/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2011 Amaury Pouly * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #define _POSIX_C_SOURCE 200809L /* for strdup */ #include #include #include #include #include "dbparser.h" #include "misc.h" enum lexem_type_t { LEX_IDENTIFIER, LEX_LPAREN, LEX_RPAREN, LEX_NUMBER, LEX_STRING, /* double-quoted string */ LEX_EQUAL, LEX_SEMICOLON, LEX_LBRACE, LEX_RBRACE, LEX_RANGLE, LEX_OR, LEX_LSHIFT, LEX_COLON, LEX_LE, LEX_EOF }; struct lexem_t { enum lexem_type_t type; /* if str is not NULL, it must be a malloc'd pointer */ char *str; uint32_t num; int line; const char *file; }; struct context_t { const char *file; char *begin; char *end; char *ptr; int line; }; #define parse_error(ctx, ...) \ do { fprintf(stderr, "%s:%d: ", ctx->file, ctx->line); \ fprintf(stderr, __VA_ARGS__); exit(2); } while(0) static void advance(struct context_t *ctx, int nr_chars) { while(nr_chars--) { if(*(ctx->ptr++) == '\n') ctx->line++; } } static inline bool eof(struct context_t *ctx) { return ctx->ptr == ctx->end; } static inline bool next_valid(struct context_t *ctx, int nr) { return ctx->ptr + nr < ctx->end; } static inline char cur_char(struct context_t *ctx) { return *ctx->ptr; } static inline char next_char(struct context_t *ctx, int nr) { return ctx->ptr[nr]; } static inline void locate_lexem(struct lexem_t *lex, struct context_t *ctx) { lex->file = ctx->file; lex->line = ctx->line; } static void __parse_string(struct context_t *ctx, void *user, void (*emit_fn)(void *user, char c)) { while(!eof(ctx)) { if(cur_char(ctx) == '"') break; else if(cur_char(ctx) == '\\') { advance(ctx, 1); if(eof(ctx)) parse_error(ctx, "Unfinished string\n"); if(cur_char(ctx) == '\\') emit_fn(user, '\\'); else if(cur_char(ctx) == '\'') emit_fn(user, '\''); else if(cur_char(ctx) == '\"') emit_fn(user, '\"'); else parse_error(ctx, "Unknown escape sequence \\%c\n", cur_char(ctx)); advance(ctx, 1); } else { emit_fn(user, cur_char(ctx)); advance(ctx, 1); } } if(eof(ctx) || cur_char(ctx) != '"') parse_error(ctx, "Unfinished string\n"); advance(ctx, 1); } static void __parse_string_emit(void *user, char c) { char **pstr = (char **)user; *(*pstr)++ = c; } static void __parse_string_count(void *user, char c) { (void) c; (*(int *)user)++; } static void parse_string(struct context_t *ctx, struct lexem_t *lexem) { locate_lexem(lexem, ctx); /* skip " */ advance(ctx, 1); /* compute length */ struct context_t cpy_ctx = *ctx; int length = 0; __parse_string(&cpy_ctx, (void *)&length, __parse_string_count); /* parse again */ lexem->type = LEX_STRING; lexem->str = xmalloc(length + 1); lexem->str[length] = 0; char *pstr = lexem->str; __parse_string(ctx, (void *)&pstr, __parse_string_emit); } static void parse_ascii_number(struct context_t *ctx, struct lexem_t *lexem) { locate_lexem(lexem, ctx); /* skip ' */ advance(ctx, 1); /* we expect n<=4 character and then ' */ int len = 0; uint32_t value = 0; while(!eof(ctx)) { if(cur_char(ctx) != '\'') { value = value << 8 | cur_char(ctx); len++; advance(ctx, 1); } else break; } if(eof(ctx) || cur_char(ctx) != '\'') parse_error(ctx, "Unterminated ascii number literal\n"); if(len == 0 || len > 4) parse_error(ctx, "Invalid ascii number literal length: only 1 to 4 characters allowed\n"); /* skip ' */ advance(ctx, 1); lexem->type = LEX_NUMBER; lexem->num = value; } static void parse_number(struct context_t *ctx, struct lexem_t *lexem) { locate_lexem(lexem, ctx); /* check base */ int base = 10; if(cur_char(ctx) == '0' && next_valid(ctx, 1) && next_char(ctx, 1) == 'x') { advance(ctx, 2); base = 16; } lexem->type = LEX_NUMBER; lexem->num = 0; while(!eof(ctx) && isxdigit(cur_char(ctx))) { if(base == 10 && !isdigit(cur_char(ctx))) break; byte v; if(convxdigit(cur_char(ctx), &v)) break; lexem->num = base * lexem->num + v; advance(ctx, 1); } } static void parse_identifier(struct context_t *ctx, struct lexem_t *lexem) { locate_lexem(lexem, ctx); /* remember position */ char *old = ctx->ptr; while(!eof(ctx) && (isalnum(cur_char(ctx)) || cur_char(ctx) == '_')) advance(ctx, 1); lexem->type = LEX_IDENTIFIER; int len = ctx->ptr - old; lexem->str = xmalloc(len + 1); lexem->str[len] = 0; memcpy(lexem->str, old, len); } static void next_lexem(struct context_t *ctx, struct lexem_t *lexem) { #define ret_simple(t, adv) \ do {locate_lexem(lexem, ctx); \ lexem->type = t; \ advance(ctx, adv); \ return;} while(0) while(!eof(ctx)) { char c = cur_char(ctx); /* skip whitespace */ if(c == ' ' || c == '\t' || c == '\n' || c == '\r') { advance(ctx, 1); continue; } /* skip C++ style comments */ if(c == '/' && next_valid(ctx, 1) && next_char(ctx, 1) == '/') { while(!eof(ctx) && cur_char(ctx) != '\n') advance(ctx, 1); continue; } /* skip C-style comments */ if(c == '/' && next_valid(ctx, 1) && next_char(ctx, 1) == '*') { advance(ctx, 2); while(true) { if(!next_valid(ctx, 1)) parse_error(ctx, "Unterminated comment"); if(cur_char(ctx) == '*' && next_char(ctx, 1) == '/') { advance(ctx, 2); break; } advance(ctx, 1); } continue; } break; } if(eof(ctx)) ret_simple(LEX_EOF, 0); char c = cur_char(ctx); bool nv = next_valid(ctx, 1); char nc = nv ? next_char(ctx, 1) : 0; if(c == '(') ret_simple(LEX_LPAREN, 1); if(c == ')') ret_simple(LEX_RPAREN, 1); if(c == '{') ret_simple(LEX_LBRACE, 1); if(c == '}') ret_simple(LEX_RBRACE, 1); if(c == '>') ret_simple(LEX_RANGLE, 1); if(c == '=') ret_simple(LEX_EQUAL, 1); if(c == ';') ret_simple(LEX_SEMICOLON, 1); if(c == ',') ret_simple(LEX_COLON, 1); if(c == '|') ret_simple(LEX_OR, 1); if(c == '<' && nv && nc == '<') ret_simple(LEX_LSHIFT, 2); if(c == '<' && nv && nc == '=') ret_simple(LEX_LE, 2); if(c == '"') return parse_string(ctx, lexem); if(c == '\'') return parse_ascii_number(ctx, lexem); if(isdigit(c)) return parse_number(ctx, lexem); if(isalpha(c) || c == '_') return parse_identifier(ctx, lexem); parse_error(ctx, "Unexpected character '%c'\n", c); #undef ret_simple } #if 0 static void log_lexem(struct lexem_t *lexem) { switch(lexem->type) { case LEX_EOF: printf(""); break; case LEX_EQUAL: printf("="); break; case LEX_IDENTIFIER: printf("id(%s)", lexem->str); break; case LEX_LPAREN: printf("("); break; case LEX_RPAREN: printf(")"); break; case LEX_LBRACE: printf("{"); break; case LEX_RBRACE: printf("}"); break; case LEX_SEMICOLON: printf(";"); break; case LEX_NUMBER: printf("num(%d)", lexem->num); break; case LEX_STRING: printf("str(%s)", lexem->str); break; case LEX_OR: printf("|"); break; case LEX_LSHIFT: printf("<<"); break; default: printf(""); } } #endif struct cmd_option_t *db_add_opt(struct cmd_option_t **opt, const char *identifier, bool is_str) { while(*opt) opt = &(*opt)->next; *opt = xmalloc(sizeof(struct cmd_option_t)); memset(*opt, 0, sizeof(struct cmd_option_t)); (*opt)->name = strdup(identifier); (*opt)->is_string = is_str; return *opt; } void db_add_str_opt(struct cmd_option_t **opt, const char *name, const char *value) { db_add_opt(opt, name, true)->str = strdup(value); } void db_add_int_opt(struct cmd_option_t **opt, const char *name, uint32_t value) { db_add_opt(opt, name, false)->val = value; } static struct cmd_source_t *db_add_src(struct cmd_source_t **src, const char *identifier, bool is_extern) { while(*src) src = &(*src)->next; *src = xmalloc(sizeof(struct cmd_source_t)); memset(*src, 0, sizeof(struct cmd_source_t)); (*src)->identifier = strdup(identifier); (*src)->is_extern = is_extern; return *src; } void db_add_source(struct cmd_file_t *cmd_file, const char *identifier, const char *filename) { db_add_src(&cmd_file->source_list, identifier, false)->filename = strdup(filename); } void db_add_extern_source(struct cmd_file_t *cmd_file, const char *identifier, int extern_nr) { db_add_src(&cmd_file->source_list, identifier, true)->extern_nr = extern_nr; } static struct cmd_inst_t *db_add_inst(struct cmd_inst_t **list, enum cmd_inst_type_t type, uint32_t argument) { while(*list) list = &(*list)->next; *list = xmalloc(sizeof(struct cmd_inst_t)); memset(*list, 0, sizeof(struct cmd_inst_t)); (*list)->type = type; (*list)->argument = argument; return *list; } void db_add_inst_id(struct cmd_section_t *cmd_section, enum cmd_inst_type_t type, const char *identifier, uint32_t argument) { db_add_inst(&cmd_section->inst_list, type, argument)->identifier = strdup(identifier); } void db_add_inst_addr(struct cmd_section_t *cmd_section, enum cmd_inst_type_t type, uint32_t addr, uint32_t argument) { db_add_inst(&cmd_section->inst_list, type, argument)->addr = addr; } struct cmd_section_t *db_add_section(struct cmd_file_t *cmd_file, uint32_t identifier, bool data) { struct cmd_section_t **prev = &cmd_file->section_list; while(*prev) prev = &(*prev)->next; *prev = xmalloc(sizeof(struct cmd_section_t)); memset(*prev, 0, sizeof(struct cmd_section_t)); (*prev)->identifier = identifier; (*prev)->is_data = data; return *prev; } struct cmd_source_t *db_find_source_by_id(struct cmd_file_t *cmd_file, const char *id) { struct cmd_source_t *src = cmd_file->source_list; while(src) { if(strcmp(src->identifier, id) == 0) return src; src = src->next; } return NULL; } struct cmd_option_t *db_find_option_by_id(struct cmd_option_t *opt, const char *name) { while(opt) { if(strcmp(opt->name, name) == 0) return opt; opt = opt->next; } return NULL; } #define INVALID_SB_SUBVERSION 0xffff static const char *parse_sb_subversion(const char *str, uint16_t *v) { int len = 0; *v = 0; while(isdigit(str[len]) && len < 3) *v = (*v) << 4 | (str[len++] - '0'); if(len == 0) *v = INVALID_SB_SUBVERSION; return str + len; } bool db_parse_sb_version(struct sb_version_t *ver, const char *str) { str = parse_sb_subversion(str, &ver->major); if(ver->major == INVALID_SB_SUBVERSION || *str != '.') return false; str = parse_sb_subversion(str + 1, &ver->minor); if(ver->minor == INVALID_SB_SUBVERSION || *str != '.') return false; str = parse_sb_subversion(str + 1, &ver->revision); if(ver->revision == INVALID_SB_SUBVERSION || *str != 0) return false; return true; } static bool db_generate_sb_subversion(uint16_t subver, char *str) { str[0] = '0' + ((subver >> 8) & 0xf); str[1] = '0' + ((subver >> 4) & 0xf); str[2] = '0' + (subver & 0xf); return true; } bool db_generate_sb_version(struct sb_version_t *ver, char *str, int size) { if(size < 12) return false; str[3] = '.'; str[7] = '.'; str[11] = 0; return db_generate_sb_subversion(ver->major, str) && db_generate_sb_subversion(ver->minor, str + 4) && db_generate_sb_subversion(ver->revision, str + 8); } #undef parse_error #define parse_error(lexem, ...) \ do { fprintf(stderr, "%s:%d: ", lexem.file, lexem.line); \ fprintf(stderr, __VA_ARGS__); exit(2); } while(0) struct lex_ctx_t { struct context_t ctx; struct lexem_t lexem; }; /* When lexems hold strings (like identifier), it might be useful to steal * the pointer and don't clean the lexem but in other case, one don't want * to keep the pointer to the string and just want to release the memory. * Thus clean_lexem should be true except when one keeps a pointer */ static inline void next(struct lex_ctx_t *ctx, bool clean_lexem) { if(clean_lexem) free(ctx->lexem.str); memset(&ctx->lexem, 0, sizeof(struct lexem_t)); next_lexem(&ctx->ctx, &ctx->lexem); } static uint32_t parse_term_expr(struct lex_ctx_t *ctx, struct cmd_option_t *const_list) { uint32_t ret = 0; if(ctx->lexem.type == LEX_NUMBER) ret = ctx->lexem.num; else if(ctx->lexem.type == LEX_IDENTIFIER) { struct cmd_option_t *c = db_find_option_by_id(const_list, ctx->lexem.str); if(c == NULL) parse_error(ctx->lexem, "Undefined reference to constant '%s'\n", ctx->lexem.str); if(c->is_string) parse_error(ctx->lexem, "Internal error: constant '%s' is not an integer\n", ctx->lexem.str); ret = c->val; } else parse_error(ctx->lexem, "Number or constant identifier expected\n"); next(ctx, true); return ret; } static uint32_t parse_shift_expr(struct lex_ctx_t *ctx, struct cmd_option_t *const_list) { uint32_t v = parse_term_expr(ctx, const_list); while(ctx->lexem.type == LEX_LSHIFT) { next(ctx, true); v <<= parse_term_expr(ctx, const_list); } return v; } static uint32_t parse_or_expr(struct lex_ctx_t *ctx, struct cmd_option_t *const_list) { uint32_t v = parse_shift_expr(ctx, const_list); while(ctx->lexem.type == LEX_OR) { next(ctx, true); v |= parse_shift_expr(ctx, const_list); } return v; } static uint32_t parse_intexpr(struct lex_ctx_t *ctx, struct cmd_option_t *const_list) { return parse_or_expr(ctx, const_list); } #define NR_INITIAL_CONSTANTS 4 static char *init_const_name[NR_INITIAL_CONSTANTS] = {"true", "false", "yes", "no"}; static uint32_t init_const_value[NR_INITIAL_CONSTANTS] = {1, 0, 1, 0}; struct cmd_file_t *db_parse_file(const char *file) { size_t size; FILE *f = fopen(file, "r"); if(f == NULL) { if(g_debug) perror("Cannot open db file"); return NULL; } fseek(f, 0, SEEK_END); size = ftell(f); fseek(f, 0, SEEK_SET); char *buf = xmalloc(size); if(fread(buf, size, 1, f) != 1) { if(g_debug) perror("Cannot read db file"); return NULL; } fclose(f); if(g_debug) printf("Parsing db file '%s'\n", file); struct cmd_file_t *cmd_file = xmalloc(sizeof(struct cmd_file_t)); memset(cmd_file, 0, sizeof(struct cmd_file_t)); /* add initial constants */ for(int i = 0; i < NR_INITIAL_CONSTANTS; i++) db_add_int_opt(&cmd_file->constant_list, init_const_name[i], init_const_value[i]); struct lex_ctx_t lctx; lctx.ctx.file = file; lctx.ctx.line = 1; lctx.ctx.begin = buf; lctx.ctx.ptr = buf; lctx.ctx.end = buf + size; #define next(clean_lexem) next(&lctx, clean_lexem) #define lexem lctx.lexem /* init lexer */ next(false); /* don't clean init lexem because it doesn't exist */ /* constants ? */ if(lexem.type == LEX_IDENTIFIER && !strcmp(lexem.str, "constants")) { next(true); if(lexem.type != LEX_LBRACE) parse_error(lexem, "'{' expected after 'constants'\n"); while(true) { next(true); if(lexem.type == LEX_RBRACE) break; if(lexem.type != LEX_IDENTIFIER) parse_error(lexem, "Identifier expected in constants\n"); const char *name = lexem.str; next(false); /* lexem string is kept as option name */ if(lexem.type != LEX_EQUAL) parse_error(lexem, "'=' expected after identifier\n"); next(true); db_add_int_opt(&cmd_file->constant_list, name, parse_intexpr(&lctx, cmd_file->constant_list)); if(lexem.type != LEX_SEMICOLON) parse_error(lexem, "';' expected after string\n"); } next(true); } /* options ? */ if(lexem.type == LEX_IDENTIFIER && !strcmp(lexem.str, "options")) { next(true); if(lexem.type != LEX_LBRACE) parse_error(lexem, "'{' expected after 'options'\n"); while(true) { next(true); if(lexem.type == LEX_RBRACE) break; if(lexem.type != LEX_IDENTIFIER) parse_error(lexem, "Identifier expected in options\n"); const char *name = lexem.str; next(false); /* lexem string is kept as option name */ if(lexem.type != LEX_EQUAL) parse_error(lexem, "'=' expected after identifier\n"); next(true); if(lexem.type == LEX_STRING) { db_add_str_opt(&cmd_file->opt_list, name, lexem.str); next(true); } else db_add_int_opt(&cmd_file->opt_list, name, parse_intexpr(&lctx, cmd_file->constant_list)); if(lexem.type != LEX_SEMICOLON) parse_error(lexem, "';' expected after string\n"); } next(true); } /* sources */ if(lexem.type != LEX_IDENTIFIER || strcmp(lexem.str, "sources")) parse_error(lexem, "'sources' expected\n"); next(true); if(lexem.type != LEX_LBRACE) parse_error(lexem, "'{' expected after 'sources'\n"); while(true) { next(true); if(lexem.type == LEX_RBRACE) break; if(lexem.type != LEX_IDENTIFIER) parse_error(lexem, "identifier expected in sources\n"); const char *srcid = lexem.str; if(db_find_source_by_id(cmd_file, srcid) != NULL) parse_error(lexem, "Duplicate source identifier\n"); next(false); /* lexem string is kept as source name */ if(lexem.type != LEX_EQUAL) parse_error(lexem, "'=' expected after identifier\n"); next(true); if(lexem.type == LEX_STRING) { db_add_source(cmd_file, srcid, lexem.str); next(true); } else if(lexem.type == LEX_IDENTIFIER && !strcmp(lexem.str, "extern")) { next(true); if(lexem.type != LEX_LPAREN) parse_error(lexem, "'(' expected after 'extern'\n"); next(true); db_add_extern_source(cmd_file, srcid, parse_intexpr(&lctx, cmd_file->constant_list)); if(lexem.type != LEX_RPAREN) parse_error(lexem, "')' expected\n"); next(true); } else parse_error(lexem, "String or 'extern' expected after '='\n"); if(lexem.type != LEX_SEMICOLON) parse_error(lexem, "';' expected\n"); } /* sections */ while(true) { next(true); if(lexem.type == LEX_EOF) break; if(lexem.type != LEX_IDENTIFIER || strcmp(lexem.str, "section") != 0) parse_error(lexem, "'section' expected\n"); next(true); if(lexem.type != LEX_LPAREN) parse_error(lexem, "'(' expected after 'section'\n"); next(true); /* can be any number */ struct cmd_section_t *sec = db_add_section(cmd_file, parse_intexpr(&lctx, cmd_file->constant_list), false); /* options ? */ if(lexem.type == LEX_SEMICOLON) { do { next(true); if(lexem.type != LEX_IDENTIFIER) parse_error(lexem, "Identifier expected for section option\n"); const char *name = lexem.str; next(false); /* lexem string is kept as option name */ if(lexem.type != LEX_EQUAL) parse_error(lexem, "'=' expected after option identifier\n"); next(true); if(lexem.type == LEX_STRING) { db_add_str_opt(&sec->opt_list, name, lexem.str); next(true); } else db_add_int_opt(&sec->opt_list, name, parse_intexpr(&lctx, cmd_file->constant_list)); }while(lexem.type == LEX_COLON); } if(lexem.type != LEX_RPAREN) parse_error(lexem, "')' expected after section identifier\n"); next(true); if(lexem.type == LEX_LBRACE) { sec->is_data = false; /* commands */ while(true) { next(true); if(lexem.type == LEX_RBRACE) break; struct cmd_inst_t *inst = db_add_inst(&sec->inst_list, CMD_LOAD, 0); if(lexem.type != LEX_IDENTIFIER) parse_error(lexem, "Instruction expected in section\n"); if(strcmp(lexem.str, "load") == 0) inst->type = CMD_LOAD; else if(strcmp(lexem.str, "call") == 0) inst->type = CMD_CALL; else if(strcmp(lexem.str, "jump") == 0) inst->type = CMD_JUMP; else if(strcmp(lexem.str, "mode") == 0) inst->type = CMD_MODE; else parse_error(lexem, "Instruction expected in section\n"); next(true); if(inst->type == CMD_LOAD) { if(lexem.type != LEX_IDENTIFIER) parse_error(lexem, "Identifier expected after instruction\n"); inst->identifier = lexem.str; if(db_find_source_by_id(cmd_file, inst->identifier) == NULL) parse_error(lexem, "Undefined reference to source '%s'\n", inst->identifier); next(false); /* lexem string kept as identifier */ if(lexem.type == LEX_RANGLE) { // load at inst->type = CMD_LOAD_AT; next(true); inst->addr = parse_intexpr(&lctx, cmd_file->constant_list); } if(lexem.type != LEX_SEMICOLON) parse_error(lexem, "';' expected after command\n"); } else if(inst->type == CMD_CALL || inst->type == CMD_JUMP) { if(lexem.type == LEX_IDENTIFIER) { inst->identifier = lexem.str; if(db_find_source_by_id(cmd_file, inst->identifier) == NULL) parse_error(lexem, "Undefined reference to source '%s'\n", inst->identifier); next(false); /* lexem string kept as identifier */ } else { inst->type = (inst->type == CMD_CALL) ? CMD_CALL_AT : CMD_JUMP_AT; inst->addr = parse_intexpr(&lctx, cmd_file->constant_list); } if(lexem.type == LEX_LPAREN) { next(true); inst->argument = parse_intexpr(&lctx, cmd_file->constant_list); if(lexem.type != LEX_RPAREN) parse_error(lexem, "Expected closing brace\n"); next(true); } if(lexem.type != LEX_SEMICOLON) parse_error(lexem, "';' expected after command\n"); } else if(inst->type == CMD_MODE) { inst->argument = parse_intexpr(&lctx, cmd_file->constant_list); if(lexem.type != LEX_SEMICOLON) parse_error(lexem, "Expected ';' after command\n"); } else parse_error(lexem, "Internal error"); } } else if(lexem.type == LEX_LE) { sec->is_data = true; next(true); if(lexem.type != LEX_IDENTIFIER) parse_error(lexem, "Identifier expected after '<='\n"); sec->source_id = lexem.str; next(false); /* lexem string is kept as source id */ if(lexem.type != LEX_SEMICOLON) parse_error(lexem, "';' expected after identifier\n"); } else parse_error(lexem, "'{' or '<=' expected after section directive\n"); } #undef lexem #undef next free(buf); return cmd_file; } void db_free_option_list(struct cmd_option_t *opt_list) { while(opt_list) { struct cmd_option_t *next = opt_list->next; fflush(stdout); free(opt_list->name); free(opt_list->str); free(opt_list); opt_list = next; } } static bool db_generate_options(FILE *f, const char *secname, struct cmd_option_t *list) { fprintf(f, "%s\n", secname); fprintf(f, "{\n"); while(list) { fprintf(f, " %s = ", list->name); if(list->is_string) fprintf(f, "\"%s\";\n", list->str); // FIXME handle escape else fprintf(f, "0x%x;\n", list->val); list = list->next; } fprintf(f, "}\n"); return true; } static bool db_generate_section_options(FILE *f, struct cmd_option_t *list) { bool first = true; while(list) { fprintf(f, "%c %s = ", first ? ';' : ',', list->name); if(list->is_string) fprintf(f, "\"%s\"", list->str); // FIXME handle escape else fprintf(f, "0x%x", list->val); first = false; list = list->next; } return true; } static bool db_generate_sources(FILE *f, struct cmd_source_t *list) { fprintf(f, "sources\n"), fprintf(f, "{\n"); while(list) { fprintf(f, " %s = ", list->identifier); if(list->is_extern) fprintf(f, "extern(%d);\n", list->extern_nr); else fprintf(f, "\"%s\";\n", list->filename); // FIXME handle escape list = list->next; } fprintf(f, "}\n"); return true; } static bool db_generate_section(FILE *f, struct cmd_section_t *section) { fprintf(f, "section(%#x", section->identifier); db_generate_section_options(f, section->opt_list); if(section->is_data) { fprintf(f, ") <= %s;\n", section->source_id); return true; } fprintf(f, ")\n{\n"); struct cmd_inst_t *inst = section->inst_list; while(inst) { fprintf(f, " "); switch(inst->type) { case CMD_LOAD: fprintf(f, "load %s;\n", inst->identifier); break; case CMD_LOAD_AT: fprintf(f, "load %s > %#x;\n", inst->identifier, inst->addr); break; case CMD_CALL: fprintf(f, "call %s(%#x);\n", inst->identifier, inst->argument); break; case CMD_CALL_AT: fprintf(f, "call %#x(%#x);\n", inst->addr, inst->argument); break; case CMD_JUMP: fprintf(f, "jump %s(%#x);\n", inst->identifier, inst->argument); break; case CMD_JUMP_AT: fprintf(f, "jump %#x(%#x);\n", inst->addr, inst->argument); break; case CMD_MODE: fprintf(f, "mode %#x;\n", inst->argument); break; default: bug("die"); } inst = inst->next; } fprintf(f, "}\n"); return true; } static bool db_generate_sections(FILE *f, struct cmd_section_t *section) { while(section) if(!db_generate_section(f, section)) return false; else section = section->next; return true; } bool db_generate_file(struct cmd_file_t *file, const char *filename, void *user, db_color_printf printf) { FILE *f = fopen(filename, "w"); if(f == NULL) return printf(user, true, GREY, "Cannot open '%s' for writing: %m\n", filename), false; if(!db_generate_options(f, "constants", file->constant_list)) goto Lerr; if(!db_generate_options(f, "options", file->opt_list)) goto Lerr; if(!db_generate_sources(f, file->source_list)) goto Lerr; if(!db_generate_sections(f, file->section_list)) goto Lerr; fclose(f); return true; Lerr: fclose(f); return false; } void db_free(struct cmd_file_t *file) { db_free_option_list(file->opt_list); db_free_option_list(file->constant_list); struct cmd_source_t *src = file->source_list; while(src) { struct cmd_source_t *next = src->next; free(src->identifier); fflush(stdout); free(src->filename); if(src->loaded) { if(src->type == CMD_SRC_BIN) free(src->bin.data); if(src->type == CMD_SRC_ELF) elf_release(&src->elf); } free(src); src = next; } struct cmd_section_t *sec = file->section_list; while(sec) { struct cmd_section_t *next = sec->next; db_free_option_list(sec->opt_list); free(sec->source_id); struct cmd_inst_t *inst = sec->inst_list; while(inst) { struct cmd_inst_t *next = inst->next; free(inst->identifier); free(inst); inst = next; } free(sec); sec = next; } free(file); }