/*
* 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/idl.h"
#include "flatbuffers/util.h"
#include "flatbuffers/code_generators.h"
#if defined(FLATBUFFERS_CPP98_STL)
#include <cctype>
#endif // defined(FLATBUFFERS_CPP98_STL)
namespace flatbuffers {
// Convert an underscore_based_indentifier in to camelCase.
// Also uppercases the first character if first is true.
std::string MakeCamel(const std::string &in, bool first) {
std::string s;
for (size_t i = 0; i < in.length(); i++) {
if (!i && first)
s += static_cast<char>(toupper(in[0]));
else if (in[i] == '_' && i + 1 < in.length())
s += static_cast<char>(toupper(in[++i]));
else
s += in[i];
}
return s;
}
// These arrays need to correspond to the IDLOptions::k enum.
struct LanguageParameters {
IDLOptions::Language language;
// Whether function names in the language typically start with uppercase.
bool first_camel_upper;
std::string file_extension;
std::string string_type;
std::string bool_type;
std::string open_curly;
std::string accessor_type;
std::string const_decl;
std::string unsubclassable_decl;
std::string enum_decl;
std::string enum_separator;
std::string getter_prefix;
std::string getter_suffix;
std::string inheritance_marker;
std::string namespace_ident;
std::string namespace_begin;
std::string namespace_end;
std::string set_bb_byteorder;
std::string get_bb_position;
std::string get_fbb_offset;
std::string accessor_prefix;
std::string accessor_prefix_static;
std::string optional_suffix;
std::string includes;
std::string class_annotation;
CommentConfig comment_config;
};
const LanguageParameters& GetLangParams(IDLOptions::Language lang) {
static LanguageParameters language_parameters[] = {
{
IDLOptions::kJava,
false,
".java",
"String",
"boolean ",
" {\n",
"class ",
" final ",
"final ",
"final class ",
";\n",
"()",
"",
" extends ",
"package ",
";",
"",
"_bb.order(ByteOrder.LITTLE_ENDIAN); ",
"position()",
"offset()",
"",
"",
"",
"import java.nio.*;\nimport java.lang.*;\nimport java.util.*;\nimport com.google.flatbuffers.*;\n",
"\n@SuppressWarnings(\"unused\")\n",
{
"/**",
" *",
" */",
},
},
{
IDLOptions::kCSharp,
true,
".cs",
"string",
"bool ",
"\n{\n",
"struct ",
" readonly ",
"",
"enum ",
",\n",
" { get",
"} ",
" : ",
"namespace ",
"\n{",
"\n}\n",
"",
"Position",
"Offset",
"__p.",
"Table.",
"?",
"using global::System;\nusing global::FlatBuffers;\n\n",
"",
{
nullptr,
"///",
nullptr,
},
},
};
if (lang == IDLOptions::kJava) {
return language_parameters[0];
} else {
assert(lang == IDLOptions::kCSharp);
return language_parameters[1];
}
}
namespace general {
class GeneralGenerator : public BaseGenerator {
public:
GeneralGenerator(const Parser &parser, const std::string &path,
const std::string &file_name)
: BaseGenerator(parser, path, file_name, "", "."),
lang_(GetLangParams(parser_.opts.lang)),
cur_name_space_( nullptr ) {
}
GeneralGenerator &operator=(const GeneralGenerator &);
bool generate() {
std::string one_file_code;
cur_name_space_ = parser_.current_namespace_;
for (auto it = parser_.enums_.vec.begin(); it != parser_.enums_.vec.end();
++it) {
std::string enumcode;
auto &enum_def = **it;
if (!parser_.opts.one_file)
cur_name_space_ = enum_def.defined_namespace;
GenEnum(enum_def, &enumcode);
if (parser_.opts.one_file) {
one_file_code += enumcode;
} else {
if (!SaveType(enum_def.name, *enum_def.defined_namespace,
enumcode, false)) return false;
}
}
for (auto it = parser_.structs_.vec.begin();
it != parser_.structs_.vec.end(); ++it) {
std::string declcode;
auto &struct_def = **it;
if (!parser_.opts.one_file)
cur_name_space_ = struct_def.defined_namespace;
GenStruct(struct_def, &declcode);
if (parser_.opts.one_file) {
one_file_code += declcode;
} else {
if (!SaveType(struct_def.name, *struct_def.defined_namespace,
declcode, true)) return false;
}
}
if (parser_.opts.one_file) {
return SaveType(file_name_, *parser_.current_namespace_,
one_file_code, true);
}
return true;
}
// Save out the generated code for a single class while adding
// declaration boilerplate.
bool SaveType(const std::string &defname, const Namespace &ns,
const std::string &classcode, bool needs_includes) {
if (!classcode.length()) return true;
std::string code;
if (lang_.language == IDLOptions::kCSharp) {
code = "// <auto-generated>\n"
"// " + std::string(FlatBuffersGeneratedWarning()) + "\n"
"// </auto-generated>\n\n";
} else {
code = "// " + std::string(FlatBuffersGeneratedWarning()) + "\n\n";
}
std::string namespace_name = FullNamespace(".", ns);
if (!namespace_name.empty()) {
code += lang_.namespace_ident + namespace_name + lang_.namespace_begin;
code += "\n\n";
}
if (needs_includes) {
code += lang_.includes;
if (parser_.opts.gen_nullable) {
code += "\nimport javax.annotation.Nullable;\n";
}
code += lang_.class_annotation;
}
code += classcode;
if (!namespace_name.empty()) code += lang_.namespace_end;
auto filename = NamespaceDir(ns) + defname + lang_.file_extension;
return SaveFile(filename.c_str(), code, false);
}
const Namespace *CurrentNameSpace() const { return cur_name_space_; }
std::string FunctionStart(char upper) {
return std::string() + (lang_.language == IDLOptions::kJava
? static_cast<char>(tolower(upper))
: upper);
}
std::string GenNullableAnnotation(const Type& t) {
return lang_.language == IDLOptions::kJava
&& parser_.opts.gen_nullable
&& !IsScalar(DestinationType(t, true).base_type) ? " @Nullable ": "";
}
static bool IsEnum(const Type& type) {
return type.enum_def != nullptr && IsInteger(type.base_type);
}
std::string GenTypeBasic(const Type &type, bool enableLangOverrides) {
static const char *java_typename[] = {
#define FLATBUFFERS_TD(ENUM, IDLTYPE, \
CTYPE, JTYPE, GTYPE, NTYPE, PTYPE) \
#JTYPE,
FLATBUFFERS_GEN_TYPES(FLATBUFFERS_TD)
#undef FLATBUFFERS_TD
};
static const char *csharp_typename[] = {
#define FLATBUFFERS_TD(ENUM, IDLTYPE, \
CTYPE, JTYPE, GTYPE, NTYPE, PTYPE) \
#NTYPE,
FLATBUFFERS_GEN_TYPES(FLATBUFFERS_TD)
#undef FLATBUFFERS_TD
};
if (enableLangOverrides) {
if (lang_.language == IDLOptions::kCSharp) {
if (IsEnum(type)) return WrapInNameSpace(*type.enum_def);
if (type.base_type == BASE_TYPE_STRUCT) {
return "Offset<" + WrapInNameSpace(*type.struct_def) + ">";
}
}
}
if (lang_.language == IDLOptions::kJava) {
return java_typename[type.base_type];
} else {
assert(lang_.language == IDLOptions::kCSharp);
return csharp_typename[type.base_type];
}
}
std::string GenTypeBasic(const Type &type) {
return GenTypeBasic(type, true);
}
std::string GenTypePointer(const Type &type) {
switch (type.base_type) {
case BASE_TYPE_STRING:
return lang_.string_type;
case BASE_TYPE_VECTOR:
return GenTypeGet(type.VectorType());
case BASE_TYPE_STRUCT:
return WrapInNameSpace(*type.struct_def);
case BASE_TYPE_UNION:
// Unions in C# use a generic Table-derived type for better type safety
if (lang_.language == IDLOptions::kCSharp) return "TTable";
// fall through
default:
return "Table";
}
}
std::string GenTypeGet(const Type &type) {
return IsScalar(type.base_type)
? GenTypeBasic(type)
: GenTypePointer(type);
}
// Find the destination type the user wants to receive the value in (e.g.
// one size higher signed types for unsigned serialized values in Java).
Type DestinationType(const Type &type, bool vectorelem) {
if (lang_.language != IDLOptions::kJava) return type;
switch (type.base_type) {
// We use int for both uchar/ushort, since that generally means less casting
// than using short for uchar.
case BASE_TYPE_UCHAR: return Type(BASE_TYPE_INT);
case BASE_TYPE_USHORT: return Type(BASE_TYPE_INT);
case BASE_TYPE_UINT: return Type(BASE_TYPE_LONG);
case BASE_TYPE_VECTOR:
if (vectorelem)
return DestinationType(type.VectorType(), vectorelem);
// else fall thru
default: return type;
}
}
std::string GenOffsetType(const StructDef &struct_def) {
if(lang_.language == IDLOptions::kCSharp) {
return "Offset<" + WrapInNameSpace(struct_def) + ">";
} else {
return "int";
}
}
std::string GenOffsetConstruct(const StructDef &struct_def,
const std::string &variable_name)
{
if(lang_.language == IDLOptions::kCSharp) {
return "new Offset<" + WrapInNameSpace(struct_def) + ">(" + variable_name +
")";
}
return variable_name;
}
std::string GenVectorOffsetType() {
if(lang_.language == IDLOptions::kCSharp) {
return "VectorOffset";
} else {
return "int";
}
}
// Generate destination type name
std::string GenTypeNameDest(const Type &type)
{
return GenTypeGet(DestinationType(type, true));
}
// Mask to turn serialized value into destination type value.
std::string DestinationMask(const Type &type, bool vectorelem) {
if (lang_.language != IDLOptions::kJava) return "";
switch (type.base_type) {
case BASE_TYPE_UCHAR: return " & 0xFF";
case BASE_TYPE_USHORT: return " & 0xFFFF";
case BASE_TYPE_UINT: return " & 0xFFFFFFFFL";
case BASE_TYPE_VECTOR:
if (vectorelem)
return DestinationMask(type.VectorType(), vectorelem);
// else fall thru
default: return "";
}
}
// Casts necessary to correctly read serialized data
std::string DestinationCast(const Type &type) {
if (type.base_type == BASE_TYPE_VECTOR) {
return DestinationCast(type.VectorType());
} else {
switch (lang_.language) {
case IDLOptions::kJava:
// Cast necessary to correctly read serialized unsigned values.
if (type.base_type == BASE_TYPE_UINT) return "(long)";
break;
case IDLOptions::kCSharp:
// Cast from raw integral types to enum.
if (IsEnum(type)) return "(" + WrapInNameSpace(*type.enum_def) + ")";
break;
default:
break;
}
}
return "";
}
// Cast statements for mutator method parameters.
// In Java, parameters representing unsigned numbers need to be cast down to
// their respective type. For example, a long holding an unsigned int value
// would be cast down to int before being put onto the buffer. In C#, one cast
// directly cast an Enum to its underlying type, which is essential before
// putting it onto the buffer.
std::string SourceCast(const Type &type, bool castFromDest) {
if (type.base_type == BASE_TYPE_VECTOR) {
return SourceCast(type.VectorType(), castFromDest);
} else {
switch (lang_.language) {
case IDLOptions::kJava:
if (castFromDest) {
if (type.base_type == BASE_TYPE_UINT) return "(int)";
else if (type.base_type == BASE_TYPE_USHORT) return "(short)";
else if (type.base_type == BASE_TYPE_UCHAR) return "(byte)";
}
break;
case IDLOptions::kCSharp:
if (IsEnum(type)) return "(" + GenTypeBasic(type, false) + ")";
break;
default:
break;
}
}
return "";
}
std::string SourceCast(const Type &type) {
return SourceCast(type, true);
}
std::string SourceCastBasic(const Type &type, bool castFromDest) {
return IsScalar(type.base_type) ? SourceCast(type, castFromDest) : "";
}
std::string SourceCastBasic(const Type &type) {
return SourceCastBasic(type, true);
}
std::string GenEnumDefaultValue(const Value &value) {
auto enum_def = value.type.enum_def;
auto vec = enum_def->vals.vec;
auto default_value = StringToInt(value.constant.c_str());
auto result = value.constant;
for (auto it = vec.begin(); it != vec.end(); ++it) {
auto enum_val = **it;
if (enum_val.value == default_value) {
result = WrapInNameSpace(*enum_def) + "." + enum_val.name;
break;
}
}
return result;
}
std::string GenDefaultValue(const Value &value, bool enableLangOverrides) {
if (enableLangOverrides) {
// handles both enum case and vector of enum case
if (lang_.language == IDLOptions::kCSharp &&
value.type.enum_def != nullptr &&
value.type.base_type != BASE_TYPE_UNION) {
return GenEnumDefaultValue(value);
}
}
auto longSuffix = lang_.language == IDLOptions::kJava ? "L" : "";
switch (value.type.base_type) {
case BASE_TYPE_FLOAT: return value.constant + "f";
case BASE_TYPE_BOOL: return value.constant == "0" ? "false" : "true";
case BASE_TYPE_ULONG:
{
if (lang_.language != IDLOptions::kJava)
return value.constant;
// Converts the ulong into its bits signed equivalent
uint64_t defaultValue = StringToUInt(value.constant.c_str());
return NumToString(static_cast<int64_t>(defaultValue)) + longSuffix;
}
case BASE_TYPE_UINT:
case BASE_TYPE_LONG: return value.constant + longSuffix;
default: return value.constant;
}
}
std::string GenDefaultValue(const Value &value) {
return GenDefaultValue(value, true);
}
std::string GenDefaultValueBasic(const Value &value, bool enableLangOverrides) {
if (!IsScalar(value.type.base_type)) {
if (enableLangOverrides) {
if (lang_.language == IDLOptions::kCSharp) {
switch (value.type.base_type) {
case BASE_TYPE_STRING:
return "default(StringOffset)";
case BASE_TYPE_STRUCT:
return "default(Offset<" + WrapInNameSpace(*value.type.struct_def) +
">)";
case BASE_TYPE_VECTOR:
return "default(VectorOffset)";
default:
break;
}
}
}
return "0";
}
return GenDefaultValue(value, enableLangOverrides);
}
std::string GenDefaultValueBasic(const Value &value) {
return GenDefaultValueBasic(value, true);
}
void GenEnum(EnumDef &enum_def, std::string *code_ptr) {
std::string &code = *code_ptr;
if (enum_def.generated) return;
// Generate enum definitions of the form:
// public static (final) int name = value;
// In Java, we use ints rather than the Enum feature, because we want them
// to map directly to how they're used in C/C++ and file formats.
// That, and Java Enums are expensive, and not universally liked.
GenComment(enum_def.doc_comment, code_ptr, &lang_.comment_config);
code += std::string("public ") + lang_.enum_decl + enum_def.name;
if (lang_.language == IDLOptions::kCSharp) {
code += lang_.inheritance_marker +
GenTypeBasic(enum_def.underlying_type, false);
}
code += lang_.open_curly;
if (lang_.language == IDLOptions::kJava) {
code += " private " + enum_def.name + "() { }\n";
}
for (auto it = enum_def.vals.vec.begin();
it != enum_def.vals.vec.end();
++it) {
auto &ev = **it;
GenComment(ev.doc_comment, code_ptr, &lang_.comment_config, " ");
if (lang_.language != IDLOptions::kCSharp) {
code += " public static";
code += lang_.const_decl;
code += GenTypeBasic(enum_def.underlying_type, false);
}
code += " " + ev.name + " = ";
code += NumToString(ev.value);
code += lang_.enum_separator;
}
// Generate a generate string table for enum values.
// We do not do that for C# where this functionality is native.
if (lang_.language != IDLOptions::kCSharp) {
// Problem is, if values are very sparse that could generate really big
// tables. Ideally in that case we generate a map lookup instead, but for
// the moment we simply don't output a table at all.
auto range = enum_def.vals.vec.back()->value -
enum_def.vals.vec.front()->value + 1;
// Average distance between values above which we consider a table
// "too sparse". Change at will.
static const int kMaxSparseness = 5;
if (range / static_cast<int64_t>(enum_def.vals.vec.size()) < kMaxSparseness) {
code += "\n public static";
code += lang_.const_decl;
code += lang_.string_type;
code += "[] names = { ";
auto val = enum_def.vals.vec.front()->value;
for (auto it = enum_def.vals.vec.begin();
it != enum_def.vals.vec.end();
++it) {
while (val++ != (*it)->value) code += "\"\", ";
code += "\"" + (*it)->name + "\", ";
}
code += "};\n\n";
code += " public static ";
code += lang_.string_type;
code += " " + MakeCamel("name", lang_.first_camel_upper);
code += "(int e) { return names[e";
if (enum_def.vals.vec.front()->value)
code += " - " + enum_def.vals.vec.front()->name;
code += "]; }\n";
}
}
// Close the class
code += "}";
// Java does not need the closing semi-colon on class definitions.
code += (lang_.language != IDLOptions::kJava) ? ";" : "";
code += "\n\n";
}
// Returns the function name that is able to read a value of the given type.
std::string GenGetter(const Type &type) {
switch (type.base_type) {
case BASE_TYPE_STRING: return lang_.accessor_prefix + "__string";
case BASE_TYPE_STRUCT: return lang_.accessor_prefix + "__struct";
case BASE_TYPE_UNION: return lang_.accessor_prefix + "__union";
case BASE_TYPE_VECTOR: return GenGetter(type.VectorType());
default: {
std::string getter =
lang_.accessor_prefix + "bb." + FunctionStart('G') + "et";
if (type.base_type == BASE_TYPE_BOOL) {
getter = "0!=" + getter;
} else if (GenTypeBasic(type, false) != "byte") {
getter += MakeCamel(GenTypeBasic(type, false));
}
return getter;
}
}
}
// Returns the function name that is able to read a value of the given type.
std::string GenGetterForLookupByKey(flatbuffers::FieldDef *key_field,
const std::string &data_buffer,
const char *num = nullptr) {
auto type = key_field->value.type;
auto dest_mask = DestinationMask(type, true);
auto dest_cast = DestinationCast(type);
auto getter = data_buffer + "." + FunctionStart('G') + "et";
if (GenTypeBasic(type, false) != "byte") {
getter += MakeCamel(GenTypeBasic(type, false));
}
getter = dest_cast + getter + "(" + GenOffsetGetter(key_field, num) + ")"
+ dest_mask;
return getter;
}
// Direct mutation is only allowed for scalar fields.
// Hence a setter method will only be generated for such fields.
std::string GenSetter(const Type &type) {
if (IsScalar(type.base_type)) {
std::string setter =
lang_.accessor_prefix + "bb." + FunctionStart('P') + "ut";
if (GenTypeBasic(type, false) != "byte" &&
type.base_type != BASE_TYPE_BOOL) {
setter += MakeCamel(GenTypeBasic(type, false));
}
return setter;
} else {
return "";
}
}
// Returns the method name for use with add/put calls.
std::string GenMethod(const Type &type) {
return IsScalar(type.base_type)
? MakeCamel(GenTypeBasic(type, false))
: (IsStruct(type) ? "Struct" : "Offset");
}
// Recursively generate arguments for a constructor, to deal with nested
// structs.
void GenStructArgs(const StructDef &struct_def, std::string *code_ptr,
const char *nameprefix) {
std::string &code = *code_ptr;
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end();
++it) {
auto &field = **it;
if (IsStruct(field.value.type)) {
// Generate arguments for a struct inside a struct. To ensure names
// don't clash, and to make it obvious these arguments are constructing
// a nested struct, prefix the name with the field name.
GenStructArgs(*field.value.type.struct_def, code_ptr,
(nameprefix + (field.name + "_")).c_str());
} else {
code += ", ";
code += GenTypeBasic(DestinationType(field.value.type, false));
code += " ";
code += nameprefix;
code += MakeCamel(field.name, lang_.first_camel_upper);
}
}
}
// Recusively generate struct construction statements of the form:
// builder.putType(name);
// and insert manual padding.
void GenStructBody(const StructDef &struct_def, std::string *code_ptr,
const char *nameprefix) {
std::string &code = *code_ptr;
code += " builder." + FunctionStart('P') + "rep(";
code += NumToString(struct_def.minalign) + ", ";
code += NumToString(struct_def.bytesize) + ");\n";
for (auto it = struct_def.fields.vec.rbegin();
it != struct_def.fields.vec.rend(); ++it) {
auto &field = **it;
if (field.padding) {
code += " builder." + FunctionStart('P') + "ad(";
code += NumToString(field.padding) + ");\n";
}
if (IsStruct(field.value.type)) {
GenStructBody(*field.value.type.struct_def, code_ptr,
(nameprefix + (field.name + "_")).c_str());
} else {
code += " builder." + FunctionStart('P') + "ut";
code += GenMethod(field.value.type) + "(";
code += SourceCast(field.value.type);
auto argname = nameprefix + MakeCamel(field.name, lang_.first_camel_upper);
code += argname;
code += ");\n";
}
}
}
std::string GenByteBufferLength(const char *bb_name) {
std::string bb_len = bb_name;
if (lang_.language == IDLOptions::kCSharp) bb_len += ".Length";
else bb_len += ".capacity()";
return bb_len;
}
std::string GenOffsetGetter(flatbuffers::FieldDef *key_field,
const char *num = nullptr) {
std::string key_offset = "";
key_offset += lang_.accessor_prefix_static + "__offset(" +
NumToString(key_field->value.offset) + ", ";
if (num) {
key_offset += num;
key_offset += (lang_.language == IDLOptions::kCSharp ?
".Value, builder.DataBuffer)" : ", _bb)");
} else {
key_offset += GenByteBufferLength("bb");
key_offset += " - tableOffset, bb)";
}
return key_offset;
}
std::string GenLookupKeyGetter(flatbuffers::FieldDef *key_field) {
std::string key_getter = " ";
key_getter += "int tableOffset = " + lang_.accessor_prefix_static;
key_getter += "__indirect(vectorLocation + 4 * (start + middle)";
key_getter += ", bb);\n ";
if (key_field->value.type.base_type == BASE_TYPE_STRING) {
key_getter += "int comp = " + lang_.accessor_prefix_static;
key_getter += FunctionStart('C') + "ompareStrings(";
key_getter += GenOffsetGetter(key_field);
key_getter += ", byteKey, bb);\n";
} else {
auto get_val = GenGetterForLookupByKey(key_field, "bb");
if (lang_.language == IDLOptions::kCSharp) {
key_getter += "int comp = " + get_val + ".CompareTo(key);\n";
} else {
key_getter += GenTypeNameDest(key_field->value.type) + " val = ";
key_getter += get_val + ";\n";
key_getter += " int comp = val > key ? 1 : val < key ? -1 : 0;\n";
}
}
return key_getter;
}
std::string GenKeyGetter(flatbuffers::FieldDef *key_field) {
std::string key_getter = "";
auto data_buffer = (lang_.language == IDLOptions::kCSharp) ?
"builder.DataBuffer" : "_bb";
if (key_field->value.type.base_type == BASE_TYPE_STRING) {
if (lang_.language == IDLOptions::kJava)
key_getter += " return ";
key_getter += lang_.accessor_prefix_static;
key_getter += FunctionStart('C') + "ompareStrings(";
key_getter += GenOffsetGetter(key_field, "o1") + ", ";
key_getter += GenOffsetGetter(key_field, "o2") + ", " + data_buffer + ")";
if (lang_.language == IDLOptions::kJava)
key_getter += ";";
}
else {
auto field_getter = GenGetterForLookupByKey(key_field, data_buffer, "o1");
if (lang_.language == IDLOptions::kCSharp) {
key_getter += field_getter;
field_getter = GenGetterForLookupByKey(key_field, data_buffer, "o2");
key_getter += ".CompareTo(" + field_getter + ")";
}
else {
key_getter += "\n " + GenTypeNameDest(key_field->value.type) + " val_1 = ";
key_getter += field_getter + ";\n " + GenTypeNameDest(key_field->value.type);
key_getter += " val_2 = ";
field_getter = GenGetterForLookupByKey(key_field, data_buffer, "o2");
key_getter += field_getter + ";\n";
key_getter += " return val_1 > val_2 ? 1 : val_1 < val_2 ? -1 : 0;\n ";
}
}
return key_getter;
}
void GenStruct(StructDef &struct_def, std::string *code_ptr) {
if (struct_def.generated) return;
std::string &code = *code_ptr;
// Generate a struct accessor class, with methods of the form:
// public type name() { return bb.getType(i + offset); }
// or for tables of the form:
// public type name() {
// int o = __offset(offset); return o != 0 ? bb.getType(o + i) : default;
// }
GenComment(struct_def.doc_comment, code_ptr, &lang_.comment_config);
code += "public ";
if (lang_.language == IDLOptions::kCSharp &&
struct_def.attributes.Lookup("csharp_partial")) {
// generate a partial class for this C# struct/table
code += "partial ";
} else {
code += lang_.unsubclassable_decl;
}
code += lang_.accessor_type + struct_def.name;
if (lang_.language == IDLOptions::kCSharp) {
code += " : IFlatbufferObject";
code += lang_.open_curly;
code += " private ";
code += struct_def.fixed ? "Struct" : "Table";
code += " __p;\n";
if (lang_.language == IDLOptions::kCSharp) {
code += " public ByteBuffer ByteBuffer { get { return __p.bb; } }\n";
}
} else {
code += lang_.inheritance_marker;
code += struct_def.fixed ? "Struct" : "Table";
code += lang_.open_curly;
}
if (!struct_def.fixed) {
// Generate a special accessor for the table that when used as the root
// of a FlatBuffer
std::string method_name = FunctionStart('G') + "etRootAs" + struct_def.name;
std::string method_signature = " public static " + struct_def.name + " " +
method_name;
// create convenience method that doesn't require an existing object
code += method_signature + "(ByteBuffer _bb) ";
code += "{ return " + method_name + "(_bb, new " + struct_def.name+ "()); }\n";
// create method that allows object reuse
code += method_signature + "(ByteBuffer _bb, " + struct_def.name + " obj) { ";
code += lang_.set_bb_byteorder;
code += "return (obj.__assign(_bb." + FunctionStart('G') + "etInt(_bb.";
code += lang_.get_bb_position;
code += ") + _bb.";
code += lang_.get_bb_position;
code += ", _bb)); }\n";
if (parser_.root_struct_def_ == &struct_def) {
if (parser_.file_identifier_.length()) {
// Check if a buffer has the identifier.
code += " public static ";
code += lang_.bool_type + struct_def.name;
code += "BufferHasIdentifier(ByteBuffer _bb) { return ";
code += lang_.accessor_prefix_static + "__has_identifier(_bb, \"";
code += parser_.file_identifier_;
code += "\"); }\n";
}
}
}
// Generate the __init method that sets the field in a pre-existing
// accessor object. This is to allow object reuse.
code += " public void __init(int _i, ByteBuffer _bb) ";
code += "{ " + lang_.accessor_prefix + "bb_pos = _i; ";
code += lang_.accessor_prefix + "bb = _bb; }\n";
code += " public " + struct_def.name + " __assign(int _i, ByteBuffer _bb) ";
code += "{ __init(_i, _bb); return this; }\n\n";
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end();
++it) {
auto &field = **it;
if (field.deprecated) continue;
GenComment(field.doc_comment, code_ptr, &lang_.comment_config, " ");
std::string type_name = GenTypeGet(field.value.type);
std::string type_name_dest = GenTypeNameDest(field.value.type);
std::string conditional_cast = "";
std::string optional = "";
if (lang_.language == IDLOptions::kCSharp &&
!struct_def.fixed &&
(field.value.type.base_type == BASE_TYPE_STRUCT ||
field.value.type.base_type == BASE_TYPE_UNION ||
(field.value.type.base_type == BASE_TYPE_VECTOR &&
field.value.type.element == BASE_TYPE_STRUCT))) {
optional = lang_.optional_suffix;
conditional_cast = "(" + type_name_dest + optional + ")";
}
std::string dest_mask = DestinationMask(field.value.type, true);
std::string dest_cast = DestinationCast(field.value.type);
std::string src_cast = SourceCast(field.value.type);
std::string method_start = " public " + GenNullableAnnotation(field.value.type) +
type_name_dest + optional + " " +
MakeCamel(field.name, lang_.first_camel_upper);
std::string obj = lang_.language == IDLOptions::kCSharp
? "(new " + type_name + "())"
: "obj";
// Most field accessors need to retrieve and test the field offset first,
// this is the prefix code for that:
auto offset_prefix = " { int o = " + lang_.accessor_prefix + "__offset(" +
NumToString(field.value.offset) +
"); return o != 0 ? ";
// Generate the accessors that don't do object reuse.
if (field.value.type.base_type == BASE_TYPE_STRUCT) {
// Calls the accessor that takes an accessor object with a new object.
if (lang_.language != IDLOptions::kCSharp) {
code += method_start + "() { return ";
code += MakeCamel(field.name, lang_.first_camel_upper);
code += "(new ";
code += type_name + "()); }\n";
}
} else if (field.value.type.base_type == BASE_TYPE_VECTOR &&
field.value.type.element == BASE_TYPE_STRUCT) {
// Accessors for vectors of structs also take accessor objects, this
// generates a variant without that argument.
if (lang_.language != IDLOptions::kCSharp) {
code += method_start + "(int j) { return ";
code += MakeCamel(field.name, lang_.first_camel_upper);
code += "(new " + type_name + "(), j); }\n";
}
} else if (field.value.type.base_type == BASE_TYPE_UNION) {
if (lang_.language == IDLOptions::kCSharp) {
// Union types in C# use generic Table-derived type for better type
// safety.
method_start += "<TTable>";
type_name = type_name_dest;
}
}
std::string getter = dest_cast + GenGetter(field.value.type);
code += method_start;
std::string default_cast = "";
// only create default casts for c# scalars or vectors of scalars
if (lang_.language == IDLOptions::kCSharp &&
(IsScalar(field.value.type.base_type) ||
(field.value.type.base_type == BASE_TYPE_VECTOR &&
IsScalar(field.value.type.element)))) {
// For scalars, default value will be returned by GetDefaultValue().
// If the scalar is an enum, GetDefaultValue() returns an actual c# enum
// that doesn't need to be casted. However, default values for enum
// elements of vectors are integer literals ("0") and are still casted
// for clarity.
if (field.value.type.enum_def == nullptr ||
field.value.type.base_type == BASE_TYPE_VECTOR) {
default_cast = "(" + type_name_dest + ")";
}
}
std::string member_suffix = "; ";
if (IsScalar(field.value.type.base_type)) {
code += lang_.getter_prefix;
member_suffix += lang_.getter_suffix;
if (struct_def.fixed) {
code += " { return " + getter;
code += "(" + lang_.accessor_prefix + "bb_pos + ";
code += NumToString(field.value.offset) + ")";
code += dest_mask;
} else {
code += offset_prefix + getter;
code += "(o + " + lang_.accessor_prefix + "bb_pos)" + dest_mask;
code += " : " + default_cast;
code += GenDefaultValue(field.value);
}
} else {
switch (field.value.type.base_type) {
case BASE_TYPE_STRUCT:
if (lang_.language != IDLOptions::kCSharp) {
code += "(" + type_name + " obj" + ")";
} else {
code += lang_.getter_prefix;
member_suffix += lang_.getter_suffix;
}
if (struct_def.fixed) {
code += " { return " + obj + ".__assign(" + lang_.accessor_prefix;
code += "bb_pos + " + NumToString(field.value.offset) + ", ";
code += lang_.accessor_prefix + "bb)";
} else {
code += offset_prefix + conditional_cast;
code += obj + ".__assign(";
code += field.value.type.struct_def->fixed
? "o + " + lang_.accessor_prefix + "bb_pos"
: lang_.accessor_prefix + "__indirect(o + " +
lang_.accessor_prefix + "bb_pos)";
code += ", " + lang_.accessor_prefix + "bb) : null";
}
break;
case BASE_TYPE_STRING:
code += lang_.getter_prefix;
member_suffix += lang_.getter_suffix;
code += offset_prefix + getter + "(o + " + lang_.accessor_prefix;
code += "bb_pos) : null";
break;
case BASE_TYPE_VECTOR: {
auto vectortype = field.value.type.VectorType();
code += "(";
if (vectortype.base_type == BASE_TYPE_STRUCT) {
if (lang_.language != IDLOptions::kCSharp)
code += type_name + " obj, ";
getter = obj + ".__assign";
}
code += "int j)" + offset_prefix + conditional_cast + getter +"(";
auto index = lang_.accessor_prefix + "__vector(o) + j * " +
NumToString(InlineSize(vectortype));
if (vectortype.base_type == BASE_TYPE_STRUCT) {
code += vectortype.struct_def->fixed
? index
: lang_.accessor_prefix + "__indirect(" + index + ")";
code += ", " + lang_.accessor_prefix + "bb";
} else {
code += index;
}
code += ")" + dest_mask + " : ";
code += field.value.type.element == BASE_TYPE_BOOL ? "false" :
(IsScalar(field.value.type.element) ? default_cast + "0" : "null");
break;
}
case BASE_TYPE_UNION:
if (lang_.language == IDLOptions::kCSharp) {
code += "() where TTable : struct, IFlatbufferObject";
code += offset_prefix + "(TTable?)" + getter;
code += "<TTable>(o) : null";
} else {
code += "(" + type_name + " obj)" + offset_prefix + getter;
code += "(obj, o) : null";
}
break;
default:
assert(0);
}
}
code += member_suffix;
code += "}\n";
if (field.value.type.base_type == BASE_TYPE_VECTOR) {
code += " public int " + MakeCamel(field.name, lang_.first_camel_upper);
code += "Length";
code += lang_.getter_prefix;
code += offset_prefix;
code += lang_.accessor_prefix + "__vector_len(o) : 0; ";
code += lang_.getter_suffix;
code += "}\n";
// See if we should generate a by-key accessor.
if (field.value.type.element == BASE_TYPE_STRUCT &&
!field.value.type.struct_def->fixed) {
auto &sd = *field.value.type.struct_def;
auto &fields = sd.fields.vec;
for (auto kit = fields.begin(); kit != fields.end(); ++kit) {
auto &key_field = **kit;
if (key_field.key) {
code += " public " + sd.name + lang_.optional_suffix + " ";
code += MakeCamel(field.name, lang_.first_camel_upper) + "ByKey(";
code += GenTypeNameDest(key_field.value.type) + " key)";
code += offset_prefix;
code += sd.name + ".__lookup_by_key(";
code += lang_.accessor_prefix + "__vector(o), key, ";
code += lang_.accessor_prefix + "bb) : null; ";
code += "}\n";
break;
}
}
}
}
// Generate a ByteBuffer accessor for strings & vectors of scalars.
if ((field.value.type.base_type == BASE_TYPE_VECTOR &&
IsScalar(field.value.type.VectorType().base_type)) ||
field.value.type.base_type == BASE_TYPE_STRING) {
switch (lang_.language) {
case IDLOptions::kJava:
code += " public ByteBuffer ";
code += MakeCamel(field.name, lang_.first_camel_upper);
code += "AsByteBuffer() { return ";
code += lang_.accessor_prefix + "__vector_as_bytebuffer(";
code += NumToString(field.value.offset) + ", ";
code += NumToString(field.value.type.base_type == BASE_TYPE_STRING
? 1
: InlineSize(field.value.type.VectorType()));
code += "); }\n";
break;
case IDLOptions::kCSharp:
code += " public ArraySegment<byte>? Get";
code += MakeCamel(field.name, lang_.first_camel_upper);
code += "Bytes() { return ";
code += lang_.accessor_prefix + "__vector_as_arraysegment(";
code += NumToString(field.value.offset);
code += "); }\n";
break;
default:
break;
}
}
// generate object accessors if is nested_flatbuffer
if (field.nested_flatbuffer) {
auto nested_type_name = WrapInNameSpace(*field.nested_flatbuffer);
auto nested_method_name = MakeCamel(field.name, lang_.first_camel_upper)
+ "As" + nested_type_name;
auto get_nested_method_name = nested_method_name;
if (lang_.language == IDLOptions::kCSharp) {
get_nested_method_name = "Get" + nested_method_name;
conditional_cast = "(" + nested_type_name + lang_.optional_suffix + ")";
}
if (lang_.language != IDLOptions::kCSharp) {
code += " public " + nested_type_name + lang_.optional_suffix + " ";
code += nested_method_name + "() { return ";
code += get_nested_method_name + "(new " + nested_type_name + "()); }\n";
} else {
obj = "(new " + nested_type_name + "())";
}
code += " public " + nested_type_name + lang_.optional_suffix + " ";
code += get_nested_method_name + "(";
if (lang_.language != IDLOptions::kCSharp)
code += nested_type_name + " obj";
code += ") { int o = " + lang_.accessor_prefix + "__offset(";
code += NumToString(field.value.offset) +"); ";
code += "return o != 0 ? " + conditional_cast + obj + ".__assign(";
code += lang_.accessor_prefix;
code += "__indirect(" + lang_.accessor_prefix + "__vector(o)), ";
code += lang_.accessor_prefix + "bb) : null; }\n";
}
// Generate mutators for scalar fields or vectors of scalars.
if (parser_.opts.mutable_buffer) {
auto underlying_type = field.value.type.base_type == BASE_TYPE_VECTOR
? field.value.type.VectorType()
: field.value.type;
// Boolean parameters have to be explicitly converted to byte
// representation.
auto setter_parameter = underlying_type.base_type == BASE_TYPE_BOOL
? "(byte)(" + field.name + " ? 1 : 0)"
: field.name;
auto mutator_prefix = MakeCamel("mutate", lang_.first_camel_upper);
// A vector mutator also needs the index of the vector element it should
// mutate.
auto mutator_params = (field.value.type.base_type == BASE_TYPE_VECTOR
? "(int j, "
: "(") + GenTypeNameDest(underlying_type) + " " + field.name + ") { ";
auto setter_index = field.value.type.base_type == BASE_TYPE_VECTOR
? lang_.accessor_prefix + "__vector(o) + j * " +
NumToString(InlineSize(underlying_type))
: (struct_def.fixed
? lang_.accessor_prefix + "bb_pos + " +
NumToString(field.value.offset)
: "o + " + lang_.accessor_prefix + "bb_pos");
if (IsScalar(field.value.type.base_type) ||
(field.value.type.base_type == BASE_TYPE_VECTOR &&
IsScalar(field.value.type.VectorType().base_type))) {
code += " public ";
code += struct_def.fixed ? "void " : lang_.bool_type;
code += mutator_prefix + MakeCamel(field.name, true);
code += mutator_params;
if (struct_def.fixed) {
code += GenSetter(underlying_type) + "(" + setter_index + ", ";
code += src_cast + setter_parameter + "); }\n";
} else {
code += "int o = " + lang_.accessor_prefix + "__offset(";
code += NumToString(field.value.offset) + ");";
code += " if (o != 0) { " + GenSetter(underlying_type);
code += "(" + setter_index + ", " + src_cast + setter_parameter +
"); return true; } else { return false; } }\n";
}
}
}
}
code += "\n";
flatbuffers::FieldDef *key_field = nullptr;
if (struct_def.fixed) {
// create a struct constructor function
code += " public static " + GenOffsetType(struct_def) + " ";
code += FunctionStart('C') + "reate";
code += struct_def.name + "(FlatBufferBuilder builder";
GenStructArgs(struct_def, code_ptr, "");
code += ") {\n";
GenStructBody(struct_def, code_ptr, "");
code += " return ";
code += GenOffsetConstruct(struct_def,
"builder." + std::string(lang_.get_fbb_offset));
code += ";\n }\n";
} else {
// Generate a method that creates a table in one go. This is only possible
// when the table has no struct fields, since those have to be created
// inline, and there's no way to do so in Java.
bool has_no_struct_fields = true;
int num_fields = 0;
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end(); ++it) {
auto &field = **it;
if (field.deprecated) continue;
if (IsStruct(field.value.type)) {
has_no_struct_fields = false;
} else {
num_fields++;
}
}
// JVM specifications restrict default constructor params to be < 255.
// Longs and doubles take up 2 units, so we set the limit to be < 127.
if (has_no_struct_fields && num_fields && num_fields < 127) {
// Generate a table constructor of the form:
// public static int createName(FlatBufferBuilder builder, args...)
code += " public static " + GenOffsetType(struct_def) + " ";
code += FunctionStart('C') + "reate" + struct_def.name;
code += "(FlatBufferBuilder builder";
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end(); ++it) {
auto &field = **it;
if (field.deprecated) continue;
code += ",\n ";
code += GenTypeBasic(DestinationType(field.value.type, false));
code += " ";
code += field.name;
if (!IsScalar(field.value.type.base_type)) code += "Offset";
// Java doesn't have defaults, which means this method must always
// supply all arguments, and thus won't compile when fields are added.
if (lang_.language != IDLOptions::kJava) {
code += " = ";
code += GenDefaultValueBasic(field.value);
}
}
code += ") {\n builder.";
code += FunctionStart('S') + "tartObject(";
code += NumToString(struct_def.fields.vec.size()) + ");\n";
for (size_t size = struct_def.sortbysize ? sizeof(largest_scalar_t) : 1;
size;
size /= 2) {
for (auto it = struct_def.fields.vec.rbegin();
it != struct_def.fields.vec.rend(); ++it) {
auto &field = **it;
if (!field.deprecated &&
(!struct_def.sortbysize ||
size == SizeOf(field.value.type.base_type))) {
code += " " + struct_def.name + ".";
code += FunctionStart('A') + "dd";
code += MakeCamel(field.name) + "(builder, " + field.name;
if (!IsScalar(field.value.type.base_type)) code += "Offset";
code += ");\n";
}
}
}
code += " return " + struct_def.name + ".";
code += FunctionStart('E') + "nd" + struct_def.name;
code += "(builder);\n }\n\n";
}
// Generate a set of static methods that allow table construction,
// of the form:
// public static void addName(FlatBufferBuilder builder, short name)
// { builder.addShort(id, name, default); }
// Unlike the Create function, these always work.
code += " public static void " + FunctionStart('S') + "tart";
code += struct_def.name;
code += "(FlatBufferBuilder builder) { builder.";
code += FunctionStart('S') + "tartObject(";
code += NumToString(struct_def.fields.vec.size()) + "); }\n";
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end(); ++it) {
auto &field = **it;
if (field.deprecated) continue;
if (field.key) key_field = &field;
code += " public static void " + FunctionStart('A') + "dd";
code += MakeCamel(field.name);
code += "(FlatBufferBuilder builder, ";
code += GenTypeBasic(DestinationType(field.value.type, false));
auto argname = MakeCamel(field.name, false);
if (!IsScalar(field.value.type.base_type)) argname += "Offset";
code += " " + argname + ") { builder." + FunctionStart('A') + "dd";
code += GenMethod(field.value.type) + "(";
code += NumToString(it - struct_def.fields.vec.begin()) + ", ";
code += SourceCastBasic(field.value.type);
code += argname;
if (!IsScalar(field.value.type.base_type) &&
field.value.type.base_type != BASE_TYPE_UNION &&
lang_.language == IDLOptions::kCSharp) {
code += ".Value";
}
code += ", ";
if (lang_.language == IDLOptions::kJava)
code += SourceCastBasic( field.value.type );
code += GenDefaultValue(field.value, false);
code += "); }\n";
if (field.value.type.base_type == BASE_TYPE_VECTOR) {
auto vector_type = field.value.type.VectorType();
auto alignment = InlineAlignment(vector_type);
auto elem_size = InlineSize(vector_type);
if (!IsStruct(vector_type)) {
// Generate a method to create a vector from a Java array.
code += " public static " + GenVectorOffsetType() + " ";
code += FunctionStart('C') + "reate";
code += MakeCamel(field.name);
code += "Vector(FlatBufferBuilder builder, ";
code += GenTypeBasic(vector_type) + "[] data) ";
code += "{ builder." + FunctionStart('S') + "tartVector(";
code += NumToString(elem_size);
code += ", data." + FunctionStart('L') + "ength, ";
code += NumToString(alignment);
code += "); for (int i = data.";
code += FunctionStart('L') + "ength - 1; i >= 0; i--) builder.";
code += FunctionStart('A') + "dd";
code += GenMethod(vector_type);
code += "(";
code += SourceCastBasic(vector_type, false);
code += "data[i]";
if (lang_.language == IDLOptions::kCSharp &&
(vector_type.base_type == BASE_TYPE_STRUCT ||
vector_type.base_type == BASE_TYPE_STRING))
code += ".Value";
code += "); return ";
code += "builder." + FunctionStart('E') + "ndVector(); }\n";
}
// Generate a method to start a vector, data to be added manually after.
code += " public static void " + FunctionStart('S') + "tart";
code += MakeCamel(field.name);
code += "Vector(FlatBufferBuilder builder, int numElems) ";
code += "{ builder." + FunctionStart('S') + "tartVector(";
code += NumToString(elem_size);
code += ", numElems, " + NumToString(alignment);
code += "); }\n";
}
}
code += " public static " + GenOffsetType(struct_def) + " ";
code += FunctionStart('E') + "nd" + struct_def.name;
code += "(FlatBufferBuilder builder) {\n int o = builder.";
code += FunctionStart('E') + "ndObject();\n";
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end();
++it) {
auto &field = **it;
if (!field.deprecated && field.required) {
code += " builder." + FunctionStart('R') + "equired(o, ";
code += NumToString(field.value.offset);
code += "); // " + field.name + "\n";
}
}
code += " return " + GenOffsetConstruct(struct_def, "o") + ";\n }\n";
if (parser_.root_struct_def_ == &struct_def) {
code += " public static void ";
code += FunctionStart('F') + "inish" + struct_def.name;
code += "Buffer(FlatBufferBuilder builder, " + GenOffsetType(struct_def);
code += " offset) {";
code += " builder." + FunctionStart('F') + "inish(offset";
if (lang_.language == IDLOptions::kCSharp) {
code += ".Value";
}
if (parser_.file_identifier_.length())
code += ", \"" + parser_.file_identifier_ + "\"";
code += "); }\n";
}
}
// Only generate key compare function for table,
// because `key_field` is not set for struct
if (struct_def.has_key && !struct_def.fixed) {
if (lang_.language == IDLOptions::kJava) {
code += "\n @Override\n protected int keysCompare(";
code += "Integer o1, Integer o2, ByteBuffer _bb) {";
code += GenKeyGetter(key_field);
code += " }\n";
}
else {
code += "\n public static VectorOffset ";
code += "CreateSortedVectorOf" + struct_def.name;
code += "(FlatBufferBuilder builder, ";
code += "Offset<" + struct_def.name + ">";
code += "[] offsets) {\n";
code += " Array.Sort(offsets, (Offset<" + struct_def.name +
"> o1, Offset<" + struct_def.name + "> o2) => " + GenKeyGetter(key_field);
code += ");\n";
code += " return builder.CreateVectorOfTables(offsets);\n }\n";
}
code += "\n public static " + struct_def.name + lang_.optional_suffix;
code += " __lookup_by_key(int vectorLocation, ";
code += GenTypeNameDest(key_field->value.type);
code += " key, ByteBuffer bb) {\n";
if (key_field->value.type.base_type == BASE_TYPE_STRING) {
code += " byte[] byteKey = ";
if (lang_.language == IDLOptions::kJava)
code += "key.getBytes(Table.UTF8_CHARSET.get());\n";
else
code += "System.Text.Encoding.UTF8.GetBytes(key);\n";
}
code += " int span = ";
code += "bb." + FunctionStart('G') + "etInt(vectorLocation - 4);\n";
code += " int start = 0;\n";
code += " while (span != 0) {\n";
code += " int middle = span / 2;\n";
code += GenLookupKeyGetter(key_field);
code += " if (comp > 0) {\n";
code += " span = middle;\n";
code += " } else if (comp < 0) {\n";
code += " middle++;\n";
code += " start += middle;\n";
code += " span -= middle;\n";
code += " } else {\n";
code += " return new " + struct_def.name;
code += "().__assign(tableOffset, bb);\n";
code += " }\n }\n";
code += " return null;\n";
code += " }\n";
}
code += "}";
// Java does not need the closing semi-colon on class definitions.
code += (lang_.language != IDLOptions::kJava) ? ";" : "";
code += "\n\n";
}
const LanguageParameters& lang_;
// This tracks the current namespace used to determine if a type need to be prefixed by its namespace
const Namespace *cur_name_space_;
};
} // namespace general
bool GenerateGeneral(const Parser &parser, const std::string &path,
const std::string &file_name) {
general::GeneralGenerator generator(parser, path, file_name);
return generator.generate();
}
std::string GeneralMakeRule(const Parser &parser, const std::string &path,
const std::string &file_name) {
assert(parser.opts.lang <= IDLOptions::kMAX);
const auto &lang = GetLangParams(parser.opts.lang);
std::string make_rule;
for (auto it = parser.enums_.vec.begin(); it != parser.enums_.vec.end();
++it) {
auto &enum_def = **it;
if (make_rule != "") make_rule += " ";
std::string directory =
BaseGenerator::NamespaceDir(parser, path, *enum_def.defined_namespace);
make_rule += directory + enum_def.name + lang.file_extension;
}
for (auto it = parser.structs_.vec.begin(); it != parser.structs_.vec.end();
++it) {
auto &struct_def = **it;
if (make_rule != "") make_rule += " ";
std::string directory =
BaseGenerator::NamespaceDir(parser, path,
*struct_def.defined_namespace);
make_rule += directory + struct_def.name + lang.file_extension;
}
make_rule += ": ";
auto included_files = parser.GetIncludedFilesRecursive(file_name);
for (auto it = included_files.begin(); it != included_files.end(); ++it) {
make_rule += " " + *it;
}
return make_rule;
}
std::string BinaryFileName(const Parser &parser,
const std::string &path,
const std::string &file_name) {
auto ext = parser.file_extension_.length() ? parser.file_extension_ : "bin";
return path + file_name + "." + ext;
}
bool GenerateBinary(const Parser &parser,
const std::string &path,
const std::string &file_name) {
return !parser.builder_.GetSize() ||
flatbuffers::SaveFile(
BinaryFileName(parser, path, file_name).c_str(),
reinterpret_cast<char *>(parser.builder_.GetBufferPointer()),
parser.builder_.GetSize(),
true);
}
std::string BinaryMakeRule(const Parser &parser,
const std::string &path,
const std::string &file_name) {
if (!parser.builder_.GetSize()) return "";
std::string filebase = flatbuffers::StripPath(
flatbuffers::StripExtension(file_name));
std::string make_rule = BinaryFileName(parser, 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