int load_game(char * path, settings * game_settings){ FILE * fp; mxml_node_t *xml_tree; mxml_node_t *xml_node; char row_node[17] = "game/board/row_x"; char row[9] = { 0 }; cord c; fp = fopen(path, "r"); if (fp == NULL) return FALSE; xml_tree = mxmlLoadFile(NULL, fp, MXML_OPAQUE_CALLBACK); fclose(fp); xml_node = mxmlFindPath(xml_tree, "game/next_turn"); game_settings->next = (xml_node == NULL) ? WHITE : string_to_color(mxmlGetOpaque(xml_node)); xml_node = mxmlFindPath(xml_tree, "game/game_mode"); game_settings->mode = (xml_node == NULL) ? PLAYER_VS_COMP : atoi(mxmlGetOpaque(xml_node)); if (game_settings->mode == PLAYER_VS_COMP){ xml_node = mxmlFindPath(xml_tree, "game/difficulty"); game_settings->minimax_depth = (xml_node == NULL) ? 1 : atoi(mxmlGetOpaque(xml_node)); xml_node = mxmlFindPath(xml_tree, "game/user_color"); game_settings->color = (xml_node == NULL) ? WHITE : string_to_color(mxmlGetOpaque(xml_node)); } for (int y = 8; y > 0; y--) { row_node[15] = '0' + y; xml_node = mxmlFindPath(xml_tree, row_node); strcpy(row, mxmlGetOpaque(xml_node)); for (int x = 0; x < 8; x++) { c.x = x; c.y = y - 1; board_piece(game_settings->board, c) = (row[x] == '_') ? EMPTY : row[x]; } } //mxmlDelete(xml_tree); return TRUE; }
int /* O - Exit status */ main(int argc, /* I - Number of command-line args */ char* argv[]) { /* I - Command-line args */ int i; /* Looping var */ FILE* fp; /* File to read */ int fd; /* File descriptor */ mxml_node_t* tree, /* XML tree */ *node; /* Node which should be in test.xml */ mxml_index_t* ind; /* XML index */ char buffer[16384]; /* Save string */ static const char* types[] = /* Strings for node types */ { "MXML_ELEMENT", "MXML_INTEGER", "MXML_OPAQUE", "MXML_REAL", "MXML_TEXT" }; /* * Check arguments... */ if (argc != 2) { fputs("Usage: testmxml filename.xml\n", stderr); return (1); } /* * Test the basic functionality... */ tree = mxmlNewElement(MXML_NO_PARENT, "element"); if (!tree) { fputs("ERROR: No parent node in basic test!\n", stderr); return (1); } if (tree->type != MXML_ELEMENT) { fprintf(stderr, "ERROR: Parent has type %s (%d), expected MXML_ELEMENT!\n", tree->type < MXML_ELEMENT || tree->type > MXML_TEXT ? "UNKNOWN" : types[tree->type], tree->type); mxmlDelete(tree); return (1); } if (strcmp(tree->value.element.name, "element")) { fprintf(stderr, "ERROR: Parent value is \"%s\", expected \"element\"!\n", tree->value.element.name); mxmlDelete(tree); return (1); } mxmlNewInteger(tree, 123); mxmlNewOpaque(tree, "opaque"); mxmlNewReal(tree, 123.4f); mxmlNewText(tree, 1, "text"); mxmlLoadString(tree, "<group type='string'>string string string</group>", MXML_NO_CALLBACK); mxmlLoadString(tree, "<group type='integer'>1 2 3</group>", MXML_INTEGER_CALLBACK); mxmlLoadString(tree, "<group type='real'>1.0 2.0 3.0</group>", MXML_REAL_CALLBACK); mxmlLoadString(tree, "<group>opaque opaque opaque</group>", MXML_OPAQUE_CALLBACK); mxmlLoadString(tree, "<foo><bar><one><two>value<two>value2</two></two></one>" "</bar></foo>", MXML_OPAQUE_CALLBACK); node = tree->child; if (!node) { fputs("ERROR: No first child node in basic test!\n", stderr); mxmlDelete(tree); return (1); } if (node->type != MXML_INTEGER) { fprintf(stderr, "ERROR: First child has type %s (%d), expected MXML_INTEGER!\n", node->type < MXML_ELEMENT || node->type > MXML_TEXT ? "UNKNOWN" : types[node->type], node->type); mxmlDelete(tree); return (1); } if (node->value.integer != 123) { fprintf(stderr, "ERROR: First child value is %d, expected 123!\n", node->value.integer); mxmlDelete(tree); return (1); } node = node->next; if (!node) { fputs("ERROR: No second child node in basic test!\n", stderr); mxmlDelete(tree); return (1); } if (node->type != MXML_OPAQUE) { fprintf(stderr, "ERROR: Second child has type %s (%d), expected MXML_OPAQUE!\n", node->type < MXML_ELEMENT || node->type > MXML_TEXT ? "UNKNOWN" : types[node->type], node->type); mxmlDelete(tree); return (1); } if (!node->value.opaque || strcmp(node->value.opaque, "opaque")) { fprintf(stderr, "ERROR: Second child value is \"%s\", expected \"opaque\"!\n", node->value.opaque ? node->value.opaque : "(null)"); mxmlDelete(tree); return (1); } node = node->next; if (!node) { fputs("ERROR: No third child node in basic test!\n", stderr); mxmlDelete(tree); return (1); } if (node->type != MXML_REAL) { fprintf(stderr, "ERROR: Third child has type %s (%d), expected MXML_REAL!\n", node->type < MXML_ELEMENT || node->type > MXML_TEXT ? "UNKNOWN" : types[node->type], node->type); mxmlDelete(tree); return (1); } if (node->value.real != 123.4f) { fprintf(stderr, "ERROR: Third child value is %f, expected 123.4!\n", node->value.real); mxmlDelete(tree); return (1); } node = node->next; if (!node) { fputs("ERROR: No fourth child node in basic test!\n", stderr); mxmlDelete(tree); return (1); } if (node->type != MXML_TEXT) { fprintf(stderr, "ERROR: Fourth child has type %s (%d), expected MXML_TEXT!\n", node->type < MXML_ELEMENT || node->type > MXML_TEXT ? "UNKNOWN" : types[node->type], node->type); mxmlDelete(tree); return (1); } if (!node->value.text.whitespace || !node->value.text.string || strcmp(node->value.text.string, "text")) { fprintf(stderr, "ERROR: Fourth child value is %d,\"%s\", expected 1,\"text\"!\n", node->value.text.whitespace, node->value.text.string ? node->value.text.string : "(null)"); mxmlDelete(tree); return (1); } for (i = 0; i < 4; i ++) { node = node->next; if (!node) { fprintf(stderr, "ERROR: No group #%d child node in basic test!\n", i + 1); mxmlDelete(tree); return (1); } if (node->type != MXML_ELEMENT) { fprintf(stderr, "ERROR: Group child #%d has type %s (%d), expected MXML_ELEMENT!\n", i + 1, node->type < MXML_ELEMENT || node->type > MXML_TEXT ? "UNKNOWN" : types[node->type], node->type); mxmlDelete(tree); return (1); } } /* * Test mxmlFindPath... */ node = mxmlFindPath(tree, "*/two"); if (!node) { fputs("ERROR: Unable to find value for \"*/two\".\n", stderr); mxmlDelete(tree); return (1); } else if (node->type != MXML_OPAQUE || strcmp(node->value.opaque, "value")) { fputs("ERROR: Bad value for \"*/two\".\n", stderr); mxmlDelete(tree); return (1); } node = mxmlFindPath(tree, "foo/*/two"); if (!node) { fputs("ERROR: Unable to find value for \"foo/*/two\".\n", stderr); mxmlDelete(tree); return (1); } else if (node->type != MXML_OPAQUE || strcmp(node->value.opaque, "value")) { fputs("ERROR: Bad value for \"foo/*/two\".\n", stderr); mxmlDelete(tree); return (1); } node = mxmlFindPath(tree, "foo/bar/one/two"); if (!node) { fputs("ERROR: Unable to find value for \"foo/bar/one/two\".\n", stderr); mxmlDelete(tree); return (1); } else if (node->type != MXML_OPAQUE || strcmp(node->value.opaque, "value")) { fputs("ERROR: Bad value for \"foo/bar/one/two\".\n", stderr); mxmlDelete(tree); return (1); } /* * Test indices... */ ind = mxmlIndexNew(tree, NULL, NULL); if (!ind) { fputs("ERROR: Unable to create index of all nodes!\n", stderr); mxmlDelete(tree); return (1); } if (ind->num_nodes != 10) { fprintf(stderr, "ERROR: Index of all nodes contains %d " "nodes; expected 10!\n", ind->num_nodes); mxmlIndexDelete(ind); mxmlDelete(tree); return (1); } mxmlIndexReset(ind); if (!mxmlIndexFind(ind, "group", NULL)) { fputs("ERROR: mxmlIndexFind for \"group\" failed!\n", stderr); mxmlIndexDelete(ind); mxmlDelete(tree); return (1); } mxmlIndexDelete(ind); ind = mxmlIndexNew(tree, "group", NULL); if (!ind) { fputs("ERROR: Unable to create index of groups!\n", stderr); mxmlDelete(tree); return (1); } if (ind->num_nodes != 4) { fprintf(stderr, "ERROR: Index of groups contains %d " "nodes; expected 4!\n", ind->num_nodes); mxmlIndexDelete(ind); mxmlDelete(tree); return (1); } mxmlIndexReset(ind); if (!mxmlIndexEnum(ind)) { fputs("ERROR: mxmlIndexEnum failed!\n", stderr); mxmlIndexDelete(ind); mxmlDelete(tree); return (1); } mxmlIndexDelete(ind); ind = mxmlIndexNew(tree, NULL, "type"); if (!ind) { fputs("ERROR: Unable to create index of type attributes!\n", stderr); mxmlDelete(tree); return (1); } if (ind->num_nodes != 3) { fprintf(stderr, "ERROR: Index of type attributes contains %d " "nodes; expected 3!\n", ind->num_nodes); mxmlIndexDelete(ind); mxmlDelete(tree); return (1); } mxmlIndexReset(ind); if (!mxmlIndexFind(ind, NULL, "string")) { fputs("ERROR: mxmlIndexFind for \"string\" failed!\n", stderr); mxmlIndexDelete(ind); mxmlDelete(tree); return (1); } mxmlIndexDelete(ind); ind = mxmlIndexNew(tree, "group", "type"); if (!ind) { fputs("ERROR: Unable to create index of elements and attributes!\n", stderr); mxmlDelete(tree); return (1); } if (ind->num_nodes != 3) { fprintf(stderr, "ERROR: Index of elements and attributes contains %d " "nodes; expected 3!\n", ind->num_nodes); mxmlIndexDelete(ind); mxmlDelete(tree); return (1); } mxmlIndexReset(ind); if (!mxmlIndexFind(ind, "group", "string")) { fputs("ERROR: mxmlIndexFind for \"string\" failed!\n", stderr); mxmlIndexDelete(ind); mxmlDelete(tree); return (1); } mxmlIndexDelete(ind); /* * Check the mxmlDelete() works properly... */ for (i = 0; i < 9; i ++) { if (tree->child) { mxmlDelete(tree->child); } else { fprintf(stderr, "ERROR: Child pointer prematurely NULL on child #%d\n", i + 1); mxmlDelete(tree); return (1); } } if (tree->child) { fputs("ERROR: Child pointer not NULL after deleting all children!\n", stderr); return (1); } if (tree->last_child) { fputs("ERROR: Last child pointer not NULL after deleting all children!\n", stderr); return (1); } mxmlDelete(tree); /* * Open the file... */ if (argv[1][0] == '<') { tree = mxmlLoadString(NULL, argv[1], type_cb); } else if ((fp = fopen(argv[1], "rb")) == NULL) { perror(argv[1]); return (1); } else { /* * Read the file... */ tree = mxmlLoadFile(NULL, fp, type_cb); fclose(fp); } if (!tree) { fputs("Unable to read XML file!\n", stderr); return (1); } if (!strcmp(argv[1], "test.xml")) { /* * Verify that mxmlFindElement() and indirectly mxmlWalkNext() work * properly... */ if ((node = mxmlFindElement(tree, tree, "choice", NULL, NULL, MXML_DESCEND)) == NULL) { fputs("Unable to find first <choice> element in XML tree!\n", stderr); mxmlDelete(tree); return (1); } if (!mxmlFindElement(node, tree, "choice", NULL, NULL, MXML_NO_DESCEND)) { fputs("Unable to find second <choice> element in XML tree!\n", stderr); mxmlDelete(tree); return (1); } } /* * Print the XML tree... */ mxmlSaveFile(tree, stdout, whitespace_cb); /* * Save the XML tree to a string and print it... */ if (mxmlSaveString(tree, buffer, sizeof(buffer), whitespace_cb) > 0) { fputs(buffer, stderr); } /* * Delete the tree... */ mxmlDelete(tree); /* * Read from/write to file descriptors... */ if (argv[1][0] != '<') { /* * Open the file again... */ if ((fd = open(argv[1], O_RDONLY | O_BINARY)) < 0) { perror(argv[1]); return (1); } /* * Read the file... */ tree = mxmlLoadFd(NULL, fd, type_cb); close(fd); /* * Create filename.xmlfd... */ snprintf(buffer, sizeof(buffer), "%sfd", argv[1]); if ((fd = open(buffer, O_WRONLY | O_CREAT | O_TRUNC | O_BINARY, 0666)) < 0) { perror(buffer); mxmlDelete(tree); return (1); } /* * Write the file... */ mxmlSaveFd(tree, fd, whitespace_cb); close(fd); /* * Delete the tree... */ mxmlDelete(tree); } /* * Test SAX methods... */ memset(event_counts, 0, sizeof(event_counts)); if (argv[1][0] == '<') { mxmlSAXLoadString(NULL, argv[1], type_cb, sax_cb, NULL); } else if ((fp = fopen(argv[1], "rb")) == NULL) { perror(argv[1]); return (1); } else { /* * Read the file... */ mxmlSAXLoadFile(NULL, fp, type_cb, sax_cb, NULL); fclose(fp); } if (!strcmp(argv[1], "test.xml")) { if (event_counts[MXML_SAX_CDATA] != 1) { fprintf(stderr, "MXML_SAX_CDATA seen %d times, expected 1 times!\n", event_counts[MXML_SAX_CDATA]); return (1); } if (event_counts[MXML_SAX_COMMENT] != 1) { fprintf(stderr, "MXML_SAX_COMMENT seen %d times, expected 1 times!\n", event_counts[MXML_SAX_COMMENT]); return (1); } if (event_counts[MXML_SAX_DATA] != 60) { fprintf(stderr, "MXML_SAX_DATA seen %d times, expected 60 times!\n", event_counts[MXML_SAX_DATA]); return (1); } if (event_counts[MXML_SAX_DIRECTIVE] != 1) { fprintf(stderr, "MXML_SAX_DIRECTIVE seen %d times, expected 1 times!\n", event_counts[MXML_SAX_DIRECTIVE]); return (1); } if (event_counts[MXML_SAX_ELEMENT_CLOSE] != 20) { fprintf(stderr, "MXML_SAX_ELEMENT_CLOSE seen %d times, expected 20 times!\n", event_counts[MXML_SAX_ELEMENT_CLOSE]); return (1); } if (event_counts[MXML_SAX_ELEMENT_OPEN] != 20) { fprintf(stderr, "MXML_SAX_ELEMENT_OPEN seen %d times, expected 20 times!\n", event_counts[MXML_SAX_ELEMENT_OPEN]); return (1); } } /* * Return... */ return (0); }