// 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 #import #import "GPBCodedInputStream.h" #import "GPBCodedInputStream_PackagePrivate.h" #import "GPBCodedOutputStream.h" #import "GPBTestUtilities.h" #import "GPBUnknownField.h" #import "GPBUnknownFields.h" #import "GPBUtilities.h" #import "GPBUtilities_PackagePrivate.h" #import "GPBWireFormat.h" #import "objectivec/Tests/Unittest.pbobjc.h" @interface CodedInputStreamTests : GPBTestCase @end @implementation CodedInputStreamTests - (NSData*)bytes_with_sentinel:(int32_t)unused, ... { va_list list; va_start(list, unused); NSMutableData* values = [NSMutableData dataWithCapacity:0]; int32_t i; while ((i = va_arg(list, int32_t)) != 256) { NSAssert(i >= 0 && i < 256, @""); uint8_t u = (uint8_t)i; [values appendBytes:&u length:1]; } va_end(list); return values; } #define bytes(...) [self bytes_with_sentinel:0, __VA_ARGS__, 256] - (void)testDecodeZigZag { [self assertReadZigZag32:bytes(0x0) value:0]; [self assertReadZigZag32:bytes(0x1) value:-1]; [self assertReadZigZag32:bytes(0x2) value:1]; [self assertReadZigZag32:bytes(0x3) value:-2]; [self assertReadZigZag32:bytes(0xFE, 0xFF, 0xFF, 0xFF, 0x07) value:(int32_t)0x3FFFFFFF]; [self assertReadZigZag32:bytes(0xFF, 0xFF, 0xFF, 0xFF, 0x07) value:(int32_t)0xC0000000]; [self assertReadZigZag32:bytes(0xFE, 0xFF, 0xFF, 0xFF, 0x0F) value:(int32_t)0x7FFFFFFF]; [self assertReadZigZag32:bytes(0xFF, 0xFF, 0xFF, 0xFF, 0x0F) value:(int32_t)0x80000000]; [self assertReadZigZag64:bytes(0x0) value:0]; [self assertReadZigZag64:bytes(0x1) value:-1]; [self assertReadZigZag64:bytes(0x2) value:1]; [self assertReadZigZag64:bytes(0x3) value:-2]; [self assertReadZigZag64:bytes(0xFE, 0xFF, 0xFF, 0xFF, 0x07) value:(int32_t)0x3FFFFFFF]; [self assertReadZigZag64:bytes(0xFF, 0xFF, 0xFF, 0xFF, 0x07) value:(int32_t)0xC0000000]; [self assertReadZigZag64:bytes(0xFE, 0xFF, 0xFF, 0xFF, 0x0F) value:(int32_t)0x7FFFFFFF]; [self assertReadZigZag64:bytes(0xFF, 0xFF, 0xFF, 0xFF, 0x0F) value:(int32_t)0x80000000]; [self assertReadZigZag64:bytes(0xFE, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0x01) value:0x7FFFFFFFFFFFFFFFL]; [self assertReadZigZag64:bytes(0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0x01) value:0x8000000000000000L]; } - (void)assertReadVarint:(NSData*)data value:(int64_t)value { if (value <= INT32_MAX && value >= INT32_MIN) { { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual((int32_t)value, [input readInt32]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual((int32_t)value, [input readEnum]); } } if (value <= UINT32_MAX && value >= 0) { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual((uint32_t)value, [input readUInt32]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value, [input readInt64]); } if (value >= 0) { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual((uint64_t)value, [input readUInt64]); } } - (void)assertReadLittleEndian32:(NSData*)data value:(int32_t)value { { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value, [input readSFixed32]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(GPBConvertInt32ToFloat(value), [input readFloat]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual((uint32_t)value, [input readFixed32]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value, [input readSFixed32]); } } - (void)assertReadLittleEndian64:(NSData*)data value:(int64_t)value { { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value, [input readSFixed64]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(GPBConvertInt64ToDouble(value), [input readDouble]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual((uint64_t)value, [input readFixed64]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value, [input readSFixed64]); } } - (void)assertReadZigZag32:(NSData*)data value:(int64_t)value { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual((int32_t)value, [input readSInt32]); } - (void)assertReadZigZag64:(NSData*)data value:(int64_t)value { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value, [input readSInt64]); } - (void)assertReadVarintFailure:(NSData*)data { { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertThrows([input readInt32]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertThrows([input readInt64]); } } - (void)testBytes { NSData* data = bytes(0xa2, 0x74); XCTAssertEqual(data.length, (NSUInteger)2); XCTAssertEqual(((uint8_t*)data.bytes)[0], (uint8_t)0xa2); XCTAssertEqual(((uint8_t*)data.bytes)[1], (uint8_t)0x74); } - (void)testReadBool { { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:bytes(0x00)]; XCTAssertEqual(NO, [input readBool]); } { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:bytes(0x01)]; XCTAssertEqual(YES, [input readBool]); } } - (void)testReadVarint { [self assertReadVarint:bytes(0x00) value:0]; [self assertReadVarint:bytes(0x01) value:1]; [self assertReadVarint:bytes(0x7f) value:127]; // 14882 [self assertReadVarint:bytes(0xa2, 0x74) value:(0x22 << 0) | (0x74 << 7)]; // 1904930 [self assertReadVarint:bytes(0xa2, 0xa2, 0x74) value:(0x22 << 0) | (0x22 << 7) | (0x74 << 14)]; // 243831074 [self assertReadVarint:bytes(0xa2, 0xa2, 0xa2, 0x74) value:(0x22 << 0) | (0x22 << 7) | (0x22 << 14) | (0x74 << 21)]; // 2961488830 [self assertReadVarint:bytes(0xbe, 0xf7, 0x92, 0x84, 0x0b) value:(0x3e << 0) | (0x77 << 7) | (0x12 << 14) | (0x04 << 21) | (0x0bLL << 28)]; // 64-bit // 7256456126 [self assertReadVarint:bytes(0xbe, 0xf7, 0x92, 0x84, 0x1b) value:(0x3e << 0) | (0x77 << 7) | (0x12 << 14) | (0x04 << 21) | (0x1bLL << 28)]; // 41256202580718336 [self assertReadVarint:bytes(0x80, 0xe6, 0xeb, 0x9c, 0xc3, 0xc9, 0xa4, 0x49) value:(0x00 << 0) | (0x66 << 7) | (0x6b << 14) | (0x1c << 21) | (0x43LL << 28) | (0x49LL << 35) | (0x24LL << 42) | (0x49LL << 49)]; // 11964378330978735131 [self assertReadVarint:bytes(0x9b, 0xa8, 0xf9, 0xc2, 0xbb, 0xd6, 0x80, 0x85, 0xa6, 0x01) value:(0x1b << 0) | (0x28 << 7) | (0x79 << 14) | (0x42 << 21) | (0x3bLL << 28) | (0x56LL << 35) | (0x00LL << 42) | (0x05LL << 49) | (0x26LL << 56) | (0x01ULL << 63)]; // Failures [self assertReadVarintFailure:bytes(0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x00)]; [self assertReadVarintFailure:bytes(0x80)]; } - (void)testReadVarint32FromVarint64 { { // Turn on lower 31 bits of the upper half on a 64 bit varint. NSData* data = bytes(0x80, 0x80, 0x80, 0x80, 0xF0, 0xFF, 0xFF, 0xFF, 0xFF, 0x7E); int32_t value32 = 0x0; GPBCodedInputStream* input32 = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value32, [input32 readInt32]); int64_t value64 = INT64_MAX & 0xFFFFFFFF00000000; GPBCodedInputStream* input64 = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value64, [input64 readInt64]); } { // Turn on lower 31 bits and lower 31 bits on upper half on a 64 bit varint. NSData* data = bytes(0xFF, 0xFF, 0xFF, 0xFF, 0xF7, 0xFF, 0xFF, 0xFF, 0xFF, 0x7E); int32_t value32 = INT32_MAX; GPBCodedInputStream* input32 = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value32, [input32 readInt32]); int64_t value64 = INT64_MAX & 0xFFFFFFFF7FFFFFFF; GPBCodedInputStream* input64 = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value64, [input64 readInt64]); } { // Turn on bits 32 and 64 bit on a 64 bit varint. NSData* data = bytes(0x80, 0x80, 0x80, 0x80, 0x88, 0x80, 0x80, 0x80, 0x80, 0x01); int32_t value32 = INT32_MIN; GPBCodedInputStream* input32 = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value32, [input32 readInt32]); int64_t value64 = INT64_MIN | (0x01LL << 31); GPBCodedInputStream* input64 = [GPBCodedInputStream streamWithData:data]; XCTAssertEqual(value64, [input64 readInt64]); } } - (void)testReadLittleEndian { [self assertReadLittleEndian32:bytes(0x78, 0x56, 0x34, 0x12) value:0x12345678]; [self assertReadLittleEndian32:bytes(0xf0, 0xde, 0xbc, 0x9a) value:0x9abcdef0]; [self assertReadLittleEndian64:bytes(0xf0, 0xde, 0xbc, 0x9a, 0x78, 0x56, 0x34, 0x12) value:0x123456789abcdef0LL]; [self assertReadLittleEndian64:bytes(0x78, 0x56, 0x34, 0x12, 0xf0, 0xde, 0xbc, 0x9a) value:0x9abcdef012345678LL]; } - (void)testReadWholeMessage { TestAllTypes* message = [self allSetRepeatedCount:kGPBDefaultRepeatCount]; NSData* rawBytes = message.data; XCTAssertEqual(message.serializedSize, (size_t)rawBytes.length); TestAllTypes* message2 = [TestAllTypes parseFromData:rawBytes extensionRegistry:nil error:NULL]; [self assertAllFieldsSet:message2 repeatedCount:kGPBDefaultRepeatCount]; } - (void)testSkipWholeMessage { TestAllTypes* message = [self allSetRepeatedCount:kGPBDefaultRepeatCount]; NSData* rawBytes = message.data; TestEmptyMessage* empty = [TestEmptyMessage parseFromData:rawBytes error:NULL]; XCTAssertNotNil(empty); GPBUnknownFields* ufs = [[[GPBUnknownFields alloc] initFromMessage:empty] autorelease]; NSMutableArray* fieldNumbers = [NSMutableArray arrayWithCapacity:ufs.count]; for (GPBUnknownField* field in ufs) { GPBWireFormat wireFormat; switch (field.type) { case GPBUnknownFieldTypeFixed32: wireFormat = GPBWireFormatFixed32; break; case GPBUnknownFieldTypeFixed64: wireFormat = GPBWireFormatFixed64; break; case GPBUnknownFieldTypeVarint: wireFormat = GPBWireFormatVarint; break; case GPBUnknownFieldTypeLengthDelimited: wireFormat = GPBWireFormatLengthDelimited; break; case GPBUnknownFieldTypeGroup: wireFormat = GPBWireFormatStartGroup; break; } uint32_t tag = GPBWireFormatMakeTag(field.number, wireFormat); [fieldNumbers addObject:@(tag)]; } // Check the tags compared to what's in the UnknownFields to confirm the stream is // skipping as expected (this covers the tags within a group also). GPBCodedInputStream* input2 = [GPBCodedInputStream streamWithData:rawBytes]; NSUInteger idx = 0; while (YES) { int32_t tag = [input2 readTag]; if (tag == 0) { XCTAssertEqual(idx, fieldNumbers.count); break; } XCTAssertEqual(tag, [fieldNumbers[idx] intValue]); [input2 skipField:tag]; ++idx; } } - (void)testLimit { TestAllTypes* message = [self allSetRepeatedCount:kGPBDefaultRepeatCount]; NSData* rawBytes = message.data; GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:rawBytes]; XCTAssertEqual([input bytesUntilLimit], rawBytes.length); [input pushLimit:8]; XCTAssertEqual([input bytesUntilLimit], 8u); [input popLimit:3]; XCTAssertEqual([input bytesUntilLimit], 3u); [input readTag]; XCTAssertEqual([input position], 1u); XCTAssertEqual([input bytesUntilLimit], 2u); } - (void)testReadHugeBlob { // Allocate and initialize a 1MB blob. NSMutableData* blob = [NSMutableData dataWithLength:1 << 20]; for (NSUInteger i = 0; i < blob.length; i++) { ((uint8_t*)blob.mutableBytes)[i] = (uint8_t)i; } // Make a message containing it. TestAllTypes* message = [TestAllTypes message]; [self setAllFields:message repeatedCount:kGPBDefaultRepeatCount]; [message setOptionalBytes:blob]; // Serialize and parse it. Make sure to parse from an InputStream, not // directly from a ByteString, so that CodedInputStream uses buffered // reading. NSData* messageData = message.data; XCTAssertNotNil(messageData); GPBCodedInputStream* stream = [GPBCodedInputStream streamWithData:messageData]; TestAllTypes* message2 = [TestAllTypes parseFromCodedInputStream:stream extensionRegistry:nil error:NULL]; XCTAssertEqualObjects(message.optionalBytes, message2.optionalBytes); // Make sure all the other fields were parsed correctly. TestAllTypes* message3 = [[message2 copy] autorelease]; TestAllTypes* types = [self allSetRepeatedCount:kGPBDefaultRepeatCount]; NSData* data = [types optionalBytes]; [message3 setOptionalBytes:data]; [self assertAllFieldsSet:message3 repeatedCount:kGPBDefaultRepeatCount]; } - (void)testReadMaliciouslyLargeBlob { NSOutputStream* rawOutput = [NSOutputStream outputStreamToMemory]; GPBCodedOutputStream* output = [GPBCodedOutputStream streamWithOutputStream:rawOutput]; int32_t tag = GPBWireFormatMakeTag(1, GPBWireFormatLengthDelimited); [output writeRawVarint32:tag]; [output writeRawVarint32:0x7FFFFFFF]; uint8_t bytes[32] = {0}; [output writeRawData:[NSData dataWithBytes:bytes length:32]]; [output flush]; NSData* data = [rawOutput propertyForKey:NSStreamDataWrittenToMemoryStreamKey]; GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:[NSMutableData dataWithData:data]]; XCTAssertEqual(tag, [input readTag]); XCTAssertThrows([input readBytes]); } - (void)testReadEmptyString { NSData* data = bytes(0x00); GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertEqualObjects(@"", [input readString]); } - (void)testInvalidGroupEndTagThrows { NSData* data = bytes(0x0B, 0x1A, 0x02, 0x4B, 0x50, 0x14); GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; XCTAssertThrowsSpecificNamed([input skipMessage], NSException, GPBCodedInputStreamException, @"should throw a GPBCodedInputStreamException exception "); } - (void)testBytesOver2GB { NSData* data = bytes(0xFF, 0xFF, 0xFF, 0xFF, 0x0F, 0x01, 0x02, 0x03); // don't need all the bytes GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; @try { __unused NSData* result = [input readBytes]; XCTFail(@"Should have thrown"); } @catch (NSException* anException) { // Ensure the correct error within the exception. XCTAssertTrue([anException isKindOfClass:[NSException class]]); XCTAssertEqualObjects(anException.name, GPBCodedInputStreamException); NSDictionary* userInfo = anException.userInfo; XCTAssertNotNil(userInfo); NSError* err = userInfo[GPBCodedInputStreamUnderlyingErrorKey]; XCTAssertNotNil(err); XCTAssertEqualObjects(err.domain, GPBCodedInputStreamErrorDomain); XCTAssertEqual(err.code, GPBCodedInputStreamErrorInvalidSize); } } // Verifies fix for b/10315336. // Note: Now that there isn't a custom string class under the hood, this test // isn't as critical, but it does cover bad input and if a custom class is added // again, it will help validate that class' handing of bad utf8. - (void)testReadMalformedString { NSOutputStream* rawOutput = [NSOutputStream outputStreamToMemory]; GPBCodedOutputStream* output = [GPBCodedOutputStream streamWithOutputStream:rawOutput]; int32_t tag = GPBWireFormatMakeTag(TestAllTypes_FieldNumber_DefaultString, GPBWireFormatLengthDelimited); [output writeRawVarint32:tag]; [output writeRawVarint32:5]; // Create an invalid utf-8 byte array. uint8_t bytes[] = {0xc2, 0xf2, 0x0, 0x0, 0x0}; [output writeRawData:[NSData dataWithBytes:bytes length:sizeof(bytes)]]; [output flush]; NSData* data = [rawOutput propertyForKey:NSStreamDataWrittenToMemoryStreamKey]; GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; NSError* error = nil; TestAllTypes* message = [TestAllTypes parseFromCodedInputStream:input extensionRegistry:nil error:&error]; XCTAssertNotNil(error); XCTAssertNil(message); } - (void)testBOMWithinStrings { // We've seen servers that end up with BOMs within strings (not always at the // start, and sometimes in multiple places), make sure they always parse // correctly. (Again, this is inpart in case a custom string class is ever // used again.) const char* strs[] = { "\xEF\xBB\xBF String with BOM", "String with \xEF\xBB\xBF in middle", "String with end bom \xEF\xBB\xBF", "\xEF\xBB\xBF\xe2\x99\xa1", // BOM White Heart "\xEF\xBB\xBF\xEF\xBB\xBF String with Two BOM", }; for (size_t i = 0; i < GPBARRAYSIZE(strs); ++i) { NSOutputStream* rawOutput = [NSOutputStream outputStreamToMemory]; GPBCodedOutputStream* output = [GPBCodedOutputStream streamWithOutputStream:rawOutput]; int32_t tag = GPBWireFormatMakeTag(TestAllTypes_FieldNumber_DefaultString, GPBWireFormatLengthDelimited); [output writeRawVarint32:tag]; size_t length = strlen(strs[i]); [output writeRawVarint32:(int32_t)length]; [output writeRawData:[NSData dataWithBytes:strs[i] length:length]]; [output flush]; NSData* data = [rawOutput propertyForKey:NSStreamDataWrittenToMemoryStreamKey]; GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; TestAllTypes* message = [TestAllTypes parseFromCodedInputStream:input extensionRegistry:nil error:NULL]; XCTAssertNotNil(message, @"Loop %zd", i); // Ensure the string is there. NSString can consume the BOM in some // cases, so don't actually check the string for exact equality. XCTAssertTrue(message.defaultString.length > 0, @"Loop %zd", i); } } - (void)assertReadByteToEndGroupFails:(NSData*)data { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; uint32_t tag = [input readTag]; XCTAssertThrows(GPBCodedInputStreamReadRetainedBytesToEndGroupNoCopy( &input->state_, GPBWireFormatGetTagFieldNumber(tag))); } - (void)assertReadByteToEndGroup:(NSData*)data value:(NSData*)value { GPBCodedInputStream* input = [GPBCodedInputStream streamWithData:data]; uint32_t tag = [input readTag]; NSData* readValue = GPBCodedInputStreamReadRetainedBytesToEndGroupNoCopy( &input->state_, GPBWireFormatGetTagFieldNumber(tag)); XCTAssertNotNil(readValue); XCTAssertEqualObjects(readValue, value); [readValue release]; } static NSData* DataForGroupsOfDepth(NSUInteger depth) { NSMutableData* data = [NSMutableData dataWithCapacity:0]; uint32_t byte = 35; // 35 = 0b100011 -> field 4/start group for (NSUInteger i = 0; i < depth; ++i) { [data appendBytes:&byte length:1]; } byte = 8; // 8 = 0b1000, -> field 1/varint [data appendBytes:&byte length:1]; byte = 1; // 1 -> varint value of 1 [data appendBytes:&byte length:1]; byte = 36; // 36 = 0b100100 -> field 4/end group for (NSUInteger i = 0; i < depth; ++i) { [data appendBytes:&byte length:1]; } return data; } - (void)testBytesToEndGroup { // 35 = 0b100011 -> field 4/start group // 36 = 0b100100 -> field 4/end group // 43 = 0b101011 -> field 5/end group // 44 = 0b101100 -> field 5/end group // 8 = 0b1000, 1 -> field 1/varint, value of 1 // 21 = 0b10101, 0x78, 0x56, 0x34, 0x12 -> field 2/fixed32, value of 0x12345678 // 25 = 0b11001, 0xf0, 0xde, 0xbc, 0x9a, 0x78, 0x56, 0x34, 0x12 -> field 3/fixed64, // value of 0x123456789abcdef0LL // 50 = 0b110010, 0x0 -> field 6/length delimited, length 0 // 50 = 0b110010, 0x1, 42 -> field 6/length delimited, length 1, byte 42 // 0 -> field 0 which is invalid/varint // 15 = 0b1111 -> field 1, wire type 7 which is invalid [self assertReadByteToEndGroup:bytes(35, 36) value:bytes(36)]; // empty group [self assertReadByteToEndGroup:bytes(35, 8, 1, 36) value:bytes(8, 1, 36)]; // varint [self assertReadByteToEndGroup:bytes(35, 21, 0x78, 0x56, 0x34, 0x12, 36) // fixed32 value:bytes(21, 0x78, 0x56, 0x34, 0x12, 36)]; [self assertReadByteToEndGroup:bytes(35, 25, 0xf0, 0xde, 0xbc, 0x9a, 0x78, 0x56, 0x34, 0x12, 36) // fixed64 value:bytes(25, 0xf0, 0xde, 0xbc, 0x9a, 0x78, 0x56, 0x34, 0x12, 36)]; [self assertReadByteToEndGroup:bytes(35, 50, 0, 36) value:bytes(50, 0, 36)]; // length delimited, length 0 [self assertReadByteToEndGroup:bytes(35, 50, 1, 42, 36) value:bytes(50, 1, 42, 36)]; // length delimited, length 1, byte 42 [self assertReadByteToEndGroup:bytes(35, 43, 44, 36) value:bytes(43, 44, 36)]; // Sub group [self assertReadByteToEndGroup:bytes(35, 8, 1, 43, 8, 1, 44, 36) // varint and sub group with varint value:bytes(8, 1, 43, 8, 1, 44, 36)]; [self assertReadByteToEndGroupFails:bytes(35, 0, 36)]; // Invalid field number [self assertReadByteToEndGroupFails:bytes(35, 15, 36)]; // Invalid wire type [self assertReadByteToEndGroupFails:bytes(35, 21, 0x78, 0x56, 0x34)]; // truncated fixed32 [self assertReadByteToEndGroupFails:bytes(35, 25, 0xf0, 0xde, 0xbc, 0x9a, 0x78, 0x56, 0x34)]; // truncated fixed64 // Missing end group [self assertReadByteToEndGroupFails:bytes(35)]; [self assertReadByteToEndGroupFails:bytes(35, 8, 1)]; [self assertReadByteToEndGroupFails:bytes(35, 43)]; [self assertReadByteToEndGroupFails:bytes(35, 43, 8, 1)]; // Wrong end group [self assertReadByteToEndGroupFails:bytes(35, 44)]; [self assertReadByteToEndGroupFails:bytes(35, 8, 1, 44)]; [self assertReadByteToEndGroupFails:bytes(35, 43, 36)]; [self assertReadByteToEndGroupFails:bytes(35, 43, 8, 1, 36)]; [self assertReadByteToEndGroupFails:bytes(35, 43, 44, 44)]; [self assertReadByteToEndGroupFails:bytes(35, 43, 8, 1, 44, 44)]; // This is the same limit as within GPBCodedInputStream. const NSUInteger kDefaultRecursionLimit = 100; // That depth parses. NSData* testData = DataForGroupsOfDepth(kDefaultRecursionLimit); [self assertReadByteToEndGroup:testData value:[testData subdataWithRange:NSMakeRange(1, testData.length - 1)]]; // One more level deep fails. testData = DataForGroupsOfDepth(kDefaultRecursionLimit + 1); [self assertReadByteToEndGroupFails:testData]; } @end