#include #include #include #include #include #include #include #include "vkfielddef.h" #include "vkgen.h" #include "vkstruct.h" @implementation Struct -(string) name { return str_mid(type.strct.tag, 4); } -(void) addToQueue { string name = [self name]; if (!Hash_Find (processed_types, name)) { //printf (" +%s\n", name); Hash_Add (processed_types, (void *) name); [queue addObject: self]; } } -(void) queueFieldTypes { qfot_struct_t *strct =&type.strct; PLItem *field_dict = [parse getObjectForKey:[self name]]; for (int i = 0; i < strct.num_fields; i++) { qfot_var_t *var = &strct.fields[i]; if (field_dict) { PLItem *item = [field_dict getObjectForKey:var.name]; FieldDef *def = [FieldDef fielddef:item struct:self field:var.name]; if (![def searchType]) { continue; } } Type *type = [Type findType:var.type]; [type addToQueue]; } } -(qfot_var_t *)findField:(string) fieldName { for (int i = 0; i < type.strct.num_fields; i++) { qfot_var_t *var = &type.strct.fields[i]; if (var.name == fieldName) { return var; } } return nil; } -(string)sTypeName { string s = "VK_STRUCTURE_TYPE"; string name = str_hold ([self outname]); int length = strlen (name); int start, end, c; for (start = 2; start < length; start = end) { for (end = start + 1; end < length; end++) { c = str_char (name, end); if (c >= 'A' && c <= 'Z') { break; } } s += "_" + str_mid (name, start, end); } str_free (name); return str_upper (s); } -(void) writeTable { PLItem *field_dict = [parse getObjectForKey:[self name]]; PLItem *new_name = [field_dict getObjectForKey:".name"]; Array *field_defs = [Array array]; int have_sType = 0; if ([parse string] == "skip") { return; } if (new_name) { outname = str_hold ([new_name string]); } for (int i = 0; i < type.strct.num_fields; i++) { qfot_var_t *field = &type.strct.fields[i]; if (field.name == "sType") { have_sType = 1; } } if (field_dict) { PLItem *field_keys = [field_dict allKeys]; for (int i = [field_keys count]; i-- > 0; ) { string field_name = [[field_keys getObjectAtIndex:i] string]; if (str_mid(field_name, 0, 1) == ".") { continue; } PLItem *field_item = [field_dict getObjectForKey:field_name]; FieldDef *field_def = [FieldDef fielddef:field_item struct:self field:field_name]; [field_defs addObject: field_def]; } } else { for (int i = 0; i < type.strct.num_fields; i++) { qfot_var_t *field = &type.strct.fields[i]; if (field.name == "sType" || field.name == "pNext") { continue; } FieldDef *field_def = [FieldDef fielddef:nil struct:self field:field.name]; [field_defs addObject: field_def]; } } for (int i = [field_defs count]; i-- > 0; ) { FieldDef *field_def = [field_defs objectAtIndex:i]; [field_def writeParseData]; } fprintf (output_file, "static plfield_t %s_fields[] = {\n", [self outname]); for (int i = [field_defs count]; i-- > 0; ) { FieldDef *field_def = [field_defs objectAtIndex:i]; [field_def writeField]; } fprintf (output_file, "\t{ }\n"); fprintf (output_file, "};\n"); fprintf (header_file, "int parse_%s (const plfield_t *field," " const plitem_t *item, void *data, plitem_t *messages," " void *context);\n", [self outname]); fprintf (output_file, "int parse_%s (const plfield_t *field," " const plitem_t *item, void *data, plitem_t *messages," " void *context)\n", [self outname]); fprintf (output_file, "{\n"); if (have_sType) { fprintf (output_file, "\t((%s *) data)->sType", [self outname]); fprintf (output_file, " = %s;\n", [self sTypeName]); } fprintf (output_file, "\tif (PL_Type (item) == QFString\n" "\t\t&& !(item = parse_reference (item, \"%s\", messages, context))) {\n" "\t\treturn 0;\n" "\t}\n" "\treturn PL_ParseStruct (%s_fields, item, data, messages," " context);\n", [self outname], [self outname]); fprintf (output_file, "}\n"); fprintf (output_file, "static exprsym_t %s_symbols[] = {\n", [self outname]); if (field_defs) { PLItem *field_def; qfot_var_t *field; for (int i = [field_defs count]; i-- > 0; ) { FieldDef *field_def = [field_defs objectAtIndex:i]; [field_def writeSymbol]; } } else { for (int i = 0; i < type.strct.num_fields; i++) { qfot_var_t *field = &type.strct.fields[i]; if (field.name == "sType" || field.name == "pNext") { continue; } Type *field_type = [Type findType: field.type]; fprintf (output_file, "\t{\"%s\", &%s, (void *) field_offset (%s, %s)},\n", field.name, [field_type cexprType], [self outname], field.name); } } fprintf (output_file, "\t{ }\n"); fprintf (output_file, "};\n"); fprintf (output_file, "static exprtab_t %s_symtab = {\n", [self outname]); fprintf (output_file, "\t%s_symbols,\n", [self outname]); fprintf (output_file, "};\n"); fprintf (output_file, "exprtype_t %s_type = {\n", [self outname]); fprintf (output_file, "\t\"%s\",\n", [self outname]); fprintf (output_file, "\tsizeof (%s),\n", [self outname]); fprintf (output_file, "\tcexpr_struct_binops,\n"); fprintf (output_file, "\t0,\n"); fprintf (output_file, "\t&%s_symtab,\n", [self outname]); fprintf (output_file, "};\n"); fprintf (output_file, "\n"); fprintf (header_file, "extern exprtype_t %s_type;\n", [self outname]); } -(void) writeSymtabInit { PLItem *field_dict = [parse getObjectForKey:[self outname]]; if ([parse string] == "skip") { return; } fprintf (output_file, "\tcexpr_init_symtab (&%s_symtab, context);\n", [self outname]); } -(void) writeSymtabEntry { } -(string) outname { if (outname) { return outname; } return [self name]; } -(string) cexprType { return [self outname] + "_type"; } -(string) parseType { return "QFMultiType | (1 << QFString) | (1 << QFDictionary)"; } -(string) parseFunc { return "parse_" + [self outname]; } -(string) parseData { return "0"; } @end