blob: a230fa3d08ad88ec2f73a566639f32aa5e58bb00 [file] [log] [blame]
// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc. All rights reserved.
//
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file or at
// https://developers.google.com/open-source/licenses/bsd
#include "text_format_conformance_suite.h"
#include <cstddef>
#include <string>
#include <utility>
#include <vector>
#include "absl/log/absl_log.h"
#include "absl/log/die_if_null.h"
#include "absl/strings/str_cat.h"
#include "absl/strings/str_format.h"
#include "conformance_test.h"
#include "conformance/test_protos/test_messages_edition2023.pb.h"
#include "editions/golden/test_messages_proto2_editions.pb.h"
#include "editions/golden/test_messages_proto3_editions.pb.h"
#include "google/protobuf/test_messages_proto2.pb.h"
#include "google/protobuf/test_messages_proto3.pb.h"
#include "google/protobuf/text_format.h"
using conformance::ConformanceRequest;
using conformance::ConformanceResponse;
using conformance::WireFormat;
using protobuf_test_messages::editions::TestAllTypesEdition2023;
using protobuf_test_messages::proto2::TestAllTypesProto2;
using protobuf_test_messages::proto2::UnknownToTestAllTypes;
using protobuf_test_messages::proto3::TestAllTypesProto3;
using TestAllTypesProto2Editions =
protobuf_test_messages::editions::proto2::TestAllTypesProto2;
using TestAllTypesProto3Editions =
protobuf_test_messages::editions::proto3::TestAllTypesProto3;
namespace google {
namespace protobuf {
// The number of repetitions to use for performance tests.
// Corresponds approx to 500KB wireformat bytes.
static const size_t kPerformanceRepeatCount = 50000;
TextFormatConformanceTestSuite::TextFormatConformanceTestSuite() {
SetFailureListFlagName("--text_format_failure_list");
}
bool TextFormatConformanceTestSuite::ParseTextFormatResponse(
const ConformanceResponse& response,
const ConformanceRequestSetting& setting, Message* test_message) {
TextFormat::Parser parser;
const ConformanceRequest& request = setting.GetRequest();
if (request.print_unknown_fields()) {
parser.AllowFieldNumber(true);
}
if (!parser.ParseFromString(response.text_payload(), test_message)) {
ABSL_LOG(ERROR) << "INTERNAL ERROR: internal text->protobuf transcode "
<< "yielded unparseable proto. Text payload: "
<< response.text_payload();
return false;
}
return true;
}
bool TextFormatConformanceTestSuite::ParseResponse(
const ConformanceResponse& response,
const ConformanceRequestSetting& setting, Message* test_message) {
const ConformanceRequest& request = setting.GetRequest();
WireFormat requested_output = request.requested_output_format();
const std::string& test_name = setting.GetTestName();
ConformanceLevel level = setting.GetLevel();
switch (response.result_case()) {
case ConformanceResponse::kProtobufPayload: {
if (requested_output != conformance::PROTOBUF) {
ReportFailure(test_name, level, request, response,
absl::StrCat("Test was asked for ",
WireFormatToString(requested_output),
" output but provided PROTOBUF instead."));
return false;
}
if (!test_message->ParseFromString(response.protobuf_payload())) {
ReportFailure(test_name, level, request, response,
"Protobuf output we received from test was unparseable.");
return false;
}
break;
}
case ConformanceResponse::kTextPayload: {
if (requested_output != conformance::TEXT_FORMAT) {
ReportFailure(
test_name, level, request, response,
absl::StrCat("Test was asked for ",
WireFormatToString(requested_output),
" output but provided TEXT_FORMAT instead."));
return false;
}
if (!ParseTextFormatResponse(response, setting, test_message)) {
ReportFailure(
test_name, level, request, response,
"TEXT_FORMAT output we received from test was unparseable.");
return false;
}
break;
}
default:
ABSL_LOG(FATAL) << test_name
<< ": unknown payload type: " << response.result_case();
}
return true;
}
void TextFormatConformanceTestSuite::RunSuiteImpl() {
TextFormatConformanceTestSuiteImpl<TestAllTypesProto2>(this);
TextFormatConformanceTestSuiteImpl<TestAllTypesProto3>(this);
if (maximum_edition_ >= Edition::EDITION_2023) {
TextFormatConformanceTestSuiteImpl<TestAllTypesProto2Editions>(this);
TextFormatConformanceTestSuiteImpl<TestAllTypesProto3Editions>(this);
TextFormatConformanceTestSuiteImpl<TestAllTypesEdition2023>(this);
}
}
template <typename MessageType>
TextFormatConformanceTestSuiteImpl<MessageType>::
TextFormatConformanceTestSuiteImpl(TextFormatConformanceTestSuite* suite)
: suite_(*ABSL_DIE_IF_NULL(suite)) {
// Flag control performance tests to keep them internal and opt-in only
if (suite_.performance_) {
if (MessageType::GetDescriptor()->name() == "TestAllTypesEdition2023") {
// There are no editions-sensitive performance tests.
return;
}
RunTextFormatPerformanceTests();
} else {
if (MessageType::GetDescriptor()->name() == "TestAllTypesProto2") {
RunGroupTests();
}
if (MessageType::GetDescriptor()->name() == "TestAllTypesEdition2023") {
RunDelimitedTests();
}
if (MessageType::GetDescriptor()->name() == "TestAllTypesProto3") {
RunAnyTests();
// TODO Run these over proto2 also.
RunAllTests();
}
}
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<MessageType>::ExpectParseFailure(
const std::string& test_name, ConformanceLevel level,
const std::string& input) {
MessageType prototype;
// We don't expect output, but if the program erroneously accepts the protobuf
// we let it send its response as this. We must not leave it unspecified.
ConformanceRequestSetting setting(
level, conformance::TEXT_FORMAT, conformance::TEXT_FORMAT,
conformance::TEXT_FORMAT_TEST, prototype, test_name, input);
const ConformanceRequest& request = setting.GetRequest();
ConformanceResponse response;
std::string effective_test_name = absl::StrCat(
setting.ConformanceLevelToString(level), ".",
setting.GetSyntaxIdentifier(), ".TextFormatInput.", test_name);
suite_.RunTest(effective_test_name, request, &response);
if (response.result_case() == ConformanceResponse::kParseError) {
suite_.ReportSuccess(effective_test_name);
} else if (response.result_case() == ConformanceResponse::kSkipped) {
suite_.ReportSkip(effective_test_name, request, response);
} else {
suite_.ReportFailure(effective_test_name, level, request, response,
"Should have failed to parse, but didn't.");
}
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<MessageType>::RunValidTextFormatTest(
const std::string& test_name, ConformanceLevel level,
const std::string& input_text) {
MessageType prototype;
RunValidTextFormatTestWithMessage(test_name, level, input_text, prototype);
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<MessageType>::
RunValidTextFormatTestWithMessage(const std::string& test_name,
ConformanceLevel level,
const std::string& input_text,
const Message& message) {
ConformanceRequestSetting setting1(
level, conformance::TEXT_FORMAT, conformance::PROTOBUF,
conformance::TEXT_FORMAT_TEST, message, test_name, input_text);
suite_.RunValidInputTest(setting1, input_text);
ConformanceRequestSetting setting2(
level, conformance::TEXT_FORMAT, conformance::TEXT_FORMAT,
conformance::TEXT_FORMAT_TEST, message, test_name, input_text);
suite_.RunValidInputTest(setting2, input_text);
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<MessageType>::
RunValidTextFormatTestWithExpected(const std::string& test_name,
ConformanceLevel level,
const std::string& input_text,
const std::string& expected_text) {
MessageType prototype;
ConformanceRequestSetting setting1(
level, conformance::TEXT_FORMAT, conformance::PROTOBUF,
conformance::TEXT_FORMAT_TEST, prototype, test_name, input_text);
suite_.RunValidInputTest(setting1, expected_text);
ConformanceRequestSetting setting2(
level, conformance::TEXT_FORMAT, conformance::TEXT_FORMAT,
conformance::TEXT_FORMAT_TEST, prototype, test_name, input_text);
suite_.RunValidInputTest(setting2, expected_text);
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<
MessageType>::RunValidUnknownTextFormatTest(const std::string& test_name,
const Message& message) {
std::string serialized_input;
message.SerializeToString(&serialized_input);
MessageType prototype;
ConformanceRequestSetting setting1(
RECOMMENDED, conformance::PROTOBUF, conformance::TEXT_FORMAT,
conformance::TEXT_FORMAT_TEST, prototype,
absl::StrCat(test_name, "_Drop"), serialized_input);
setting1.SetPrototypeMessageForCompare(message);
suite_.RunValidBinaryInputTest(setting1, "");
ConformanceRequestSetting setting2(
RECOMMENDED, conformance::PROTOBUF, conformance::TEXT_FORMAT,
conformance::TEXT_FORMAT_TEST, prototype,
absl::StrCat(test_name, "_Print"), serialized_input);
setting2.SetPrototypeMessageForCompare(message);
setting2.SetPrintUnknownFields(true);
suite_.RunValidBinaryInputTest(setting2, serialized_input);
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<MessageType>::RunDelimitedTests() {
RunValidTextFormatTest("GroupFieldNoColon", REQUIRED,
"GroupLikeType { group_int32: 1 }");
RunValidTextFormatTest("GroupFieldWithColon", REQUIRED,
"GroupLikeType: { group_int32: 1 }");
RunValidTextFormatTest("GroupFieldEmpty", REQUIRED, "GroupLikeType {}");
RunValidTextFormatTest(
"GroupFieldExtension", REQUIRED,
"[protobuf_test_messages.editions.groupliketype] { c: 1 }");
RunValidTextFormatTest(
"DelimitedFieldExtension", REQUIRED,
"[protobuf_test_messages.editions.delimited_ext] { c: 1 }");
// Test that lower-cased group name (i.e. implicit field name) are accepted.
RunValidTextFormatTest("DelimitedFieldLowercased", REQUIRED,
"groupliketype { group_int32: 1 }");
RunValidTextFormatTest("DelimitedFieldLowercasedDifferent", REQUIRED,
"delimited_field { group_int32: 1 }");
// Extensions always used the field name, and should never accept the message
// name.
ExpectParseFailure(
"DelimitedFieldExtensionMessageName", REQUIRED,
"[protobuf_test_messages.editions.GroupLikeType] { group_int32: 1 }");
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<MessageType>::RunGroupTests() {
RunValidTextFormatTest("GroupFieldNoColon", REQUIRED,
"Data { group_int32: 1 }");
RunValidTextFormatTest("GroupFieldWithColon", REQUIRED,
"Data: { group_int32: 1 }");
RunValidTextFormatTest("GroupFieldEmpty", REQUIRED, "Data {}");
RunValidTextFormatTest("GroupFieldMultiWord", REQUIRED,
"MultiWordGroupField { group_int32: 1 }");
// Test that lower-cased group name (i.e. implicit field name) is accepted
RunValidTextFormatTest("GroupFieldLowercased", REQUIRED,
"data { group_int32: 1 }");
RunValidTextFormatTest("GroupFieldLowercasedMultiWord", REQUIRED,
"multiwordgroupfield { group_int32: 1 }");
// Test extensions of group type
RunValidTextFormatTest("GroupFieldExtension", REQUIRED,
absl::StrFormat("[%s] { group_int32: 1 }",
MessageType::GetDescriptor()
->file()
->FindExtensionByName("groupfield")
->PrintableNameForExtension()));
ExpectParseFailure("GroupFieldExtensionGroupName", REQUIRED,
absl::StrFormat("[%s] { group_int32: 1 }",
MessageType::GetDescriptor()
->file()
->FindMessageTypeByName("GroupField")
->full_name()));
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<MessageType>::RunAllTests() {
RunValidTextFormatTest("HelloWorld", REQUIRED,
"optional_string: 'Hello, World!'");
// Integer fields.
RunValidTextFormatTest("Int32FieldMaxValue", REQUIRED,
"optional_int32: 2147483647");
RunValidTextFormatTest("Int32FieldMinValue", REQUIRED,
"optional_int32: -2147483648");
RunValidTextFormatTest("Uint32FieldMaxValue", REQUIRED,
"optional_uint32: 4294967295");
RunValidTextFormatTest("Int64FieldMaxValue", REQUIRED,
"optional_int64: 9223372036854775807");
RunValidTextFormatTest("Int64FieldMinValue", REQUIRED,
"optional_int64: -9223372036854775808");
RunValidTextFormatTest("Uint64FieldMaxValue", REQUIRED,
"optional_uint64: 18446744073709551615");
// Integer fields - Hex
RunValidTextFormatTestWithExpected("Int32FieldMaxValueHex", REQUIRED,
"optional_int32: 0x7FFFFFFF",
"optional_int32: 2147483647");
RunValidTextFormatTestWithExpected("Int32FieldMinValueHex", REQUIRED,
"optional_int32: -0x80000000",
"optional_int32: -2147483648");
RunValidTextFormatTestWithExpected("Uint32FieldMaxValueHex", REQUIRED,
"optional_uint32: 0xFFFFFFFF",
"optional_uint32: 4294967295");
RunValidTextFormatTestWithExpected("Int64FieldMaxValueHex", REQUIRED,
"optional_int64: 0x7FFFFFFFFFFFFFFF",
"optional_int64: 9223372036854775807");
RunValidTextFormatTestWithExpected("Int64FieldMinValueHex", REQUIRED,
"optional_int64: -0x8000000000000000",
"optional_int64: -9223372036854775808");
RunValidTextFormatTestWithExpected("Uint64FieldMaxValueHex", REQUIRED,
"optional_uint64: 0xFFFFFFFFFFFFFFFF",
"optional_uint64: 18446744073709551615");
// Integer fields - Octal
RunValidTextFormatTestWithExpected("Int32FieldMaxValueOctal", REQUIRED,
"optional_int32: 017777777777",
"optional_int32: 2147483647");
RunValidTextFormatTestWithExpected("Int32FieldMinValueOctal", REQUIRED,
"optional_int32: -020000000000",
"optional_int32: -2147483648");
RunValidTextFormatTestWithExpected("Uint32FieldMaxValueOctal", REQUIRED,
"optional_uint32: 037777777777",
"optional_uint32: 4294967295");
RunValidTextFormatTestWithExpected("Int64FieldMaxValueOctal", REQUIRED,
"optional_int64: 0777777777777777777777",
"optional_int64: 9223372036854775807");
RunValidTextFormatTestWithExpected("Int64FieldMinValueOctal", REQUIRED,
"optional_int64: -01000000000000000000000",
"optional_int64: -9223372036854775808");
RunValidTextFormatTestWithExpected("Uint64FieldMaxValueOctal", REQUIRED,
"optional_uint64: 01777777777777777777777",
"optional_uint64: 18446744073709551615");
// Parsers reject out-of-bound integer values.
ExpectParseFailure("Int32FieldTooLarge", REQUIRED,
"optional_int32: 2147483648");
ExpectParseFailure("Int32FieldTooSmall", REQUIRED,
"optional_int32: -2147483649");
ExpectParseFailure("Uint32FieldTooLarge", REQUIRED,
"optional_uint32: 4294967296");
ExpectParseFailure("Int64FieldTooLarge", REQUIRED,
"optional_int64: 9223372036854775808");
ExpectParseFailure("Int64FieldTooSmall", REQUIRED,
"optional_int64: -9223372036854775809");
ExpectParseFailure("Uint64FieldTooLarge", REQUIRED,
"optional_uint64: 18446744073709551616");
// Parsers reject out-of-bound integer values - Hex
ExpectParseFailure("Int32FieldTooLargeHex", REQUIRED,
"optional_int32: 0x80000000");
ExpectParseFailure("Int32FieldTooSmallHex", REQUIRED,
"optional_int32: -0x80000001");
ExpectParseFailure("Uint32FieldTooLargeHex", REQUIRED,
"optional_uint32: 0x100000000");
ExpectParseFailure("Int64FieldTooLargeHex", REQUIRED,
"optional_int64: 0x8000000000000000");
ExpectParseFailure("Int64FieldTooSmallHex", REQUIRED,
"optional_int64: -0x8000000000000001");
ExpectParseFailure("Uint64FieldTooLargeHex", REQUIRED,
"optional_uint64: 0x10000000000000000");
// Parsers reject out-of-bound integer values - Octal
ExpectParseFailure("Int32FieldTooLargeOctal", REQUIRED,
"optional_int32: 020000000000");
ExpectParseFailure("Int32FieldTooSmallOctal", REQUIRED,
"optional_int32: -020000000001");
ExpectParseFailure("Uint32FieldTooLargeOctal", REQUIRED,
"optional_uint32: 040000000000");
ExpectParseFailure("Int64FieldTooLargeOctal", REQUIRED,
"optional_int64: 01000000000000000000000");
ExpectParseFailure("Int64FieldTooSmallOctal", REQUIRED,
"optional_int64: -01000000000000000000001");
ExpectParseFailure("Uint64FieldTooLargeOctal", REQUIRED,
"optional_uint64: 02000000000000000000000");
// Floating point fields
for (const auto& suffix : std::vector<std::string>{"", "f", "F"}) {
const std::string name_suffix =
suffix.empty() ? "" : absl::StrCat("_", suffix);
RunValidTextFormatTest(absl::StrCat("FloatField", name_suffix), REQUIRED,
absl::StrCat("optional_float: 3.192837", suffix));
RunValidTextFormatTestWithExpected(
absl::StrCat("FloatFieldZero", name_suffix), REQUIRED,
absl::StrCat("optional_float: 0", suffix),
"" /* implicit presence, so zero means unset*/);
RunValidTextFormatTest(absl::StrCat("FloatFieldNegative", name_suffix),
REQUIRED,
absl::StrCat("optional_float: -3.192837", suffix));
RunValidTextFormatTest(
absl::StrCat("FloatFieldWithVeryPreciseNumber", name_suffix), REQUIRED,
absl::StrCat("optional_float: 3.123456789123456789", suffix));
RunValidTextFormatTest(
absl::StrCat("FloatFieldMaxValue", name_suffix), REQUIRED,
absl::StrCat("optional_float: 3.4028235e+38", suffix));
RunValidTextFormatTest(absl::StrCat("FloatFieldMinValue", name_suffix),
REQUIRED,
absl::StrCat("optional_float: 1.17549e-38", suffix));
RunValidTextFormatTest(absl::StrCat("FloatFieldWithInt32Max", name_suffix),
REQUIRED,
absl::StrCat("optional_float: 4294967296", suffix));
RunValidTextFormatTest(
absl::StrCat("FloatFieldLargerThanInt64", name_suffix), REQUIRED,
absl::StrCat("optional_float: 9223372036854775808", suffix));
RunValidTextFormatTest(
absl::StrCat("FloatFieldTooLarge", name_suffix), REQUIRED,
absl::StrCat("optional_float: 3.4028235e+39", suffix));
RunValidTextFormatTest(absl::StrCat("FloatFieldTooSmall", name_suffix),
REQUIRED,
absl::StrCat("optional_float: 1.17549e-39", suffix));
RunValidTextFormatTest(
absl::StrCat("FloatFieldLargerThanUint64", name_suffix), REQUIRED,
absl::StrCat("optional_float: 18446744073709551616", suffix));
// https://protobuf.dev/reference/protobuf/textformat-spec/#literals says
// "-0" is a valid float literal. -0 should be considered not the same as 0
// when considering implicit presence, and so should round trip.
RunValidTextFormatTest(absl::StrCat("FloatFieldNegativeZero", name_suffix),
REQUIRED,
absl::StrCat("optional_float: -0", suffix));
// https://protobuf.dev/reference/protobuf/textformat-spec/#literals says
// ".123", "-.123", ".123e2" are a valid float literal.
RunValidTextFormatTest(absl::StrCat("FloatFieldNoLeadingZero", name_suffix),
REQUIRED,
absl::StrCat("optional_float: .123", suffix));
RunValidTextFormatTest(
absl::StrCat("FloatFieldNegativeNoLeadingZero", name_suffix), REQUIRED,
absl::StrCat("optional_float: -.123", suffix));
RunValidTextFormatTest(
absl::StrCat("FloatFieldNoLeadingZeroWithExponent", name_suffix),
REQUIRED, absl::StrCat("optional_float: .123e2", suffix));
}
// https://protobuf.dev/reference/protobuf/textformat-spec/#value say case
// doesn't matter for special values, test a few
for (const auto& value : std::vector<std::string>{"nan", "NaN", "nAn"}) {
RunValidTextFormatTest(absl::StrCat("FloatFieldValue_", value), REQUIRED,
absl::StrCat("optional_float: ", value));
}
for (const auto& value : std::vector<std::string>{
"inf", "infinity", "INF", "INFINITY", "iNF", "inFINITY"}) {
RunValidTextFormatTest(absl::StrCat("FloatFieldValue_Pos", value), REQUIRED,
absl::StrCat("optional_float: ", value));
RunValidTextFormatTest(absl::StrCat("FloatFieldValue_Neg", value), REQUIRED,
absl::StrCat("optional_float: -", value));
}
// https://protobuf.dev/reference/protobuf/textformat-spec/#numeric and
// https://protobuf.dev/reference/protobuf/textformat-spec/#value says
// hex or octal float literals are invalid.
ExpectParseFailure("FloatFieldNoHex", REQUIRED, "optional_float: 0x1");
ExpectParseFailure("FloatFieldNoNegativeHex", REQUIRED,
"optional_float: -0x1");
ExpectParseFailure("FloatFieldNoOctal", REQUIRED, "optional_float: 012");
ExpectParseFailure("FloatFieldNoNegativeOctal", REQUIRED,
"optional_float: -012");
// https://protobuf.dev/reference/protobuf/textformat-spec/#value says
// overflows are mapped to infinity/-infinity.
RunValidTextFormatTestWithExpected("FloatFieldOverflowInfinity", REQUIRED,
"optional_float: 1e50",
"optional_float: inf");
RunValidTextFormatTestWithExpected("FloatFieldOverflowNegativeInfinity",
REQUIRED, "optional_float: -1e50",
"optional_float: -inf");
RunValidTextFormatTestWithExpected("DoubleFieldOverflowInfinity", REQUIRED,
"optional_double: 1e9999",
"optional_double: inf");
RunValidTextFormatTestWithExpected("DoubleFieldOverflowNegativeInfinity",
REQUIRED, "optional_double: -1e9999",
"optional_double: -inf");
// Exponent is one more than uint64 max.
RunValidTextFormatTestWithExpected(
"FloatFieldOverflowInfinityHugeExponent", REQUIRED,
"optional_float: 1e18446744073709551616", "optional_float: inf");
RunValidTextFormatTestWithExpected(
"DoubleFieldOverflowInfinityHugeExponent", REQUIRED,
"optional_double: 1e18446744073709551616", "optional_double: inf");
RunValidTextFormatTestWithExpected(
"DoubleFieldLargeNegativeExponentParsesAsZero", REQUIRED,
"optional_double: 1e-18446744073709551616", "");
RunValidTextFormatTestWithExpected(
"NegDoubleFieldLargeNegativeExponentParsesAsNegZero", REQUIRED,
"optional_double: -1e-18446744073709551616", "optional_double: -0");
RunValidTextFormatTestWithExpected(
"FloatFieldLargeNegativeExponentParsesAsZero", REQUIRED,
"optional_float: 1e-50", "");
RunValidTextFormatTestWithExpected(
"NegFloatFieldLargeNegativeExponentParsesAsNegZero", REQUIRED,
"optional_float: -1e-50", "optional_float: -0");
// String literals x {Strings, Bytes}
for (const auto& field_type : std::vector<std::string>{"String", "Bytes"}) {
const std::string field_name =
field_type == "String" ? "optional_string" : "optional_bytes";
RunValidTextFormatTest(
absl::StrCat("StringLiteralConcat", field_type), REQUIRED,
absl::StrCat(field_name, ": 'first' \"second\"\n'third'"));
RunValidTextFormatTest(
absl::StrCat("StringLiteralBasicEscapes", field_type), REQUIRED,
absl::StrCat(field_name, ": '\\a\\b\\f\\n\\r\\t\\v\\?\\\\\\'\\\"'"));
RunValidTextFormatTest(
absl::StrCat("StringLiteralOctalEscapes", field_type), REQUIRED,
absl::StrCat(field_name, ": '\\341\\210\\264'"));
RunValidTextFormatTest(absl::StrCat("StringLiteralHexEscapes", field_type),
REQUIRED,
absl::StrCat(field_name, ": '\\xe1\\x88\\xb4'"));
RunValidTextFormatTest(
absl::StrCat("StringLiteralShortUnicodeEscape", field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\u1234'"));
RunValidTextFormatTest(
absl::StrCat("StringLiteralLongUnicodeEscapes", field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\U00001234\\U00010437'"));
// String literals don't include line feeds.
ExpectParseFailure(absl::StrCat("StringLiteralIncludesLF", field_type),
REQUIRED,
absl::StrCat(field_name, ": 'first line\nsecond line'"));
// Unicode escapes don't include code points that lie beyond the planes
// (> 0x10ffff).
ExpectParseFailure(
absl::StrCat("StringLiteralLongUnicodeEscapeTooLarge", field_type),
REQUIRED, absl::StrCat(field_name, ": '\\U00110000'"));
// Unicode escapes don't include surrogates.
ExpectParseFailure(
absl::StrCat("StringLiteralShortUnicodeEscapeSurrogatePair",
field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\ud801\\udc37'"));
ExpectParseFailure(
absl::StrCat("StringLiteralShortUnicodeEscapeSurrogateFirstOnly",
field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\ud800'"));
ExpectParseFailure(
absl::StrCat("StringLiteralShortUnicodeEscapeSurrogateSecondOnly",
field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\udc00'"));
ExpectParseFailure(
absl::StrCat("StringLiteralLongUnicodeEscapeSurrogateFirstOnly",
field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\U0000d800'"));
ExpectParseFailure(
absl::StrCat("StringLiteralLongUnicodeEscapeSurrogateSecondOnly",
field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\U0000dc00'"));
ExpectParseFailure(
absl::StrCat("StringLiteralLongUnicodeEscapeSurrogatePair", field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\U0000d801\\U00000dc37'"));
ExpectParseFailure(
absl::StrCat("StringLiteralUnicodeEscapeSurrogatePairLongShort",
field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\U0000d801\\udc37'"));
ExpectParseFailure(
absl::StrCat("StringLiteralUnicodeEscapeSurrogatePairShortLong",
field_type),
RECOMMENDED, absl::StrCat(field_name, ": '\\ud801\\U0000dc37'"));
// The following method depend on the type of field, as strings have extra
// validation.
const auto test_method =
field_type == "String"
? &TextFormatConformanceTestSuiteImpl::ExpectParseFailure
: &TextFormatConformanceTestSuiteImpl::RunValidTextFormatTest;
// String fields reject invalid UTF-8 byte sequences; bytes fields don't.
(this->*test_method)(absl::StrCat(field_type, "FieldBadUTF8Octal"),
REQUIRED, absl::StrCat(field_name, ": '\\300'"));
(this->*test_method)(absl::StrCat(field_type, "FieldBadUTF8Hex"), REQUIRED,
absl::StrCat(field_name, ": '\\xc0'"));
}
// Separators
for (const auto& test_case : std::vector<std::pair<std::string, std::string>>{
{"string", "\"abc\""},
{"bytes", "\"abc\""},
{"int32", "123"},
{"bool", "true"},
{"double", "1.23"},
{"fixed32", "0x123"},
}) {
// Optional Field Separators
for (const auto& field_type :
std::vector<std::string>{"Single", "Repeated"}) {
std::string field_name, field_value;
if (field_type == "Single") {
field_name = absl::StrCat("optional_", test_case.first);
field_value = test_case.second;
} else {
field_name = absl::StrCat("repeated_", test_case.first);
field_value = absl::StrCat("[", test_case.second, "]");
}
RunValidTextFormatTest(absl::StrCat("FieldSeparatorCommaTopLevel",
field_type, "_", test_case.first),
REQUIRED,
absl::StrCat(field_name, ": ", field_value, ","));
RunValidTextFormatTest(absl::StrCat("FieldSeparatorSemiTopLevelSingle",
field_type, "_", test_case.first),
REQUIRED,
absl::StrCat(field_name, ": ", field_value, ";"));
ExpectParseFailure(
absl::StrCat("FieldSeparatorCommaTopLevelDuplicatesFails", field_type,
"_", test_case.first),
REQUIRED, absl::StrCat(field_name, ": ", field_value, ",,"));
ExpectParseFailure(
absl::StrCat("FieldSeparatorSemiTopLevelDuplicateFails", field_type,
"_", test_case.first),
REQUIRED, absl::StrCat(field_name, ": ", field_value, ";;"));
}
// Required List Separators
RunValidTextFormatTest(
absl::StrCat("ListSeparator_", test_case.first), REQUIRED,
absl::StrCat("repeated_", test_case.first, ": [", test_case.second, ",",
test_case.second, "]"));
ExpectParseFailure(
absl::StrCat("ListSeparatorSemiFails_", test_case.first), REQUIRED,
absl::StrCat("repeated_", test_case.first, ": [", test_case.second, ";",
test_case.second, "]"));
// For string and bytes, if we skip the separator, the parser will treat
// the two values as a single value.
if (test_case.first == "string" || test_case.first == "bytes") {
RunValidTextFormatTest(
absl::StrCat("ListSeparatorMissingIsOneValue_", test_case.first),
REQUIRED,
absl::StrCat("repeated_", test_case.first, ": [", test_case.second,
" ", test_case.second, "]"));
} else {
ExpectParseFailure(
absl::StrCat("ListSeparatorMissingFails_", test_case.first), REQUIRED,
absl::StrCat("repeated_", test_case.first, ": [", test_case.second,
" ", test_case.second, "]"));
}
ExpectParseFailure(
absl::StrCat("ListSeparatorDuplicateFails_", test_case.first), REQUIRED,
absl::StrCat("repeated_", test_case.first, ": [", test_case.second,
",,", test_case.second, "]"));
ExpectParseFailure(
absl::StrCat("ListSeparatorSingleTrailingFails_", test_case.first),
REQUIRED,
absl::StrCat("repeated_", test_case.first, ": [", test_case.second,
",]"));
ExpectParseFailure(
absl::StrCat("ListSeparatorTwoValuesTrailingFails_", test_case.first),
REQUIRED,
absl::StrCat("repeated_", test_case.first, ": [", test_case.second, ",",
test_case.second, ",]"));
}
// The test message don't really have all types nested, so just check one
// data type for the nested field separator support
RunValidTextFormatTest("FieldSeparatorCommaNested", REQUIRED,
"optional_nested_message: { a: 123, }");
RunValidTextFormatTest("FieldSeparatorSemiNested", REQUIRED,
"optional_nested_message: { a: 123; }");
ExpectParseFailure("FieldSeparatorCommaNestedDuplicates", REQUIRED,
"optional_nested_message: { a: 123,, }");
ExpectParseFailure("FieldSeparatorSemiNestedDuplicates", REQUIRED,
"optional_nested_message: { a: 123;; }");
// Unknown Fields
UnknownToTestAllTypes message;
// Unable to print unknown Fixed32/Fixed64 fields as if they are known.
// Fixed32/Fixed64 fields are not added in the tests.
message.set_optional_int32(123);
message.set_optional_string("hello");
message.set_optional_bool(true);
RunValidUnknownTextFormatTest("ScalarUnknownFields", message);
message.Clear();
message.mutable_nested_message()->set_c(111);
RunValidUnknownTextFormatTest("MessageUnknownFields", message);
message.Clear();
message.mutable_optionalgroup()->set_a(321);
RunValidUnknownTextFormatTest("GroupUnknownFields", message);
message.add_repeated_int32(1);
message.add_repeated_int32(2);
message.add_repeated_int32(3);
RunValidUnknownTextFormatTest("RepeatedUnknownFields", message);
// Map fields
MessageType prototype;
(*prototype.mutable_map_string_string())["c"] = "value";
(*prototype.mutable_map_string_string())["b"] = "value";
(*prototype.mutable_map_string_string())["a"] = "value";
RunValidTextFormatTestWithMessage("AlphabeticallySortedMapStringKeys",
REQUIRED,
R"(
map_string_string {
key: "a"
value: "value"
}
map_string_string {
key: "b"
value: "value"
}
map_string_string {
key: "c"
value: "value"
}
)",
prototype);
prototype.Clear();
(*prototype.mutable_map_int32_int32())[3] = 0;
(*prototype.mutable_map_int32_int32())[2] = 0;
(*prototype.mutable_map_int32_int32())[1] = 0;
RunValidTextFormatTestWithMessage("AlphabeticallySortedMapIntKeys", REQUIRED,
R"(
map_int32_int32 {
key: 1
value: 0
}
map_int32_int32 {
key: 2
value: 0
}
map_int32_int32 {
key: 3
value: 0
}
)",
prototype);
prototype.Clear();
(*prototype.mutable_map_bool_bool())[true] = false;
(*prototype.mutable_map_bool_bool())[false] = false;
RunValidTextFormatTestWithMessage("AlphabeticallySortedMapBoolKeys", REQUIRED,
R"(
map_bool_bool {
key: false
value: false
}
map_bool_bool {
key: true
value: false
}
)",
prototype);
prototype.Clear();
ConformanceRequestSetting setting_map(
REQUIRED, conformance::TEXT_FORMAT, conformance::PROTOBUF,
conformance::TEXT_FORMAT_TEST, prototype, "DuplicateMapKey", R"(
map_string_nested_message {
key: "duplicate"
value: { a: 123 }
}
map_string_nested_message {
key: "duplicate"
value: { corecursive: {} }
}
)");
// The last-specified value will be retained in a parsed map
suite_.RunValidInputTest(setting_map, R"(
map_string_nested_message {
key: "duplicate"
value: { corecursive: {} }
}
)");
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<MessageType>::RunAnyTests() {
// Any fields
RunValidTextFormatTest("AnyField", REQUIRED,
R"(
optional_any: {
[type.googleapis.com/protobuf_test_messages.proto3.TestAllTypesProto3]
{ optional_int32: 12345
}
}
)");
RunValidTextFormatTest("AnyFieldWithRawBytes", REQUIRED,
R"(
optional_any: {
type_url:
"type.googleapis.com/protobuf_test_messages.proto3.TestAllTypesProto3" value:
"\b\271`"
}
)");
ExpectParseFailure("AnyFieldWithInvalidType", REQUIRED,
R"(
optional_any: {
[type.googleapis.com/unknown] {
optional_int32: 12345
}
}
)");
}
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<
MessageType>::RunTextFormatPerformanceTests() {
TestTextFormatPerformanceMergeMessageWithRepeatedField("Bool",
"repeated_bool: true");
TestTextFormatPerformanceMergeMessageWithRepeatedField(
"Double", "repeated_double: 123");
TestTextFormatPerformanceMergeMessageWithRepeatedField(
"Int32", "repeated_uint32: 123");
TestTextFormatPerformanceMergeMessageWithRepeatedField(
"Int64", "repeated_uint64: 123");
TestTextFormatPerformanceMergeMessageWithRepeatedField(
"String", R"(repeated_string: "foo")");
TestTextFormatPerformanceMergeMessageWithRepeatedField(
"Bytes", R"(repeated_bytes: "foo")");
}
// This is currently considered valid input by some languages but not others
template <typename MessageType>
void TextFormatConformanceTestSuiteImpl<MessageType>::
TestTextFormatPerformanceMergeMessageWithRepeatedField(
const std::string& test_type_name, const std::string& message_field) {
std::string recursive_message =
absl::StrCat("recursive_message { ", message_field, " }");
std::string input;
for (size_t i = 0; i < kPerformanceRepeatCount; i++) {
absl::StrAppend(&input, recursive_message);
}
std::string expected = "recursive_message { ";
for (size_t i = 0; i < kPerformanceRepeatCount; i++) {
absl::StrAppend(&expected, message_field, " ");
}
absl::StrAppend(&expected, "}");
RunValidTextFormatTestWithExpected(
absl::StrCat("TestTextFormatPerformanceMergeMessageWithRepeatedField",
test_type_name),
RECOMMENDED, input, expected);
}
} // namespace protobuf
} // namespace google