// 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 #include #include #include #include #include #include #include #include #include namespace google { namespace protobuf { namespace compiler { namespace javanano { using internal::WireFormat; using internal::WireFormatLite; namespace { const char* PrimitiveTypeName(JavaType type) { switch (type) { case JAVATYPE_INT : return "int"; case JAVATYPE_LONG : return "long"; case JAVATYPE_FLOAT : return "float"; case JAVATYPE_DOUBLE : return "double"; case JAVATYPE_BOOLEAN: return "boolean"; case JAVATYPE_STRING : return "java.lang.String"; case JAVATYPE_BYTES : return "byte[]"; case JAVATYPE_ENUM : return NULL; case JAVATYPE_MESSAGE: return NULL; // No default because we want the compiler to complain if any new // JavaTypes are added. } GOOGLE_LOG(FATAL) << "Can't get here."; return NULL; } bool IsReferenceType(JavaType type) { switch (type) { case JAVATYPE_INT : return false; case JAVATYPE_LONG : return false; case JAVATYPE_FLOAT : return false; case JAVATYPE_DOUBLE : return false; case JAVATYPE_BOOLEAN: return false; case JAVATYPE_STRING : return true; case JAVATYPE_BYTES : return true; case JAVATYPE_ENUM : return false; case JAVATYPE_MESSAGE: return true; // No default because we want the compiler to complain if any new // JavaTypes are added. } GOOGLE_LOG(FATAL) << "Can't get here."; return false; } bool IsArrayType(JavaType type) { switch (type) { case JAVATYPE_INT : return false; case JAVATYPE_LONG : return false; case JAVATYPE_FLOAT : return false; case JAVATYPE_DOUBLE : return false; case JAVATYPE_BOOLEAN: return false; case JAVATYPE_STRING : return false; case JAVATYPE_BYTES : return true; case JAVATYPE_ENUM : return false; case JAVATYPE_MESSAGE: return false; // No default because we want the compiler to complain if any new // JavaTypes are added. } GOOGLE_LOG(FATAL) << "Can't get here."; return false; } const char* GetCapitalizedType(const FieldDescriptor* field) { switch (field->type()) { case FieldDescriptor::TYPE_INT32 : return "Int32" ; case FieldDescriptor::TYPE_UINT32 : return "UInt32" ; case FieldDescriptor::TYPE_SINT32 : return "SInt32" ; case FieldDescriptor::TYPE_FIXED32 : return "Fixed32" ; case FieldDescriptor::TYPE_SFIXED32: return "SFixed32"; case FieldDescriptor::TYPE_INT64 : return "Int64" ; case FieldDescriptor::TYPE_UINT64 : return "UInt64" ; case FieldDescriptor::TYPE_SINT64 : return "SInt64" ; case FieldDescriptor::TYPE_FIXED64 : return "Fixed64" ; case FieldDescriptor::TYPE_SFIXED64: return "SFixed64"; case FieldDescriptor::TYPE_FLOAT : return "Float" ; case FieldDescriptor::TYPE_DOUBLE : return "Double" ; case FieldDescriptor::TYPE_BOOL : return "Bool" ; case FieldDescriptor::TYPE_STRING : return "String" ; case FieldDescriptor::TYPE_BYTES : return "Bytes" ; case FieldDescriptor::TYPE_ENUM : return "Enum" ; case FieldDescriptor::TYPE_GROUP : return "Group" ; case FieldDescriptor::TYPE_MESSAGE : return "Message" ; // No default because we want the compiler to complain if any new // types are added. } GOOGLE_LOG(FATAL) << "Can't get here."; return NULL; } // For encodings with fixed sizes, returns that size in bytes. Otherwise // returns -1. int FixedSize(FieldDescriptor::Type type) { switch (type) { case FieldDescriptor::TYPE_INT32 : return -1; case FieldDescriptor::TYPE_INT64 : return -1; case FieldDescriptor::TYPE_UINT32 : return -1; case FieldDescriptor::TYPE_UINT64 : return -1; case FieldDescriptor::TYPE_SINT32 : return -1; case FieldDescriptor::TYPE_SINT64 : return -1; case FieldDescriptor::TYPE_FIXED32 : return WireFormatLite::kFixed32Size; case FieldDescriptor::TYPE_FIXED64 : return WireFormatLite::kFixed64Size; case FieldDescriptor::TYPE_SFIXED32: return WireFormatLite::kSFixed32Size; case FieldDescriptor::TYPE_SFIXED64: return WireFormatLite::kSFixed64Size; case FieldDescriptor::TYPE_FLOAT : return WireFormatLite::kFloatSize; case FieldDescriptor::TYPE_DOUBLE : return WireFormatLite::kDoubleSize; case FieldDescriptor::TYPE_BOOL : return WireFormatLite::kBoolSize; case FieldDescriptor::TYPE_ENUM : return -1; case FieldDescriptor::TYPE_STRING : return -1; case FieldDescriptor::TYPE_BYTES : return -1; case FieldDescriptor::TYPE_GROUP : return -1; case FieldDescriptor::TYPE_MESSAGE : return -1; // No default because we want the compiler to complain if any new // types are added. } GOOGLE_LOG(FATAL) << "Can't get here."; return -1; } // Returns true if the field has a default value equal to NaN. bool IsDefaultNaN(const FieldDescriptor* field) { switch (field->type()) { case FieldDescriptor::TYPE_INT32 : return false; case FieldDescriptor::TYPE_UINT32 : return false; case FieldDescriptor::TYPE_SINT32 : return false; case FieldDescriptor::TYPE_FIXED32 : return false; case FieldDescriptor::TYPE_SFIXED32: return false; case FieldDescriptor::TYPE_INT64 : return false; case FieldDescriptor::TYPE_UINT64 : return false; case FieldDescriptor::TYPE_SINT64 : return false; case FieldDescriptor::TYPE_FIXED64 : return false; case FieldDescriptor::TYPE_SFIXED64: return false; case FieldDescriptor::TYPE_FLOAT : return isnan(field->default_value_float()); case FieldDescriptor::TYPE_DOUBLE : return isnan(field->default_value_double()); case FieldDescriptor::TYPE_BOOL : return false; case FieldDescriptor::TYPE_STRING : return false; case FieldDescriptor::TYPE_BYTES : return false; case FieldDescriptor::TYPE_ENUM : return false; case FieldDescriptor::TYPE_GROUP : return false; case FieldDescriptor::TYPE_MESSAGE : return false; // No default because we want the compiler to complain if any new // types are added. } GOOGLE_LOG(FATAL) << "Can't get here."; return false; } // Return true if the type is a that has variable length // for instance String's. bool IsVariableLenType(JavaType type) { switch (type) { case JAVATYPE_INT : return false; case JAVATYPE_LONG : return false; case JAVATYPE_FLOAT : return false; case JAVATYPE_DOUBLE : return false; case JAVATYPE_BOOLEAN: return false; case JAVATYPE_STRING : return true; case JAVATYPE_BYTES : return true; case JAVATYPE_ENUM : return false; case JAVATYPE_MESSAGE: return true; // No default because we want the compiler to complain if any new // JavaTypes are added. } GOOGLE_LOG(FATAL) << "Can't get here."; return false; } bool AllAscii(const string& text) { for (int i = 0; i < text.size(); i++) { if ((text[i] & 0x80) != 0) { return false; } } return true; } void SetPrimitiveVariables(const FieldDescriptor* descriptor, const Params params, map* variables) { (*variables)["name"] = RenameJavaKeywords(UnderscoresToCamelCase(descriptor)); (*variables)["capitalized_name"] = RenameJavaKeywords(UnderscoresToCapitalizedCamelCase(descriptor)); (*variables)["number"] = SimpleItoa(descriptor->number()); if (params.use_reference_types_for_primitives() && !descriptor->is_repeated()) { (*variables)["type"] = BoxedPrimitiveTypeName(GetJavaType(descriptor)); } else { (*variables)["type"] = PrimitiveTypeName(GetJavaType(descriptor)); } (*variables)["default"] = DefaultValue(params, descriptor); (*variables)["default_constant"] = FieldDefaultConstantName(descriptor); // For C++-string types (string and bytes), we might need to have // the generated code do the unicode decoding (see comments in // InternalNano.java for gory details.). We would like to do this // once into a "private static final" field and re-use that from // then on. if (descriptor->cpp_type() == FieldDescriptor::CPPTYPE_STRING && !descriptor->default_value_string().empty() && !params.use_reference_types_for_primitives()) { string default_value; if (descriptor->type() == FieldDescriptor::TYPE_BYTES) { default_value = strings::Substitute( "com.google.protobuf.nano.InternalNano.bytesDefaultValue(\"$0\")", CEscape(descriptor->default_value_string())); (*variables)["default_copy_if_needed"] = (*variables)["default"] + ".clone()"; } else { if (AllAscii(descriptor->default_value_string())) { // All chars are ASCII. In this case CEscape() works fine. default_value = "\"" + CEscape(descriptor->default_value_string()) + "\""; } else { default_value = strings::Substitute( "com.google.protobuf.nano.InternalNano.stringDefaultValue(\"$0\")", CEscape(descriptor->default_value_string())); } (*variables)["default_copy_if_needed"] = (*variables)["default"]; } (*variables)["default_constant_value"] = default_value; } else { (*variables)["default_copy_if_needed"] = (*variables)["default"]; } (*variables)["boxed_type"] = BoxedPrimitiveTypeName(GetJavaType(descriptor)); (*variables)["capitalized_type"] = GetCapitalizedType(descriptor); (*variables)["tag"] = SimpleItoa(WireFormat::MakeTag(descriptor)); (*variables)["tag_size"] = SimpleItoa( WireFormat::TagSize(descriptor->number(), descriptor->type())); int fixed_size = FixedSize(descriptor->type()); if (fixed_size != -1) { (*variables)["fixed_size"] = SimpleItoa(fixed_size); } (*variables)["message_name"] = descriptor->containing_type()->name(); (*variables)["empty_array_name"] = EmptyArrayName(params, descriptor); } } // namespace // =================================================================== PrimitiveFieldGenerator:: PrimitiveFieldGenerator(const FieldDescriptor* descriptor, const Params& params) : FieldGenerator(params), descriptor_(descriptor) { SetPrimitiveVariables(descriptor, params, &variables_); } PrimitiveFieldGenerator::~PrimitiveFieldGenerator() {} void PrimitiveFieldGenerator:: GenerateMembers(io::Printer* printer) const { if (variables_.find("default_constant_value") != variables_.end()) { // Those primitive types that need a saved default. printer->Print(variables_, "private static final $type$ $default_constant$ = $default_constant_value$;\n"); } printer->Print(variables_, "public $type$ $name$;\n"); if (params_.generate_has()) { printer->Print(variables_, "public boolean has$capitalized_name$ = false;\n"); } } void PrimitiveFieldGenerator:: GenerateClearCode(io::Printer* printer) const { printer->Print(variables_, "$name$ = $default_copy_if_needed$;\n"); if (params_.generate_has()) { printer->Print(variables_, "has$capitalized_name$ = false;\n"); } } void PrimitiveFieldGenerator:: GenerateMergingCode(io::Printer* printer) const { printer->Print(variables_, "this.$name$ = input.read$capitalized_type$();\n"); if (params_.generate_has()) { printer->Print(variables_, "has$capitalized_name$ = true;\n"); } } void PrimitiveFieldGenerator:: GenerateSerializationConditional(io::Printer* printer) const { if (params_.use_reference_types_for_primitives()) { // For reference type mode, serialize based on equality // to null. printer->Print(variables_, "if (this.$name$ != null) {\n"); return; } if (params_.generate_has()) { printer->Print(variables_, "if (has$capitalized_name$ || "); } else { printer->Print(variables_, "if ("); } if (IsArrayType(GetJavaType(descriptor_))) { printer->Print(variables_, "!java.util.Arrays.equals(this.$name$, $default$)) {\n"); } else if (IsReferenceType(GetJavaType(descriptor_))) { printer->Print(variables_, "!this.$name$.equals($default$)) {\n"); } else if (IsDefaultNaN(descriptor_)) { printer->Print(variables_, "!$capitalized_type$.isNaN(this.$name$)) {\n"); } else { printer->Print(variables_, "this.$name$ != $default$) {\n"); } } void PrimitiveFieldGenerator:: GenerateSerializationCode(io::Printer* printer) const { if (descriptor_->is_required()) { printer->Print(variables_, "output.write$capitalized_type$($number$, this.$name$);\n"); } else { GenerateSerializationConditional(printer); printer->Print(variables_, " output.write$capitalized_type$($number$, this.$name$);\n" "}\n"); } } void PrimitiveFieldGenerator:: GenerateSerializedSizeCode(io::Printer* printer) const { if (descriptor_->is_required()) { printer->Print(variables_, "size += com.google.protobuf.nano.CodedOutputByteBufferNano\n" " .compute$capitalized_type$Size($number$, this.$name$);\n"); } else { GenerateSerializationConditional(printer); printer->Print(variables_, " size += com.google.protobuf.nano.CodedOutputByteBufferNano\n" " .compute$capitalized_type$Size($number$, this.$name$);\n" "}\n"); } } void PrimitiveFieldGenerator:: GenerateEqualsCode(io::Printer* printer) const { // 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. JavaType java_type = GetJavaType(descriptor_); if (java_type == JAVATYPE_BYTES) { printer->Print(variables_, "if (!java.util.Arrays.equals(this.$name$, other.$name$)"); if (params_.generate_has()) { printer->Print(variables_, "\n" " || (java.util.Arrays.equals(this.$name$, $default$)\n" " && this.has$capitalized_name$ != other.has$capitalized_name$)"); } printer->Print(") {\n" " return false;\n" "}\n"); } else if (java_type == JAVATYPE_STRING || params_.use_reference_types_for_primitives()) { printer->Print(variables_, "if (this.$name$ == null) {\n" " if (other.$name$ != null) {\n" " return false;\n" " }\n" "} else if (!this.$name$.equals(other.$name$)"); if (params_.generate_has()) { printer->Print(variables_, "\n" " || (this.$name$.equals($default$)\n" " && this.has$capitalized_name$ != other.has$capitalized_name$)"); } printer->Print(") {\n" " return false;\n" "}\n"); } else { 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 PrimitiveFieldGenerator:: GenerateHashCodeCode(io::Printer* printer) const { JavaType java_type = GetJavaType(descriptor_); if (java_type == JAVATYPE_BYTES) { printer->Print(variables_, "result = 31 * result + java.util.Arrays.hashCode(this.$name$);\n"); } else if (java_type == JAVATYPE_STRING || params_.use_reference_types_for_primitives()) { printer->Print(variables_, "result = 31 * result\n" " + (this.$name$ == null ? 0 : this.$name$.hashCode());\n"); } else { switch (java_type) { // For all Java primitive types below, the hash codes match the // results of BoxedType.valueOf(primitiveValue).hashCode(). case JAVATYPE_INT: printer->Print(variables_, "result = 31 * result + this.$name$;\n"); break; case JAVATYPE_LONG: printer->Print(variables_, "result = 31 * result\n" " + (int) (this.$name$ ^ (this.$name$ >>> 32));\n"); break; case JAVATYPE_FLOAT: printer->Print(variables_, "result = 31 * result\n" " + java.lang.Float.floatToIntBits(this.$name$);\n"); break; case JAVATYPE_DOUBLE: printer->Print(variables_, "{\n" " long v = java.lang.Double.doubleToLongBits(this.$name$);\n" " result = 31 * result + (int) (v ^ (v >>> 32));\n" "}\n"); break; case JAVATYPE_BOOLEAN: printer->Print(variables_, "result = 31 * result + (this.$name$ ? 1231 : 1237);\n"); break; default: GOOGLE_LOG(ERROR) << "unknown java type for primitive field"; break; } } } // =================================================================== AccessorPrimitiveFieldGenerator:: AccessorPrimitiveFieldGenerator(const FieldDescriptor* descriptor, const Params& params, int has_bit_index) : FieldGenerator(params), descriptor_(descriptor) { SetPrimitiveVariables(descriptor, params, &variables_); SetBitOperationVariables("has", has_bit_index, &variables_); } AccessorPrimitiveFieldGenerator::~AccessorPrimitiveFieldGenerator() {} void AccessorPrimitiveFieldGenerator:: GenerateMembers(io::Printer* printer) const { if (variables_.find("default_constant_value") != variables_.end()) { printer->Print(variables_, "private static final $type$ $default_constant$ = $default_constant_value$;\n"); } printer->Print(variables_, "private $type$ $name$_;\n" "public $type$ get$capitalized_name$() {\n" " return $name$_;\n" "}\n" "public $message_name$ set$capitalized_name$($type$ value) {\n"); if (IsReferenceType(GetJavaType(descriptor_))) { printer->Print(variables_, " if (value == null) {\n" " throw new java.lang.NullPointerException();\n" " }\n"); } printer->Print(variables_, " $name$_ = 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" " $name$_ = $default_copy_if_needed$;\n" " $clear_has$;\n" " return this;\n" "}\n"); } void AccessorPrimitiveFieldGenerator:: GenerateClearCode(io::Printer* printer) const { printer->Print(variables_, "$name$_ = $default_copy_if_needed$;\n"); } void AccessorPrimitiveFieldGenerator:: GenerateMergingCode(io::Printer* printer) const { printer->Print(variables_, "$name$_ = input.read$capitalized_type$();\n" "$set_has$;\n"); } void AccessorPrimitiveFieldGenerator:: GenerateSerializationCode(io::Printer* printer) const { printer->Print(variables_, "if ($get_has$) {\n" " output.write$capitalized_type$($number$, $name$_);\n" "}\n"); } void AccessorPrimitiveFieldGenerator:: GenerateSerializedSizeCode(io::Printer* printer) const { printer->Print(variables_, "if ($get_has$) {\n" " size += com.google.protobuf.nano.CodedOutputByteBufferNano\n" " .compute$capitalized_type$Size($number$, $name$_);\n" "}\n"); } void AccessorPrimitiveFieldGenerator:: GenerateEqualsCode(io::Printer* printer) const { switch (GetJavaType(descriptor_)) { // For all Java primitive types below, the hash codes match the // results of BoxedType.valueOf(primitiveValue).hashCode(). case JAVATYPE_INT: case JAVATYPE_LONG: case JAVATYPE_FLOAT: case JAVATYPE_DOUBLE: case JAVATYPE_BOOLEAN: printer->Print(variables_, "if ($different_has$\n" " || $name$_ != other.$name$_) {\n" " return false;\n" "}\n"); break; case JAVATYPE_STRING: // Accessor style would guarantee $name$_ non-null printer->Print(variables_, "if ($different_has$\n" " || !$name$_.equals(other.$name$_)) {\n" " return false;\n" "}\n"); break; case JAVATYPE_BYTES: // Accessor style would guarantee $name$_ non-null printer->Print(variables_, "if ($different_has$\n" " || !java.util.Arrays.equals($name$_, other.$name$_)) {\n" " return false;\n" "}\n"); break; default: GOOGLE_LOG(ERROR) << "unknown java type for primitive field"; break; } } void AccessorPrimitiveFieldGenerator:: GenerateHashCodeCode(io::Printer* printer) const { switch (GetJavaType(descriptor_)) { // For all Java primitive types below, the hash codes match the // results of BoxedType.valueOf(primitiveValue).hashCode(). case JAVATYPE_INT: printer->Print(variables_, "result = 31 * result + $name$_;\n"); break; case JAVATYPE_LONG: printer->Print(variables_, "result = 31 * result + (int) ($name$_ ^ ($name$_ >>> 32));\n"); break; case JAVATYPE_FLOAT: printer->Print(variables_, "result = 31 * result +\n" " java.lang.Float.floatToIntBits($name$_);\n"); break; case JAVATYPE_DOUBLE: printer->Print(variables_, "{\n" " long v = java.lang.Double.doubleToLongBits($name$_);\n" " result = 31 * result + (int) (v ^ (v >>> 32));\n" "}\n"); break; case JAVATYPE_BOOLEAN: printer->Print(variables_, "result = 31 * result + ($name$_ ? 1231 : 1237);\n"); break; case JAVATYPE_STRING: // Accessor style would guarantee $name$_ non-null printer->Print(variables_, "result = 31 * result + $name$_.hashCode();\n"); break; case JAVATYPE_BYTES: // Accessor style would guarantee $name$_ non-null printer->Print(variables_, "result = 31 * result + java.util.Arrays.hashCode($name$_);\n"); break; default: GOOGLE_LOG(ERROR) << "unknown java type for primitive field"; break; } } // =================================================================== RepeatedPrimitiveFieldGenerator:: RepeatedPrimitiveFieldGenerator(const FieldDescriptor* descriptor, const Params& params) : FieldGenerator(params), descriptor_(descriptor) { SetPrimitiveVariables(descriptor, params, &variables_); } RepeatedPrimitiveFieldGenerator::~RepeatedPrimitiveFieldGenerator() {} void RepeatedPrimitiveFieldGenerator:: GenerateMembers(io::Printer* printer) const { printer->Print(variables_, "public $type$[] $name$;\n"); } void RepeatedPrimitiveFieldGenerator:: GenerateClearCode(io::Printer* printer) const { printer->Print(variables_, "$name$ = $default$;\n"); } void RepeatedPrimitiveFieldGenerator:: GenerateMergingCode(io::Printer* printer) const { // First, figure out the length of the array, then parse. if (descriptor_->options().packed()) { printer->Print(variables_, "int length = input.readRawVarint32();\n" "int limit = input.pushLimit(length);\n" "// First pass to compute array length.\n" "int arrayLength = 0;\n" "int startPos = input.getPosition();\n" "while (input.getBytesUntilLimit() > 0) {\n" " input.read$capitalized_type$();\n" " arrayLength++;\n" "}\n" "input.rewindToPosition(startPos);\n" "int i = this.$name$ == null ? 0 : this.$name$.length;\n" "$type$[] newArray = new $type$[i + arrayLength];\n" "if (i != 0) {\n" " java.lang.System.arraycopy(this.$name$, 0, newArray, 0, i);\n" "}\n" "for (; i < newArray.length; i++) {\n" " newArray[i] = input.read$capitalized_type$();\n" "}\n" "this.$name$ = newArray;\n" "input.popLimit(limit);\n"); } else { printer->Print(variables_, "int arrayLength = com.google.protobuf.nano.WireFormatNano\n" " .getRepeatedFieldArrayLength(input, $tag$);\n" "int i = this.$name$ == null ? 0 : this.$name$.length;\n"); if (GetJavaType(descriptor_) == JAVATYPE_BYTES) { printer->Print(variables_, "byte[][] newArray = new byte[i + arrayLength][];\n"); } else { printer->Print(variables_, "$type$[] newArray = new $type$[i + arrayLength];\n"); } printer->Print(variables_, "if (i != 0) {\n" " java.lang.System.arraycopy(this.$name$, 0, newArray, 0, i);\n" "}\n" "for (; i < newArray.length - 1; i++) {\n" " newArray[i] = input.read$capitalized_type$();\n" " input.readTag();\n" "}\n" "// Last one without readTag.\n" "newArray[i] = input.read$capitalized_type$();\n" "this.$name$ = newArray;\n"); } } void RepeatedPrimitiveFieldGenerator:: GenerateRepeatedDataSizeCode(io::Printer* printer) const { // Creates a variable dataSize and puts the serialized size in // there. if (FixedSize(descriptor_->type()) == -1) { printer->Print(variables_, "int dataSize = 0;\n" "for ($type$ element : this.$name$) {\n" " dataSize += com.google.protobuf.nano.CodedOutputByteBufferNano\n" " .compute$capitalized_type$SizeNoTag(element);\n" "}\n"); } else { printer->Print(variables_, "int dataSize = $fixed_size$ * this.$name$.length;\n"); } } void RepeatedPrimitiveFieldGenerator:: 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 ($type$ element : this.$name$) {\n" " output.write$capitalized_type$NoTag(element);\n" "}\n"); } else { printer->Print(variables_, "for ($type$ element : this.$name$) {\n" " output.write$capitalized_type$($number$, element);\n" "}\n"); } printer->Outdent(); printer->Print("}\n"); } void RepeatedPrimitiveFieldGenerator:: 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 RepeatedPrimitiveFieldGenerator:: 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 RepeatedPrimitiveFieldGenerator:: 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