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gerrit-public.fairphone.software / platform / external / flatbuffers / 9cadf05d8937444e093fe9b8e18a8460896f163a / . / src / idl_gen_python.cpp
blob: 50694d7c62a355c18df5cde14e7417342e2a7096 [file] [log] [blame]
/*
* 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 <cctype>
#include <set>
#include <string>
#include <unordered_set>
#include <vector>
#include "flatbuffers/code_generators.h"
#include "flatbuffers/flatbuffers.h"
#include "flatbuffers/idl.h"
#include "flatbuffers/util.h"
namespace flatbuffers {
namespace python {
// Hardcode spaces per indentation.
const CommentConfig def_comment = { nullptr, "#", nullptr };
const std::string Indent = " ";
class PythonGenerator : public BaseGenerator {
public:
PythonGenerator(const Parser &parser, const std::string &path,
const std::string &file_name)
: BaseGenerator(parser, path, file_name, "" /* not used */,
"" /* not used */),
float_const_gen_("float('nan')", "float('inf')", "float('-inf')") {
static const char *const keywords[] = {
"False", "None", "True", "and", "as", "assert", "break",
"class", "continue", "def", "del", "elif", "else", "except",
"finally", "for", "from", "global", "if", "import", "in",
"is", "lambda", "nonlocal", "not", "or", "pass", "raise",
"return", "try", "while", "with", "yield"
};
keywords_.insert(std::begin(keywords), std::end(keywords));
}
// Most field accessors need to retrieve and test the field offset first,
// this is the prefix code for that.
std::string OffsetPrefix(const FieldDef &field) {
return "\n" + Indent + Indent +
"o = flatbuffers.number_types.UOffsetTFlags.py_type" +
"(self._tab.Offset(" + NumToString(field.value.offset) + "))\n" +
Indent + Indent + "if o != 0:\n";
}
// Begin a class declaration.
void BeginClass(const StructDef &struct_def, std::string *code_ptr) {
auto &code = *code_ptr;
code += "class " + NormalizedName(struct_def) + "(object):\n";
code += Indent + "__slots__ = ['_tab']";
code += "\n\n";
}
// Begin enum code with a class declaration.
void BeginEnum(const std::string &class_name, std::string *code_ptr) {
auto &code = *code_ptr;
code += "class " + class_name + "(object):\n";
}
std::string EscapeKeyword(const std::string &name) const {
return keywords_.find(name) == keywords_.end() ? name : name + "_";
}
std::string NormalizedName(const Definition &definition) const {
return EscapeKeyword(definition.name);
}
std::string NormalizedName(const EnumVal &ev) const {
return EscapeKeyword(ev.name);
}
// Converts the name of a definition into upper Camel format.
std::string MakeUpperCamel(const Definition &definition) const {
return MakeCamel(NormalizedName(definition), true);
}
// Converts the name of a definition into lower Camel format.
std::string MakeLowerCamel(const Definition &definition) const {
auto name = MakeCamel(NormalizedName(definition), false);
name[0] = char(tolower(name[0]));
return name;
}
// Starts a new line and then indents.
std::string GenIndents(int num) {
return "\n" + std::string(num * Indent.length(), ' ');
}
// A single enum member.
void EnumMember(const EnumDef &enum_def, const EnumVal &ev,
std::string *code_ptr) {
auto &code = *code_ptr;
code += Indent;
code += NormalizedName(ev);
code += " = ";
code += enum_def.ToString(ev) + "\n";
}
// End enum code.
void EndEnum(std::string *code_ptr) {
auto &code = *code_ptr;
code += "\n";
}
// Initialize a new struct or table from existing data.
void NewRootTypeFromBuffer(const StructDef &struct_def,
std::string *code_ptr) {
auto &code = *code_ptr;
code += Indent + "@classmethod\n";
code += Indent + "def GetRootAs";
code += NormalizedName(struct_def);
code += "(cls, buf, offset):";
code += "\n";
code += Indent + Indent;
code += "n = flatbuffers.encode.Get";
code += "(flatbuffers.packer.uoffset, buf, offset)\n";
code += Indent + Indent + "x = " + NormalizedName(struct_def) + "()\n";
code += Indent + Indent + "x.Init(buf, n + offset)\n";
code += Indent + Indent + "return x\n";
code += "\n";
}
// Initialize an existing object with other data, to avoid an allocation.
void InitializeExisting(const StructDef &struct_def,
std::string *code_ptr) {
auto &code = *code_ptr;
GenReceiver(struct_def, code_ptr);
code += "Init(self, buf, pos):\n";
code += Indent + Indent + "self._tab = flatbuffers.table.Table(buf, pos)\n";
code += "\n";
}
// Get the length of a vector.
void GetVectorLen(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field)) + "Length(self";
code += "):" + OffsetPrefix(field);
code += Indent + Indent + Indent + "return self._tab.VectorLen(o)\n";
code += Indent + Indent + "return 0\n\n";
}
// Determines whether a vector is none or not.
void GetVectorIsNone(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field)) + "IsNone(self";
code += "):";
code += GenIndents(2) +
"o = flatbuffers.number_types.UOffsetTFlags.py_type" +
"(self._tab.Offset(" + NumToString(field.value.offset) + "))";
code += GenIndents(2) + "return o == 0";
code += "\n\n";
}
// Get the value of a struct's scalar.
void GetScalarFieldOfStruct(const StructDef &struct_def,
const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
std::string getter = GenGetter(field.value.type);
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field));
code += "(self): return " + getter;
code += "self._tab.Pos + flatbuffers.number_types.UOffsetTFlags.py_type(";
code += NumToString(field.value.offset) + "))\n";
}
// Get the value of a table's scalar.
void GetScalarFieldOfTable(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
std::string getter = GenGetter(field.value.type);
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field));
code += "(self):";
code += OffsetPrefix(field);
getter += "o + self._tab.Pos)";
auto is_bool = IsBool(field.value.type.base_type);
if (is_bool) { getter = "bool(" + getter + ")"; }
code += Indent + Indent + Indent + "return " + getter + "\n";
std::string default_value;
if (is_bool) {
default_value = field.value.constant == "0" ? "False" : "True";
} else {
default_value = IsFloat(field.value.type.base_type)
? float_const_gen_.GenFloatConstant(field)
: field.value.constant;
}
code += Indent + Indent + "return " + default_value + "\n\n";
}
// Get a struct by initializing an existing struct.
// Specific to Struct.
void GetStructFieldOfStruct(const StructDef &struct_def,
const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field));
code += "(self, obj):\n";
code += Indent + Indent + "obj.Init(self._tab.Bytes, self._tab.Pos + ";
code += NumToString(field.value.offset) + ")";
code += "\n" + Indent + Indent + "return obj\n\n";
}
// Get the value of a fixed size array.
void GetArrayOfStruct(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
const auto vec_type = field.value.type.VectorType();
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field));
if (IsStruct(vec_type)) {
code += "(self, obj, i):\n";
code += Indent + Indent + "obj.Init(self._tab.Bytes, self._tab.Pos + ";
code += NumToString(field.value.offset) + " + i * ";
code += NumToString(InlineSize(vec_type));
code += ")\n" + Indent + Indent + "return obj\n\n";
} else {
auto getter = GenGetter(vec_type);
code += "(self): return [" + getter;
code += "self._tab.Pos + flatbuffers.number_types.UOffsetTFlags.py_type(";
code += NumToString(field.value.offset) + " + i * ";
code += NumToString(InlineSize(vec_type));
code += ")) for i in range(";
code += NumToString(field.value.type.fixed_length) + ")]\n";
}
}
// Get a struct by initializing an existing struct.
// Specific to Table.
void GetStructFieldOfTable(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field));
code += "(self):";
code += OffsetPrefix(field);
if (field.value.type.struct_def->fixed) {
code += Indent + Indent + Indent + "x = o + self._tab.Pos\n";
} else {
code += Indent + Indent + Indent;
code += "x = self._tab.Indirect(o + self._tab.Pos)\n";
}
if (parser_.opts.include_dependence_headers) {
code += Indent + Indent + Indent;
code += "from " + GenPackageReference(field.value.type) + " import " +
TypeName(field) + "\n";
}
code += Indent + Indent + Indent + "obj = " + TypeName(field) + "()\n";
code += Indent + Indent + Indent + "obj.Init(self._tab.Bytes, x)\n";
code += Indent + Indent + Indent + "return obj\n";
code += Indent + Indent + "return None\n\n";
}
// Get the value of a string.
void GetStringField(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field));
code += "(self):";
code += OffsetPrefix(field);
code += Indent + Indent + Indent + "return " + GenGetter(field.value.type);
code += "o + self._tab.Pos)\n";
code += Indent + Indent + "return None\n\n";
}
// Get the value of a union from an object.
void GetUnionField(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field)) + "(self):";
code += OffsetPrefix(field);
// TODO(rw): this works and is not the good way to it:
bool is_native_table = TypeName(field) == "*flatbuffers.Table";
if (is_native_table) {
code += Indent + Indent + Indent + "from flatbuffers.table import Table\n";
} else if (parser_.opts.include_dependence_headers) {
code += Indent + Indent + Indent;
code += "from " + GenPackageReference(field.value.type) + " import " +
TypeName(field) + "\n";
}
code += Indent + Indent + Indent + "obj = Table(bytearray(), 0)\n";
code += Indent + Indent + Indent + GenGetter(field.value.type);
code += "obj, o)\n" + Indent + Indent + Indent + "return obj\n";
code += Indent + Indent + "return None\n\n";
}
// Generate the package reference when importing a struct or enum from its
// module.
std::string GenPackageReference(const Type &type) {
Namespace *namespaces;
if (type.struct_def) {
namespaces = type.struct_def->defined_namespace;
} else if (type.enum_def) {
namespaces = type.enum_def->defined_namespace;
} else {
return "." + GenTypeGet(type);
}
return namespaces->GetFullyQualifiedName(GenTypeGet(type));
}
// Get the value of a vector's struct member.
void GetMemberOfVectorOfStruct(const StructDef &struct_def,
const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
auto vectortype = field.value.type.VectorType();
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field));
code += "(self, j):" + OffsetPrefix(field);
code += Indent + Indent + Indent + "x = self._tab.Vector(o)\n";
code += Indent + Indent + Indent;
code += "x += flatbuffers.number_types.UOffsetTFlags.py_type(j) * ";
code += NumToString(InlineSize(vectortype)) + "\n";
if (!(vectortype.struct_def->fixed)) {
code += Indent + Indent + Indent + "x = self._tab.Indirect(x)\n";
}
if (parser_.opts.include_dependence_headers) {
code += Indent + Indent + Indent;
code += "from " + GenPackageReference(field.value.type) + " import " +
TypeName(field) + "\n";
}
code += Indent + Indent + Indent + "obj = " + TypeName(field) + "()\n";
code += Indent + Indent + Indent + "obj.Init(self._tab.Bytes, x)\n";
code += Indent + Indent + Indent + "return obj\n";
code += Indent + Indent + "return None\n\n";
}
// Get the value of a vector's non-struct member. Uses a named return
// argument to conveniently set the zero value for the result.
void GetMemberOfVectorOfNonStruct(const StructDef &struct_def,
const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
auto vectortype = field.value.type.VectorType();
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field));
code += "(self, j):";
code += OffsetPrefix(field);
code += Indent + Indent + Indent + "a = self._tab.Vector(o)\n";
code += Indent + Indent + Indent;
code += "return " + GenGetter(field.value.type);
code += "a + flatbuffers.number_types.UOffsetTFlags.py_type(j * ";
code += NumToString(InlineSize(vectortype)) + "))\n";
if (vectortype.base_type == BASE_TYPE_STRING) {
code += Indent + Indent + "return \"\"\n";
} else {
code += Indent + Indent + "return 0\n";
}
code += "\n";
}
// Returns a non-struct vector as a numpy array. Much faster
// than iterating over the vector element by element.
void GetVectorOfNonStructAsNumpy(const StructDef &struct_def,
const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
auto vectortype = field.value.type.VectorType();
// Currently, we only support accessing as numpy array if
// the vector type is a scalar.
if (!(IsScalar(vectortype.base_type))) { return; }
GenReceiver(struct_def, code_ptr);
code += MakeCamel(NormalizedName(field)) + "AsNumpy(self):";
code += OffsetPrefix(field);
code += Indent + Indent + Indent;
code += "return ";
code += "self._tab.GetVectorAsNumpy(flatbuffers.number_types.";
code += MakeCamel(GenTypeGet(field.value.type));
code += "Flags, o)\n";
if (vectortype.base_type == BASE_TYPE_STRING) {
code += Indent + Indent + "return \"\"\n";
} else {
code += Indent + Indent + "return 0\n";
}
code += "\n";
}
// Begin the creator function signature.
void BeginBuilderArgs(const StructDef &struct_def,
std::string *code_ptr) {
auto &code = *code_ptr;
code += "\n";
code += "def Create" + NormalizedName(struct_def);
code += "(builder";
}
// Recursively generate arguments for a constructor, to deal with nested
// structs.
void StructBuilderArgs(const StructDef &struct_def,
const std::string nameprefix,
const std::string namesuffix, bool has_field_name,
const std::string fieldname_suffix,
std::string *code_ptr) {
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end(); ++it) {
auto &field = **it;
const auto &field_type = field.value.type;
const auto &type =
IsArray(field_type) ? field_type.VectorType() : field_type;
if (IsStruct(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.
auto subprefix = nameprefix;
if (has_field_name) {
subprefix += NormalizedName(field) + fieldname_suffix;
}
StructBuilderArgs(*field.value.type.struct_def, subprefix, namesuffix,
has_field_name, fieldname_suffix, code_ptr);
} else {
auto &code = *code_ptr;
code += std::string(", ") + nameprefix;
if (has_field_name) {
code += MakeCamel(NormalizedName(field), false);
}
code += namesuffix;
}
}
}
// End the creator function signature.
void EndBuilderArgs(std::string *code_ptr) {
auto &code = *code_ptr;
code += "):\n";
}
// Recursively generate struct construction statements and instert manual
// padding.
void StructBuilderBody(const StructDef &struct_def, const char *nameprefix,
std::string *code_ptr, size_t index = 0,
bool in_array = false) {
auto &code = *code_ptr;
std::string indent(index * 4, ' ');
code +=
indent + " builder.Prep(" + 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;
const auto &field_type = field.value.type;
const auto &type =
IsArray(field_type) ? field_type.VectorType() : field_type;
if (field.padding)
code +=
indent + " builder.Pad(" + NumToString(field.padding) + ")\n";
if (IsStruct(field_type)) {
StructBuilderBody(*field_type.struct_def,
(nameprefix + (NormalizedName(field) + "_")).c_str(),
code_ptr, index, in_array);
} else {
const auto index_var = "_idx" + NumToString(index);
if (IsArray(field_type)) {
code += indent + " for " + index_var + " in range(";
code += NumToString(field_type.fixed_length);
code += " , 0, -1):\n";
in_array = true;
}
if (IsStruct(type)) {
StructBuilderBody(
*field_type.struct_def,
(nameprefix + (NormalizedName(field) + "_")).c_str(), code_ptr,
index + 1, in_array);
} else {
code += IsArray(field_type) ? " " : "";
code += indent + " builder.Prepend" + GenMethod(field) + "(";
code += nameprefix + MakeCamel(NormalizedName(field), false);
size_t array_cnt = index + (IsArray(field_type) ? 1 : 0);
for (size_t i = 0; in_array && i < array_cnt; i++) {
code += "[_idx" + NumToString(i) + "-1]";
}
code += ")\n";
}
}
}
}
void EndBuilderBody(std::string *code_ptr) {
auto &code = *code_ptr;
code += " return builder.Offset()\n";
}
// Get the value of a table's starting offset.
void GetStartOfTable(const StructDef &struct_def,
std::string *code_ptr) {
auto &code = *code_ptr;
code += "def " + NormalizedName(struct_def) + "Start";
code += "(builder): ";
code += "builder.StartObject(";
code += NumToString(struct_def.fields.vec.size());
code += ")\n";
}
// Set the value of a table's field.
void BuildFieldOfTable(const StructDef &struct_def,
const FieldDef &field, const size_t offset,
std::string *code_ptr) {
auto &code = *code_ptr;
code += "def " + NormalizedName(struct_def) + "Add" + MakeCamel(NormalizedName(field));
code += "(builder, ";
code += MakeCamel(NormalizedName(field), false);
code += "): ";
code += "builder.Prepend";
code += GenMethod(field) + "Slot(";
code += NumToString(offset) + ", ";
if (!IsScalar(field.value.type.base_type) && (!struct_def.fixed)) {
code += "flatbuffers.number_types.UOffsetTFlags.py_type";
code += "(";
code += MakeCamel(NormalizedName(field), false) + ")";
} else {
code += MakeCamel(NormalizedName(field), false);
}
code += ", ";
code += IsFloat(field.value.type.base_type)
? float_const_gen_.GenFloatConstant(field)
: field.value.constant;
code += ")\n";
}
// Set the value of one of the members of a table's vector.
void BuildVectorOfTable(const StructDef &struct_def,
const FieldDef &field, std::string *code_ptr) {
auto &code = *code_ptr;
code += "def " + NormalizedName(struct_def) + "Start";
code += MakeCamel(NormalizedName(field));
code += "Vector(builder, numElems): return builder.StartVector(";
auto vector_type = field.value.type.VectorType();
auto alignment = InlineAlignment(vector_type);
auto elem_size = InlineSize(vector_type);
code += NumToString(elem_size);
code += ", numElems, " + NumToString(alignment);
code += ")\n";
}
// Get the offset of the end of a table.
void GetEndOffsetOnTable(const StructDef &struct_def,
std::string *code_ptr) {
auto &code = *code_ptr;
code += "def " + NormalizedName(struct_def) + "End";
code += "(builder): ";
code += "return builder.EndObject()\n";
}
// Generate the receiver for function signatures.
void GenReceiver(const StructDef &struct_def, std::string *code_ptr) {
auto &code = *code_ptr;
code += Indent + "# " + NormalizedName(struct_def) + "\n";
code += Indent + "def ";
}
// Generate a struct field, conditioned on its child type(s).
void GenStructAccessor(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
GenComment(field.doc_comment, code_ptr, &def_comment, Indent.c_str());
if (IsScalar(field.value.type.base_type)) {
if (struct_def.fixed) {
GetScalarFieldOfStruct(struct_def, field, code_ptr);
} else {
GetScalarFieldOfTable(struct_def, field, code_ptr);
}
} else if (IsArray(field.value.type)) {
GetArrayOfStruct(struct_def, field, code_ptr);
} else {
switch (field.value.type.base_type) {
case BASE_TYPE_STRUCT:
if (struct_def.fixed) {
GetStructFieldOfStruct(struct_def, field, code_ptr);
} else {
GetStructFieldOfTable(struct_def, field, code_ptr);
}
break;
case BASE_TYPE_STRING:
GetStringField(struct_def, field, code_ptr);
break;
case BASE_TYPE_VECTOR: {
auto vectortype = field.value.type.VectorType();
if (vectortype.base_type == BASE_TYPE_STRUCT) {
GetMemberOfVectorOfStruct(struct_def, field, code_ptr);
} else {
GetMemberOfVectorOfNonStruct(struct_def, field, code_ptr);
GetVectorOfNonStructAsNumpy(struct_def, field, code_ptr);
}
break;
}
case BASE_TYPE_UNION: GetUnionField(struct_def, field, code_ptr); break;
default: FLATBUFFERS_ASSERT(0);
}
}
if (field.value.type.base_type == BASE_TYPE_VECTOR ||
field.value.type.base_type == BASE_TYPE_ARRAY) {
GetVectorLen(struct_def, field, code_ptr);
GetVectorIsNone(struct_def, field, code_ptr);
}
}
// Generate table constructors, conditioned on its members' types.
void GenTableBuilders(const StructDef &struct_def, std::string *code_ptr) {
GetStartOfTable(struct_def, code_ptr);
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end(); ++it) {
auto &field = **it;
if (field.deprecated) continue;
auto offset = it - struct_def.fields.vec.begin();
BuildFieldOfTable(struct_def, field, offset, code_ptr);
if (field.value.type.base_type == BASE_TYPE_VECTOR) {
BuildVectorOfTable(struct_def, field, code_ptr);
}
}
GetEndOffsetOnTable(struct_def, code_ptr);
}
// Generate function to check for proper file identifier
void GenHasFileIdentifier(const StructDef &struct_def,
std::string *code_ptr) {
auto &code = *code_ptr;
std::string escapedID;
// In the event any of file_identifier characters are special(NULL, \, etc),
// problems occur. To prevent this, convert all chars to their hex-escaped
// equivalent.
for (auto it = parser_.file_identifier_.begin();
it != parser_.file_identifier_.end(); ++it) {
escapedID += "\\x" + IntToStringHex(*it, 2);
}
code += Indent + "@classmethod\n";
code += Indent + "def " + NormalizedName(struct_def);
code += "BufferHasIdentifier(cls, buf, offset, size_prefixed=False):";
code += "\n";
code += Indent + Indent;
code += "return flatbuffers.util.BufferHasIdentifier(buf, offset, b\"";
code += escapedID;
code += "\", size_prefixed=size_prefixed)\n";
code += "\n";
}
// Generates struct or table methods.
void GenStruct(const StructDef &struct_def, std::string *code_ptr) {
if (struct_def.generated) return;
GenComment(struct_def.doc_comment, code_ptr, &def_comment);
BeginClass(struct_def, code_ptr);
if (!struct_def.fixed) {
// Generate a special accessor for the table that has been declared as
// the root type.
NewRootTypeFromBuffer(struct_def, code_ptr);
if (parser_.file_identifier_.length()) {
// Generate a special function to test file_identifier
GenHasFileIdentifier(struct_def, code_ptr);
}
}
// Generates the Init method that sets the field in a pre-existing
// accessor object. This is to allow object reuse.
InitializeExisting(struct_def, code_ptr);
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end(); ++it) {
auto &field = **it;
if (field.deprecated) continue;
GenStructAccessor(struct_def, field, code_ptr);
}
if (struct_def.fixed) {
// creates a struct constructor function
GenStructBuilder(struct_def, code_ptr);
} else {
// Creates a set of functions that allow table construction.
GenTableBuilders(struct_def, code_ptr);
}
}
void GenReceiverForObjectAPI(const StructDef &struct_def,
std::string *code_ptr) {
auto &code = *code_ptr;
code += GenIndents(1) + "# " + NormalizedName(struct_def) + "T";
code += GenIndents(1) + "def ";
}
void BeginClassForObjectAPI(const StructDef &struct_def,
std::string *code_ptr) {
auto &code = *code_ptr;
code += "\n";
code += "class " + NormalizedName(struct_def) + "T(object):";
code += "\n";
}
// Gets the accoresponding python builtin type of a BaseType for scalars and
// string.
std::string GetBasePythonTypeForScalarAndString(const BaseType &base_type) {
if (IsBool(base_type)) {
return "bool";
} else if (IsFloat(base_type)) {
return "float";
} else if (IsInteger(base_type)) {
return "int";
} else if (base_type == BASE_TYPE_STRING) {
return "str";
} else {
FLATBUFFERS_ASSERT(false && "base_type is not a scalar or string type.");
return "";
}
}
std::string GetDefaultValue(const FieldDef &field) {
BaseType base_type = field.value.type.base_type;
if (IsBool(base_type)) {
return field.value.constant == "0" ? "False" : "True";
} else if (IsFloat(base_type)) {
return float_const_gen_.GenFloatConstant(field);
} else if (IsInteger(base_type)) {
return field.value.constant;
} else {
// For string, struct, and table.
return "None";
}
}
void GenUnionInit(const FieldDef &field, std::string *field_types_ptr,
std::set<std::string> *import_list,
std::set<std::string> *import_typing_list) {
// Gets all possible types in the union.
import_typing_list->insert("Union");
auto &field_types = *field_types_ptr;
field_types = "Union[";
std::string separator_string = ", ";
auto enum_def = field.value.type.enum_def;
for (auto it = enum_def->Vals().begin(); it != enum_def->Vals().end();
++it) {
auto &ev = **it;
// Union only supports string and table.
std::string field_type;
switch (ev.union_type.base_type) {
case BASE_TYPE_STRUCT:
field_type = GenTypeGet(ev.union_type) + "T";
if (parser_.opts.include_dependence_headers) {
auto package_reference = GenPackageReference(ev.union_type);
field_type = package_reference + "." + field_type;
import_list->insert("import " + package_reference);
}
break;
case BASE_TYPE_STRING:
field_type += "str";
break;
case BASE_TYPE_NONE:
field_type += "None";
break;
default:
break;
}
field_types += field_type + separator_string;
}
// Removes the last separator_string.
field_types.erase(field_types.length() - separator_string.size());
field_types += "]";
// Gets the import lists for the union.
if (parser_.opts.include_dependence_headers) {
// The package reference is generated based on enum_def, instead
// of struct_def in field.type. That's why GenPackageReference() is
// not used.
Namespace *namespaces = field.value.type.enum_def->defined_namespace;
auto package_reference = namespaces->GetFullyQualifiedName(
MakeUpperCamel(*(field.value.type.enum_def)));
auto union_name = MakeUpperCamel(*(field.value.type.enum_def));
import_list->insert("import " + package_reference);
}
}
void GenStructInit(const FieldDef &field,
std::string *field_type_ptr,
std::set<std::string> *import_list,
std::set<std::string> *import_typing_list) {
import_typing_list->insert("Optional");
auto &field_type = *field_type_ptr;
if (parser_.opts.include_dependence_headers) {
auto package_reference = GenPackageReference(field.value.type);
field_type = package_reference + "." + TypeName(field) + "T]";
import_list->insert("import " + package_reference);
} else {
field_type = TypeName(field) + "T]";
}
field_type = "Optional[" + field_type;
}
void GenVectorInit(const FieldDef &field, std::string *field_type_ptr,
std::set<std::string> *import_list,
std::set<std::string> *import_typing_list) {
import_typing_list->insert("List");
auto &field_type = *field_type_ptr;
auto base_type = field.value.type.VectorType().base_type;
if (base_type == BASE_TYPE_STRUCT) {
field_type = GenTypeGet(field.value.type.VectorType()) + "T]";
if (parser_.opts.include_dependence_headers) {
auto package_reference =
GenPackageReference(field.value.type.VectorType());
field_type = package_reference + "." +
GenTypeGet(field.value.type.VectorType()) + "T]";
import_list->insert("import " + package_reference);
}
field_type = "List[" + field_type;
} else {
field_type =
"List[" + GetBasePythonTypeForScalarAndString(base_type) + "]";
}
}
void GenInitialize(const StructDef &struct_def, std::string *code_ptr,
std::set<std::string> *import_list) {
std::string code;
std::set<std::string> import_typing_list;
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end(); ++it) {
auto &field = **it;
if (field.deprecated) continue;
// Determines field type, default value, and typing imports.
auto base_type = field.value.type.base_type;
std::string field_type;
switch (base_type) {
case BASE_TYPE_UNION: {
GenUnionInit(field, &field_type, import_list, &import_typing_list);
break;
}
case BASE_TYPE_STRUCT: {
GenStructInit(field, &field_type, import_list, &import_typing_list);
break;
}
case BASE_TYPE_VECTOR:
case BASE_TYPE_ARRAY: {
GenVectorInit(field, &field_type, import_list, &import_typing_list);
break;
}
default:
// Scalar or sting fields.
field_type = GetBasePythonTypeForScalarAndString(base_type);
break;
}
auto default_value = GetDefaultValue(field);
// Wrties the init statement.
auto field_instance_name = MakeLowerCamel(field);
code += GenIndents(2) + "self." + field_instance_name + " = " +
default_value + " # type: " + field_type;
}
// Writes __init__ method.
auto &code_base = *code_ptr;
GenReceiverForObjectAPI(struct_def, code_ptr);
code_base += "__init__(self):";
if (code.empty()) {
code_base += GenIndents(2) + "pass";
} else {
code_base += code;
}
code_base += "\n";
// Merges the typing imports into import_list.
if (!import_typing_list.empty()) {
// Adds the try statement.
std::string typing_imports = "try:";
typing_imports += GenIndents(1) + "from typing import ";
std::string separator_string = ", ";
for (auto it = import_typing_list.begin(); it != import_typing_list.end();
++it) {
const std::string &im = *it;
typing_imports += im + separator_string;
}
// Removes the last separator_string.
typing_imports.erase(typing_imports.length() - separator_string.size());
// Adds the except statement.
typing_imports += "\n";
typing_imports += "except:";
typing_imports += GenIndents(1) + "pass";
import_list->insert(typing_imports);
}
// Removes the import of the struct itself, if applied.
auto package_reference =
struct_def.defined_namespace->GetFullyQualifiedName(
MakeUpperCamel(struct_def));
auto struct_import = "import " + package_reference;
import_list->erase(struct_import);
}
void InitializeFromBuf(const StructDef &struct_def, std::string *code_ptr) {
auto &code = *code_ptr;
auto instance_name = MakeLowerCamel(struct_def);
auto struct_name = NormalizedName(struct_def);
code += GenIndents(1) + "@classmethod";
code += GenIndents(1) + "def InitFromBuf(cls, buf, pos):";
code += GenIndents(2) + instance_name + " = " + struct_name + "()";
code += GenIndents(2) + instance_name + ".Init(buf, pos)";
code += GenIndents(2) + "return cls.InitFromObj(" + instance_name + ")";
code += "\n";
}
void InitializeFromObjForObject(const StructDef &struct_def,
std::string *code_ptr) {
auto &code = *code_ptr;
auto instance_name = MakeLowerCamel(struct_def);
auto struct_name = NormalizedName(struct_def);
code += GenIndents(1) + "@classmethod";
code += GenIndents(1) + "def InitFromObj(cls, " + instance_name + "):";
code += GenIndents(2) + "x = " + struct_name + "T()";
code += GenIndents(2) + "x._UnPack(" + instance_name + ")";
code += GenIndents(2) + "return x";
code += "\n";
}
void GenUnPackForStruct(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
auto struct_instance_name = MakeLowerCamel(struct_def);
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto field_type = TypeName(field);
if (parser_.opts.include_dependence_headers) {
auto package_reference = GenPackageReference(field.value.type);
field_type = package_reference + "." + TypeName(field);
}
code += GenIndents(2) + "if " + struct_instance_name + "." +
field_accessor_name + "(";
// if field is a struct, we need to create an instance for it first.
if (struct_def.fixed && field.value.type.base_type == BASE_TYPE_STRUCT) {
code += field_type + "()";
}
code += ") is not None:";
code += GenIndents(3) + "self." + field_instance_name + " = " + field_type +
"T.InitFromObj(" + struct_instance_name + "." +
field_accessor_name + "(";
// A struct's accessor requires a struct buf instance.
if (struct_def.fixed && field.value.type.base_type == BASE_TYPE_STRUCT) {
code += field_type + "()";
}
code += "))";
}
void GenUnPackForUnion(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto struct_instance_name = MakeLowerCamel(struct_def);
auto union_name = MakeUpperCamel(*(field.value.type.enum_def));
if (parser_.opts.include_dependence_headers) {
Namespace *namespaces = field.value.type.enum_def->defined_namespace;
auto package_reference = namespaces->GetFullyQualifiedName(
MakeUpperCamel(*(field.value.type.enum_def)));
union_name = package_reference + "." + union_name;
}
code += GenIndents(2) + "self." + field_instance_name + " = " + union_name +
"Creator(" + "self." + field_instance_name + "Type, " +
struct_instance_name + "." + field_accessor_name + "())";
}
void GenUnPackForStructVector(const StructDef &struct_def,
const FieldDef &field, std::string *code_ptr) {
auto &code = *code_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto struct_instance_name = MakeLowerCamel(struct_def);
code += GenIndents(2) + "if not " + struct_instance_name + "." +
field_accessor_name + "IsNone():";
code += GenIndents(3) + "self." + field_instance_name + " = []";
code += GenIndents(3) + "for i in range(" + struct_instance_name + "." +
field_accessor_name + "Length()):";
auto field_type_name = TypeName(field);
auto one_instance = field_type_name + "_";
one_instance[0] = char(tolower(one_instance[0]));
if (parser_.opts.include_dependence_headers) {
auto package_reference = GenPackageReference(field.value.type);
field_type_name = package_reference + "." + TypeName(field);
}
code += GenIndents(4) + "if " + struct_instance_name + "." +
field_accessor_name + "(i) is None:";
code += GenIndents(5) + "self." + field_instance_name + ".append(None)";
code += GenIndents(4) + "else:";
code += GenIndents(5) + one_instance + " = " + field_type_name +
"T.InitFromObj(" + struct_instance_name + "." +
field_accessor_name + "(i))";
code += GenIndents(5) + "self." + field_instance_name + ".append(" +
one_instance + ")";
}
void GenUnpackforScalarVectorHelper(const StructDef &struct_def,
const FieldDef &field,
std::string *code_ptr, int indents) {
auto &code = *code_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto struct_instance_name = MakeLowerCamel(struct_def);
code += GenIndents(indents) + "self." + field_instance_name + " = []";
code += GenIndents(indents) + "for i in range(" + struct_instance_name +
"." + field_accessor_name + "Length()):";
code += GenIndents(indents + 1) + "self." + field_instance_name +
".append(" + struct_instance_name + "." + field_accessor_name +
"(i))";
}
void GenUnPackForScalarVector(const StructDef &struct_def,
const FieldDef &field, std::string *code_ptr) {
auto &code = *code_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto struct_instance_name = MakeLowerCamel(struct_def);
code += GenIndents(2) + "if not " + struct_instance_name + "." +
field_accessor_name + "IsNone():";
// String does not have the AsNumpy method.
if (!(IsScalar(field.value.type.VectorType().base_type))) {
GenUnpackforScalarVectorHelper(struct_def, field, code_ptr, 3);
return;
}
code += GenIndents(3) + "if np is None:";
GenUnpackforScalarVectorHelper(struct_def, field, code_ptr, 4);
// If numpy exists, use the AsNumpy method to optimize the unpack speed.
code += GenIndents(3) + "else:";
code += GenIndents(4) + "self." + field_instance_name + " = " +
struct_instance_name + "." + field_accessor_name + "AsNumpy()";
}
void GenUnPackForScalar(const StructDef &struct_def, const FieldDef &field,
std::string *code_ptr) {
auto &code = *code_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto struct_instance_name = MakeLowerCamel(struct_def);
code += GenIndents(2) + "self." + field_instance_name + " = " +
struct_instance_name + "." + field_accessor_name + "()";
}
// Generates the UnPack method for the object class.
void GenUnPack(const StructDef &struct_def, std::string *code_ptr) {
std::string code;
// Items that needs to be imported. No duplicate modules will be imported.
std::set<std::string> import_list;
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end(); ++it) {
auto &field = **it;
if (field.deprecated) continue;
auto field_type = TypeName(field);
switch (field.value.type.base_type) {
case BASE_TYPE_STRUCT: {
GenUnPackForStruct(struct_def, field, &code);
break;
}
case BASE_TYPE_UNION: {
GenUnPackForUnion(struct_def, field, &code);
break;
}
case BASE_TYPE_VECTOR: {
auto vectortype = field.value.type.VectorType();
if (vectortype.base_type == BASE_TYPE_STRUCT) {
GenUnPackForStructVector(struct_def, field, &code);
} else {
GenUnPackForScalarVector(struct_def, field, &code);
}
break;
}
case BASE_TYPE_ARRAY: {
GenUnPackForScalarVector(struct_def, field, &code);
break;
}
default:
GenUnPackForScalar(struct_def, field, &code);
}
}
// Writes import statements and code into the generated file.
auto &code_base = *code_ptr;
auto struct_instance_name = MakeLowerCamel(struct_def);
auto struct_name = MakeUpperCamel(struct_def);
GenReceiverForObjectAPI(struct_def, code_ptr);
code_base += "_UnPack(self, " + struct_instance_name + "):";
code_base += GenIndents(2) + "if " + struct_instance_name + " is None:";
code_base += GenIndents(3) + "return";
// Write the import statements.
for (std::set<std::string>::iterator it = import_list.begin();
it != import_list.end(); ++it) {
code_base += GenIndents(2) + *it;
}
// Write the code.
code_base += code;
code_base += "\n";
}
void GenPackForStruct(const StructDef &struct_def, std::string *code_ptr) {
auto &code = *code_ptr;
auto struct_name = MakeUpperCamel(struct_def);
GenReceiverForObjectAPI(struct_def, code_ptr);
code += "Pack(self, builder):";
code += GenIndents(2) + "return Create" + struct_name + "(builder";
StructBuilderArgs(struct_def,
/* nameprefix = */ "self.",
/* namesuffix = */ "",
/* has_field_name = */ true,
/* fieldname_suffix = */ ".", code_ptr);
code += ")\n";
}
void GenPackForStructVectorField(const StructDef &struct_def,
const FieldDef &field,
std::string *code_prefix_ptr,
std::string *code_ptr) {
auto &code_prefix = *code_prefix_ptr;
auto &code = *code_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto struct_name = NormalizedName(struct_def);
auto field_accessor_name = MakeUpperCamel(field);
// Creates the field.
code_prefix +=
GenIndents(2) + "if self." + field_instance_name + " is not None:";
if (field.value.type.struct_def->fixed) {
code_prefix += GenIndents(3) + struct_name + "Start" +
field_accessor_name + "Vector(builder, len(self." +
field_instance_name + "))";
code_prefix += GenIndents(3) + "for i in reversed(range(len(self." +
field_instance_name + "))):";
code_prefix +=
GenIndents(4) + "self." + field_instance_name + "[i].Pack(builder)";
code_prefix += GenIndents(3) + field_instance_name +
" = builder.EndVector(len(self." + field_instance_name +
"))";
} else {
// If the vector is a struct vector, we need to first build accessor for
// each struct element.
code_prefix += GenIndents(3) + field_instance_name + "list = []";
code_prefix += GenIndents(3);
code_prefix += "for i in range(len(self." + field_instance_name + ")):";
code_prefix += GenIndents(4) + field_instance_name + "list.append(self." +
field_instance_name + "[i].Pack(builder))";
code_prefix += GenIndents(3) + struct_name + "Start" +
field_accessor_name + "Vector(builder, len(self." +
field_instance_name + "))";
code_prefix += GenIndents(3) + "for i in reversed(range(len(self." +
field_instance_name + "))):";
code_prefix += GenIndents(4) + "builder.PrependUOffsetTRelative" + "(" +
field_instance_name + "list[i])";
code_prefix += GenIndents(3) + field_instance_name +
" = builder.EndVector(len(self." + field_instance_name +
"))";
}
// Adds the field into the struct.
code += GenIndents(2) + "if self." + field_instance_name + " is not None:";
code += GenIndents(3) + struct_name + "Add" + field_accessor_name +
"(builder, " + field_instance_name + ")";
}
void GenPackForScalarVectorFieldHelper(const StructDef &struct_def,
const FieldDef &field,
std::string *code_ptr, int indents) {
auto &code = *code_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto struct_name = NormalizedName(struct_def);
auto vectortype = field.value.type.VectorType();
code += GenIndents(indents) + struct_name + "Start" + field_accessor_name +
"Vector(builder, len(self." + field_instance_name + "))";
code += GenIndents(indents) + "for i in reversed(range(len(self." +
field_instance_name + "))):";
code += GenIndents(indents + 1) + "builder.Prepend";
std::string type_name;
switch (vectortype.base_type) {
case BASE_TYPE_BOOL:
type_name = "Bool";
break;
case BASE_TYPE_CHAR:
type_name = "Byte";
break;
case BASE_TYPE_UCHAR:
type_name = "Uint8";
break;
case BASE_TYPE_SHORT:
type_name = "Int16";
break;
case BASE_TYPE_USHORT:
type_name = "Uint16";
break;
case BASE_TYPE_INT:
type_name = "Int32";
break;
case BASE_TYPE_UINT:
type_name = "Uint32";
break;
case BASE_TYPE_LONG:
type_name = "Int64";
break;
case BASE_TYPE_ULONG:
type_name = "Uint64";
break;
case BASE_TYPE_FLOAT:
type_name = "Float32";
break;
case BASE_TYPE_DOUBLE:
type_name = "Float64";
break;
case BASE_TYPE_STRING:
type_name = "UOffsetTRelative";
break;
default:
type_name = "VOffsetT";
break;
}
code += type_name;
}
void GenPackForScalarVectorField(const StructDef &struct_def,
const FieldDef &field,
std::string *code_prefix_ptr,
std::string *code_ptr) {
auto &code = *code_ptr;
auto &code_prefix = *code_prefix_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto struct_name = NormalizedName(struct_def);
// Adds the field into the struct.
code += GenIndents(2) + "if self." + field_instance_name + " is not None:";
code += GenIndents(3) + struct_name + "Add" + field_accessor_name +
"(builder, " + field_instance_name + ")";
// Creates the field.
code_prefix +=
GenIndents(2) + "if self." + field_instance_name + " is not None:";
// If the vector is a string vector, we need to first build accessor for
// each string element. And this generated code, needs to be
// placed ahead of code_prefix.
auto vectortype = field.value.type.VectorType();
if (vectortype.base_type == BASE_TYPE_STRING) {
code_prefix += GenIndents(3) + MakeLowerCamel(field) + "list = []";
code_prefix += GenIndents(3) + "for i in range(len(self." +
field_instance_name + ")):";
code_prefix += GenIndents(4) + MakeLowerCamel(field) +
"list.append(builder.CreateString(self." +
field_instance_name + "[i]))";
GenPackForScalarVectorFieldHelper(struct_def, field, code_prefix_ptr, 3);
code_prefix += "(" + MakeLowerCamel(field) + "list[i])";
code_prefix += GenIndents(3) + field_instance_name +
" = builder.EndVector(len(self." + field_instance_name +
"))";
return;
}
code_prefix += GenIndents(3) + "if np is not None and type(self." +
field_instance_name + ") is np.ndarray:";
code_prefix += GenIndents(4) + field_instance_name +
" = builder.CreateNumpyVector(self." + field_instance_name +
")";
code_prefix += GenIndents(3) + "else:";
GenPackForScalarVectorFieldHelper(struct_def, field, code_prefix_ptr, 4);
code_prefix += "(self." + field_instance_name + "[i])";
code_prefix += GenIndents(4) + field_instance_name +
" = builder.EndVector(len(self." + field_instance_name +
"))";
}
void GenPackForStructField(const StructDef &struct_def, const FieldDef &field,
std::string *code_prefix_ptr,
std::string *code_ptr) {
auto &code_prefix = *code_prefix_ptr;
auto &code = *code_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto struct_name = NormalizedName(struct_def);
if (field.value.type.struct_def->fixed) {
// Pure struct fields need to be created along with their parent
// structs.
code +=
GenIndents(2) + "if self." + field_instance_name + " is not None:";
code += GenIndents(3) + field_instance_name + " = self." +
field_instance_name + ".Pack(builder)";
} else {
// Tables need to be created before their parent structs are created.
code_prefix +=
GenIndents(2) + "if self." + field_instance_name + " is not None:";
code_prefix += GenIndents(3) + field_instance_name + " = self." +
field_instance_name + ".Pack(builder)";
code +=
GenIndents(2) + "if self." + field_instance_name + " is not None:";
}
code += GenIndents(3) + struct_name + "Add" + field_accessor_name +
"(builder, " + field_instance_name + ")";
}
void GenPackForUnionField(const StructDef &struct_def, const FieldDef &field,
std::string *code_prefix_ptr,
std::string *code_ptr) {
auto &code_prefix = *code_prefix_ptr;
auto &code = *code_ptr;
auto field_instance_name = MakeLowerCamel(field);
auto field_accessor_name = MakeUpperCamel(field);
auto struct_name = NormalizedName(struct_def);
// TODO(luwa): TypeT should be moved under the None check as well.
code_prefix +=
GenIndents(2) + "if self." + field_instance_name + " is not None:";
code_prefix += GenIndents(3) + field_instance_name + " = self." +
field_instance_name + ".Pack(builder)";
code += GenIndents(2) + "if self." + field_instance_name + " is not None:";
code += GenIndents(3) + struct_name + "Add" + field_accessor_name +
"(builder, " + field_instance_name + ")";
}
void GenPackForTable(const StructDef &struct_def, std::string *code_ptr) {
auto &code_base = *code_ptr;
std::string code, code_prefix;
auto struct_instance_name = MakeLowerCamel(struct_def);
auto struct_name = NormalizedName(struct_def);
GenReceiverForObjectAPI(struct_def, code_ptr);
code_base += "Pack(self, builder):";
code += GenIndents(2) + struct_name + "Start(builder)";
for (auto it = struct_def.fields.vec.begin();
it != struct_def.fields.vec.end(); ++it) {
auto &field = **it;
if (field.deprecated) continue;
auto field_accessor_name = MakeUpperCamel(field);
auto field_instance_name = MakeLowerCamel(field);
switch (field.value.type.base_type) {
case BASE_TYPE_STRUCT: {
GenPackForStructField(struct_def, field, &code_prefix, &code);
break;
}
case BASE_TYPE_UNION: {
GenPackForUnionField(struct_def, field, &code_prefix, &code);
break;
}
case BASE_TYPE_VECTOR: {
auto vectortype = field.value.type.VectorType();
if (vectortype.base_type == BASE_TYPE_STRUCT) {
GenPackForStructVectorField(struct_def, field, &code_prefix, &code);
} else {
GenPackForScalarVectorField(struct_def, field, &code_prefix, &code);
}
break;
}
case BASE_TYPE_ARRAY: {
GenPackForScalarVectorField(struct_def, field, &code_prefix, &code);
break;
}
case BASE_TYPE_STRING: {
code_prefix += GenIndents(2) + "if self." + field_instance_name +
" is not None:";
code_prefix += GenIndents(3) + field_instance_name +
" = builder.CreateString(self." + field_instance_name +
")";
code += GenIndents(2) + "if self." + field_instance_name +
" is not None:";
code += GenIndents(3) + struct_name + "Add" + field_accessor_name +
"(builder, " + field_instance_name + ")";
break;
}
default:
// Generates code for scalar values. If the value equals to the
// default value, builder will automatically ignore it. So we don't
// need to check the value ahead.
code += GenIndents(2) + struct_name + "Add" + field_accessor_name +
"(builder, self." + field_instance_name + ")";
break;
}
}
code += GenIndents(2) + struct_instance_name + " = " + struct_name +
"End(builder)";
code += GenIndents(2) + "return " + struct_instance_name;
code_base += code_prefix + code;
code_base += "\n";
}
void GenStructForObjectAPI(const StructDef &struct_def,
std::string *code_ptr) {
if (struct_def.generated) return;
std::set<std::string> import_list;
std::string code;
// Creates an object class for a struct or a table
BeginClassForObjectAPI(struct_def, &code);
GenInitialize(struct_def, &code, &import_list);
InitializeFromBuf(struct_def, &code);
InitializeFromObjForObject(struct_def, &code);
GenUnPack(struct_def, &code);
if (struct_def.fixed) {
GenPackForStruct(struct_def, &code);
} else {
GenPackForTable(struct_def, &code);
}
// Adds the imports at top.
auto &code_base = *code_ptr;
code_base += "\n";
for (auto it = import_list.begin(); it != import_list.end(); it++) {
auto im = *it;
code_base += im + "\n";
}
code_base += code;
}
void GenUnionCreatorForStruct(const EnumDef &enum_def, const EnumVal &ev,
std::string *code_ptr) {
auto &code = *code_ptr;
auto union_name = NormalizedName(enum_def);
auto field_name = NormalizedName(ev);
auto field_type = GenTypeGet(ev.union_type) + "T";
code += GenIndents(1) + "if unionType == " + union_name + "()." +
field_name + ":";
if (parser_.opts.include_dependence_headers) {
auto package_reference = GenPackageReference(ev.union_type);
code += GenIndents(2) + "import " + package_reference;
field_type = package_reference + "." + field_type;
}
code += GenIndents(2) + "return " + field_type +
".InitFromBuf(table.Bytes, table.Pos)";
}
void GenUnionCreatorForString(const EnumDef &enum_def, const EnumVal &ev,
std::string *code_ptr) {
auto &code = *code_ptr;
auto union_name = NormalizedName(enum_def);
auto field_name = NormalizedName(ev);
code += GenIndents(1) + "if unionType == " + union_name + "()." +
field_name + ":";
code += GenIndents(2) + "tab = Table(table.Bytes, table.Pos)";
code += GenIndents(2) + "union = tab.String(table.Pos)";
code += GenIndents(2) + "return union";
}
// Creates an union object based on union type.
void GenUnionCreator(const EnumDef &enum_def, std::string *code_ptr) {
auto &code = *code_ptr;
auto union_name = MakeUpperCamel(enum_def);
code += "\n";
code += "def " + union_name + "Creator(unionType, table):";
code += GenIndents(1) + "from flatbuffers.table import Table";
code += GenIndents(1) + "if not isinstance(table, Table):";
code += GenIndents(2) + "return None";
for (auto it = enum_def.Vals().begin(); it != enum_def.Vals().end(); ++it) {
auto &ev = **it;
// Union only supports string and table.
switch (ev.union_type.base_type) {
case BASE_TYPE_STRUCT:
GenUnionCreatorForStruct(enum_def, ev, &code);
break;
case BASE_TYPE_STRING:
GenUnionCreatorForString(enum_def, ev, &code);
break;
default:
break;
}
}
code += GenIndents(1) + "return None";
code += "\n";
}
// Generate enum declarations.
void GenEnum(const EnumDef &enum_def, std::string *code_ptr) {
if (enum_def.generated) return;
GenComment(enum_def.doc_comment, code_ptr, &def_comment);
BeginEnum(NormalizedName(enum_def), code_ptr);
for (auto it = enum_def.Vals().begin(); it != enum_def.Vals().end(); ++it) {
auto &ev = **it;
GenComment(ev.doc_comment, code_ptr, &def_comment, Indent.c_str());
EnumMember(enum_def, ev, code_ptr);
}
EndEnum(code_ptr);
}
// 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 "self._tab.String(";
case BASE_TYPE_UNION: return "self._tab.Union(";
case BASE_TYPE_VECTOR: return GenGetter(type.VectorType());
default:
return "self._tab.Get(flatbuffers.number_types." +
MakeCamel(GenTypeGet(type)) + "Flags, ";
}
}
// Returns the method name for use with add/put calls.
std::string GenMethod(const FieldDef &field) {
return (IsScalar(field.value.type.base_type) || IsArray(field.value.type))
? MakeCamel(GenTypeBasic(field.value.type))
: (IsStruct(field.value.type) ? "Struct" : "UOffsetTRelative");
}
std::string GenTypeBasic(const Type &type) {
// clang-format off
static const char *ctypename[] = {
#define FLATBUFFERS_TD(ENUM, IDLTYPE, \
CTYPE, JTYPE, GTYPE, NTYPE, PTYPE, ...) \
#PTYPE,
FLATBUFFERS_GEN_TYPES(FLATBUFFERS_TD)
#undef FLATBUFFERS_TD
};
// clang-format on
return ctypename[IsArray(type) ? type.VectorType().base_type
: type.base_type];
}
std::string GenTypePointer(const Type &type) {
switch (type.base_type) {
case BASE_TYPE_STRING: return "string";
case BASE_TYPE_VECTOR: return GenTypeGet(type.VectorType());
case BASE_TYPE_STRUCT: return type.struct_def->name;
case BASE_TYPE_UNION:
// fall through
default: return "*flatbuffers.Table";
}
}
std::string GenTypeGet(const Type &type) {
return IsScalar(type.base_type) ? GenTypeBasic(type) : GenTypePointer(type);
}
std::string TypeName(const FieldDef &field) {
return GenTypeGet(field.value.type);
}
// Create a struct with a builder and the struct's arguments.
void GenStructBuilder(const StructDef &struct_def, std::string *code_ptr) {
BeginBuilderArgs(struct_def, code_ptr);
StructBuilderArgs(struct_def,
/* nameprefix = */ "",
/* namesuffix = */ "",
/* has_field_name = */ true,
/* fieldname_suffix = */ "_", code_ptr);
EndBuilderArgs(code_ptr);
StructBuilderBody(struct_def, "", code_ptr);
EndBuilderBody(code_ptr);
}
bool generate() {
if (!generateEnums()) return false;
if (!generateStructs()) return false;
return true;
}
private:
bool generateEnums() {
for (auto it = parser_.enums_.vec.begin(); it != parser_.enums_.vec.end();
++it) {
auto &enum_def = **it;
std::string enumcode;
GenEnum(enum_def, &enumcode);
if (parser_.opts.generate_object_based_api & enum_def.is_union) {
GenUnionCreator(enum_def, &enumcode);
}
if (!SaveType(enum_def, enumcode, false)) return false;
}
return true;
}
bool generateStructs() {
for (auto it = parser_.structs_.vec.begin();
it != parser_.structs_.vec.end(); ++it) {
auto &struct_def = **it;
std::string declcode;
GenStruct(struct_def, &declcode);
if (parser_.opts.generate_object_based_api) {
GenStructForObjectAPI(struct_def, &declcode);
}
if (!SaveType(struct_def, declcode, true)) return false;
}
return true;
}
// Begin by declaring namespace and imports.
void BeginFile(const std::string &name_space_name, const bool needs_imports,
std::string *code_ptr) {
auto &code = *code_ptr;
code = code + "# " + FlatBuffersGeneratedWarning() + "\n\n";
code += "# namespace: " + name_space_name + "\n\n";
if (needs_imports) {
code += "import flatbuffers\n";
code += "from flatbuffers.compat import import_numpy\n";
code += "np = import_numpy()\n\n";
}
}
// Save out the generated code for a Python Table type.
bool SaveType(const Definition &def, const std::string &classcode,
bool needs_imports) {
if (!classcode.length()) return true;
std::string namespace_dir = path_;
auto &namespaces = def.defined_namespace->components;
for (auto it = namespaces.begin(); it != namespaces.end(); ++it) {
if (it != namespaces.begin()) namespace_dir += kPathSeparator;
namespace_dir += *it;
std::string init_py_filename = namespace_dir + "/__init__.py";
SaveFile(init_py_filename.c_str(), "", false);
}
std::string code = "";
BeginFile(LastNamespacePart(*def.defined_namespace), needs_imports, &code);
code += classcode;
std::string filename =
NamespaceDir(*def.defined_namespace) + NormalizedName(def) + ".py";
return SaveFile(filename.c_str(), code, false);
}
private:
std::unordered_set<std::string> keywords_;
const SimpleFloatConstantGenerator float_const_gen_;
};
} // namespace python
bool GeneratePython(const Parser &parser, const std::string &path,
const std::string &file_name) {
python::PythonGenerator generator(parser, path, file_name);
return generator.generate();
}
} // namespace flatbuffers