t gen_group_get_opcode(struct gen_group *group) { return group->opcode; } struct gen_group * gen_spec_find_struct(struct gen_spec *spec, const char *name) { for (int i = 0; i < spec->nstructs; i++) if (strcmp(spec->structs[i]->name, name) == 0) return spec->structs[i]; return NULL; } uint32_t gen_spec_get_gen(struct gen_spec *spec) { return spec->gen; } static void __attribute__((noreturn)) fail(struct location *loc, const char *msg, ...) { va_list ap; va_start(ap, msg); fprintf(stderr, "%s:%d: error: ", loc->filename, loc->line_number); vfprintf(stderr, msg, ap); fprintf(stderr, "\n"); va_end(ap); exit(EXIT_FAILURE); } static void * fail_on_null(void *p) { if (p == NULL) { fprintf(stderr, "aubinator: out of memory\n"); exit(EXIT_FAILURE); } return p; } static char * xstrdup(const char *s) { return fail_on_null(strdup(s)); } static void * zalloc(size_t s) { return calloc(s, 1); } static void * xzalloc(size_t s) { return fail_on_null(zalloc(s)); } static struct gen_group * create_group(struct parser_context *ctx, const char *name, const char **atts) { struct gen_group *group; group = xzalloc(sizeof(*group)); if (name) group->name = xstrdup(name); group->group_offset = 0; group->group_count = 0; return group; } static void get_group_offset_count(struct parser_context *ctx, const char *name, const char **atts, uint32_t *offset, uint32_t *count) { char *p; int i; for (i = 0; atts[i]; i += 2) { if (strcmp(atts[i], "count") == 0) *count = strtoul(atts[i + 1], &p, 0); else if (strcmp(atts[i], "start") == 0) *offset = strtoul(atts[i + 1], &p, 0); } return; } static inline uint64_t mask(int start, int end) { uint64_t v; v = ~0ULL >> (63 - end + start); return v << start; } static inline uint64_t field(uint64_t value, int start, int end) { /* The field values are obtained from the DWord, * Hence, get the relative start and end positions * by doing a %32 on the start and end positions */ return (value & mask(start % 32, end % 32)) >> (start % 32); } static inline uint64_t field_address(uint64_t value, int start, int end) { /* no need to right shift for address/offset */ return (value & mask(start % 32, end % 32)); } static struct gen_type string_to_type(struct parser_context *ctx, const char *s) { int i, f; struct gen_group *g; if (strcmp(s, "int") == 0) return (struct gen_type) { .kind = GEN_TYPE_INT }; else if (strcmp(s, "uint") == 0) return (struct gen_type) { .kind = GEN_TYPE_UINT }; else if (strcmp(s, "bool") == 0) return (struct gen_type) { .kind = GEN_TYPE_BOOL }; else if (strcmp(s, "float") == 0) return (struct gen_type) { .kind = GEN_TYPE_FLOAT }; else if (strcmp(s, "address") == 0) return (struct gen_type) { .kind = GEN_TYPE_ADDRESS }; else if (strcmp(s, "offset") == 0) return (struct gen_type) { .kind = GEN_TYPE_OFFSET }; else if (sscanf(s, "u%d.%d", &i, &f) == 2) return (struct gen_type) { .kind = GEN_TYPE_UFIXED, .i = i, .f = f }; else if (sscanf(s, "s%d.%d", &i, &f) == 2) return (struct gen_type) { .kind = GEN_TYPE_SFIXED, .i = i, .f = f }; else if (g = gen_spec_find_struct(ctx->spec, s), g != NULL) return (struct gen_type) { .kind = GEN_TYPE_STRUCT, .gen_struct = g }; else if (strcmp(s, "mbo") == 0) return (struct gen_type) { .kind = GEN_TYPE_MBO }; else fail(&ctx->loc, "invalid type: %s", s); } static struct gen_field * create_field(struct parser_context *ctx, const char **atts) { struct gen_field *field; char *p; int i; field = xzalloc(sizeof(*field)); for (i = 0; atts[i]; i += 2) { if (strcmp(atts[i], "name") == 0) field->name = xstrdup(atts[i + 1]); else if (strcmp(atts[i], "start") == 0) field->start = ctx->group->group_offset+strtoul(atts[i + 1], &p, 0); else if (strcmp(atts[i], "end") == 0) { field->end = ctx->group->group_offset+strtoul(atts[i + 1], &p, 0); if (ctx->group->group_offset) ctx->group->group_offset = field->end+1; } else if (strcmp(atts[i], "type") == 0) field->type = string_to_type(ctx, atts[i + 1]); else if (strcmp(atts[i], "default") == 0 && field->start >= 16 && field->end <= 31) { field->has_default = true; field->default_value = strtoul(atts[i + 1], &p, 0); } } return field; } static void start_element(void *data, const char *element_name, const char **atts) { struct parser_context *ctx = data; int i; const char *name = NULL; const char *gen = NULL; ctx->loc.line_number = XML_GetCurrentLineNumber(ctx->parser); for (i = 0; atts[i]; i += 2) { if (strcmp(atts[i], "name") == 0) name = atts[i + 1]; else if (strcmp(atts[i], "gen") == 0) gen = atts[i + 1]; } if (strcmp(element_name, "genxml") == 0) { if (name == NULL) fail(&ctx->loc, "no platform name given"); if (gen == NULL) fail(&ctx->loc, "no gen given"); ctx->platform = xstrdup(name); int major, minor; int n = sscanf(gen, "%d.%d", &major, &minor); if (n == 0) fail(&ctx->loc, "invalid gen given: %s", gen); if (n == 1) minor = 0; ctx->spec->gen = MAKE_GEN(major, minor); } else if (strcmp(element_name, "instruction") == 0 || strcmp(element_name, "struct") == 0 || strcmp(element_name, "register") == 0) { ctx->group = create_group(ctx, name, atts); } else if (strcmp(element_name, "group") == 0) { get_group_offset_count(ctx, name, atts, &ctx->group->group_offset, &ctx->group->group_count); } else if (strcmp(element_name, "field") == 0) { do { ctx->fields[ctx->nfields++] = create_field(ctx, atts); if (ctx->group->group_count) ctx->group->group_count--; } while (ctx->group->group_count > 0); } else if (strcmp(element_name, "enum") == 0) { } else if (strcmp(element_name, "value") == 0) { } } static void end_element(void *data, const char *name) { struct parser_context *ctx = data; if (strcmp(name, "instruction") == 0 || strcmp(name, "struct") == 0 || strcmp(name, "register") == 0) { size_t size = ctx->nfields * sizeof(ctx->fields[0]); struct gen_group *group = ctx->group; group->fields = xzalloc(size); group->nfields = ctx->nfields; memcpy(group->fields, ctx->fields, size); ctx->nfields = 0; ctx->group = NULL; for (int i = 0; i < group->nfields; i++) { if (group->fields[i]->start >= 16 && group->fields[i]->end <= 31 && group->fields[i]->has_default) { group->opcode_mask |= mask(group->fields[i]->start % 32, group->fields[i]->end % 32); group->opcode |= group->fields[i]->default_value << group->fields[i]->start; } } struct gen_spec *spec = ctx->spec; if (strcmp(name, "instruction") == 0) spec->commands[spec->ncommands++] = group; else if (strcmp(name, "struct") == 0) spec->structs[spec->nstructs++] = group; else if (strcmp(name, "register") == 0) spec->registers[spec->nregisters++] = group; } else if (strcmp(name, "group") == 0) { ctx->group->group_offset = 0; ctx->group->group_count = 0; } } static void character_data(void *data, const XML_Char *s, int len) { } struct gen_spec * gen_spec_load(const char *filename) { struct parser_context ctx; void *buf; int len; FILE *input; input = fopen(filename, "r"); printf("xml filename = %s\n", filename); if (input == NULL) { fprintf(stderr, "failed to open xml description\n"); exit(EXIT_FAILURE); } memset(&ctx, 0, sizeof ctx); ctx.parser = XML_ParserCreate(NULL); XML_SetUserData(ctx.parser, &ctx); if (ctx.parser == NULL) { fprintf(stderr, "failed to create parser\n"); fclose(input); return NULL; } XML_SetElementHandler(ctx.parser, start_element, end_element); XML_SetCharacterDataHandler(ctx.parser, character_data); ctx.loc.filename = filename; ctx.spec = xzalloc(sizeof(*ctx.spec)); do { buf = XML_GetBuffer(ctx.parser, XML_BUFFER_SIZE); len = fread(buf, 1, XML_BUFFER_SIZE, input); if (len < 0) { fprintf(stderr, "fread: %m\n"); fclose(input); return NULL; } if (XML_ParseBuffer(ctx.parser, len, len == 0) == 0) { fprintf(stderr, "Error parsing XML at line %ld col %ld: %s\n", XML_GetCurrentLineNumber(ctx.parser), XML_GetCurrentColumnNumber(ctx.parser), XML_ErrorString(XML_GetErrorCode(ctx.parser))); fclose(input); return NULL; } } while (len > 0); XML_ParserFree(ctx.parser); fclose(input); return ctx.spec; } struct gen_group * gen_spec_find_instruction(struct gen_spec *spec, const uint32_t *p) { for (int i = 0; i < spec->ncommands; i++) { uint32_t opcode = *p & spec->commands[i]->opcode_mask; if (opcode == spec->commands[i]->opcode) return spec->commands[i]; } return NULL; } int gen_group_get_length(struct gen_group *group, const uint32_t *p) { uint32_t h = p[0]; uint32_t type = field(h, 29, 31); switch (type) { case 0: /* MI */ { uint32_t opcode = field(h, 23, 28); if (opcode < 16) return 1; else return field(h, 0, 7) + 2; break; } case 3: /* Render */ { uint32_t subtype = field(h, 27, 28); switch (subtype) { case 0: return field(h, 0, 7) + 2; case 1: return 1; case 2: return 2; case 3: return field(h, 0, 7) + 2; } } } unreachable("bad opcode"); } void gen_field_iterator_init(struct gen_field_iterator *iter, struct gen_group *group, const uint32_t *p) { iter->group = group; iter->p = p; iter->i = 0; } bool gen_field_iterator_next(struct gen_field_iterator *iter) { struct gen_field *f; union { uint32_t dw; float f; } v; if (iter->i == iter->group->nfields) return false; f = iter->group->fields[iter->i++]; iter->name = f->name; v.dw = iter->p[f->start / 32]; switch (f->type.kind) { case GEN_TYPE_UNKNOWN: case GEN_TYPE_INT: snprintf(iter->value, sizeof(iter->value), "%ld", field(v.dw, f->start, f->end)); break; case GEN_TYPE_UINT: snprintf(iter->value, sizeof(iter->value), "%lu", field(v.dw, f->start, f->end)); break; case GEN_TYPE_BOOL: snprintf(iter->value, sizeof(iter->value), "%s", field(v.dw, f->start, f->end) ? "true" : "false"); break; case GEN_TYPE_FLOAT: snprintf(iter->value, sizeof(iter->value), "%f", v.f); break; case GEN_TYPE_ADDRESS: case GEN_TYPE_OFFSET: snprintf(iter->value, sizeof(iter->value), "0x%08lx", field_address(v.dw, f->start, f->end)); break; case GEN_TYPE_STRUCT: snprintf(iter->value, sizeof(iter->value), "", f->type.gen_struct->name, (f->start / 32)); break; case GEN_TYPE_UFIXED: snprintf(iter->value, sizeof(iter->value), "%f", (float) field(v.dw, f->start, f->end) / (1 << f->type.f)); break; case GEN_TYPE_SFIXED: /* FIXME: Sign extend extracted field. */ snprintf(iter->value, sizeof(iter->value), "%s", "foo"); break; case GEN_TYPE_MBO: break; } return true; }