/* plist.c Property list management Copyright (C) 2000 Jeff Teunissen 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. You should have received a copy of the GNU General Public License along with this program; if not, write to: Free Software Foundation, Inc. 59 Temple Place - Suite 330 Boston, MA 02111-1307, USA */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include #include #include #if defined(_WIN32) && defined(HAVE_MALLOC_H) #include #endif #include "qfalloca.h" #include "QF/darray.h" #include "QF/dstring.h" #include "QF/hash.h" #include "QF/plist.h" #include "QF/qtypes.h" #include "QF/sys.h" /* Generic property list item. */ struct plitem_s { pltype_t type; unsigned users; void *data; void *user_data; int line; };//plitem_t /* Dictionaries */ struct dictkey_s { char *key; plitem_t *value; }; typedef struct dictkey_s dictkey_t; struct pldict_s { hashtab_t *tab; struct DARRAY_TYPE (dictkey_t *) keys; }; typedef struct pldict_s pldict_t; /* Arrays */ struct plarray_s { int numvals; ///< Number of items in array int maxvals; ///< Number of items that can be stored ///< before a realloc is necesary. struct plitem_s **values; ///< Array data }; typedef struct plarray_s plarray_t; /* Typeless, unformatted binary data */ struct plbinary_s { size_t size; void *data; }; typedef struct plbinary_s plbinary_t; typedef struct pldata_s { // Unparsed property list string const char *ptr; unsigned end; unsigned pos; unsigned line; unsigned line_start; dstring_t *errmsg; hashctx_t **hashctx; } pldata_t; // Ugly defines for fast checking and conversion from char to number #define inrange(ch,min,max) ((ch) >= (min) && (ch) <= (max)) #define char2num(ch) \ (inrange((ch), '0', '9') ? ((ch) - '0') \ : 10 + (inrange((ch), 'a', 'f') ? ((ch) - 'a') \ : ((ch) - 'A'))) static const char *pl_types[] = { "dictionary", "array", "biinary", "string", }; static byte quotable_bitmap[32]; static inline int is_quotable (byte x) { return quotable_bitmap[x / 8] & (1 << (x % 8)); } static void init_quotables (void) { const char *unquotables = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ" "`abcdefghijklmnopqrstuvwxyz!#$%&*+-./:?@|~_^"; const byte *c; memset (quotable_bitmap, ~0, sizeof (quotable_bitmap)); for (c = (byte *) unquotables; *c; c++) quotable_bitmap[*c / 8] &= ~(1 << (*c % 8)); } static plitem_t *pl_parsepropertylistitem (pldata_t *pl); static const char * dict_get_key (const void *i, void *unused) { dictkey_t *item = (dictkey_t *) i; return item->key; } static void dict_free (void *i, void *unused) { dictkey_t *item = (dictkey_t *) i; free (item->key); if (item->value) // Make descended stuff get freed PL_Release (item->value); free (item); } static plitem_t * pl_newitem (pltype_t type) { plitem_t *item = calloc (1, sizeof (plitem_t)); item->type = type; return item; } VISIBLE plitem_t * PL_NewDictionary (hashctx_t **hashctx) { plitem_t *item = pl_newitem (QFDictionary); pldict_t *dict = malloc (sizeof (pldict_t)); dict->tab = Hash_NewTable (1021, dict_get_key, dict_free, NULL, hashctx); DARRAY_INIT (&dict->keys, 8); item->data = dict; return item; } VISIBLE plitem_t * PL_NewArray (void) { plitem_t *item = pl_newitem (QFArray); plarray_t *array = calloc (1, sizeof (plarray_t)); item->data = array; return item; } VISIBLE plitem_t * PL_NewData (void *data, size_t size) { plitem_t *item = pl_newitem (QFBinary); plbinary_t *bin = malloc (sizeof (plbinary_t)); item->data = bin; bin->data = data; bin->size = size; return item; } static plitem_t * new_string (const char *str, size_t len, pldata_t *pl) { plitem_t *item = pl_newitem (QFString); item->data = malloc (len + 1); memcpy (item->data, str, len); ((char *) item->data)[len] = 0; item->line = pl ? pl->line : 0; return item; } VISIBLE plitem_t * PL_NewString (const char *str) { return new_string (str, strlen (str), 0); } VISIBLE plitem_t * PL_Retain (plitem_t *item) { if (item) { item->users++; } return item; } VISIBLE plitem_t * PL_Release (plitem_t *item) { pldict_t *dict; plarray_t *array; if (!item || (item->users && --item->users > 0)) { return item; } switch (item->type) { case QFDictionary: dict = item->data; Hash_DelTable (dict->tab); DARRAY_CLEAR (&dict->keys); free (item->data); break; case QFArray: { array = item->data; int i = array->numvals; while (i-- > 0) { PL_Release (array->values[i]); } free (array->values); free (item->data); } break; case QFBinary: free (((plbinary_t *) item->data)->data); free (item->data); break; case QFString: free (item->data); break; case QFMultiType: break; } free (item); return 0; } VISIBLE void PL_SetUserData (plitem_t *item, void *data) { item->user_data = data; } VISIBLE void * PL_GetUserData (plitem_t *item) { return item->user_data; } VISIBLE size_t PL_BinarySize (const plitem_t *binary) { if (!binary || binary->type != QFBinary) { return 0; } plbinary_t *bin = (plbinary_t *) binary->data; return bin->size; } VISIBLE const void * PL_BinaryData (const plitem_t *binary) { if (!binary || binary->type != QFBinary) { return 0; } plbinary_t *bin = (plbinary_t *) binary->data; return bin->data; } VISIBLE const char * PL_String (const plitem_t *string) { if (!string || string->type != QFString) { return NULL; } return string->data; } VISIBLE plitem_t * PL_ObjectForKey (const plitem_t *item, const char *key) { if (!item || item->type != QFDictionary) { return NULL; } pldict_t *dict = (pldict_t *) item->data; dictkey_t *k = (dictkey_t *) Hash_Find (dict->tab, key); return k ? k->value : NULL; } VISIBLE const char * PL_KeyAtIndex (const plitem_t *item, int index) { if (!item || item->type != QFDictionary) { return NULL; } pldict_t *dict = (pldict_t *) item->data; if (index < 0 || (size_t) index >= dict->keys.size) { return NULL; } return dict->keys.a[index]->key; } VISIBLE void PL_RemoveObjectForKey (plitem_t *item, const char *key) { if (!item || item->type != QFDictionary) { return; } pldict_t *dict = (pldict_t *) item->data; dictkey_t *k; plitem_t *value; k = (dictkey_t *) Hash_Del (dict->tab, key); if (!k) { return; } value = k->value; k->value = 0; for (size_t i = 0; i < dict->keys.size; i++) { if (dict->keys.a[i] == k) { DARRAY_REMOVE_AT (&dict->keys, i); break; } } dict_free (k, 0); value->users--; } VISIBLE plitem_t * PL_D_AllKeys (const plitem_t *item) { if (!item || item->type != QFDictionary) { return NULL; } pldict_t *dict = (pldict_t *) item->data; dictkey_t *current; plitem_t *array; if (!(array = PL_NewArray ())) return NULL; for (size_t i = 0; i < dict->keys.size; i++) { current = dict->keys.a[i]; PL_A_AddObject (array, PL_NewString (current->key)); } return array; } VISIBLE int PL_D_NumKeys (const plitem_t *item) { if (!item || item->type != QFDictionary) { return 0; } pldict_t *dict = (pldict_t *) item->data; return Hash_NumElements (dict->tab); } VISIBLE plitem_t * PL_ObjectAtIndex (const plitem_t *array, int index) { if (!array || array->type != QFArray) { return NULL; } plarray_t *arr = (plarray_t *) array->data; return index >= 0 && index < arr->numvals ? arr->values[index] : NULL; } VISIBLE bool PL_D_AddObject (plitem_t *item, const char *key, plitem_t *value) { if (!item || item->type != QFDictionary || !value) { return false; } pldict_t *dict = (pldict_t *) item->data; dictkey_t *k; if ((k = Hash_Find (dict->tab, key))) { PL_Retain (value); PL_Release (k->value); k->value = value; } else { k = malloc (sizeof (dictkey_t)); if (!k) return false; PL_Retain (value); k->key = strdup (key); k->value = value; Hash_Add (dict->tab, k); DARRAY_APPEND (&dict->keys, k); } return true; } VISIBLE bool PL_D_Extend (plitem_t *dstDict, plitem_t *srcDict) { if (!dstDict || dstDict->type != QFDictionary || !srcDict || srcDict->type != QFDictionary || ((pldict_t *) srcDict->data)->keys.size < 1) { return false; } pldict_t *dst = dstDict->data; pldict_t *src = srcDict->data; size_t count = dst->keys.size; DARRAY_RESIZE (&dst->keys, dst->keys.size + src->keys.size);// open space DARRAY_RESIZE (&dst->keys, count); // put size back so it's correct for (size_t i = 0; i < src->keys.size; i++) { dictkey_t *key = src->keys.a[i]; dictkey_t *k; if ((k = Hash_Find (dst->tab, key->key))) { PL_Retain (key->value); PL_Release (k->value); k->value = key->value; } else { k = malloc (sizeof (dictkey_t)); if (!k) return false; PL_Retain (key->value); k->key = strdup (key->key); k->value = key->value; Hash_Add (dst->tab, k); DARRAY_APPEND (&dst->keys, k); } } return true; } static bool check_array_size (plarray_t *arr, int count) { if (count > arr->maxvals) { int newmax = (count + 127) & ~127; int size = newmax * sizeof (plitem_t *); plitem_t **tmp = realloc (arr->values, size); if (!tmp) return false; arr->maxvals = newmax; arr->values = tmp; } return true; } VISIBLE bool PL_A_InsertObjectAtIndex (plitem_t *array, plitem_t *item, int index) { if (!array || array->type != QFArray || !item) { return false; } plarray_t *arr; arr = (plarray_t *)array->data; if (!check_array_size (arr, arr->numvals + 1)) { return false; } if (index == -1) index = arr->numvals; if (index < 0 || index > arr->numvals) return false; memmove (arr->values + index + 1, arr->values + index, (arr->numvals - index) * sizeof (plitem_t *)); PL_Retain (item); arr->values[index] = item; arr->numvals++; return true; } VISIBLE bool PL_A_AddObject (plitem_t *array, plitem_t *item) { return PL_A_InsertObjectAtIndex (array, item, -1); } VISIBLE bool PL_A_Extend (plitem_t *dstArray, plitem_t *srcArray) { if (!dstArray || dstArray->type != QFArray || !srcArray || srcArray->type != QFArray || ((plarray_t *) srcArray->data)->numvals < 1) { return false; } plarray_t *dst = dstArray->data; plarray_t *src = srcArray->data; if (!check_array_size (dst, dst->numvals + src->numvals)) { return false; } for (int i = 0; i < src->numvals; i++) { PL_Retain (src->values[i]); dst->values[dst->numvals++] = src->values[i]; } return true; } VISIBLE int PL_A_NumObjects (const plitem_t *array) { if (!array || array->type != QFArray) { return 0; } return ((plarray_t *) array->data)->numvals; } VISIBLE void PL_RemoveObjectAtIndex (plitem_t *array, int index) { if (!array || array->type != QFArray) { return; } plarray_t *arr; plitem_t *item; arr = (plarray_t *)array->data; if (index < 0 || index >= arr->numvals) return; item = arr->values[index]; arr->numvals--; while (index < arr->numvals) { arr->values[index] = arr->values[index + 1]; index++; } item->users--; } static void __attribute__((format(PRINTF, 2, 3))) pl_error (pldata_t *pl, const char *fmt, ...) { if (!pl->errmsg) { pl->errmsg = dstring_new (); } va_list args; va_start (args, fmt); dvsprintf (pl->errmsg, fmt, args); va_end (args); } static bool pl_skipspace (pldata_t *pl, int end_ok) { while (pl->pos < pl->end) { char c = pl->ptr[pl->pos]; if (!isspace ((byte) c)) { if (c == '/' && pl->pos < pl->end - 1) { // check for comments if (pl->ptr[pl->pos + 1] == '/') { pl->pos += 2; while (pl->pos < pl->end) { c = pl->ptr[pl->pos]; if (c == '\n') break; pl->pos++; } if (pl->pos >= pl->end) { // end of string in a single-line comment is always // an error pl_error (pl, "Reached end of string in comment"); return false; } } else if (pl->ptr[pl->pos + 1] == '*') { // "/*" comments pl->pos += 2; while (pl->pos < pl->end) { c = pl->ptr[pl->pos]; if (c == '\n') { pl->line++; pl->line_start = pl->pos + 1; } else if (c == '*' && pl->pos < pl->end - 1 && pl->ptr[pl->pos+1] == '/') { pl->pos++; break; } pl->pos++; } if (pl->pos >= pl->end) { // end of string in a multi-line comment is always // an error pl_error (pl, "Reached end of string in comment"); return false; } } else { return true; } } else { return true; } } if (c == '\n') { pl->line++; pl->line_start = pl->pos + 1; } pl->pos++; } if (!end_ok) { pl_error (pl, "Reached end of string"); } return false; } static int pl_checknext (pldata_t *pl, const char *valid, int end_ok) { if (!pl_skipspace (pl, end_ok)) { return end_ok; } char ch = pl->ptr[pl->pos]; if (strchr (valid, ch)) { return 1; } size_t len = strlen (valid); size_t size = 3 + (strlen (valid) - 1) * 7 + 1; char expected[size], *p = expected; p[0] = '\''; p[1] = valid[0]; p[2] = '\''; p += 3; for (size_t i = 1; i < len; i++, p++) { memcpy (p, " or 'x'", 7); p[5] = valid[i]; } p[0] = 0; pl_error (pl, "Unexpected character %c (wanted %s)", ch, expected); return 0; } static inline byte from_hex (byte a) { if (a >= '0' && a <= '9') return a - '0'; if (a >= 'A' && a <= 'F') return a - 'A' + 10; return a - 'a' + 10; } static inline byte make_byte (byte h, byte l) { return (from_hex (h) << 4) | from_hex (l); } static int pl_parsekeyvalue (pldata_t *pl, plitem_t *dict, int end_ok) { plitem_t *key = 0; plitem_t *value = 0; if (!(key = pl_parsepropertylistitem (pl))) { return 0; } if (key->type != QFString) { pl_error (pl, "Key is not a string"); goto error; } if (!pl_checknext (pl, "=", 0)) { goto error; } pl->pos++; if (!(value = pl_parsepropertylistitem (pl))) { goto error; } if (!PL_D_AddObject (dict, PL_String (key), value)) { goto error; } PL_Release (key); // don't need the key item if (!pl_checknext (pl, end_ok ? ";" : ";}", end_ok)) { return 0; } if (pl->ptr[pl->pos] == ';') { pl->pos++; } return 1; error: PL_Release (key); PL_Release (value); return 0; } static plitem_t * pl_parsedictionary (pldata_t *pl) { plitem_t *dict = PL_NewDictionary (pl->hashctx); dict->line = pl->line; pl->pos++; // skip over opening { while (pl_skipspace (pl, 0) && pl->ptr[pl->pos] != '}') { if (!pl_parsekeyvalue (pl, dict, 0)) { PL_Release (dict); return NULL; } } if (pl->pos >= pl->end) { pl_error (pl, "Unexpected end of string when parsing dictionary"); PL_Release (dict); return NULL; } pl->pos++; // skip over closing } return dict; } static int pl_parsevalue (pldata_t *pl, plitem_t *array, int end_ok) { plitem_t *value; if (!(value = pl_parsepropertylistitem (pl))) { return 0; } if (!PL_A_AddObject (array, value)) { pl_error (pl, "too many items in array"); PL_Release (value); return 0; } if (!pl_checknext (pl, end_ok ? "," : ",)", end_ok)) { return 0; } if (pl->ptr[pl->pos] == ',') { pl->pos++; } return 1; } static plitem_t * pl_parsearray (pldata_t *pl) { plitem_t *array = PL_NewArray (); array->line = pl->line; pl->pos++; // skip over opening ( while (pl_skipspace (pl, 0) && pl->ptr[pl->pos] != ')') { if (!pl_parsevalue (pl, array, 0)) { PL_Release (array); return NULL; } } if (pl->pos >= pl->end) { pl_error (pl, "Unexpected end of string when parsing array"); PL_Release (array); return NULL; } pl->pos++; // skip over opening ) return array; } static plitem_t * pl_parsebinary (pldata_t *pl) { unsigned start = ++pl->pos; int nibbles = 0, i; char *str, c; while (pl->pos < pl->end) { c = pl->ptr[pl->pos++]; if (isxdigit ((byte) c)) { nibbles++; continue; } if (c == '>') { if (nibbles & 1) { pl_error (pl, "invalid data, missing nibble"); return NULL; } int len = nibbles / 2; str = malloc (len); for (i = 0; i < len; i++) { str[i] = make_byte (pl->ptr[start + i * 2], pl->ptr[start + i * 2 + 1]); } plitem_t *item = PL_NewData (str, len); item->line = pl->line; return item; } pl_error (pl, "invalid character in data: %02x", c); return NULL; } pl_error (pl, "Reached end of string while parsing data"); return NULL; } static plitem_t * pl_parsequotedstring (pldata_t *pl) { unsigned int start = ++pl->pos; unsigned int escaped = 0; unsigned int shrink = 0; bool hex = false; bool long_string = false; plitem_t *str; if (pl->ptr[pl->pos] == '"' && pl->ptr[pl->pos + 1] == '"') { long_string = true; start += 2; pl->pos += 2; } while (pl->pos < pl->end) { char c = pl->ptr[pl->pos]; if (escaped) { if (escaped == 1 && inrange (c, '0', '7')) { escaped++; hex = false; } else if (escaped > 1) { if (escaped == 2 && c == 'x') { hex = true; shrink++; escaped++; } else if (hex && inrange (escaped, 3, 4) && isxdigit ((byte) c)) { shrink++; escaped++; } else if (inrange (escaped, 1, 3) && inrange (c, '0', '7')) { shrink++; escaped++; } else { pl->pos--; escaped = 0; } } else { escaped = 0; } } else { if (c == '\\') { escaped = 1; shrink++; } else if (c == '"' && (!long_string || (pl->ptr[pl->pos + 1] == '"' && pl->ptr[pl->pos + 2] == '"'))) { break; } } if (c == '\n') { pl->line++; pl->line_start = pl->pos + 1; } pl->pos++; } if (pl->pos >= pl->end) { pl_error (pl, "Reached end of string while parsing quoted string"); return NULL; } if (pl->pos - start - shrink == 0) { str = new_string ("", 0, pl); } else { char *chars = alloca(pl->pos - start - shrink); unsigned int j; unsigned int k; escaped = 0; hex = false; for (j = start, k = 0; j < pl->pos; j++) { char c = pl->ptr[j]; if (escaped) { if (escaped == 1 && inrange (c, '0', '7')) { chars[k] = c - '0'; hex = false; escaped++; } else if (escaped > 1) { if (escaped == 2 && c == 'x') { hex = true; escaped++; } else if (hex && inrange (escaped, 3, 4) && isxdigit ((byte) c)) { chars[k] <<= 4; chars[k] |= char2num (c); escaped++; } else if (inrange (escaped, 1, 3) && inrange (c, '0', '7')) { chars[k] <<= 3; chars[k] |= (c - '0'); escaped++; } else { escaped = 0; j--; k++; } } else { escaped = 0; switch (c) { case 'a': chars[k] = '\a'; break; case 'b': chars[k] = '\b'; break; case 't': chars[k] = '\t'; break; case 'r': chars[k] = '\r'; break; case 'n': chars[k] = '\n'; break; case 'v': chars[k] = '\v'; break; case 'f': chars[k] = '\f'; break; default: chars[k] = c; break; } k++; } } else { chars[k] = c; if (c == '\\') { escaped = 1; } else { k++; } } } str = new_string (chars, pl->pos - start - shrink, pl); } if (long_string) pl->pos += 2; pl->pos++; return str; } static plitem_t * pl_parseunquotedstring (pldata_t *pl) { unsigned int start = pl->pos; while (pl->pos < pl->end) { if (is_quotable (pl->ptr[pl->pos])) break; pl->pos++; } return new_string (&pl->ptr[start], pl->pos - start, pl); } static plitem_t * pl_parsepropertylistitem (pldata_t *pl) { if (!pl_skipspace (pl, 0)) { return NULL; } switch (pl->ptr[pl->pos]) { case '{': return pl_parsedictionary (pl); case '(': return pl_parsearray (pl); case '<': return pl_parsebinary (pl); case '"': return pl_parsequotedstring (pl); default: return pl_parseunquotedstring (pl); } } static plitem_t * pl_parseitem (const char *string, hashctx_t **hashctx, plitem_t *(*parse) (pldata_t *)) { plitem_t *newpl = NULL; if (!quotable_bitmap[0]) init_quotables (); pldata_t pl = { .ptr = string, .end = strlen (string), .line = 1, .hashctx = hashctx, }; if (!(newpl = parse (&pl))) { if (pl.errmsg) { Sys_Printf ("plist: %d,%d: %s\n", pl.line, pl.pos - pl.line_start, pl.errmsg->str); dstring_delete (pl.errmsg); } return NULL; } return newpl; } VISIBLE plitem_t * PL_GetPropertyList (const char *string, hashctx_t **hashctx) { return pl_parseitem (string, hashctx, pl_parsepropertylistitem); } static plitem_t * pl_getdictionary (pldata_t *pl) { plitem_t *dict = PL_NewDictionary (pl->hashctx); dict->line = pl->line; while (pl_skipspace (pl, 1)) { if (!pl_parsekeyvalue (pl, dict, 1)) { PL_Release (dict); return NULL; } } return dict; } VISIBLE plitem_t * PL_GetDictionary (const char *string, hashctx_t **hashctx) { return pl_parseitem (string, hashctx, pl_getdictionary); } static plitem_t * pl_getarray (pldata_t *pl) { plitem_t *array = PL_NewArray (); array->line = pl->line; while (pl_skipspace (pl, 1)) { if (!pl_parsevalue (pl, array, 1)) { PL_Release (array); return NULL; } } return array; } VISIBLE plitem_t * PL_GetArray (const char *string, hashctx_t **hashctx) { return pl_parseitem (string, hashctx, pl_getarray); } static void write_tabs (dstring_t *dstr, int num) { char *tabs = dstring_reservestr (dstr, num); memset (tabs, '\t', num); tabs[num] = 0; } static void write_string_len (dstring_t *dstr, const char *str, int len) { char *dst = dstring_reservestr (dstr, len); memcpy (dst, str, len); dst[len] = 0; } static char to_hex (byte b) { char c = (b & 0xf) + '0'; if (c > '9') c = c - '0' + 'A'; return c; } static void write_binary (dstring_t *dstr, byte *binary, int len) { int i; char *dst = dstring_reservestr (dstr, len * 2); for (i = 0; i < len; i++) { *dst++ = to_hex (binary[i] >> 4); *dst++ = to_hex (binary[i]); } } static void write_string (dstring_t *dstr, const char *str) { const char *s; int len = 0; char *dst; int quoted = 0; for (s = str; *s; s++) { if (is_quotable (*s)) quoted = 1; len++; } if (!quoted) { dst = dstring_reservestr (dstr, len); strcpy (dst, str); return; } // assume worst case of all octal chars plus two quotes. dst = dstring_reservestr (dstr, len * 4 + 2); *dst++= '\"'; while (*str) { if (*str && isascii ((byte) *str) && isprint ((byte) *str) && *str != '\\' && *str != '\"') { *dst++ = *str++; continue; } if (*str) { *dst++ = '\\'; switch (*str) { case '\"': case '\\': *dst++ = *str; break; case '\n': *dst++ = 'n'; break; case '\a': *dst++ = 'a'; break; case '\b': *dst++ = 'b'; break; case '\f': *dst++ = 'f'; break; case '\r': *dst++ = 'r'; break; case '\t': *dst++ = 't'; break; case '\v': *dst++ = 'v'; break; default: *dst++ = '0' + ((((byte) *str) >> 6) & 3); *dst++ = '0' + ((((byte) *str) >> 3) & 7); *dst++ = '0' + (((byte) *str) & 7); break; } str++; } } *dst++ = '\"'; *dst++ = 0; dstr->size = dst - dstr->str; } static void write_item (dstring_t *dstr, const plitem_t *item, int level) { dictkey_t *current; plarray_t *array; pldict_t *dict; plbinary_t *binary; int i; switch (item->type) { case QFDictionary: write_string_len (dstr, "{\n", 2); dict = (pldict_t *) item->data; for (size_t i = 0; i < dict->keys.size; i++) { current = dict->keys.a[i]; write_tabs (dstr, level + 1); write_string (dstr, current->key); write_string_len (dstr, " = ", 3); write_item (dstr, current->value, level + 1); write_string_len (dstr, ";\n", 2); } write_tabs (dstr, level); write_string_len (dstr, "}", 1); break; case QFArray: write_string_len (dstr, "(\n", 2); array = (plarray_t *) item->data; for (i = 0; i < array->numvals; i++) { write_tabs (dstr, level + 1); write_item (dstr, array->values[i], level + 1); if (i < array->numvals - 1) write_string_len (dstr, ",\n", 2); } write_string_len (dstr, "\n", 1); write_tabs (dstr, level); write_string_len (dstr, ")", 1); break; case QFBinary: write_string_len (dstr, "<", 1); binary = (plbinary_t *) item->data; write_binary (dstr, binary->data, binary->size); write_string_len (dstr, ">", 1); break; case QFString: write_string (dstr, item->data); break; default: break; } } VISIBLE char * PL_WritePropertyList (const plitem_t *pl) { dstring_t *dstr = dstring_newstr (); if (pl) { if (!quotable_bitmap[0]) init_quotables (); write_item (dstr, pl, 0); write_string_len (dstr, "\n", 1); } return dstring_freeze (dstr); } VISIBLE pltype_t PL_Type (const plitem_t *item) { return item->type; } VISIBLE int PL_Line (const plitem_t *item) { return item->line; } VISIBLE void PL_Message (plitem_t *messages, const plitem_t *item, const char *fmt, ...) { va_list args; dstring_t *va_str; dstring_t *msg_str; char *msg; va_str = dstring_new (); msg_str = dstring_new (); va_start (args, fmt); dvsprintf (va_str, fmt, args); va_end (args); if (item) { msg = dsprintf (msg_str, "%d: %s", item->line, va_str->str); } else { msg = dsprintf (msg_str, "internal: %s", va_str->str); } PL_A_AddObject (messages, PL_NewString (msg)); dstring_delete (va_str); dstring_delete (msg_str); } static int pl_default_parser (const plfield_t *field, const plitem_t *item, void *data, plitem_t *messages, void *context) { switch (field->type) { case QFDictionary: { *(hashtab_t **)data = ((pldict_t *)item->data)->tab; } return 1; case QFArray: { plarray_t *array = (plarray_t *)item->data; typedef struct DARRAY_TYPE (plitem_t *) arraydata_t; arraydata_t *arraydata = DARRAY_ALLOCFIXED(arraydata_t, array->numvals, malloc); memcpy (arraydata->a, array->values, array->numvals * sizeof (arraydata->a[0])); } return 1; case QFBinary: { plbinary_t *binary = (plbinary_t *)item->data; typedef struct DARRAY_TYPE (byte) bindata_t; bindata_t *bindata = DARRAY_ALLOCFIXED(bindata_t, binary->size, malloc); memcpy (bindata->a, binary->data, binary->size); *(bindata_t **)data = bindata; } return 1; case QFString: *(char **)data = (char *)item->data; return 1; case QFMultiType: break; } PL_Message (messages, 0, "invalid item type: %d", field->type); return 0; } VISIBLE int PL_CheckType (pltype_t field_type, pltype_t item_type) { if (field_type & QFMultiType) { // field_type is a mask of allowed types return field_type & (1 << item_type); } else { // exact match return field_type == item_type; } } VISIBLE void PL_TypeMismatch (plitem_t *messages, const plitem_t *item, const char *name, pltype_t field_type, pltype_t item_type) { const int num_types = sizeof (pl_types) / sizeof (pl_types[0]); if (field_type & QFMultiType) { PL_Message (messages, item, "error: %s is the wrong type. Got %s, expected one of:", name, pl_types[item_type]); field_type &= ~QFMultiType; for (int type = 0; field_type && type < num_types; type++, field_type >>= 1) { if (field_type & 1) { PL_Message (messages, item, " %s", pl_types[type]); } } } else { PL_Message (messages, item, "error: %s is the wrong type. Got %s, expected %s", name, pl_types[item_type], pl_types[field_type]); } } VISIBLE int PL_ParseStruct (const plfield_t *fields, const plitem_t *item, void *data, plitem_t *messages, void *context) { pldict_t *dict = item->data; dictkey_t *current; int result = 1; plparser_t parser; if (item->type != QFDictionary) { PL_Message (messages, item, "error: not a dictionary object"); return 0; } for (size_t i = 0; i < dict->keys.size; i++) { const plfield_t *f; current = dict->keys.a[i]; for (f = fields; f->name; f++) { if (strcmp (f->name, current->key) == 0) { plitem_t *item = current->value; void *flddata = (byte *)data + f->offset; if (f->parser) { parser = f->parser; } else { parser = pl_default_parser; } if (!PL_CheckType (f->type, item->type)) { PL_TypeMismatch (messages, item, current->key, f->type, item->type); result = 0; } else { if (!parser (f, item, flddata, messages, context)) { result = 0; } } break; } } if (!f->name) { PL_Message (messages, item, "error: unknown field '%s'", current->key); result = 0; } } return result; } VISIBLE int PL_ParseArray (const plfield_t *field, const plitem_t *array, void *data, plitem_t *messages, void *context) { int result = 1; plparser_t parser; plarray_t *plarray = (plarray_t *) array->data; plelement_t *element = (plelement_t *) field->data; typedef struct arr_s DARRAY_TYPE(byte) arr_t; arr_t *arr; plfield_t f = { 0, 0, element->type, element->parser, element->data }; if (array->type != QFArray) { PL_Message (messages, array, "error: not an array object"); return 0; } if (f.parser) { parser = f.parser; } else { parser = pl_default_parser; } arr = DARRAY_ALLOCFIXED_OBJ (arr_t, plarray->numvals * element->stride, element->alloc, context); memset (arr->a, 0, arr->size); // the array is allocated using bytes, but need the actual number of // elements in the array arr->size = arr->maxSize = plarray->numvals; for (int i = 0; i < plarray->numvals; i++) { plitem_t *item = plarray->values[i]; void *eledata = &arr->a[i * element->stride]; f.offset = i; if (!PL_CheckType (element->type, item->type)) { char index[16]; snprintf (index, sizeof(index) - 1, "%d", i); index[15] = 0; PL_TypeMismatch (messages, item, index, element->type, item->type); result = 0; } else { if (!parser (&f, item, eledata, messages, context)) { result = 0; } } } *(arr_t **) data = arr; return result; } VISIBLE int PL_ParseLabeledArray (const plfield_t *field, const plitem_t *item, void *data, plitem_t *messages, void *context) { pldict_t *dict = item->data; dictkey_t *current; int result = 1; plparser_t parser; plelement_t *element = (plelement_t *) field->data; typedef struct arr_s DARRAY_TYPE(byte) arr_t; arr_t *arr; plfield_t f = { 0, 0, element->type, element->parser, element->data }; if (item->type != QFDictionary) { PL_Message (messages, item, "error: not a dictionary object"); return 0; } if (f.parser) { parser = f.parser; } else { parser = pl_default_parser; } arr = DARRAY_ALLOCFIXED_OBJ (arr_t, dict->keys.size * element->stride, element->alloc, context); memset (arr->a, 0, arr->size); // the array is allocated using bytes, but need the actual number of // elements in the array arr->size = arr->maxSize = dict->keys.size; for (size_t i = 0; i < dict->keys.size; i++) { current = dict->keys.a[i]; plitem_t *item = current->value; void *eledata = &arr->a[i * element->stride]; f.name = current->key; f.offset = i; if (!PL_CheckType (element->type, item->type)) { char index[16]; snprintf (index, sizeof(index) - 1, "%zd", i); index[15] = 0; PL_TypeMismatch (messages, item, index, element->type, item->type); result = 0; } else { if (!parser (&f, item, eledata, messages, context)) { result = 0; } } } *(arr_t **) data = arr; return result; } VISIBLE int PL_ParseSymtab (const plfield_t *field, const plitem_t *item, void *data, plitem_t *messages, void *context) { pldict_t *dict = item->data; dictkey_t *current; int result = 1; plparser_t parser; __auto_type tab = (hashtab_t *) data; plelement_t *element = (plelement_t *) field->data; plfield_t f = { 0, 0, element->type, element->parser, element->data }; if (item->type != QFDictionary) { PL_Message (messages, item, "error: not a dictionary object"); return 0; } if (f.parser) { parser = f.parser; } else { PL_Message (messages, item, "no parser set"); return 0; } void *obj = element->alloc (context, element->stride); memset (obj, 0, element->stride); for (size_t i = 0; i < dict->keys.size; i++) { current = dict->keys.a[i]; const char *key = current->key; plitem_t *item = current->value; if (!PL_CheckType (element->type, item->type)) { PL_TypeMismatch (messages, item, key, element->type, item->type); result = 0; continue; } f.name = key; if (Hash_Find (tab, key)) { PL_Message (messages, item, "duplicate name"); result = 0; } else { if (!parser (&f, item, obj, messages, context)) { result = 0; } else { Hash_Add (tab, obj); obj = element->alloc (context, element->stride); memset (obj, 0, element->stride); } } } Hash_Free (tab, obj); return result; }