ref: b33ff7e96c5c410f722808314579810f23c86cd8
dir: /src/deh_str.c/
// // Copyright(C) 2005-2014 Simon Howard // // 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 program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // // Parses Text substitution sections in dehacked files // #include <stdio.h> #include <stdlib.h> #include <string.h> #include <stdarg.h> #include "doomtype.h" #include "deh_str.h" #include "m_misc.h" #include "z_zone.h" typedef struct { char *from_text; char *to_text; } deh_substitution_t; static deh_substitution_t **hash_table = NULL; static int hash_table_entries; static int hash_table_length = -1; // This is the algorithm used by glib static unsigned int strhash(const char *s) { const char *p = s; unsigned int h = *p; if (h) { for (p += 1; *p; p++) h = (h << 5) - h + *p; } return h; } static deh_substitution_t *SubstitutionForString(const char *s) { int entry; // Fallback if we have not initialized the hash table yet if (hash_table_length < 0) return NULL; entry = strhash(s) % hash_table_length; while (hash_table[entry] != NULL) { if (!strcmp(hash_table[entry]->from_text, s)) { // substitution found! return hash_table[entry]; } entry = (entry + 1) % hash_table_length; } // no substitution found return NULL; } // Look up a string to see if it has been replaced with something else // This will be used throughout the program to substitute text const char *DEH_String(const char *s) { deh_substitution_t *subst; subst = SubstitutionForString(s); if (subst != NULL) { return subst->to_text; } else { return s; } } static void InitHashTable(void) { // init hash table hash_table_entries = 0; hash_table_length = 16; hash_table = Z_Malloc(sizeof(deh_substitution_t *) * hash_table_length, PU_STATIC, NULL); memset(hash_table, 0, sizeof(deh_substitution_t *) * hash_table_length); } static void DEH_AddToHashtable(deh_substitution_t *sub); static void IncreaseHashtable(void) { deh_substitution_t **old_table; int old_table_length; int i; // save the old table old_table = hash_table; old_table_length = hash_table_length; // double the size hash_table_length *= 2; hash_table = Z_Malloc(sizeof(deh_substitution_t *) * hash_table_length, PU_STATIC, NULL); memset(hash_table, 0, sizeof(deh_substitution_t *) * hash_table_length); // go through the old table and insert all the old entries for (i=0; i<old_table_length; ++i) { if (old_table[i] != NULL) { DEH_AddToHashtable(old_table[i]); } } // free the old table Z_Free(old_table); } static void DEH_AddToHashtable(deh_substitution_t *sub) { int entry; // if the hash table is more than 60% full, increase its size if ((hash_table_entries * 10) / hash_table_length > 6) { IncreaseHashtable(); } // find where to insert it entry = strhash(sub->from_text) % hash_table_length; while (hash_table[entry] != NULL) { entry = (entry + 1) % hash_table_length; } hash_table[entry] = sub; ++hash_table_entries; } void DEH_AddStringReplacement(const char *from_text, const char *to_text) { deh_substitution_t *sub; size_t len; // Initialize the hash table if this is the first time if (hash_table_length < 0) { InitHashTable(); } // Check to see if there is an existing substitution already in place. sub = SubstitutionForString(from_text); if (sub != NULL) { Z_Free(sub->to_text); len = strlen(to_text) + 1; sub->to_text = Z_Malloc(len, PU_STATIC, NULL); memcpy(sub->to_text, to_text, len); } else { // We need to allocate a new substitution. sub = Z_Malloc(sizeof(*sub), PU_STATIC, 0); // We need to create our own duplicates of the provided strings. len = strlen(from_text) + 1; sub->from_text = Z_Malloc(len, PU_STATIC, NULL); memcpy(sub->from_text, from_text, len); len = strlen(to_text) + 1; sub->to_text = Z_Malloc(len, PU_STATIC, NULL); memcpy(sub->to_text, to_text, len); DEH_AddToHashtable(sub); } } typedef enum { FORMAT_ARG_INVALID, FORMAT_ARG_INT, FORMAT_ARG_FLOAT, FORMAT_ARG_CHAR, FORMAT_ARG_STRING, FORMAT_ARG_PTR, FORMAT_ARG_SAVE_POS } format_arg_t; // Get the type of a format argument. // We can mix-and-match different format arguments as long as they // are for the same data type. static format_arg_t FormatArgumentType(char c) { switch (c) { case 'd': case 'i': case 'o': case 'u': case 'x': case 'X': return FORMAT_ARG_INT; case 'e': case 'E': case 'f': case 'F': case 'g': case 'G': case 'a': case 'A': return FORMAT_ARG_FLOAT; case 'c': case 'C': return FORMAT_ARG_CHAR; case 's': case 'S': return FORMAT_ARG_STRING; case 'p': return FORMAT_ARG_PTR; case 'n': return FORMAT_ARG_SAVE_POS; default: return FORMAT_ARG_INVALID; } } // Given the specified string, get the type of the first format // string encountered. static format_arg_t NextFormatArgument(const char **str) { format_arg_t argtype; // Search for the '%' starting the next string. while (**str != '\0') { if (**str == '%') { ++*str; // Don't stop for double-%s. if (**str != '%') { break; } } ++*str; } // Find the type of the format string. while (**str != '\0') { argtype = FormatArgumentType(**str); if (argtype != FORMAT_ARG_INVALID) { ++*str; return argtype; } ++*str; } // Stop searching, we have reached the end. *str = NULL; return FORMAT_ARG_INVALID; } // Check if the specified argument type is a valid replacement for // the original. static boolean ValidArgumentReplacement(format_arg_t original, format_arg_t replacement) { // In general, the original and replacement types should be // identical. However, there are some cases where the replacement // is valid and the types don't match. // Characters can be represented as ints. if (original == FORMAT_ARG_CHAR && replacement == FORMAT_ARG_INT) { return true; } // Strings are pointers. if (original == FORMAT_ARG_STRING && replacement == FORMAT_ARG_PTR) { return true; } return original == replacement; } // Return true if the specified string contains no format arguments. static boolean ValidFormatReplacement(const char *original, const char *replacement) { const char *rover1; const char *rover2; int argtype1, argtype2; // Check each argument in turn and compare types. rover1 = original; rover2 = replacement; for (;;) { argtype1 = NextFormatArgument(&rover1); argtype2 = NextFormatArgument(&rover2); if (argtype2 == FORMAT_ARG_INVALID) { // No more arguments left to read from the replacement string. break; } else if (argtype1 == FORMAT_ARG_INVALID) { // Replacement string has more arguments than the original. return false; } else if (!ValidArgumentReplacement(argtype1, argtype2)) { // Not a valid replacement argument. return false; } } return true; } // Get replacement format string, checking arguments. static const char *FormatStringReplacement(const char *s) { const char *repl; repl = DEH_String(s); if (!ValidFormatReplacement(s, repl)) { printf("WARNING: Unsafe dehacked replacement provided for " "printf format string: %s\n", s); return s; } return repl; } // printf(), performing a replacement on the format string. void DEH_printf(const char *fmt, ...) { va_list args; const char *repl; repl = FormatStringReplacement(fmt); va_start(args, fmt); vprintf(repl, args); va_end(args); } // fprintf(), performing a replacement on the format string. void DEH_fprintf(FILE *fstream, const char *fmt, ...) { va_list args; const char *repl; repl = FormatStringReplacement(fmt); va_start(args, fmt); vfprintf(fstream, repl, args); va_end(args); } // snprintf(), performing a replacement on the format string. void DEH_snprintf(char *buffer, size_t len, const char *fmt, ...) { va_list args; const char *repl; repl = FormatStringReplacement(fmt); va_start(args, fmt); M_vsnprintf(buffer, len, repl, args); va_end(args); }