src/google/protobuf/compiler/javanano/javanano_enum_field.cc - platform/external/protobuf - Git at Google

 // Protocol Buffers - Google's data interchange format
 // Copyright 2008 Google Inc.  All rights reserved.
 // http://code.google.com/p/protobuf/
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 // notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 // copyright notice, this list of conditions and the following disclaimer
 // in the documentation and/or other materials provided with the
 // distribution.
 //     * Neither the name of Google Inc. nor the names of its
 // contributors may be used to endorse or promote products derived from
 // this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 // Author: kenton@google.com (Kenton Varda)
 //  Based on original Protocol Buffers design by
 //  Sanjay Ghemawat, Jeff Dean, and others.

 #include <map>
 #include <string>

 #include <google/protobuf/compiler/javanano/javanano_enum_field.h>
 #include <google/protobuf/stubs/common.h>
 #include <google/protobuf/compiler/javanano/javanano_helpers.h>
 #include <google/protobuf/io/printer.h>
 #include <google/protobuf/wire_format.h>
 #include <google/protobuf/stubs/strutil.h>

 namespace google {
 namespace protobuf {
 namespace compiler {
 namespace javanano {

 namespace {

 // TODO(kenton):  Factor out a "SetCommonFieldVariables()" to get rid of
 //   repeat code between this and the other field types.
 void SetEnumVariables(const Params& params,
     const FieldDescriptor* descriptor, map<string, string>* variables) {
   (*variables)["name"] =
     RenameJavaKeywords(UnderscoresToCamelCase(descriptor));
   (*variables)["capitalized_name"] =
     RenameJavaKeywords(UnderscoresToCapitalizedCamelCase(descriptor));
   (*variables)["number"] = SimpleItoa(descriptor->number());
   if (params.use_reference_types_for_primitives()
       && !params.reftypes_primitive_enums()
       && !descriptor->is_repeated()) {
     (*variables)["type"] = "java.lang.Integer";
     (*variables)["default"] = "null";
   } else {
     (*variables)["type"] = "int";
     (*variables)["default"] = DefaultValue(params, descriptor);
   }
   (*variables)["repeated_default"] =
       "com.google.protobuf.nano.WireFormatNano.EMPTY_INT_ARRAY";
   (*variables)["tag"] = SimpleItoa(internal::WireFormat::MakeTag(descriptor));
   (*variables)["tag_size"] = SimpleItoa(
       internal::WireFormat::TagSize(descriptor->number(), descriptor->type()));
   (*variables)["non_packed_tag"] = SimpleItoa(
       internal::WireFormatLite::MakeTag(descriptor->number(),
           internal::WireFormat::WireTypeForFieldType(descriptor->type())));
   (*variables)["message_name"] = descriptor->containing_type()->name();
   const EnumDescriptor* enum_type = descriptor->enum_type();
   (*variables)["message_type_intdef"] = "@"
       + ToJavaName(params, enum_type->name(), true,
           enum_type->containing_type(), enum_type->file());
 }

 void LoadEnumValues(const Params& params,
     const EnumDescriptor* enum_descriptor, vector<string>* canonical_values) {
   string enum_class_name = ClassName(params, enum_descriptor);
   for (int i = 0; i < enum_descriptor->value_count(); i++) {
     const EnumValueDescriptor* value = enum_descriptor->value(i);
     const EnumValueDescriptor* canonical_value =
         enum_descriptor->FindValueByNumber(value->number());
     if (value == canonical_value) {
       canonical_values->push_back(
           enum_class_name + "." + RenameJavaKeywords(value->name()));
     }
   }
 }

 void PrintCaseLabels(
     io::Printer* printer, const vector<string>& canonical_values) {
   for (int i = 0; i < canonical_values.size(); i++) {
     printer->Print(
       "  case $value$:\n",
       "value", canonical_values[i]);
   }
 }

 }  // namespace

 // ===================================================================

 EnumFieldGenerator::
 EnumFieldGenerator(const FieldDescriptor* descriptor, const Params& params)
   : FieldGenerator(params), descriptor_(descriptor) {
   SetEnumVariables(params, descriptor, &variables_);
   LoadEnumValues(params, descriptor->enum_type(), &canonical_values_);
 }

 EnumFieldGenerator::~EnumFieldGenerator() {}

 void EnumFieldGenerator::
 GenerateMembers(io::Printer* printer, bool /* unused lazy_init */) const {
   if (params_.generate_intdefs()) {
     printer->Print(variables_, "$message_type_intdef$\n");
   }
   printer->Print(variables_, "public $type$ $name$;\n");

   if (params_.generate_has()) {
     printer->Print(variables_,
       "public boolean has$capitalized_name$;\n");
   }
 }

 void EnumFieldGenerator::
 GenerateClearCode(io::Printer* printer) const {
   printer->Print(variables_,
     "$name$ = $default$;\n");

   if (params_.generate_has()) {
     printer->Print(variables_,
       "has$capitalized_name$ = false;\n");
   }
 }

 void EnumFieldGenerator::
 GenerateMergingCode(io::Printer* printer) const {
   if (params_.store_unknown_fields()) {
     printer->Print("int initialPos = input.getPosition();\n");
   }
   printer->Print(variables_,
     "int value = input.readInt32();\n"
     "switch (value) {\n");
   PrintCaseLabels(printer, canonical_values_);
   printer->Print(variables_,
     "    this.$name$ = value;\n");
   if (params_.generate_has()) {
     printer->Print(variables_,
       "    has$capitalized_name$ = true;\n");
   }
   printer->Print(
     "    break;\n");
   if (params_.store_unknown_fields()) {
     // If storing unknown fields, store invalid values there.
     // This is consistent with full protobuf, but note that if a client writes
     // a new value to this field, both will be serialized on the wire, and
     // other clients which are aware of unknown fields will see the previous
     // value, not the new one.
     printer->Print(
       "  default:\n"
       "    input.rewindToPosition(initialPos);\n"
       "    storeUnknownField(input, tag);\n"
       "    break;\n");
   }
   printer->Print("}\n");
 }

 void EnumFieldGenerator::
 GenerateSerializationCode(io::Printer* printer) const {
   if (descriptor_->is_required() && !params_.generate_has()) {
     // Always serialize a required field if we don't have the 'has' signal.
     printer->Print(variables_,
       "output.writeInt32($number$, this.$name$);\n");
   } else {
     if (params_.generate_has()) {
       printer->Print(variables_,
         "if (this.$name$ != $default$ || has$capitalized_name$) {\n");
     } else {
       printer->Print(variables_,
         "if (this.$name$ != $default$) {\n");
     }
     printer->Print(variables_,
       "  output.writeInt32($number$, this.$name$);\n"
       "}\n");
   }
 }

 void EnumFieldGenerator::
 GenerateSerializedSizeCode(io::Printer* printer) const {
   if (descriptor_->is_required() && !params_.generate_has()) {
     printer->Print(variables_,
       "size += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
       "  .computeInt32Size($number$, this.$name$);\n");
   } else {
     if (params_.generate_has()) {
       printer->Print(variables_,
         "if (this.$name$ != $default$ || has$capitalized_name$) {\n");
     } else {
       printer->Print(variables_,
         "if (this.$name$ != $default$) {\n");
     }
     printer->Print(variables_,
       "  size += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
       "    .computeInt32Size($number$, this.$name$);\n"
       "}\n");
   }
 }

 void EnumFieldGenerator::GenerateEqualsCode(io::Printer* printer) const {
   if (params_.use_reference_types_for_primitives()
         && !params_.reftypes_primitive_enums()) {
     printer->Print(variables_,
       "if (this.$name$ == null) {\n"
       "  if (other.$name$ != null) {\n"
       "    return false;\n"
       "  }\n"
       "} else if (!this.$name$.equals(other.$name$)) {\n"
       "  return false;"
       "}\n");
   } else {
     // We define equality as serialized form equality. If generate_has(),
     // then if the field value equals the default value in both messages,
     // but one's 'has' field is set and the other's is not, the serialized
     // forms are different and we should return false.
     printer->Print(variables_,
       "if (this.$name$ != other.$name$");
     if (params_.generate_has()) {
       printer->Print(variables_,
         "\n"
         "    || (this.$name$ == $default$\n"
         "        && this.has$capitalized_name$ != other.has$capitalized_name$)");
     }
     printer->Print(") {\n"
       "  return false;\n"
       "}\n");
   }
 }

 void EnumFieldGenerator::GenerateHashCodeCode(io::Printer* printer) const {
   printer->Print(
     "result = 31 * result + ");
   if (params_.use_reference_types_for_primitives()
         && !params_.reftypes_primitive_enums()) {
     printer->Print(variables_,
       "(this.$name$ == null ? 0 : this.$name$)");
   } else {
     printer->Print(variables_,
       "this.$name$");
   }
   printer->Print(";\n");
 }

 // ===================================================================

 AccessorEnumFieldGenerator::
 AccessorEnumFieldGenerator(const FieldDescriptor* descriptor,
     const Params& params, int has_bit_index)
   : FieldGenerator(params), descriptor_(descriptor) {
   SetEnumVariables(params, descriptor, &variables_);
   LoadEnumValues(params, descriptor->enum_type(), &canonical_values_);
   SetBitOperationVariables("has", has_bit_index, &variables_);
 }

 AccessorEnumFieldGenerator::~AccessorEnumFieldGenerator() {}

 void AccessorEnumFieldGenerator::
 GenerateMembers(io::Printer* printer, bool /* unused lazy_init */) const {
   printer->Print(variables_, "private int $name$_;\n");
   if (params_.generate_intdefs()) {
     printer->Print(variables_, "$message_type_intdef$\n");
   }
   printer->Print(variables_,
     "public int get$capitalized_name$() {\n"
     "  return $name$_;\n"
     "}\n"
     "public $message_name$ set$capitalized_name$(");
   if (params_.generate_intdefs()) {
     printer->Print(variables_,
       "\n"
       "    $message_type_intdef$ ");
   }
   printer->Print(variables_,
     "int value) {\n"
     "  $name$_ = value;\n"
     "  $set_has$;\n"
     "  return this;\n"
     "}\n"
     "public boolean has$capitalized_name$() {\n"
     "  return $get_has$;\n"
     "}\n"
     "public $message_name$ clear$capitalized_name$() {\n"
     "  $name$_ = $default$;\n"
     "  $clear_has$;\n"
     "  return this;\n"
     "}\n");
 }

 void AccessorEnumFieldGenerator::
 GenerateClearCode(io::Printer* printer) const {
   printer->Print(variables_,
     "$name$_ = $default$;\n");
 }

 void AccessorEnumFieldGenerator::
 GenerateMergingCode(io::Printer* printer) const {
   if (params_.store_unknown_fields()) {
     printer->Print("int initialPos = input.getPosition();\n");
   }
   printer->Print(variables_,
     "int value = input.readInt32();\n"
     "switch (value) {\n");
   PrintCaseLabels(printer, canonical_values_);
   printer->Print(variables_,
     "    $name$_ = value;\n"
     "    $set_has$;\n"
     "    break;\n");
   if (params_.store_unknown_fields()) {
     // If storing unknown fields, store invalid values there.
     // This is consistent with full protobuf, but note that if a client writes
     // a new value to this field, both will be serialized on the wire, and
     // other clients which are aware of unknown fields will see the previous
     // value, not the new one.
     printer->Print(
       "  default:\n"
       "    input.rewindToPosition(initialPos);\n"
       "    storeUnknownField(input, tag);\n"
       "    break;\n");
   }
   printer->Print("}\n");
 }

 void AccessorEnumFieldGenerator::
 GenerateSerializationCode(io::Printer* printer) const {
   printer->Print(variables_,
     "if ($get_has$) {\n"
     "  output.writeInt32($number$, $name$_);\n"
     "}\n");
 }

 void AccessorEnumFieldGenerator::
 GenerateSerializedSizeCode(io::Printer* printer) const {
   printer->Print(variables_,
     "if ($get_has$) {\n"
     "  size += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
     "    .computeInt32Size($number$, $name$_);\n"
     "}\n");
 }

 void AccessorEnumFieldGenerator::
 GenerateEqualsCode(io::Printer* printer) const {
   printer->Print(variables_,
     "if ($different_has$\n"
     "    || $name$_ != other.$name$_) {\n"
     "  return false;\n"
     "}\n");
 }

 void AccessorEnumFieldGenerator::
 GenerateHashCodeCode(io::Printer* printer) const {
   printer->Print(variables_,
     "result = 31 * result + $name$_;\n");
 }

 // ===================================================================

 RepeatedEnumFieldGenerator::
 RepeatedEnumFieldGenerator(const FieldDescriptor* descriptor, const Params& params)
   : FieldGenerator(params), descriptor_(descriptor) {
   SetEnumVariables(params, descriptor, &variables_);
   LoadEnumValues(params, descriptor->enum_type(), &canonical_values_);
 }

 RepeatedEnumFieldGenerator::~RepeatedEnumFieldGenerator() {}

 void RepeatedEnumFieldGenerator::
 GenerateMembers(io::Printer* printer, bool /* unused lazy_init */) const {
   printer->Print(variables_,
     "public $type$[] $name$;\n");
 }

 void RepeatedEnumFieldGenerator::
 GenerateClearCode(io::Printer* printer) const {
   printer->Print(variables_,
     "$name$ = $repeated_default$;\n");
 }

 void RepeatedEnumFieldGenerator::
 GenerateMergingCode(io::Printer* printer) const {
   // First, figure out the maximum length of the array, then parse,
   // and finally copy the valid values to the field.
   printer->Print(variables_,
     "int length = com.google.protobuf.nano.WireFormatNano\n"
     "    .getRepeatedFieldArrayLength(input, $non_packed_tag$);\n"
     "int[] validValues = new int[length];\n"
     "int validCount = 0;\n"
     "for (int i = 0; i < length; i++) {\n"
     "  if (i != 0) { // tag for first value already consumed.\n"
     "    input.readTag();\n"
     "  }\n");
   if (params_.store_unknown_fields()) {
     printer->Print("  int initialPos = input.getPosition();\n");
   }
   printer->Print(
     "  int value = input.readInt32();\n"
     "  switch (value) {\n");
   printer->Indent();
   PrintCaseLabels(printer, canonical_values_);
   printer->Outdent();
   printer->Print(variables_,
     "      validValues[validCount++] = value;\n"
     "      break;\n");
   if (params_.store_unknown_fields()) {
     // If storing unknown fields, store invalid values there.
     // This is consistent with full protobuf. Note that this can lead to very
     // strange behaviors if a value is serialized and reread, e.g. changes in
     // value ordering.
     printer->Print(
       "    default:\n"
       "      input.rewindToPosition(initialPos);\n"
       "      storeUnknownField(input, tag);\n"
       "      break;\n");
   }
   printer->Print(variables_,
     "  }\n"
     "}\n"
     "if (validCount != 0) {\n"
     "  int i = this.$name$ == null ? 0 : this.$name$.length;\n"
     "  if (i == 0 && validCount == validValues.length) {\n"
     "    this.$name$ = validValues;\n"
     "  } else {\n"
     "    int[] newArray = new int[i + validCount];\n"
     "    if (i != 0) {\n"
     "      java.lang.System.arraycopy(this.$name$, 0, newArray, 0, i);\n"
     "    }\n"
     "    java.lang.System.arraycopy(validValues, 0, newArray, i, validCount);\n"
     "    this.$name$ = newArray;\n"
     "  }\n"
     "}\n");
 }

 void RepeatedEnumFieldGenerator::
 GenerateMergingCodeFromPacked(io::Printer* printer) const {
   printer->Print(variables_,
     "int bytes = input.readRawVarint32();\n"
     "int limit = input.pushLimit(bytes);\n"
     "// First pass to compute array length.\n"
     "int arrayLength = 0;\n"
     "int startPos = input.getPosition();\n"
     "while (input.getBytesUntilLimit() > 0) {\n"
     "  switch (input.readInt32()) {\n");
   printer->Indent();
   PrintCaseLabels(printer, canonical_values_);
   printer->Outdent();
   printer->Print(variables_,
     "      arrayLength++;\n"
     "      break;\n"
     "  }\n"
     "}\n"
     "if (arrayLength != 0) {\n"
     "  input.rewindToPosition(startPos);\n"
     "  int i = this.$name$ == null ? 0 : this.$name$.length;\n"
     "  int[] newArray = new int[i + arrayLength];\n"
     "  if (i != 0) {\n"
     "    java.lang.System.arraycopy(this.$name$, 0, newArray, 0, i);\n"
     "  }\n"
     "  while (input.getBytesUntilLimit() > 0) {\n");
   if (params_.store_unknown_fields()) {
     printer->Print("    int initialPos = input.getPosition();\n");
   }
   printer->Print(variables_,
     "    int value = input.readInt32();\n"
     "    switch (value) {\n");
   printer->Indent();
   printer->Indent();
   PrintCaseLabels(printer, canonical_values_);
   printer->Outdent();
   printer->Outdent();
   printer->Print(variables_,
     "        newArray[i++] = value;\n"
     "        break;\n");
   if (params_.store_unknown_fields()) {
     // If storing unknown fields, store invalid values there.
     // This is consistent with full protobuf. Note that this can lead to very
     // strange behaviors if a value is serialized and reread, e.g. changes in
     // value ordering.
     printer->Print(variables_,
       "      default:\n"
       "        input.rewindToPosition(initialPos);\n"
       "        storeUnknownField(input, $non_packed_tag$);\n"
       "        break;\n");
   }
   printer->Print(variables_,
     "    }\n"
     "  }\n"
     "  this.$name$ = newArray;\n"
     "}\n"
     "input.popLimit(limit);\n");
 }

 void RepeatedEnumFieldGenerator::
 GenerateRepeatedDataSizeCode(io::Printer* printer) const {
   // Creates a variable dataSize and puts the serialized size in there.
   printer->Print(variables_,
     "int dataSize = 0;\n"
     "for (int i = 0; i < this.$name$.length; i++) {\n"
     "  int element = this.$name$[i];\n"
     "  dataSize += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
     "      .computeInt32SizeNoTag(element);\n"
     "}\n");
 }

 void RepeatedEnumFieldGenerator::
 GenerateSerializationCode(io::Printer* printer) const {
   printer->Print(variables_,
     "if (this.$name$ != null && this.$name$.length > 0) {\n");
   printer->Indent();

   if (descriptor_->options().packed()) {
     GenerateRepeatedDataSizeCode(printer);
     printer->Print(variables_,
       "output.writeRawVarint32($tag$);\n"
       "output.writeRawVarint32(dataSize);\n"
       "for (int i = 0; i < this.$name$.length; i++) {\n"
       "  output.writeRawVarint32(this.$name$[i]);\n"
       "}\n");
   } else {
     printer->Print(variables_,
       "for (int i = 0; i < this.$name$.length; i++) {\n"
       "  output.writeInt32($number$, this.$name$[i]);\n"
       "}\n");
   }

   printer->Outdent();
   printer->Print(variables_,
     "}\n");
 }

 void RepeatedEnumFieldGenerator::
 GenerateSerializedSizeCode(io::Printer* printer) const {
   printer->Print(variables_,
     "if (this.$name$ != null && this.$name$.length > 0) {\n");
   printer->Indent();

   GenerateRepeatedDataSizeCode(printer);

   printer->Print(
     "size += dataSize;\n");
   if (descriptor_->options().packed()) {
     printer->Print(variables_,
       "size += $tag_size$;\n"
       "size += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
       "    .computeRawVarint32Size(dataSize);\n");
   } else {
     printer->Print(variables_,
       "size += $tag_size$ * this.$name$.length;\n");
   }

   printer->Outdent();

   printer->Print(
     "}\n");
 }

 void RepeatedEnumFieldGenerator::
 GenerateFixClonedCode(io::Printer* printer) const {
   printer->Print(variables_,
     "if (this.$name$ != null && this.$name$.length > 0) {\n"
     "  cloned.$name$ = this.$name$.clone();\n"
     "}\n");
 }

 void RepeatedEnumFieldGenerator::
 GenerateEqualsCode(io::Printer* printer) const {
   printer->Print(variables_,
     "if (!com.google.protobuf.nano.InternalNano.equals(\n"
     "    this.$name$, other.$name$)) {\n"
     "  return false;\n"
     "}\n");
 }

 void RepeatedEnumFieldGenerator::
 GenerateHashCodeCode(io::Printer* printer) const {
   printer->Print(variables_,
     "result = 31 * result\n"
     "    + com.google.protobuf.nano.InternalNano.hashCode(this.$name$);\n");
 }

 }  // namespace javanano
 }  // namespace compiler
 }  // namespace protobuf
 }  // namespace google
	// Protocol Buffers - Google's data interchange format
	// Copyright 2008 Google Inc. All rights reserved.
	// http://code.google.com/p/protobuf/
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following disclaimer
	// in the documentation and/or other materials provided with the
	// distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived from
	// this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	// Author: kenton@google.com (Kenton Varda)
	// Based on original Protocol Buffers design by
	// Sanjay Ghemawat, Jeff Dean, and others.

	#include <map>
	#include <string>

	#include <google/protobuf/compiler/javanano/javanano_enum_field.h>
	#include <google/protobuf/stubs/common.h>
	#include <google/protobuf/compiler/javanano/javanano_helpers.h>
	#include <google/protobuf/io/printer.h>
	#include <google/protobuf/wire_format.h>
	#include <google/protobuf/stubs/strutil.h>

	namespace google {
	namespace protobuf {
	namespace compiler {
	namespace javanano {

	namespace {

	// TODO(kenton): Factor out a "SetCommonFieldVariables()" to get rid of
	// repeat code between this and the other field types.
	void SetEnumVariables(const Params& params,
	const FieldDescriptor* descriptor, map<string, string>* variables) {
	(*variables)["name"] =
	RenameJavaKeywords(UnderscoresToCamelCase(descriptor));
	(*variables)["capitalized_name"] =
	RenameJavaKeywords(UnderscoresToCapitalizedCamelCase(descriptor));
	(*variables)["number"] = SimpleItoa(descriptor->number());
	if (params.use_reference_types_for_primitives()
	&& !params.reftypes_primitive_enums()
	&& !descriptor->is_repeated()) {
	(*variables)["type"] = "java.lang.Integer";
	(*variables)["default"] = "null";
	} else {
	(*variables)["type"] = "int";
	(*variables)["default"] = DefaultValue(params, descriptor);
	}
	(*variables)["repeated_default"] =
	"com.google.protobuf.nano.WireFormatNano.EMPTY_INT_ARRAY";
	(*variables)["tag"] = SimpleItoa(internal::WireFormat::MakeTag(descriptor));
	(*variables)["tag_size"] = SimpleItoa(
	internal::WireFormat::TagSize(descriptor->number(), descriptor->type()));
	(*variables)["non_packed_tag"] = SimpleItoa(
	internal::WireFormatLite::MakeTag(descriptor->number(),
	internal::WireFormat::WireTypeForFieldType(descriptor->type())));
	(*variables)["message_name"] = descriptor->containing_type()->name();
	const EnumDescriptor* enum_type = descriptor->enum_type();
	(*variables)["message_type_intdef"] = "@"
	+ ToJavaName(params, enum_type->name(), true,
	enum_type->containing_type(), enum_type->file());
	}

	void LoadEnumValues(const Params& params,
	const EnumDescriptor* enum_descriptor, vector<string>* canonical_values) {
	string enum_class_name = ClassName(params, enum_descriptor);
	for (int i = 0; i < enum_descriptor->value_count(); i++) {
	const EnumValueDescriptor* value = enum_descriptor->value(i);
	const EnumValueDescriptor* canonical_value =
	enum_descriptor->FindValueByNumber(value->number());
	if (value == canonical_value) {
	canonical_values->push_back(
	enum_class_name + "." + RenameJavaKeywords(value->name()));
	}
	}
	}

	void PrintCaseLabels(
	io::Printer* printer, const vector<string>& canonical_values) {
	for (int i = 0; i < canonical_values.size(); i++) {
	printer->Print(
	" case $value$:\n",
	"value", canonical_values[i]);
	}
	}

	} // namespace

	// ===================================================================

	EnumFieldGenerator::
	EnumFieldGenerator(const FieldDescriptor* descriptor, const Params& params)
	: FieldGenerator(params), descriptor_(descriptor) {
	SetEnumVariables(params, descriptor, &variables_);
	LoadEnumValues(params, descriptor->enum_type(), &canonical_values_);
	}

	EnumFieldGenerator::~EnumFieldGenerator() {}

	void EnumFieldGenerator::
	GenerateMembers(io::Printer* printer, bool /* unused lazy_init */) const {
	if (params_.generate_intdefs()) {
	printer->Print(variables_, "$message_type_intdef$\n");
	}
	printer->Print(variables_, "public $type$ $name$;\n");

	if (params_.generate_has()) {
	printer->Print(variables_,
	"public boolean has$capitalized_name$;\n");
	}
	}

	void EnumFieldGenerator::
	GenerateClearCode(io::Printer* printer) const {
	printer->Print(variables_,
	"$name$ = $default$;\n");

	if (params_.generate_has()) {
	printer->Print(variables_,
	"has$capitalized_name$ = false;\n");
	}
	}

	void EnumFieldGenerator::
	GenerateMergingCode(io::Printer* printer) const {
	if (params_.store_unknown_fields()) {
	printer->Print("int initialPos = input.getPosition();\n");
	}
	printer->Print(variables_,
	"int value = input.readInt32();\n"
	"switch (value) {\n");
	PrintCaseLabels(printer, canonical_values_);
	printer->Print(variables_,
	" this.$name$ = value;\n");
	if (params_.generate_has()) {
	printer->Print(variables_,
	" has$capitalized_name$ = true;\n");
	}
	printer->Print(
	" break;\n");
	if (params_.store_unknown_fields()) {
	// If storing unknown fields, store invalid values there.
	// This is consistent with full protobuf, but note that if a client writes
	// a new value to this field, both will be serialized on the wire, and
	// other clients which are aware of unknown fields will see the previous
	// value, not the new one.
	printer->Print(
	" default:\n"
	" input.rewindToPosition(initialPos);\n"
	" storeUnknownField(input, tag);\n"
	" break;\n");
	}
	printer->Print("}\n");
	}

	void EnumFieldGenerator::
	GenerateSerializationCode(io::Printer* printer) const {
	if (descriptor_->is_required() && !params_.generate_has()) {
	// Always serialize a required field if we don't have the 'has' signal.
	printer->Print(variables_,
	"output.writeInt32($number$, this.$name$);\n");
	} else {
	if (params_.generate_has()) {
	printer->Print(variables_,
	"if (this.$name$ != $default$ \|\| has$capitalized_name$) {\n");
	} else {
	printer->Print(variables_,
	"if (this.$name$ != $default$) {\n");
	}
	printer->Print(variables_,
	" output.writeInt32($number$, this.$name$);\n"
	"}\n");
	}
	}

	void EnumFieldGenerator::
	GenerateSerializedSizeCode(io::Printer* printer) const {
	if (descriptor_->is_required() && !params_.generate_has()) {
	printer->Print(variables_,
	"size += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
	" .computeInt32Size($number$, this.$name$);\n");
	} else {
	if (params_.generate_has()) {
	printer->Print(variables_,
	"if (this.$name$ != $default$ \|\| has$capitalized_name$) {\n");
	} else {
	printer->Print(variables_,
	"if (this.$name$ != $default$) {\n");
	}
	printer->Print(variables_,
	" size += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
	" .computeInt32Size($number$, this.$name$);\n"
	"}\n");
	}
	}

	void EnumFieldGenerator::GenerateEqualsCode(io::Printer* printer) const {
	if (params_.use_reference_types_for_primitives()
	&& !params_.reftypes_primitive_enums()) {
	printer->Print(variables_,
	"if (this.$name$ == null) {\n"
	" if (other.$name$ != null) {\n"
	" return false;\n"
	" }\n"
	"} else if (!this.$name$.equals(other.$name$)) {\n"
	" return false;"
	"}\n");
	} else {
	// We define equality as serialized form equality. If generate_has(),
	// then if the field value equals the default value in both messages,
	// but one's 'has' field is set and the other's is not, the serialized
	// forms are different and we should return false.
	printer->Print(variables_,
	"if (this.$name$ != other.$name$");
	if (params_.generate_has()) {
	printer->Print(variables_,
	"\n"
	" \|\| (this.$name$ == $default$\n"
	" && this.has$capitalized_name$ != other.has$capitalized_name$)");
	}
	printer->Print(") {\n"
	" return false;\n"
	"}\n");
	}
	}

	void EnumFieldGenerator::GenerateHashCodeCode(io::Printer* printer) const {
	printer->Print(
	"result = 31 * result + ");
	if (params_.use_reference_types_for_primitives()
	&& !params_.reftypes_primitive_enums()) {
	printer->Print(variables_,
	"(this.$name$ == null ? 0 : this.$name$)");
	} else {
	printer->Print(variables_,
	"this.$name$");
	}
	printer->Print(";\n");
	}

	// ===================================================================

	AccessorEnumFieldGenerator::
	AccessorEnumFieldGenerator(const FieldDescriptor* descriptor,
	const Params& params, int has_bit_index)
	: FieldGenerator(params), descriptor_(descriptor) {
	SetEnumVariables(params, descriptor, &variables_);
	LoadEnumValues(params, descriptor->enum_type(), &canonical_values_);
	SetBitOperationVariables("has", has_bit_index, &variables_);
	}

	AccessorEnumFieldGenerator::~AccessorEnumFieldGenerator() {}

	void AccessorEnumFieldGenerator::
	GenerateMembers(io::Printer* printer, bool /* unused lazy_init */) const {
	printer->Print(variables_, "private int $name$_;\n");
	if (params_.generate_intdefs()) {
	printer->Print(variables_, "$message_type_intdef$\n");
	}
	printer->Print(variables_,
	"public int get$capitalized_name$() {\n"
	" return $name$_;\n"
	"}\n"
	"public $message_name$ set$capitalized_name$(");
	if (params_.generate_intdefs()) {
	printer->Print(variables_,
	"\n"
	" $message_type_intdef$ ");
	}
	printer->Print(variables_,
	"int value) {\n"
	" $name$_ = value;\n"
	" $set_has$;\n"
	" return this;\n"
	"}\n"
	"public boolean has$capitalized_name$() {\n"
	" return $get_has$;\n"
	"}\n"
	"public $message_name$ clear$capitalized_name$() {\n"
	" $name$_ = $default$;\n"
	" $clear_has$;\n"
	" return this;\n"
	"}\n");
	}

	void AccessorEnumFieldGenerator::
	GenerateClearCode(io::Printer* printer) const {
	printer->Print(variables_,
	"$name$_ = $default$;\n");
	}

	void AccessorEnumFieldGenerator::
	GenerateMergingCode(io::Printer* printer) const {
	if (params_.store_unknown_fields()) {
	printer->Print("int initialPos = input.getPosition();\n");
	}
	printer->Print(variables_,
	"int value = input.readInt32();\n"
	"switch (value) {\n");
	PrintCaseLabels(printer, canonical_values_);
	printer->Print(variables_,
	" $name$_ = value;\n"
	" $set_has$;\n"
	" break;\n");
	if (params_.store_unknown_fields()) {
	// If storing unknown fields, store invalid values there.
	// This is consistent with full protobuf, but note that if a client writes
	// a new value to this field, both will be serialized on the wire, and
	// other clients which are aware of unknown fields will see the previous
	// value, not the new one.
	printer->Print(
	" default:\n"
	" input.rewindToPosition(initialPos);\n"
	" storeUnknownField(input, tag);\n"
	" break;\n");
	}
	printer->Print("}\n");
	}

	void AccessorEnumFieldGenerator::
	GenerateSerializationCode(io::Printer* printer) const {
	printer->Print(variables_,
	"if ($get_has$) {\n"
	" output.writeInt32($number$, $name$_);\n"
	"}\n");
	}

	void AccessorEnumFieldGenerator::
	GenerateSerializedSizeCode(io::Printer* printer) const {
	printer->Print(variables_,
	"if ($get_has$) {\n"
	" size += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
	" .computeInt32Size($number$, $name$_);\n"
	"}\n");
	}

	void AccessorEnumFieldGenerator::
	GenerateEqualsCode(io::Printer* printer) const {
	printer->Print(variables_,
	"if ($different_has$\n"
	" \|\| $name$_ != other.$name$_) {\n"
	" return false;\n"
	"}\n");
	}

	void AccessorEnumFieldGenerator::
	GenerateHashCodeCode(io::Printer* printer) const {
	printer->Print(variables_,
	"result = 31 * result + $name$_;\n");
	}

	// ===================================================================

	RepeatedEnumFieldGenerator::
	RepeatedEnumFieldGenerator(const FieldDescriptor* descriptor, const Params& params)
	: FieldGenerator(params), descriptor_(descriptor) {
	SetEnumVariables(params, descriptor, &variables_);
	LoadEnumValues(params, descriptor->enum_type(), &canonical_values_);
	}

	RepeatedEnumFieldGenerator::~RepeatedEnumFieldGenerator() {}

	void RepeatedEnumFieldGenerator::
	GenerateMembers(io::Printer* printer, bool /* unused lazy_init */) const {
	printer->Print(variables_,
	"public $type$[] $name$;\n");
	}

	void RepeatedEnumFieldGenerator::
	GenerateClearCode(io::Printer* printer) const {
	printer->Print(variables_,
	"$name$ = $repeated_default$;\n");
	}

	void RepeatedEnumFieldGenerator::
	GenerateMergingCode(io::Printer* printer) const {
	// First, figure out the maximum length of the array, then parse,
	// and finally copy the valid values to the field.
	printer->Print(variables_,
	"int length = com.google.protobuf.nano.WireFormatNano\n"
	" .getRepeatedFieldArrayLength(input, $non_packed_tag$);\n"
	"int[] validValues = new int[length];\n"
	"int validCount = 0;\n"
	"for (int i = 0; i < length; i++) {\n"
	" if (i != 0) { // tag for first value already consumed.\n"
	" input.readTag();\n"
	" }\n");
	if (params_.store_unknown_fields()) {
	printer->Print(" int initialPos = input.getPosition();\n");
	}
	printer->Print(
	" int value = input.readInt32();\n"
	" switch (value) {\n");
	printer->Indent();
	PrintCaseLabels(printer, canonical_values_);
	printer->Outdent();
	printer->Print(variables_,
	" validValues[validCount++] = value;\n"
	" break;\n");
	if (params_.store_unknown_fields()) {
	// If storing unknown fields, store invalid values there.
	// This is consistent with full protobuf. Note that this can lead to very
	// strange behaviors if a value is serialized and reread, e.g. changes in
	// value ordering.
	printer->Print(
	" default:\n"
	" input.rewindToPosition(initialPos);\n"
	" storeUnknownField(input, tag);\n"
	" break;\n");
	}
	printer->Print(variables_,
	" }\n"
	"}\n"
	"if (validCount != 0) {\n"
	" int i = this.$name$ == null ? 0 : this.$name$.length;\n"
	" if (i == 0 && validCount == validValues.length) {\n"
	" this.$name$ = validValues;\n"
	" } else {\n"
	" int[] newArray = new int[i + validCount];\n"
	" if (i != 0) {\n"
	" java.lang.System.arraycopy(this.$name$, 0, newArray, 0, i);\n"
	" }\n"
	" java.lang.System.arraycopy(validValues, 0, newArray, i, validCount);\n"
	" this.$name$ = newArray;\n"
	" }\n"
	"}\n");
	}

	void RepeatedEnumFieldGenerator::
	GenerateMergingCodeFromPacked(io::Printer* printer) const {
	printer->Print(variables_,
	"int bytes = input.readRawVarint32();\n"
	"int limit = input.pushLimit(bytes);\n"
	"// First pass to compute array length.\n"
	"int arrayLength = 0;\n"
	"int startPos = input.getPosition();\n"
	"while (input.getBytesUntilLimit() > 0) {\n"
	" switch (input.readInt32()) {\n");
	printer->Indent();
	PrintCaseLabels(printer, canonical_values_);
	printer->Outdent();
	printer->Print(variables_,
	" arrayLength++;\n"
	" break;\n"
	" }\n"
	"}\n"
	"if (arrayLength != 0) {\n"
	" input.rewindToPosition(startPos);\n"
	" int i = this.$name$ == null ? 0 : this.$name$.length;\n"
	" int[] newArray = new int[i + arrayLength];\n"
	" if (i != 0) {\n"
	" java.lang.System.arraycopy(this.$name$, 0, newArray, 0, i);\n"
	" }\n"
	" while (input.getBytesUntilLimit() > 0) {\n");
	if (params_.store_unknown_fields()) {
	printer->Print(" int initialPos = input.getPosition();\n");
	}
	printer->Print(variables_,
	" int value = input.readInt32();\n"
	" switch (value) {\n");
	printer->Indent();
	printer->Indent();
	PrintCaseLabels(printer, canonical_values_);
	printer->Outdent();
	printer->Outdent();
	printer->Print(variables_,
	" newArray[i++] = value;\n"
	" break;\n");
	if (params_.store_unknown_fields()) {
	// If storing unknown fields, store invalid values there.
	// This is consistent with full protobuf. Note that this can lead to very
	// strange behaviors if a value is serialized and reread, e.g. changes in
	// value ordering.
	printer->Print(variables_,
	" default:\n"
	" input.rewindToPosition(initialPos);\n"
	" storeUnknownField(input, $non_packed_tag$);\n"
	" break;\n");
	}
	printer->Print(variables_,
	" }\n"
	" }\n"
	" this.$name$ = newArray;\n"
	"}\n"
	"input.popLimit(limit);\n");
	}

	void RepeatedEnumFieldGenerator::
	GenerateRepeatedDataSizeCode(io::Printer* printer) const {
	// Creates a variable dataSize and puts the serialized size in there.
	printer->Print(variables_,
	"int dataSize = 0;\n"
	"for (int i = 0; i < this.$name$.length; i++) {\n"
	" int element = this.$name$[i];\n"
	" dataSize += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
	" .computeInt32SizeNoTag(element);\n"
	"}\n");
	}

	void RepeatedEnumFieldGenerator::
	GenerateSerializationCode(io::Printer* printer) const {
	printer->Print(variables_,
	"if (this.$name$ != null && this.$name$.length > 0) {\n");
	printer->Indent();

	if (descriptor_->options().packed()) {
	GenerateRepeatedDataSizeCode(printer);
	printer->Print(variables_,
	"output.writeRawVarint32($tag$);\n"
	"output.writeRawVarint32(dataSize);\n"
	"for (int i = 0; i < this.$name$.length; i++) {\n"
	" output.writeRawVarint32(this.$name$[i]);\n"
	"}\n");
	} else {
	printer->Print(variables_,
	"for (int i = 0; i < this.$name$.length; i++) {\n"
	" output.writeInt32($number$, this.$name$[i]);\n"
	"}\n");
	}

	printer->Outdent();
	printer->Print(variables_,
	"}\n");
	}

	void RepeatedEnumFieldGenerator::
	GenerateSerializedSizeCode(io::Printer* printer) const {
	printer->Print(variables_,
	"if (this.$name$ != null && this.$name$.length > 0) {\n");
	printer->Indent();

	GenerateRepeatedDataSizeCode(printer);

	printer->Print(
	"size += dataSize;\n");
	if (descriptor_->options().packed()) {
	printer->Print(variables_,
	"size += $tag_size$;\n"
	"size += com.google.protobuf.nano.CodedOutputByteBufferNano\n"
	" .computeRawVarint32Size(dataSize);\n");
	} else {
	printer->Print(variables_,
	"size += $tag_size$ * this.$name$.length;\n");
	}

	printer->Outdent();

	printer->Print(
	"}\n");
	}

	void RepeatedEnumFieldGenerator::
	GenerateFixClonedCode(io::Printer* printer) const {
	printer->Print(variables_,
	"if (this.$name$ != null && this.$name$.length > 0) {\n"
	" cloned.$name$ = this.$name$.clone();\n"
	"}\n");
	}

	void RepeatedEnumFieldGenerator::
	GenerateEqualsCode(io::Printer* printer) const {
	printer->Print(variables_,
	"if (!com.google.protobuf.nano.InternalNano.equals(\n"
	" this.$name$, other.$name$)) {\n"
	" return false;\n"
	"}\n");
	}

	void RepeatedEnumFieldGenerator::
	GenerateHashCodeCode(io::Printer* printer) const {
	printer->Print(variables_,
	"result = 31 * result\n"
	" + com.google.protobuf.nano.InternalNano.hashCode(this.$name$);\n");
	}

	} // namespace javanano
	} // namespace compiler
	} // namespace protobuf
	} // namespace google