/* * Copyright 2014 Google Inc. All rights reserved. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ // independent from idl_parser, since this code is not needed for most clients #include "flatbuffers/flatbuffers.h" #include "flatbuffers/flexbuffers.h" #include "flatbuffers/idl.h" #include "flatbuffers/util.h" namespace flatbuffers { struct PrintScalarTag {}; struct PrintPointerTag {}; template struct PrintTag { typedef PrintScalarTag type; }; template<> struct PrintTag { typedef PrintPointerTag type; }; struct JsonPrinter { // If indentation is less than 0, that indicates we don't want any newlines // either. void AddNewLine() { if (opts.indent_step >= 0) text += '\n'; } void AddIndent(int ident) { text.append(ident, ' '); } int Indent() const { return std::max(opts.indent_step, 0); } // Output an identifier with or without quotes depending on strictness. void OutputIdentifier(const std::string &name) { if (opts.strict_json) text += '\"'; text += name; if (opts.strict_json) text += '\"'; } // Print (and its template specialization below for pointers) generate text // for a single FlatBuffer value into JSON format. // The general case for scalars: template bool PrintScalar(T val, const Type &type, int /*indent*/) { if (IsBool(type.base_type)) { text += val != 0 ? "true" : "false"; return true; // done } if (opts.output_enum_identifiers && type.enum_def) { const auto &enum_def = *type.enum_def; if (auto ev = enum_def.ReverseLookup(static_cast(val))) { text += '\"'; text += ev->name; text += '\"'; return true; // done } else if (val && enum_def.attributes.Lookup("bit_flags")) { const auto entry_len = text.length(); const auto u64 = static_cast(val); uint64_t mask = 0; text += '\"'; for (auto it = enum_def.Vals().begin(), e = enum_def.Vals().end(); it != e; ++it) { auto f = (*it)->GetAsUInt64(); if (f & u64) { mask |= f; text += (*it)->name; text += ' '; } } // Don't slice if (u64 != mask) if (mask && (u64 == mask)) { text[text.length() - 1] = '\"'; return true; // done } text.resize(entry_len); // restore } // print as numeric value } text += NumToString(val); return true; } void AddComma() { if (!opts.protobuf_ascii_alike) text += ','; } // Print a vector or an array of JSON values, comma seperated, wrapped in // "[]". template bool PrintContainer(PrintScalarTag, const Container &c, size_t size, const Type &type, int indent, const uint8_t *) { const auto elem_indent = indent + Indent(); text += '['; AddNewLine(); for (uoffset_t i = 0; i < size; i++) { if (i) { AddComma(); AddNewLine(); } AddIndent(elem_indent); if (!PrintScalar(c[i], type, elem_indent)) { return false; } } AddNewLine(); AddIndent(indent); text += ']'; return true; } // Print a vector or an array of JSON values, comma seperated, wrapped in // "[]". template bool PrintContainer(PrintPointerTag, const Container &c, size_t size, const Type &type, int indent, const uint8_t *prev_val) { const auto is_struct = IsStruct(type); const auto elem_indent = indent + Indent(); text += '['; AddNewLine(); for (uoffset_t i = 0; i < size; i++) { if (i) { AddComma(); AddNewLine(); } AddIndent(elem_indent); auto ptr = is_struct ? reinterpret_cast( c.Data() + type.struct_def->bytesize * i) : c[i]; if (!PrintOffset(ptr, type, elem_indent, prev_val, static_cast(i))) { return false; } } AddNewLine(); AddIndent(indent); text += ']'; return true; } template bool PrintVector(const void *val, const Type &type, int indent, const uint8_t *prev_val) { typedef Vector Container; typedef typename PrintTag::type tag; auto &vec = *reinterpret_cast(val); return PrintContainer(tag(), vec, vec.size(), type, indent, prev_val); } // Print an array a sequence of JSON values, comma separated, wrapped in "[]". template bool PrintArray(const void *val, size_t size, const Type &type, int indent) { typedef Array Container; typedef typename PrintTag::type tag; auto &arr = *reinterpret_cast(val); return PrintContainer(tag(), arr, size, type, indent, nullptr); } bool PrintOffset(const void *val, const Type &type, int indent, const uint8_t *prev_val, soffset_t vector_index) { switch (type.base_type) { case BASE_TYPE_UNION: { // If this assert hits, you have an corrupt buffer, a union type field // was not present or was out of range. FLATBUFFERS_ASSERT(prev_val); auto union_type_byte = *prev_val; // Always a uint8_t. if (vector_index >= 0) { auto type_vec = reinterpret_cast *>( prev_val + ReadScalar(prev_val)); union_type_byte = type_vec->Get(static_cast(vector_index)); } auto enum_val = type.enum_def->ReverseLookup(union_type_byte, true); if (enum_val) { return PrintOffset(val, enum_val->union_type, indent, nullptr, -1); } else { return false; } } case BASE_TYPE_STRUCT: return GenStruct(*type.struct_def, reinterpret_cast(val), indent); case BASE_TYPE_STRING: { auto s = reinterpret_cast(val); return EscapeString(s->c_str(), s->size(), &text, opts.allow_non_utf8, opts.natural_utf8); } case BASE_TYPE_VECTOR: { const auto vec_type = type.VectorType(); // Call PrintVector above specifically for each element type: // clang-format off switch (vec_type.base_type) { #define FLATBUFFERS_TD(ENUM, IDLTYPE, CTYPE, ...) \ case BASE_TYPE_ ## ENUM: \ if (!PrintVector( \ val, vec_type, indent, prev_val)) { \ return false; \ } \ break; FLATBUFFERS_GEN_TYPES(FLATBUFFERS_TD) #undef FLATBUFFERS_TD } // clang-format on return true; } case BASE_TYPE_ARRAY: { const auto vec_type = type.VectorType(); // Call PrintArray above specifically for each element type: // clang-format off switch (vec_type.base_type) { #define FLATBUFFERS_TD(ENUM, IDLTYPE, CTYPE, ...) \ case BASE_TYPE_ ## ENUM: \ if (!PrintArray( \ val, type.fixed_length, vec_type, indent)) { \ return false; \ } \ break; FLATBUFFERS_GEN_TYPES_SCALAR(FLATBUFFERS_TD) // Arrays of scalars or structs are only possible. FLATBUFFERS_GEN_TYPES_POINTER(FLATBUFFERS_TD) #undef FLATBUFFERS_TD case BASE_TYPE_ARRAY: FLATBUFFERS_ASSERT(0); } // clang-format on return true; } default: FLATBUFFERS_ASSERT(0); return false; } } template static T GetFieldDefault(const FieldDef &fd) { T val; auto check = StringToNumber(fd.value.constant.c_str(), &val); (void)check; FLATBUFFERS_ASSERT(check); return val; } // Generate text for a scalar field. template bool GenField(const FieldDef &fd, const Table *table, bool fixed, int indent) { return PrintScalar( fixed ? reinterpret_cast(table)->GetField( fd.value.offset) : table->GetField(fd.value.offset, GetFieldDefault(fd)), fd.value.type, indent); } // Generate text for non-scalar field. bool GenFieldOffset(const FieldDef &fd, const Table *table, bool fixed, int indent, const uint8_t *prev_val) { const void *val = nullptr; if (fixed) { // The only non-scalar fields in structs are structs or arrays. FLATBUFFERS_ASSERT(IsStruct(fd.value.type) || IsArray(fd.value.type)); val = reinterpret_cast(table)->GetStruct( fd.value.offset); } else if (fd.flexbuffer) { auto vec = table->GetPointer *>(fd.value.offset); auto root = flexbuffers::GetRoot(vec->data(), vec->size()); root.ToString(true, opts.strict_json, text); return true; } else if (fd.nested_flatbuffer) { auto vec = table->GetPointer *>(fd.value.offset); auto root = GetRoot(vec->data()); return GenStruct(*fd.nested_flatbuffer, root, indent); } else { val = IsStruct(fd.value.type) ? table->GetStruct(fd.value.offset) : table->GetPointer(fd.value.offset); } return PrintOffset(val, fd.value.type, indent, prev_val, -1); } // Generate text for a struct or table, values separated by commas, indented, // and bracketed by "{}" bool GenStruct(const StructDef &struct_def, const Table *table, int indent) { text += '{'; int fieldout = 0; const uint8_t *prev_val = nullptr; const auto elem_indent = indent + Indent(); for (auto it = struct_def.fields.vec.begin(); it != struct_def.fields.vec.end(); ++it) { FieldDef &fd = **it; auto is_present = struct_def.fixed || table->CheckField(fd.value.offset); auto output_anyway = (opts.output_default_scalars_in_json || fd.key) && IsScalar(fd.value.type.base_type) && !fd.deprecated; if (is_present || output_anyway) { if (fieldout++) { AddComma(); } AddNewLine(); AddIndent(elem_indent); OutputIdentifier(fd.name); if (!opts.protobuf_ascii_alike || (fd.value.type.base_type != BASE_TYPE_STRUCT && fd.value.type.base_type != BASE_TYPE_VECTOR)) text += ':'; text += ' '; // clang-format off switch (fd.value.type.base_type) { #define FLATBUFFERS_TD(ENUM, IDLTYPE, CTYPE, ...) \ case BASE_TYPE_ ## ENUM: \ if (!GenField(fd, table, struct_def.fixed, elem_indent)) { \ return false; \ } \ break; FLATBUFFERS_GEN_TYPES_SCALAR(FLATBUFFERS_TD) #undef FLATBUFFERS_TD // Generate drop-thru case statements for all pointer types: #define FLATBUFFERS_TD(ENUM, ...) \ case BASE_TYPE_ ## ENUM: FLATBUFFERS_GEN_TYPES_POINTER(FLATBUFFERS_TD) FLATBUFFERS_GEN_TYPE_ARRAY(FLATBUFFERS_TD) #undef FLATBUFFERS_TD if (!GenFieldOffset(fd, table, struct_def.fixed, elem_indent, prev_val)) { return false; } break; } // clang-format on // Track prev val for use with union types. if (struct_def.fixed) { prev_val = reinterpret_cast(table) + fd.value.offset; } else { prev_val = table->GetAddressOf(fd.value.offset); } } } AddNewLine(); AddIndent(indent); text += '}'; return true; } JsonPrinter(const Parser &parser, std::string &dest) : opts(parser.opts), text(dest) { text.reserve(1024); // Reduce amount of inevitable reallocs. } const IDLOptions &opts; std::string &text; }; static bool GenerateTextImpl(const Parser &parser, const Table *table, const StructDef &struct_def, std::string *_text) { JsonPrinter printer(parser, *_text); if (!printer.GenStruct(struct_def, table, 0)) { return false; } printer.AddNewLine(); return true; } // Generate a text representation of a flatbuffer in JSON format. bool GenerateTextFromTable(const Parser &parser, const void *table, const std::string &table_name, std::string *_text) { auto struct_def = parser.LookupStruct(table_name); if (struct_def == nullptr) { return false; } auto root = static_cast(table); return GenerateTextImpl(parser, root, *struct_def, _text); } // Generate a text representation of a flatbuffer in JSON format. bool GenerateText(const Parser &parser, const void *flatbuffer, std::string *_text) { FLATBUFFERS_ASSERT(parser.root_struct_def_); // call SetRootType() auto root = parser.opts.size_prefixed ? GetSizePrefixedRoot
(flatbuffer) : GetRoot
(flatbuffer); return GenerateTextImpl(parser, root, *parser.root_struct_def_, _text); } static std::string TextFileName(const std::string &path, const std::string &file_name) { return path + file_name + ".json"; } bool GenerateTextFile(const Parser &parser, const std::string &path, const std::string &file_name) { if (parser.opts.use_flexbuffers) { std::string json; parser.flex_root_.ToString(true, parser.opts.strict_json, json); return flatbuffers::SaveFile(TextFileName(path, file_name).c_str(), json.c_str(), json.size(), true); } if (!parser.builder_.GetSize() || !parser.root_struct_def_) return true; std::string text; if (!GenerateText(parser, parser.builder_.GetBufferPointer(), &text)) { return false; } return flatbuffers::SaveFile(TextFileName(path, file_name).c_str(), text, false); } std::string TextMakeRule(const Parser &parser, const std::string &path, const std::string &file_name) { if (!parser.builder_.GetSize() || !parser.root_struct_def_) return ""; std::string filebase = flatbuffers::StripPath(flatbuffers::StripExtension(file_name)); std::string make_rule = TextFileName(path, filebase) + ": " + file_name; auto included_files = parser.GetIncludedFilesRecursive(parser.root_struct_def_->file); for (auto it = included_files.begin(); it != included_files.end(); ++it) { make_rule += " " + *it; } return make_rule; } } // namespace flatbuffers