// // GCDAsyncSocket.m // // This class is in the public domain. // Originally created by Robbie Hanson in Q4 2010. // Updated and maintained by Deusty LLC and the Apple development community. // // https://github.com/robbiehanson/CocoaAsyncSocket // #import "GCDAsyncSocket.h" #if TARGET_OS_IPHONE #import #endif #import #import #import #import #import #import #import #import #import #import #import #import #if ! __has_feature(objc_arc) #warning This file must be compiled with ARC. Use -fobjc-arc flag (or convert project to ARC). // For more information see: https://github.com/robbiehanson/CocoaAsyncSocket/wiki/ARC #endif /** * Does ARC support support GCD objects? * It does if the minimum deployment target is iOS 6+ or Mac OS X 10.8+ **/ #if TARGET_OS_IPHONE // Compiling for iOS #if __IPHONE_OS_VERSION_MIN_REQUIRED >= 60000 // iOS 6.0 or later #define NEEDS_DISPATCH_RETAIN_RELEASE 0 #else // iOS 5.X or earlier #define NEEDS_DISPATCH_RETAIN_RELEASE 1 #endif #else // Compiling for Mac OS X #if MAC_OS_X_VERSION_MIN_REQUIRED >= 1080 // Mac OS X 10.8 or later #define NEEDS_DISPATCH_RETAIN_RELEASE 0 #else #define NEEDS_DISPATCH_RETAIN_RELEASE 1 // Mac OS X 10.7 or earlier #endif #endif #if 0 // Logging Enabled - See log level below // Logging uses the CocoaLumberjack framework (which is also GCD based). // https://github.com/robbiehanson/CocoaLumberjack // // It allows us to do a lot of logging without significantly slowing down the code. #import "DDLog.h" #define LogAsync YES #define LogContext 65535 #define LogObjc(flg, frmt, ...) LOG_OBJC_MAYBE(LogAsync, logLevel, flg, LogContext, frmt, ##__VA_ARGS__) #define LogC(flg, frmt, ...) LOG_C_MAYBE(LogAsync, logLevel, flg, LogContext, frmt, ##__VA_ARGS__) #define LogError(frmt, ...) LogObjc(LOG_FLAG_ERROR, (@"%@: " frmt), THIS_FILE, ##__VA_ARGS__) #define LogWarn(frmt, ...) LogObjc(LOG_FLAG_WARN, (@"%@: " frmt), THIS_FILE, ##__VA_ARGS__) #define LogInfo(frmt, ...) LogObjc(LOG_FLAG_INFO, (@"%@: " frmt), THIS_FILE, ##__VA_ARGS__) #define LogVerbose(frmt, ...) LogObjc(LOG_FLAG_VERBOSE, (@"%@: " frmt), THIS_FILE, ##__VA_ARGS__) #define LogCError(frmt, ...) LogC(LOG_FLAG_ERROR, (@"%@: " frmt), THIS_FILE, ##__VA_ARGS__) #define LogCWarn(frmt, ...) LogC(LOG_FLAG_WARN, (@"%@: " frmt), THIS_FILE, ##__VA_ARGS__) #define LogCInfo(frmt, ...) LogC(LOG_FLAG_INFO, (@"%@: " frmt), THIS_FILE, ##__VA_ARGS__) #define LogCVerbose(frmt, ...) LogC(LOG_FLAG_VERBOSE, (@"%@: " frmt), THIS_FILE, ##__VA_ARGS__) #define LogTrace() LogObjc(LOG_FLAG_VERBOSE, @"%@: %@", THIS_FILE, THIS_METHOD) #define LogCTrace() LogC(LOG_FLAG_VERBOSE, @"%@: %s", THIS_FILE, __FUNCTION__) // Log levels : off, error, warn, info, verbose static const int logLevel = LOG_LEVEL_VERBOSE; #else // Logging Disabled #define LogError(frmt, ...) {} #define LogWarn(frmt, ...) {} #define LogInfo(frmt, ...) {} #define LogVerbose(frmt, ...) {} #define LogCError(frmt, ...) {} #define LogCWarn(frmt, ...) {} #define LogCInfo(frmt, ...) {} #define LogCVerbose(frmt, ...) {} #define LogTrace() {} #define LogCTrace(frmt, ...) {} #endif /** * Seeing a return statements within an inner block * can sometimes be mistaken for a return point of the enclosing method. * This makes inline blocks a bit easier to read. **/ #define return_from_block return /** * A socket file descriptor is really just an integer. * It represents the index of the socket within the kernel. * This makes invalid file descriptor comparisons easier to read. **/ #define SOCKET_NULL -1 NSString *const GCDAsyncSocketException = @"GCDAsyncSocketException"; NSString *const GCDAsyncSocketErrorDomain = @"GCDAsyncSocketErrorDomain"; NSString *const GCDAsyncSocketQueueName = @"GCDAsyncSocket"; NSString *const GCDAsyncSocketThreadName = @"GCDAsyncSocket-CFStream"; #if SECURE_TRANSPORT_MAYBE_AVAILABLE NSString *const GCDAsyncSocketSSLCipherSuites = @"GCDAsyncSocketSSLCipherSuites"; #if TARGET_OS_IPHONE NSString *const GCDAsyncSocketSSLProtocolVersionMin = @"GCDAsyncSocketSSLProtocolVersionMin"; NSString *const GCDAsyncSocketSSLProtocolVersionMax = @"GCDAsyncSocketSSLProtocolVersionMax"; #else NSString *const GCDAsyncSocketSSLDiffieHellmanParameters = @"GCDAsyncSocketSSLDiffieHellmanParameters"; #endif #endif enum GCDAsyncSocketFlags { kSocketStarted = 1 << 0, // If set, socket has been started (accepting/connecting) kConnected = 1 << 1, // If set, the socket is connected kForbidReadsWrites = 1 << 2, // If set, no new reads or writes are allowed kReadsPaused = 1 << 3, // If set, reads are paused due to possible timeout kWritesPaused = 1 << 4, // If set, writes are paused due to possible timeout kDisconnectAfterReads = 1 << 5, // If set, disconnect after no more reads are queued kDisconnectAfterWrites = 1 << 6, // If set, disconnect after no more writes are queued kSocketCanAcceptBytes = 1 << 7, // If set, we know socket can accept bytes. If unset, it's unknown. kReadSourceSuspended = 1 << 8, // If set, the read source is suspended kWriteSourceSuspended = 1 << 9, // If set, the write source is suspended kQueuedTLS = 1 << 10, // If set, we've queued an upgrade to TLS kStartingReadTLS = 1 << 11, // If set, we're waiting for TLS negotiation to complete kStartingWriteTLS = 1 << 12, // If set, we're waiting for TLS negotiation to complete kSocketSecure = 1 << 13, // If set, socket is using secure communication via SSL/TLS kSocketHasReadEOF = 1 << 14, // If set, we have read EOF from socket kReadStreamClosed = 1 << 15, // If set, we've read EOF plus prebuffer has been drained #if TARGET_OS_IPHONE kAddedStreamsToRunLoop = 1 << 16, // If set, CFStreams have been added to listener thread kUsingCFStreamForTLS = 1 << 17, // If set, we're forced to use CFStream instead of SecureTransport kSecureSocketHasBytesAvailable = 1 << 18, // If set, CFReadStream has notified us of bytes available #endif }; enum GCDAsyncSocketConfig { kIPv4Disabled = 1 << 0, // If set, IPv4 is disabled kIPv6Disabled = 1 << 1, // If set, IPv6 is disabled kPreferIPv6 = 1 << 2, // If set, IPv6 is preferred over IPv4 kAllowHalfDuplexConnection = 1 << 3, // If set, the socket will stay open even if the read stream closes }; #if TARGET_OS_IPHONE static NSThread *cfstreamThread; // Used for CFStreams #endif @interface GCDAsyncSocket () { uint32_t flags; uint16_t config; #if __has_feature(objc_arc_weak) __weak id delegate; #else __unsafe_unretained id delegate; #endif dispatch_queue_t delegateQueue; int socket4FD; int socket6FD; int connectIndex; NSData * connectInterface4; NSData * connectInterface6; dispatch_queue_t socketQueue; dispatch_source_t accept4Source; dispatch_source_t accept6Source; dispatch_source_t connectTimer; dispatch_source_t readSource; dispatch_source_t writeSource; dispatch_source_t readTimer; dispatch_source_t writeTimer; NSMutableArray *readQueue; NSMutableArray *writeQueue; GCDAsyncReadPacket *currentRead; GCDAsyncWritePacket *currentWrite; unsigned long socketFDBytesAvailable; GCDAsyncSocketPreBuffer *preBuffer; #if TARGET_OS_IPHONE CFStreamClientContext streamContext; CFReadStreamRef readStream; CFWriteStreamRef writeStream; #endif #if SECURE_TRANSPORT_MAYBE_AVAILABLE SSLContextRef sslContext; GCDAsyncSocketPreBuffer *sslPreBuffer; size_t sslWriteCachedLength; OSStatus sslErrCode; #endif void *IsOnSocketQueueOrTargetQueueKey; id userData; } // Accepting - (BOOL)doAccept:(int)socketFD; // Connecting - (void)startConnectTimeout:(NSTimeInterval)timeout; - (void)endConnectTimeout; - (void)doConnectTimeout; - (void)lookup:(int)aConnectIndex host:(NSString *)host port:(uint16_t)port; - (void)lookup:(int)aConnectIndex didSucceedWithAddress4:(NSData *)address4 address6:(NSData *)address6; - (void)lookup:(int)aConnectIndex didFail:(NSError *)error; - (BOOL)connectWithAddress4:(NSData *)address4 address6:(NSData *)address6 error:(NSError **)errPtr; - (void)didConnect:(int)aConnectIndex; - (void)didNotConnect:(int)aConnectIndex error:(NSError *)error; // Disconnect - (void)closeWithError:(NSError *)error; - (void)maybeClose; // Errors - (NSError *)badConfigError:(NSString *)msg; - (NSError *)badParamError:(NSString *)msg; - (NSError *)gaiError:(int)gai_error; - (NSError *)errnoError; - (NSError *)errnoErrorWithReason:(NSString *)reason; - (NSError *)connectTimeoutError; - (NSError *)otherError:(NSString *)msg; // Diagnostics - (NSString *)connectedHost4; - (NSString *)connectedHost6; - (uint16_t)connectedPort4; - (uint16_t)connectedPort6; - (NSString *)localHost4; - (NSString *)localHost6; - (uint16_t)localPort4; - (uint16_t)localPort6; - (NSString *)connectedHostFromSocket4:(int)socketFD; - (NSString *)connectedHostFromSocket6:(int)socketFD; - (uint16_t)connectedPortFromSocket4:(int)socketFD; - (uint16_t)connectedPortFromSocket6:(int)socketFD; - (NSString *)localHostFromSocket4:(int)socketFD; - (NSString *)localHostFromSocket6:(int)socketFD; - (uint16_t)localPortFromSocket4:(int)socketFD; - (uint16_t)localPortFromSocket6:(int)socketFD; // Utilities - (void)getInterfaceAddress4:(NSMutableData **)addr4Ptr address6:(NSMutableData **)addr6Ptr fromDescription:(NSString *)interfaceDescription port:(uint16_t)port; - (void)setupReadAndWriteSourcesForNewlyConnectedSocket:(int)socketFD; - (void)suspendReadSource; - (void)resumeReadSource; - (void)suspendWriteSource; - (void)resumeWriteSource; // Reading - (void)maybeDequeueRead; - (void)flushSSLBuffers; - (void)doReadData; - (void)doReadEOF; - (void)completeCurrentRead; - (void)endCurrentRead; - (void)setupReadTimerWithTimeout:(NSTimeInterval)timeout; - (void)doReadTimeout; - (void)doReadTimeoutWithExtension:(NSTimeInterval)timeoutExtension; // Writing - (void)maybeDequeueWrite; - (void)doWriteData; - (void)completeCurrentWrite; - (void)endCurrentWrite; - (void)setupWriteTimerWithTimeout:(NSTimeInterval)timeout; - (void)doWriteTimeout; - (void)doWriteTimeoutWithExtension:(NSTimeInterval)timeoutExtension; // Security - (void)maybeStartTLS; #if SECURE_TRANSPORT_MAYBE_AVAILABLE - (void)ssl_startTLS; - (void)ssl_continueSSLHandshake; #endif #if TARGET_OS_IPHONE - (void)cf_startTLS; #endif // CFStream #if TARGET_OS_IPHONE + (void)startCFStreamThreadIfNeeded; - (BOOL)createReadAndWriteStream; - (BOOL)registerForStreamCallbacksIncludingReadWrite:(BOOL)includeReadWrite; - (BOOL)addStreamsToRunLoop; - (BOOL)openStreams; - (void)removeStreamsFromRunLoop; #endif // Class Methods + (NSString *)hostFromSockaddr4:(const struct sockaddr_in *)pSockaddr4; + (NSString *)hostFromSockaddr6:(const struct sockaddr_in6 *)pSockaddr6; + (uint16_t)portFromSockaddr4:(const struct sockaddr_in *)pSockaddr4; + (uint16_t)portFromSockaddr6:(const struct sockaddr_in6 *)pSockaddr6; @end //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark - //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// /** * A PreBuffer is used when there is more data available on the socket * than is being requested by current read request. * In this case we slurp up all data from the socket (to minimize sys calls), * and store additional yet unread data in a "prebuffer". * * The prebuffer is entirely drained before we read from the socket again. * In other words, a large chunk of data is written is written to the prebuffer. * The prebuffer is then drained via a series of one or more reads (for subsequent read request(s)). * * A ring buffer was once used for this purpose. * But a ring buffer takes up twice as much memory as needed (double the size for mirroring). * In fact, it generally takes up more than twice the needed size as everything has to be rounded up to vm_page_size. * And since the prebuffer is always completely drained after being written to, a full ring buffer isn't needed. * * The current design is very simple and straight-forward, while also keeping memory requirements lower. **/ @interface GCDAsyncSocketPreBuffer : NSObject { uint8_t *preBuffer; size_t preBufferSize; uint8_t *readPointer; uint8_t *writePointer; } - (id)initWithCapacity:(size_t)numBytes; - (void)ensureCapacityForWrite:(size_t)numBytes; - (size_t)availableBytes; - (uint8_t *)readBuffer; - (void)getReadBuffer:(uint8_t **)bufferPtr availableBytes:(size_t *)availableBytesPtr; - (size_t)availableSpace; - (uint8_t *)writeBuffer; - (void)getWriteBuffer:(uint8_t **)bufferPtr availableSpace:(size_t *)availableSpacePtr; - (void)didRead:(size_t)bytesRead; - (void)didWrite:(size_t)bytesWritten; - (void)reset; @end @implementation GCDAsyncSocketPreBuffer - (id)initWithCapacity:(size_t)numBytes { if ((self = [super init])) { preBufferSize = numBytes; preBuffer = malloc(preBufferSize); readPointer = preBuffer; writePointer = preBuffer; } return self; } - (void)dealloc { if (preBuffer) free(preBuffer); } - (void)ensureCapacityForWrite:(size_t)numBytes { size_t availableSpace = preBufferSize - (writePointer - readPointer); if (numBytes > availableSpace) { size_t additionalBytes = numBytes - availableSpace; size_t newPreBufferSize = preBufferSize + additionalBytes; uint8_t *newPreBuffer = realloc(preBuffer, newPreBufferSize); size_t readPointerOffset = readPointer - preBuffer; size_t writePointerOffset = writePointer - preBuffer; preBuffer = newPreBuffer; preBufferSize = newPreBufferSize; readPointer = preBuffer + readPointerOffset; writePointer = preBuffer + writePointerOffset; } } - (size_t)availableBytes { return writePointer - readPointer; } - (uint8_t *)readBuffer { return readPointer; } - (void)getReadBuffer:(uint8_t **)bufferPtr availableBytes:(size_t *)availableBytesPtr { if (bufferPtr) *bufferPtr = readPointer; if (availableBytesPtr) *availableBytesPtr = writePointer - readPointer; } - (void)didRead:(size_t)bytesRead { readPointer += bytesRead; if (readPointer == writePointer) { // The prebuffer has been drained. Reset pointers. readPointer = preBuffer; writePointer = preBuffer; } } - (size_t)availableSpace { return preBufferSize - (writePointer - readPointer); } - (uint8_t *)writeBuffer { return writePointer; } - (void)getWriteBuffer:(uint8_t **)bufferPtr availableSpace:(size_t *)availableSpacePtr { if (bufferPtr) *bufferPtr = writePointer; if (availableSpacePtr) *availableSpacePtr = preBufferSize - (writePointer - readPointer); } - (void)didWrite:(size_t)bytesWritten { writePointer += bytesWritten; } - (void)reset { readPointer = preBuffer; writePointer = preBuffer; } @end //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark - //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// /** * The GCDAsyncReadPacket encompasses the instructions for any given read. * The content of a read packet allows the code to determine if we're: * - reading to a certain length * - reading to a certain separator * - or simply reading the first chunk of available data **/ @interface GCDAsyncReadPacket : NSObject { @public NSMutableData *buffer; NSUInteger startOffset; NSUInteger bytesDone; NSUInteger maxLength; NSTimeInterval timeout; NSUInteger readLength; NSData *term; BOOL bufferOwner; NSUInteger originalBufferLength; long tag; } - (id)initWithData:(NSMutableData *)d startOffset:(NSUInteger)s maxLength:(NSUInteger)m timeout:(NSTimeInterval)t readLength:(NSUInteger)l terminator:(NSData *)e tag:(long)i; - (void)ensureCapacityForAdditionalDataOfLength:(NSUInteger)bytesToRead; - (NSUInteger)optimalReadLengthWithDefault:(NSUInteger)defaultValue shouldPreBuffer:(BOOL *)shouldPreBufferPtr; - (NSUInteger)readLengthForNonTermWithHint:(NSUInteger)bytesAvailable; - (NSUInteger)readLengthForTermWithHint:(NSUInteger)bytesAvailable shouldPreBuffer:(BOOL *)shouldPreBufferPtr; - (NSUInteger)readLengthForTermWithPreBuffer:(GCDAsyncSocketPreBuffer *)preBuffer found:(BOOL *)foundPtr; - (NSInteger)searchForTermAfterPreBuffering:(ssize_t)numBytes; @end @implementation GCDAsyncReadPacket - (id)initWithData:(NSMutableData *)d startOffset:(NSUInteger)s maxLength:(NSUInteger)m timeout:(NSTimeInterval)t readLength:(NSUInteger)l terminator:(NSData *)e tag:(long)i { if((self = [super init])) { bytesDone = 0; maxLength = m; timeout = t; readLength = l; term = [e copy]; tag = i; if (d) { buffer = d; startOffset = s; bufferOwner = NO; originalBufferLength = [d length]; } else { if (readLength > 0) buffer = [[NSMutableData alloc] initWithLength:readLength]; else buffer = [[NSMutableData alloc] initWithLength:0]; startOffset = 0; bufferOwner = YES; originalBufferLength = 0; } } return self; } /** * Increases the length of the buffer (if needed) to ensure a read of the given size will fit. **/ - (void)ensureCapacityForAdditionalDataOfLength:(NSUInteger)bytesToRead { NSUInteger buffSize = [buffer length]; NSUInteger buffUsed = startOffset + bytesDone; NSUInteger buffSpace = buffSize - buffUsed; if (bytesToRead > buffSpace) { NSUInteger buffInc = bytesToRead - buffSpace; [buffer increaseLengthBy:buffInc]; } } /** * This method is used when we do NOT know how much data is available to be read from the socket. * This method returns the default value unless it exceeds the specified readLength or maxLength. * * Furthermore, the shouldPreBuffer decision is based upon the packet type, * and whether the returned value would fit in the current buffer without requiring a resize of the buffer. **/ - (NSUInteger)optimalReadLengthWithDefault:(NSUInteger)defaultValue shouldPreBuffer:(BOOL *)shouldPreBufferPtr { NSUInteger result; if (readLength > 0) { // Read a specific length of data result = MIN(defaultValue, (readLength - bytesDone)); // There is no need to prebuffer since we know exactly how much data we need to read. // Even if the buffer isn't currently big enough to fit this amount of data, // it would have to be resized eventually anyway. if (shouldPreBufferPtr) *shouldPreBufferPtr = NO; } else { // Either reading until we find a specified terminator, // or we're simply reading all available data. // // In other words, one of: // // - readDataToData packet // - readDataWithTimeout packet if (maxLength > 0) result = MIN(defaultValue, (maxLength - bytesDone)); else result = defaultValue; // Since we don't know the size of the read in advance, // the shouldPreBuffer decision is based upon whether the returned value would fit // in the current buffer without requiring a resize of the buffer. // // This is because, in all likelyhood, the amount read from the socket will be less than the default value. // Thus we should avoid over-allocating the read buffer when we can simply use the pre-buffer instead. if (shouldPreBufferPtr) { NSUInteger buffSize = [buffer length]; NSUInteger buffUsed = startOffset + bytesDone; NSUInteger buffSpace = buffSize - buffUsed; if (buffSpace >= result) *shouldPreBufferPtr = NO; else *shouldPreBufferPtr = YES; } } return result; } /** * For read packets without a set terminator, returns the amount of data * that can be read without exceeding the readLength or maxLength. * * The given parameter indicates the number of bytes estimated to be available on the socket, * which is taken into consideration during the calculation. * * The given hint MUST be greater than zero. **/ - (NSUInteger)readLengthForNonTermWithHint:(NSUInteger)bytesAvailable { NSAssert(term == nil, @"This method does not apply to term reads"); NSAssert(bytesAvailable > 0, @"Invalid parameter: bytesAvailable"); if (readLength > 0) { // Read a specific length of data return MIN(bytesAvailable, (readLength - bytesDone)); // No need to avoid resizing the buffer. // If the user provided their own buffer, // and told us to read a certain length of data that exceeds the size of the buffer, // then it is clear that our code will resize the buffer during the read operation. // // This method does not actually do any resizing. // The resizing will happen elsewhere if needed. } else { // Read all available data NSUInteger result = bytesAvailable; if (maxLength > 0) { result = MIN(result, (maxLength - bytesDone)); } // No need to avoid resizing the buffer. // If the user provided their own buffer, // and told us to read all available data without giving us a maxLength, // then it is clear that our code might resize the buffer during the read operation. // // This method does not actually do any resizing. // The resizing will happen elsewhere if needed. return result; } } /** * For read packets with a set terminator, returns the amount of data * that can be read without exceeding the maxLength. * * The given parameter indicates the number of bytes estimated to be available on the socket, * which is taken into consideration during the calculation. * * To optimize memory allocations, mem copies, and mem moves * the shouldPreBuffer boolean value will indicate if the data should be read into a prebuffer first, * or if the data can be read directly into the read packet's buffer. **/ - (NSUInteger)readLengthForTermWithHint:(NSUInteger)bytesAvailable shouldPreBuffer:(BOOL *)shouldPreBufferPtr { NSAssert(term != nil, @"This method does not apply to non-term reads"); NSAssert(bytesAvailable > 0, @"Invalid parameter: bytesAvailable"); NSUInteger result = bytesAvailable; if (maxLength > 0) { result = MIN(result, (maxLength - bytesDone)); } // Should the data be read into the read packet's buffer, or into a pre-buffer first? // // One would imagine the preferred option is the faster one. // So which one is faster? // // Reading directly into the packet's buffer requires: // 1. Possibly resizing packet buffer (malloc/realloc) // 2. Filling buffer (read) // 3. Searching for term (memcmp) // 4. Possibly copying overflow into prebuffer (malloc/realloc, memcpy) // // Reading into prebuffer first: // 1. Possibly resizing prebuffer (malloc/realloc) // 2. Filling buffer (read) // 3. Searching for term (memcmp) // 4. Copying underflow into packet buffer (malloc/realloc, memcpy) // 5. Removing underflow from prebuffer (memmove) // // Comparing the performance of the two we can see that reading // data into the prebuffer first is slower due to the extra memove. // // However: // The implementation of NSMutableData is open source via core foundation's CFMutableData. // Decreasing the length of a mutable data object doesn't cause a realloc. // In other words, the capacity of a mutable data object can grow, but doesn't shrink. // // This means the prebuffer will rarely need a realloc. // The packet buffer, on the other hand, may often need a realloc. // This is especially true if we are the buffer owner. // Furthermore, if we are constantly realloc'ing the packet buffer, // and then moving the overflow into the prebuffer, // then we're consistently over-allocating memory for each term read. // And now we get into a bit of a tradeoff between speed and memory utilization. // // The end result is that the two perform very similarly. // And we can answer the original question very simply by another means. // // If we can read all the data directly into the packet's buffer without resizing it first, // then we do so. Otherwise we use the prebuffer. if (shouldPreBufferPtr) { NSUInteger buffSize = [buffer length]; NSUInteger buffUsed = startOffset + bytesDone; if ((buffSize - buffUsed) >= result) *shouldPreBufferPtr = NO; else *shouldPreBufferPtr = YES; } return result; } /** * For read packets with a set terminator, * returns the amount of data that can be read from the given preBuffer, * without going over a terminator or the maxLength. * * It is assumed the terminator has not already been read. **/ - (NSUInteger)readLengthForTermWithPreBuffer:(GCDAsyncSocketPreBuffer *)preBuffer found:(BOOL *)foundPtr { NSAssert(term != nil, @"This method does not apply to non-term reads"); NSAssert([preBuffer availableBytes] > 0, @"Invoked with empty pre buffer!"); // We know that the terminator, as a whole, doesn't exist in our own buffer. // But it is possible that a _portion_ of it exists in our buffer. // So we're going to look for the terminator starting with a portion of our own buffer. // // Example: // // term length = 3 bytes // bytesDone = 5 bytes // preBuffer length = 5 bytes // // If we append the preBuffer to our buffer, // it would look like this: // // --------------------- // |B|B|B|B|B|P|P|P|P|P| // --------------------- // // So we start our search here: // // --------------------- // |B|B|B|B|B|P|P|P|P|P| // -------^-^-^--------- // // And move forwards... // // --------------------- // |B|B|B|B|B|P|P|P|P|P| // ---------^-^-^------- // // Until we find the terminator or reach the end. // // --------------------- // |B|B|B|B|B|P|P|P|P|P| // ---------------^-^-^- BOOL found = NO; NSUInteger termLength = [term length]; NSUInteger preBufferLength = [preBuffer availableBytes]; if ((bytesDone + preBufferLength) < termLength) { // Not enough data for a full term sequence yet return preBufferLength; } NSUInteger maxPreBufferLength; if (maxLength > 0) { maxPreBufferLength = MIN(preBufferLength, (maxLength - bytesDone)); // Note: maxLength >= termLength } else { maxPreBufferLength = preBufferLength; } uint8_t seq[termLength]; const void *termBuf = [term bytes]; NSUInteger bufLen = MIN(bytesDone, (termLength - 1)); uint8_t *buf = (uint8_t *)[buffer mutableBytes] + startOffset + bytesDone - bufLen; NSUInteger preLen = termLength - bufLen; const uint8_t *pre = [preBuffer readBuffer]; NSUInteger loopCount = bufLen + maxPreBufferLength - termLength + 1; // Plus one. See example above. NSUInteger result = maxPreBufferLength; NSUInteger i; for (i = 0; i < loopCount; i++) { if (bufLen > 0) { // Combining bytes from buffer and preBuffer memcpy(seq, buf, bufLen); memcpy(seq + bufLen, pre, preLen); if (memcmp(seq, termBuf, termLength) == 0) { result = preLen; found = YES; break; } buf++; bufLen--; preLen++; } else { // Comparing directly from preBuffer if (memcmp(pre, termBuf, termLength) == 0) { NSUInteger preOffset = pre - [preBuffer readBuffer]; // pointer arithmetic result = preOffset + termLength; found = YES; break; } pre++; } } // There is no need to avoid resizing the buffer in this particular situation. if (foundPtr) *foundPtr = found; return result; } /** * For read packets with a set terminator, scans the packet buffer for the term. * It is assumed the terminator had not been fully read prior to the new bytes. * * If the term is found, the number of excess bytes after the term are returned. * If the term is not found, this method will return -1. * * Note: A return value of zero means the term was found at the very end. * * Prerequisites: * The given number of bytes have been added to the end of our buffer. * Our bytesDone variable has NOT been changed due to the prebuffered bytes. **/ - (NSInteger)searchForTermAfterPreBuffering:(ssize_t)numBytes { NSAssert(term != nil, @"This method does not apply to non-term reads"); // The implementation of this method is very similar to the above method. // See the above method for a discussion of the algorithm used here. uint8_t *buff = [buffer mutableBytes]; NSUInteger buffLength = bytesDone + numBytes; const void *termBuff = [term bytes]; NSUInteger termLength = [term length]; // Note: We are dealing with unsigned integers, // so make sure the math doesn't go below zero. NSUInteger i = ((buffLength - numBytes) >= termLength) ? (buffLength - numBytes - termLength + 1) : 0; while (i + termLength <= buffLength) { uint8_t *subBuffer = buff + startOffset + i; if (memcmp(subBuffer, termBuff, termLength) == 0) { return buffLength - (i + termLength); } i++; } return -1; } @end //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark - //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// /** * The GCDAsyncWritePacket encompasses the instructions for any given write. **/ @interface GCDAsyncWritePacket : NSObject { @public NSData *buffer; NSUInteger bytesDone; long tag; NSTimeInterval timeout; } - (id)initWithData:(NSData *)d timeout:(NSTimeInterval)t tag:(long)i; @end @implementation GCDAsyncWritePacket - (id)initWithData:(NSData *)d timeout:(NSTimeInterval)t tag:(long)i { if((self = [super init])) { buffer = d; // Retain not copy. For performance as documented in header file. bytesDone = 0; timeout = t; tag = i; } return self; } @end //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark - //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// /** * The GCDAsyncSpecialPacket encompasses special instructions for interruptions in the read/write queues. * This class my be altered to support more than just TLS in the future. **/ @interface GCDAsyncSpecialPacket : NSObject { @public NSDictionary *tlsSettings; } - (id)initWithTLSSettings:(NSDictionary *)settings; @end @implementation GCDAsyncSpecialPacket - (id)initWithTLSSettings:(NSDictionary *)settings { if((self = [super init])) { tlsSettings = [settings copy]; } return self; } @end //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark - //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// @implementation GCDAsyncSocket - (id)init { return [self initWithDelegate:nil delegateQueue:NULL socketQueue:NULL]; } - (id)initWithSocketQueue:(dispatch_queue_t)sq { return [self initWithDelegate:nil delegateQueue:NULL socketQueue:sq]; } - (id)initWithDelegate:(id)aDelegate delegateQueue:(dispatch_queue_t)dq { return [self initWithDelegate:aDelegate delegateQueue:dq socketQueue:NULL]; } - (id)initWithDelegate:(id)aDelegate delegateQueue:(dispatch_queue_t)dq socketQueue:(dispatch_queue_t)sq { if((self = [super init])) { delegate = aDelegate; delegateQueue = dq; #if NEEDS_DISPATCH_RETAIN_RELEASE if (dq) dispatch_retain(dq); #endif socket4FD = SOCKET_NULL; socket6FD = SOCKET_NULL; connectIndex = 0; if (sq) { NSAssert(sq != dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_LOW, 0), @"The given socketQueue parameter must not be a concurrent queue."); NSAssert(sq != dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_HIGH, 0), @"The given socketQueue parameter must not be a concurrent queue."); NSAssert(sq != dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_DEFAULT, 0), @"The given socketQueue parameter must not be a concurrent queue."); socketQueue = sq; #if NEEDS_DISPATCH_RETAIN_RELEASE dispatch_retain(sq); #endif } else { socketQueue = dispatch_queue_create([GCDAsyncSocketQueueName UTF8String], NULL); } // The dispatch_queue_set_specific() and dispatch_get_specific() functions take a "void *key" parameter. // From the documentation: // // > Keys are only compared as pointers and are never dereferenced. // > Thus, you can use a pointer to a static variable for a specific subsystem or // > any other value that allows you to identify the value uniquely. // // We're just going to use the memory address of an ivar. // Specifically an ivar that is explicitly named for our purpose to make the code more readable. // // However, it feels tedious (and less readable) to include the "&" all the time: // dispatch_get_specific(&IsOnSocketQueueOrTargetQueueKey) // // So we're going to make it so it doesn't matter if we use the '&' or not, // by assigning the value of the ivar to the address of the ivar. // Thus: IsOnSocketQueueOrTargetQueueKey == &IsOnSocketQueueOrTargetQueueKey; IsOnSocketQueueOrTargetQueueKey = &IsOnSocketQueueOrTargetQueueKey; void *nonNullUnusedPointer = (__bridge void *)self; dispatch_queue_set_specific(socketQueue, IsOnSocketQueueOrTargetQueueKey, nonNullUnusedPointer, NULL); readQueue = [[NSMutableArray alloc] initWithCapacity:5]; currentRead = nil; writeQueue = [[NSMutableArray alloc] initWithCapacity:5]; currentWrite = nil; preBuffer = [[GCDAsyncSocketPreBuffer alloc] initWithCapacity:(1024 * 4)]; } return self; } - (void)dealloc { LogInfo(@"%@ - %@ (start)", THIS_METHOD, self); if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { [self closeWithError:nil]; } else { dispatch_sync(socketQueue, ^{ [self closeWithError:nil]; }); } delegate = nil; #if NEEDS_DISPATCH_RETAIN_RELEASE if (delegateQueue) dispatch_release(delegateQueue); #endif delegateQueue = NULL; #if NEEDS_DISPATCH_RETAIN_RELEASE if (socketQueue) dispatch_release(socketQueue); #endif socketQueue = NULL; LogInfo(@"%@ - %@ (finish)", THIS_METHOD, self); } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Configuration //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// - (id)delegate { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { return delegate; } else { __block id result; dispatch_sync(socketQueue, ^{ result = delegate; }); return result; } } - (void)setDelegate:(id)newDelegate synchronously:(BOOL)synchronously { dispatch_block_t block = ^{ delegate = newDelegate; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { block(); } else { if (synchronously) dispatch_sync(socketQueue, block); else dispatch_async(socketQueue, block); } } - (void)setDelegate:(id)newDelegate { [self setDelegate:newDelegate synchronously:NO]; } - (void)synchronouslySetDelegate:(id)newDelegate { [self setDelegate:newDelegate synchronously:YES]; } - (dispatch_queue_t)delegateQueue { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { return delegateQueue; } else { __block dispatch_queue_t result; dispatch_sync(socketQueue, ^{ result = delegateQueue; }); return result; } } - (void)setDelegateQueue:(dispatch_queue_t)newDelegateQueue synchronously:(BOOL)synchronously { dispatch_block_t block = ^{ #if NEEDS_DISPATCH_RETAIN_RELEASE if (delegateQueue) dispatch_release(delegateQueue); if (newDelegateQueue) dispatch_retain(newDelegateQueue); #endif delegateQueue = newDelegateQueue; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { block(); } else { if (synchronously) dispatch_sync(socketQueue, block); else dispatch_async(socketQueue, block); } } - (void)setDelegateQueue:(dispatch_queue_t)newDelegateQueue { [self setDelegateQueue:newDelegateQueue synchronously:NO]; } - (void)synchronouslySetDelegateQueue:(dispatch_queue_t)newDelegateQueue { [self setDelegateQueue:newDelegateQueue synchronously:YES]; } - (void)getDelegate:(id *)delegatePtr delegateQueue:(dispatch_queue_t *)delegateQueuePtr { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { if (delegatePtr) *delegatePtr = delegate; if (delegateQueuePtr) *delegateQueuePtr = delegateQueue; } else { __block id dPtr = NULL; __block dispatch_queue_t dqPtr = NULL; dispatch_sync(socketQueue, ^{ dPtr = delegate; dqPtr = delegateQueue; }); if (delegatePtr) *delegatePtr = dPtr; if (delegateQueuePtr) *delegateQueuePtr = dqPtr; } } - (void)setDelegate:(id)newDelegate delegateQueue:(dispatch_queue_t)newDelegateQueue synchronously:(BOOL)synchronously { dispatch_block_t block = ^{ delegate = newDelegate; #if NEEDS_DISPATCH_RETAIN_RELEASE if (delegateQueue) dispatch_release(delegateQueue); if (newDelegateQueue) dispatch_retain(newDelegateQueue); #endif delegateQueue = newDelegateQueue; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { block(); } else { if (synchronously) dispatch_sync(socketQueue, block); else dispatch_async(socketQueue, block); } } - (void)setDelegate:(id)newDelegate delegateQueue:(dispatch_queue_t)newDelegateQueue { [self setDelegate:newDelegate delegateQueue:newDelegateQueue synchronously:NO]; } - (void)synchronouslySetDelegate:(id)newDelegate delegateQueue:(dispatch_queue_t)newDelegateQueue { [self setDelegate:newDelegate delegateQueue:newDelegateQueue synchronously:YES]; } - (BOOL)isIPv4Enabled { // Note: YES means kIPv4Disabled is OFF if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { return ((config & kIPv4Disabled) == 0); } else { __block BOOL result; dispatch_sync(socketQueue, ^{ result = ((config & kIPv4Disabled) == 0); }); return result; } } - (void)setIPv4Enabled:(BOOL)flag { // Note: YES means kIPv4Disabled is OFF dispatch_block_t block = ^{ if (flag) config &= ~kIPv4Disabled; else config |= kIPv4Disabled; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_async(socketQueue, block); } - (BOOL)isIPv6Enabled { // Note: YES means kIPv6Disabled is OFF if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { return ((config & kIPv6Disabled) == 0); } else { __block BOOL result; dispatch_sync(socketQueue, ^{ result = ((config & kIPv6Disabled) == 0); }); return result; } } - (void)setIPv6Enabled:(BOOL)flag { // Note: YES means kIPv6Disabled is OFF dispatch_block_t block = ^{ if (flag) config &= ~kIPv6Disabled; else config |= kIPv6Disabled; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_async(socketQueue, block); } - (BOOL)isIPv4PreferredOverIPv6 { // Note: YES means kPreferIPv6 is OFF if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { return ((config & kPreferIPv6) == 0); } else { __block BOOL result; dispatch_sync(socketQueue, ^{ result = ((config & kPreferIPv6) == 0); }); return result; } } - (void)setPreferIPv4OverIPv6:(BOOL)flag { // Note: YES means kPreferIPv6 is OFF dispatch_block_t block = ^{ if (flag) config &= ~kPreferIPv6; else config |= kPreferIPv6; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_async(socketQueue, block); } - (id)userData { __block id result = nil; dispatch_block_t block = ^{ result = userData; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); return result; } - (void)setUserData:(id)arbitraryUserData { dispatch_block_t block = ^{ if (userData != arbitraryUserData) { userData = arbitraryUserData; } }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_async(socketQueue, block); } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Accepting //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// - (BOOL)acceptOnPort:(uint16_t)port error:(NSError **)errPtr { return [self acceptOnInterface:nil port:port error:errPtr]; } - (BOOL)acceptOnInterface:(NSString *)inInterface port:(uint16_t)port error:(NSError **)errPtr { LogTrace(); // Just in-case interface parameter is immutable. NSString *interface = [inInterface copy]; __block BOOL result = NO; __block NSError *err = nil; // CreateSocket Block // This block will be invoked within the dispatch block below. int(^createSocket)(int, NSData*) = ^int (int domain, NSData *interfaceAddr) { int socketFD = socket(domain, SOCK_STREAM, 0); if (socketFD == SOCKET_NULL) { NSString *reason = @"Error in socket() function"; err = [self errnoErrorWithReason:reason]; return SOCKET_NULL; } int status; // Set socket options status = fcntl(socketFD, F_SETFL, O_NONBLOCK); if (status == -1) { NSString *reason = @"Error enabling non-blocking IO on socket (fcntl)"; err = [self errnoErrorWithReason:reason]; LogVerbose(@"close(socketFD)"); close(socketFD); return SOCKET_NULL; } int reuseOn = 1; status = setsockopt(socketFD, SOL_SOCKET, SO_REUSEADDR, &reuseOn, sizeof(reuseOn)); if (status == -1) { NSString *reason = @"Error enabling address reuse (setsockopt)"; err = [self errnoErrorWithReason:reason]; LogVerbose(@"close(socketFD)"); close(socketFD); return SOCKET_NULL; } // Bind socket status = bind(socketFD, (const struct sockaddr *)[interfaceAddr bytes], (socklen_t)[interfaceAddr length]); if (status == -1) { NSString *reason = @"Error in bind() function"; err = [self errnoErrorWithReason:reason]; LogVerbose(@"close(socketFD)"); close(socketFD); return SOCKET_NULL; } // Listen status = listen(socketFD, 1024); if (status == -1) { NSString *reason = @"Error in listen() function"; err = [self errnoErrorWithReason:reason]; LogVerbose(@"close(socketFD)"); close(socketFD); return SOCKET_NULL; } return socketFD; }; // Create dispatch block and run on socketQueue dispatch_block_t block = ^{ @autoreleasepool { if (delegate == nil) // Must have delegate set { NSString *msg = @"Attempting to accept without a delegate. Set a delegate first."; err = [self badConfigError:msg]; return_from_block; } if (delegateQueue == NULL) // Must have delegate queue set { NSString *msg = @"Attempting to accept without a delegate queue. Set a delegate queue first."; err = [self badConfigError:msg]; return_from_block; } BOOL isIPv4Disabled = (config & kIPv4Disabled) ? YES : NO; BOOL isIPv6Disabled = (config & kIPv6Disabled) ? YES : NO; if (isIPv4Disabled && isIPv6Disabled) // Must have IPv4 or IPv6 enabled { NSString *msg = @"Both IPv4 and IPv6 have been disabled. Must enable at least one protocol first."; err = [self badConfigError:msg]; return_from_block; } if (![self isDisconnected]) // Must be disconnected { NSString *msg = @"Attempting to accept while connected or accepting connections. Disconnect first."; err = [self badConfigError:msg]; return_from_block; } // Clear queues (spurious read/write requests post disconnect) [readQueue removeAllObjects]; [writeQueue removeAllObjects]; // Resolve interface from description NSMutableData *interface4 = nil; NSMutableData *interface6 = nil; [self getInterfaceAddress4:&interface4 address6:&interface6 fromDescription:interface port:port]; if ((interface4 == nil) && (interface6 == nil)) { NSString *msg = @"Unknown interface. Specify valid interface by name (e.g. \"en1\") or IP address."; err = [self badParamError:msg]; return_from_block; } if (isIPv4Disabled && (interface6 == nil)) { NSString *msg = @"IPv4 has been disabled and specified interface doesn't support IPv6."; err = [self badParamError:msg]; return_from_block; } if (isIPv6Disabled && (interface4 == nil)) { NSString *msg = @"IPv6 has been disabled and specified interface doesn't support IPv4."; err = [self badParamError:msg]; return_from_block; } BOOL enableIPv4 = !isIPv4Disabled && (interface4 != nil); BOOL enableIPv6 = !isIPv6Disabled && (interface6 != nil); // Create sockets, configure, bind, and listen if (enableIPv4) { LogVerbose(@"Creating IPv4 socket"); socket4FD = createSocket(AF_INET, interface4); if (socket4FD == SOCKET_NULL) { return_from_block; } } if (enableIPv6) { LogVerbose(@"Creating IPv6 socket"); if (enableIPv4 && (port == 0)) { // No specific port was specified, so we allowed the OS to pick an available port for us. // Now we need to make sure the IPv6 socket listens on the same port as the IPv4 socket. struct sockaddr_in6 *addr6 = (struct sockaddr_in6 *)[interface6 mutableBytes]; addr6->sin6_port = htons([self localPort4]); } socket6FD = createSocket(AF_INET6, interface6); if (socket6FD == SOCKET_NULL) { if (socket4FD != SOCKET_NULL) { LogVerbose(@"close(socket4FD)"); close(socket4FD); } return_from_block; } } // Create accept sources if (enableIPv4) { accept4Source = dispatch_source_create(DISPATCH_SOURCE_TYPE_READ, socket4FD, 0, socketQueue); int socketFD = socket4FD; dispatch_source_t acceptSource = accept4Source; dispatch_source_set_event_handler(accept4Source, ^{ @autoreleasepool { LogVerbose(@"event4Block"); unsigned long i = 0; unsigned long numPendingConnections = dispatch_source_get_data(acceptSource); LogVerbose(@"numPendingConnections: %lu", numPendingConnections); while ([self doAccept:socketFD] && (++i < numPendingConnections)); }}); dispatch_source_set_cancel_handler(accept4Source, ^{ #if NEEDS_DISPATCH_RETAIN_RELEASE LogVerbose(@"dispatch_release(accept4Source)"); dispatch_release(acceptSource); #endif LogVerbose(@"close(socket4FD)"); close(socketFD); }); LogVerbose(@"dispatch_resume(accept4Source)"); dispatch_resume(accept4Source); } if (enableIPv6) { accept6Source = dispatch_source_create(DISPATCH_SOURCE_TYPE_READ, socket6FD, 0, socketQueue); int socketFD = socket6FD; dispatch_source_t acceptSource = accept6Source; dispatch_source_set_event_handler(accept6Source, ^{ @autoreleasepool { LogVerbose(@"event6Block"); unsigned long i = 0; unsigned long numPendingConnections = dispatch_source_get_data(acceptSource); LogVerbose(@"numPendingConnections: %lu", numPendingConnections); while ([self doAccept:socketFD] && (++i < numPendingConnections)); }}); dispatch_source_set_cancel_handler(accept6Source, ^{ #if NEEDS_DISPATCH_RETAIN_RELEASE LogVerbose(@"dispatch_release(accept6Source)"); dispatch_release(acceptSource); #endif LogVerbose(@"close(socket6FD)"); close(socketFD); }); LogVerbose(@"dispatch_resume(accept6Source)"); dispatch_resume(accept6Source); } flags |= kSocketStarted; result = YES; }}; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); if (result == NO) { LogInfo(@"Error in accept: %@", err); if (errPtr) *errPtr = err; } return result; } - (BOOL)doAccept:(int)parentSocketFD { LogTrace(); BOOL isIPv4; int childSocketFD; NSData *childSocketAddress; if (parentSocketFD == socket4FD) { isIPv4 = YES; struct sockaddr_in addr; socklen_t addrLen = sizeof(addr); childSocketFD = accept(parentSocketFD, (struct sockaddr *)&addr, &addrLen); if (childSocketFD == -1) { LogWarn(@"Accept failed with error: %@", [self errnoError]); return NO; } childSocketAddress = [NSData dataWithBytes:&addr length:addrLen]; } else // if (parentSocketFD == socket6FD) { isIPv4 = NO; struct sockaddr_in6 addr; socklen_t addrLen = sizeof(addr); childSocketFD = accept(parentSocketFD, (struct sockaddr *)&addr, &addrLen); if (childSocketFD == -1) { LogWarn(@"Accept failed with error: %@", [self errnoError]); return NO; } childSocketAddress = [NSData dataWithBytes:&addr length:addrLen]; } // Enable non-blocking IO on the socket int result = fcntl(childSocketFD, F_SETFL, O_NONBLOCK); if (result == -1) { LogWarn(@"Error enabling non-blocking IO on accepted socket (fcntl)"); return NO; } // Prevent SIGPIPE signals int nosigpipe = 1; setsockopt(childSocketFD, SOL_SOCKET, SO_NOSIGPIPE, &nosigpipe, sizeof(nosigpipe)); // Notify delegate if (delegateQueue) { __strong id theDelegate = delegate; dispatch_async(delegateQueue, ^{ @autoreleasepool { // Query delegate for custom socket queue dispatch_queue_t childSocketQueue = NULL; if ([theDelegate respondsToSelector:@selector(newSocketQueueForConnectionFromAddress:onSocket:)]) { childSocketQueue = [theDelegate newSocketQueueForConnectionFromAddress:childSocketAddress onSocket:self]; } // Create GCDAsyncSocket instance for accepted socket GCDAsyncSocket *acceptedSocket = [[GCDAsyncSocket alloc] initWithDelegate:theDelegate delegateQueue:delegateQueue socketQueue:childSocketQueue]; if (isIPv4) acceptedSocket->socket4FD = childSocketFD; else acceptedSocket->socket6FD = childSocketFD; acceptedSocket->flags = (kSocketStarted | kConnected); // Setup read and write sources for accepted socket dispatch_async(acceptedSocket->socketQueue, ^{ @autoreleasepool { [acceptedSocket setupReadAndWriteSourcesForNewlyConnectedSocket:childSocketFD]; }}); // Notify delegate if ([theDelegate respondsToSelector:@selector(socket:didAcceptNewSocket:)]) { [theDelegate socket:self didAcceptNewSocket:acceptedSocket]; } // Release the socket queue returned from the delegate (it was retained by acceptedSocket) #if NEEDS_DISPATCH_RETAIN_RELEASE if (childSocketQueue) dispatch_release(childSocketQueue); #endif // The accepted socket should have been retained by the delegate. // Otherwise it gets properly released when exiting the block. }}); } return YES; } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Connecting //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// /** * This method runs through the various checks required prior to a connection attempt. * It is shared between the connectToHost and connectToAddress methods. * **/ - (BOOL)preConnectWithInterface:(NSString *)interface error:(NSError **)errPtr { NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); if (delegate == nil) // Must have delegate set { if (errPtr) { NSString *msg = @"Attempting to connect without a delegate. Set a delegate first."; *errPtr = [self badConfigError:msg]; } return NO; } if (delegateQueue == NULL) // Must have delegate queue set { if (errPtr) { NSString *msg = @"Attempting to connect without a delegate queue. Set a delegate queue first."; *errPtr = [self badConfigError:msg]; } return NO; } if (![self isDisconnected]) // Must be disconnected { if (errPtr) { NSString *msg = @"Attempting to connect while connected or accepting connections. Disconnect first."; *errPtr = [self badConfigError:msg]; } return NO; } BOOL isIPv4Disabled = (config & kIPv4Disabled) ? YES : NO; BOOL isIPv6Disabled = (config & kIPv6Disabled) ? YES : NO; if (isIPv4Disabled && isIPv6Disabled) // Must have IPv4 or IPv6 enabled { if (errPtr) { NSString *msg = @"Both IPv4 and IPv6 have been disabled. Must enable at least one protocol first."; *errPtr = [self badConfigError:msg]; } return NO; } if (interface) { NSMutableData *interface4 = nil; NSMutableData *interface6 = nil; [self getInterfaceAddress4:&interface4 address6:&interface6 fromDescription:interface port:0]; if ((interface4 == nil) && (interface6 == nil)) { if (errPtr) { NSString *msg = @"Unknown interface. Specify valid interface by name (e.g. \"en1\") or IP address."; *errPtr = [self badParamError:msg]; } return NO; } if (isIPv4Disabled && (interface6 == nil)) { if (errPtr) { NSString *msg = @"IPv4 has been disabled and specified interface doesn't support IPv6."; *errPtr = [self badParamError:msg]; } return NO; } if (isIPv6Disabled && (interface4 == nil)) { if (errPtr) { NSString *msg = @"IPv6 has been disabled and specified interface doesn't support IPv4."; *errPtr = [self badParamError:msg]; } return NO; } connectInterface4 = interface4; connectInterface6 = interface6; } // Clear queues (spurious read/write requests post disconnect) [readQueue removeAllObjects]; [writeQueue removeAllObjects]; return YES; } - (BOOL)connectToHost:(NSString*)host onPort:(uint16_t)port error:(NSError **)errPtr { return [self connectToHost:host onPort:port withTimeout:-1 error:errPtr]; } - (BOOL)connectToHost:(NSString *)host onPort:(uint16_t)port withTimeout:(NSTimeInterval)timeout error:(NSError **)errPtr { return [self connectToHost:host onPort:port viaInterface:nil withTimeout:timeout error:errPtr]; } - (BOOL)connectToHost:(NSString *)inHost onPort:(uint16_t)port viaInterface:(NSString *)inInterface withTimeout:(NSTimeInterval)timeout error:(NSError **)errPtr { LogTrace(); // Just in case immutable objects were passed NSString *host = [inHost copy]; NSString *interface = [inInterface copy]; __block BOOL result = NO; __block NSError *err = nil; dispatch_block_t block = ^{ @autoreleasepool { // Check for problems with host parameter if ([host length] == 0) { NSString *msg = @"Invalid host parameter (nil or \"\"). Should be a domain name or IP address string."; err = [self badParamError:msg]; return_from_block; } // Run through standard pre-connect checks if (![self preConnectWithInterface:interface error:&err]) { return_from_block; } // We've made it past all the checks. // It's time to start the connection process. flags |= kSocketStarted; LogVerbose(@"Dispatching DNS lookup..."); // It's possible that the given host parameter is actually a NSMutableString. // So we want to copy it now, within this block that will be executed synchronously. // This way the asynchronous lookup block below doesn't have to worry about it changing. int aConnectIndex = connectIndex; NSString *hostCpy = [host copy]; dispatch_queue_t globalConcurrentQueue = dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_DEFAULT, 0); dispatch_async(globalConcurrentQueue, ^{ @autoreleasepool { [self lookup:aConnectIndex host:hostCpy port:port]; }}); [self startConnectTimeout:timeout]; result = YES; }}; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); if (result == NO) { if (errPtr) *errPtr = err; } return result; } - (BOOL)connectToAddress:(NSData *)remoteAddr error:(NSError **)errPtr { return [self connectToAddress:remoteAddr viaInterface:nil withTimeout:-1 error:errPtr]; } - (BOOL)connectToAddress:(NSData *)remoteAddr withTimeout:(NSTimeInterval)timeout error:(NSError **)errPtr { return [self connectToAddress:remoteAddr viaInterface:nil withTimeout:timeout error:errPtr]; } - (BOOL)connectToAddress:(NSData *)inRemoteAddr viaInterface:(NSString *)inInterface withTimeout:(NSTimeInterval)timeout error:(NSError **)errPtr { LogTrace(); // Just in case immutable objects were passed NSData *remoteAddr = [inRemoteAddr copy]; NSString *interface = [inInterface copy]; __block BOOL result = NO; __block NSError *err = nil; dispatch_block_t block = ^{ @autoreleasepool { // Check for problems with remoteAddr parameter NSData *address4 = nil; NSData *address6 = nil; if ([remoteAddr length] >= sizeof(struct sockaddr)) { const struct sockaddr *sockaddr = (const struct sockaddr *)[remoteAddr bytes]; if (sockaddr->sa_family == AF_INET) { if ([remoteAddr length] == sizeof(struct sockaddr_in)) { address4 = remoteAddr; } } else if (sockaddr->sa_family == AF_INET6) { if ([remoteAddr length] == sizeof(struct sockaddr_in6)) { address6 = remoteAddr; } } } if ((address4 == nil) && (address6 == nil)) { NSString *msg = @"A valid IPv4 or IPv6 address was not given"; err = [self badParamError:msg]; return_from_block; } BOOL isIPv4Disabled = (config & kIPv4Disabled) ? YES : NO; BOOL isIPv6Disabled = (config & kIPv6Disabled) ? YES : NO; if (isIPv4Disabled && (address4 != nil)) { NSString *msg = @"IPv4 has been disabled and an IPv4 address was passed."; err = [self badParamError:msg]; return_from_block; } if (isIPv6Disabled && (address6 != nil)) { NSString *msg = @"IPv6 has been disabled and an IPv6 address was passed."; err = [self badParamError:msg]; return_from_block; } // Run through standard pre-connect checks if (![self preConnectWithInterface:interface error:&err]) { return_from_block; } // We've made it past all the checks. // It's time to start the connection process. if (![self connectWithAddress4:address4 address6:address6 error:&err]) { return_from_block; } flags |= kSocketStarted; [self startConnectTimeout:timeout]; result = YES; }}; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); if (result == NO) { if (errPtr) *errPtr = err; } return result; } - (void)lookup:(int)aConnectIndex host:(NSString *)host port:(uint16_t)port { LogTrace(); // This method is executed on a global concurrent queue. // It posts the results back to the socket queue. // The lookupIndex is used to ignore the results if the connect operation was cancelled or timed out. NSError *error = nil; NSData *address4 = nil; NSData *address6 = nil; if ([host isEqualToString:@"localhost"] || [host isEqualToString:@"loopback"]) { // Use LOOPBACK address struct sockaddr_in nativeAddr; nativeAddr.sin_len = sizeof(struct sockaddr_in); nativeAddr.sin_family = AF_INET; nativeAddr.sin_port = htons(port); nativeAddr.sin_addr.s_addr = htonl(INADDR_LOOPBACK); memset(&(nativeAddr.sin_zero), 0, sizeof(nativeAddr.sin_zero)); struct sockaddr_in6 nativeAddr6; nativeAddr6.sin6_len = sizeof(struct sockaddr_in6); nativeAddr6.sin6_family = AF_INET6; nativeAddr6.sin6_port = htons(port); nativeAddr6.sin6_flowinfo = 0; nativeAddr6.sin6_addr = in6addr_loopback; nativeAddr6.sin6_scope_id = 0; // Wrap the native address structures address4 = [NSData dataWithBytes:&nativeAddr length:sizeof(nativeAddr)]; address6 = [NSData dataWithBytes:&nativeAddr6 length:sizeof(nativeAddr6)]; } else { NSString *portStr = [NSString stringWithFormat:@"%hu", port]; struct addrinfo hints, *res, *res0; memset(&hints, 0, sizeof(hints)); hints.ai_family = PF_UNSPEC; hints.ai_socktype = SOCK_STREAM; hints.ai_protocol = IPPROTO_TCP; int gai_error = getaddrinfo([host UTF8String], [portStr UTF8String], &hints, &res0); if (gai_error) { error = [self gaiError:gai_error]; } else { for(res = res0; res; res = res->ai_next) { if ((address4 == nil) && (res->ai_family == AF_INET)) { // Found IPv4 address // Wrap the native address structure address4 = [NSData dataWithBytes:res->ai_addr length:res->ai_addrlen]; } else if ((address6 == nil) && (res->ai_family == AF_INET6)) { // Found IPv6 address // Wrap the native address structure address6 = [NSData dataWithBytes:res->ai_addr length:res->ai_addrlen]; } } freeaddrinfo(res0); if ((address4 == nil) && (address6 == nil)) { error = [self gaiError:EAI_FAIL]; } } } if (error) { dispatch_async(socketQueue, ^{ @autoreleasepool { [self lookup:aConnectIndex didFail:error]; }}); } else { dispatch_async(socketQueue, ^{ @autoreleasepool { [self lookup:aConnectIndex didSucceedWithAddress4:address4 address6:address6]; }}); } } - (void)lookup:(int)aConnectIndex didSucceedWithAddress4:(NSData *)address4 address6:(NSData *)address6 { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); NSAssert(address4 || address6, @"Expected at least one valid address"); if (aConnectIndex != connectIndex) { LogInfo(@"Ignoring lookupDidSucceed, already disconnected"); // The connect operation has been cancelled. // That is, socket was disconnected, or connection has already timed out. return; } // Check for problems BOOL isIPv4Disabled = (config & kIPv4Disabled) ? YES : NO; BOOL isIPv6Disabled = (config & kIPv6Disabled) ? YES : NO; if (isIPv4Disabled && (address6 == nil)) { NSString *msg = @"IPv4 has been disabled and DNS lookup found no IPv6 address."; [self closeWithError:[self otherError:msg]]; return; } if (isIPv6Disabled && (address4 == nil)) { NSString *msg = @"IPv6 has been disabled and DNS lookup found no IPv4 address."; [self closeWithError:[self otherError:msg]]; return; } // Start the normal connection process NSError *err = nil; if (![self connectWithAddress4:address4 address6:address6 error:&err]) { [self closeWithError:err]; } } /** * This method is called if the DNS lookup fails. * This method is executed on the socketQueue. * * Since the DNS lookup executed synchronously on a global concurrent queue, * the original connection request may have already been cancelled or timed-out by the time this method is invoked. * The lookupIndex tells us whether the lookup is still valid or not. **/ - (void)lookup:(int)aConnectIndex didFail:(NSError *)error { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); if (aConnectIndex != connectIndex) { LogInfo(@"Ignoring lookup:didFail: - already disconnected"); // The connect operation has been cancelled. // That is, socket was disconnected, or connection has already timed out. return; } [self endConnectTimeout]; [self closeWithError:error]; } - (BOOL)connectWithAddress4:(NSData *)address4 address6:(NSData *)address6 error:(NSError **)errPtr { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); LogVerbose(@"IPv4: %@:%hu", [[self class] hostFromAddress:address4], [[self class] portFromAddress:address4]); LogVerbose(@"IPv6: %@:%hu", [[self class] hostFromAddress:address6], [[self class] portFromAddress:address6]); // Determine socket type BOOL preferIPv6 = (config & kPreferIPv6) ? YES : NO; BOOL useIPv6 = ((preferIPv6 && address6) || (address4 == nil)); // Create the socket int socketFD; NSData *address; NSData *connectInterface; if (useIPv6) { LogVerbose(@"Creating IPv6 socket"); socket6FD = socket(AF_INET6, SOCK_STREAM, 0); socketFD = socket6FD; address = address6; connectInterface = connectInterface6; } else { LogVerbose(@"Creating IPv4 socket"); socket4FD = socket(AF_INET, SOCK_STREAM, 0); socketFD = socket4FD; address = address4; connectInterface = connectInterface4; } if (socketFD == SOCKET_NULL) { if (errPtr) *errPtr = [self errnoErrorWithReason:@"Error in socket() function"]; return NO; } // Bind the socket to the desired interface (if needed) if (connectInterface) { LogVerbose(@"Binding socket..."); if ([[self class] portFromAddress:connectInterface] > 0) { // Since we're going to be binding to a specific port, // we should turn on reuseaddr to allow us to override sockets in time_wait. int reuseOn = 1; setsockopt(socketFD, SOL_SOCKET, SO_REUSEADDR, &reuseOn, sizeof(reuseOn)); } const struct sockaddr *interfaceAddr = (const struct sockaddr *)[connectInterface bytes]; int result = bind(socketFD, interfaceAddr, (socklen_t)[connectInterface length]); if (result != 0) { if (errPtr) *errPtr = [self errnoErrorWithReason:@"Error in bind() function"]; return NO; } } // Prevent SIGPIPE signals int nosigpipe = 1; setsockopt(socketFD, SOL_SOCKET, SO_NOSIGPIPE, &nosigpipe, sizeof(nosigpipe)); // Start the connection process in a background queue int aConnectIndex = connectIndex; dispatch_queue_t globalConcurrentQueue = dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_DEFAULT, 0); dispatch_async(globalConcurrentQueue, ^{ int result = connect(socketFD, (const struct sockaddr *)[address bytes], (socklen_t)[address length]); if (result == 0) { dispatch_async(socketQueue, ^{ @autoreleasepool { [self didConnect:aConnectIndex]; }}); } else { NSError *error = [self errnoErrorWithReason:@"Error in connect() function"]; dispatch_async(socketQueue, ^{ @autoreleasepool { [self didNotConnect:aConnectIndex error:error]; }}); } }); LogVerbose(@"Connecting..."); return YES; } - (void)didConnect:(int)aConnectIndex { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); if (aConnectIndex != connectIndex) { LogInfo(@"Ignoring didConnect, already disconnected"); // The connect operation has been cancelled. // That is, socket was disconnected, or connection has already timed out. return; } flags |= kConnected; [self endConnectTimeout]; #if TARGET_OS_IPHONE // The endConnectTimeout method executed above incremented the connectIndex. aConnectIndex = connectIndex; #endif // Setup read/write streams (as workaround for specific shortcomings in the iOS platform) // // Note: // There may be configuration options that must be set by the delegate before opening the streams. // The primary example is the kCFStreamNetworkServiceTypeVoIP flag, which only works on an unopened stream. // // Thus we wait until after the socket:didConnectToHost:port: delegate method has completed. // This gives the delegate time to properly configure the streams if needed. dispatch_block_t SetupStreamsPart1 = ^{ #if TARGET_OS_IPHONE if (![self createReadAndWriteStream]) { [self closeWithError:[self otherError:@"Error creating CFStreams"]]; return; } if (![self registerForStreamCallbacksIncludingReadWrite:NO]) { [self closeWithError:[self otherError:@"Error in CFStreamSetClient"]]; return; } #endif }; dispatch_block_t SetupStreamsPart2 = ^{ #if TARGET_OS_IPHONE if (aConnectIndex != connectIndex) { // The socket has been disconnected. return; } if (![self addStreamsToRunLoop]) { [self closeWithError:[self otherError:@"Error in CFStreamScheduleWithRunLoop"]]; return; } if (![self openStreams]) { [self closeWithError:[self otherError:@"Error creating CFStreams"]]; return; } #endif }; // Notify delegate NSString *host = [self connectedHost]; uint16_t port = [self connectedPort]; if (delegateQueue && [delegate respondsToSelector:@selector(socket:didConnectToHost:port:)]) { SetupStreamsPart1(); __strong id theDelegate = delegate; dispatch_async(delegateQueue, ^{ @autoreleasepool { [theDelegate socket:self didConnectToHost:host port:port]; dispatch_async(socketQueue, ^{ @autoreleasepool { SetupStreamsPart2(); }}); }}); } else { SetupStreamsPart1(); SetupStreamsPart2(); } // Get the connected socket int socketFD = (socket4FD != SOCKET_NULL) ? socket4FD : socket6FD; // Enable non-blocking IO on the socket int result = fcntl(socketFD, F_SETFL, O_NONBLOCK); if (result == -1) { NSString *errMsg = @"Error enabling non-blocking IO on socket (fcntl)"; [self closeWithError:[self otherError:errMsg]]; return; } // Setup our read/write sources [self setupReadAndWriteSourcesForNewlyConnectedSocket:socketFD]; // Dequeue any pending read/write requests [self maybeDequeueRead]; [self maybeDequeueWrite]; } - (void)didNotConnect:(int)aConnectIndex error:(NSError *)error { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); if (aConnectIndex != connectIndex) { LogInfo(@"Ignoring didNotConnect, already disconnected"); // The connect operation has been cancelled. // That is, socket was disconnected, or connection has already timed out. return; } [self closeWithError:error]; } - (void)startConnectTimeout:(NSTimeInterval)timeout { if (timeout >= 0.0) { connectTimer = dispatch_source_create(DISPATCH_SOURCE_TYPE_TIMER, 0, 0, socketQueue); dispatch_source_set_event_handler(connectTimer, ^{ @autoreleasepool { [self doConnectTimeout]; }}); #if NEEDS_DISPATCH_RETAIN_RELEASE dispatch_source_t theConnectTimer = connectTimer; dispatch_source_set_cancel_handler(connectTimer, ^{ LogVerbose(@"dispatch_release(connectTimer)"); dispatch_release(theConnectTimer); }); #endif dispatch_time_t tt = dispatch_time(DISPATCH_TIME_NOW, (timeout * NSEC_PER_SEC)); dispatch_source_set_timer(connectTimer, tt, DISPATCH_TIME_FOREVER, 0); dispatch_resume(connectTimer); } } - (void)endConnectTimeout { LogTrace(); if (connectTimer) { dispatch_source_cancel(connectTimer); connectTimer = NULL; } // Increment connectIndex. // This will prevent us from processing results from any related background asynchronous operations. // // Note: This should be called from close method even if connectTimer is NULL. // This is because one might disconnect a socket prior to a successful connection which had no timeout. connectIndex++; if (connectInterface4) { connectInterface4 = nil; } if (connectInterface6) { connectInterface6 = nil; } } - (void)doConnectTimeout { LogTrace(); [self endConnectTimeout]; [self closeWithError:[self connectTimeoutError]]; } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Disconnecting //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// - (void)closeWithError:(NSError *)error { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); [self endConnectTimeout]; if (currentRead != nil) [self endCurrentRead]; if (currentWrite != nil) [self endCurrentWrite]; [readQueue removeAllObjects]; [writeQueue removeAllObjects]; [preBuffer reset]; #if TARGET_OS_IPHONE { if (readStream || writeStream) { [self removeStreamsFromRunLoop]; if (readStream) { CFReadStreamSetClient(readStream, kCFStreamEventNone, NULL, NULL); CFReadStreamClose(readStream); CFRelease(readStream); readStream = NULL; } if (writeStream) { CFWriteStreamSetClient(writeStream, kCFStreamEventNone, NULL, NULL); CFWriteStreamClose(writeStream); CFRelease(writeStream); writeStream = NULL; } } } #endif #if SECURE_TRANSPORT_MAYBE_AVAILABLE { [sslPreBuffer reset]; sslErrCode = noErr; if (sslContext) { // Getting a linker error here about the SSLx() functions? // You need to add the Security Framework to your application. SSLClose(sslContext); #if TARGET_OS_IPHONE CFRelease(sslContext); #else SSLDisposeContext(sslContext); #endif sslContext = NULL; } } #endif // For some crazy reason (in my opinion), cancelling a dispatch source doesn't // invoke the cancel handler if the dispatch source is paused. // So we have to unpause the source if needed. // This allows the cancel handler to be run, which in turn releases the source and closes the socket. if (!accept4Source && !accept6Source && !readSource && !writeSource) { LogVerbose(@"manually closing close"); if (socket4FD != SOCKET_NULL) { LogVerbose(@"close(socket4FD)"); close(socket4FD); socket4FD = SOCKET_NULL; } if (socket6FD != SOCKET_NULL) { LogVerbose(@"close(socket6FD)"); close(socket6FD); socket6FD = SOCKET_NULL; } } else { if (accept4Source) { LogVerbose(@"dispatch_source_cancel(accept4Source)"); dispatch_source_cancel(accept4Source); // We never suspend accept4Source accept4Source = NULL; } if (accept6Source) { LogVerbose(@"dispatch_source_cancel(accept6Source)"); dispatch_source_cancel(accept6Source); // We never suspend accept6Source accept6Source = NULL; } if (readSource) { LogVerbose(@"dispatch_source_cancel(readSource)"); dispatch_source_cancel(readSource); [self resumeReadSource]; readSource = NULL; } if (writeSource) { LogVerbose(@"dispatch_source_cancel(writeSource)"); dispatch_source_cancel(writeSource); [self resumeWriteSource]; writeSource = NULL; } // The sockets will be closed by the cancel handlers of the corresponding source socket4FD = SOCKET_NULL; socket6FD = SOCKET_NULL; } // If the client has passed the connect/accept method, then the connection has at least begun. // Notify delegate that it is now ending. BOOL shouldCallDelegate = (flags & kSocketStarted); // Clear stored socket info and all flags (config remains as is) socketFDBytesAvailable = 0; flags = 0; if (shouldCallDelegate) { if (delegateQueue && [delegate respondsToSelector: @selector(socketDidDisconnect:withError:)]) { __strong id theDelegate = delegate; dispatch_async(delegateQueue, ^{ @autoreleasepool { [theDelegate socketDidDisconnect:self withError:error]; }}); } } } - (void)disconnect { dispatch_block_t block = ^{ @autoreleasepool { if (flags & kSocketStarted) { [self closeWithError:nil]; } }}; // Synchronous disconnection, as documented in the header file if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); } - (void)disconnectAfterReading { dispatch_async(socketQueue, ^{ @autoreleasepool { if (flags & kSocketStarted) { flags |= (kForbidReadsWrites | kDisconnectAfterReads); [self maybeClose]; } }}); } - (void)disconnectAfterWriting { dispatch_async(socketQueue, ^{ @autoreleasepool { if (flags & kSocketStarted) { flags |= (kForbidReadsWrites | kDisconnectAfterWrites); [self maybeClose]; } }}); } - (void)disconnectAfterReadingAndWriting { dispatch_async(socketQueue, ^{ @autoreleasepool { if (flags & kSocketStarted) { flags |= (kForbidReadsWrites | kDisconnectAfterReads | kDisconnectAfterWrites); [self maybeClose]; } }}); } /** * Closes the socket if possible. * That is, if all writes have completed, and we're set to disconnect after writing, * or if all reads have completed, and we're set to disconnect after reading. **/ - (void)maybeClose { NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); BOOL shouldClose = NO; if (flags & kDisconnectAfterReads) { if (([readQueue count] == 0) && (currentRead == nil)) { if (flags & kDisconnectAfterWrites) { if (([writeQueue count] == 0) && (currentWrite == nil)) { shouldClose = YES; } } else { shouldClose = YES; } } } else if (flags & kDisconnectAfterWrites) { if (([writeQueue count] == 0) && (currentWrite == nil)) { shouldClose = YES; } } if (shouldClose) { [self closeWithError:nil]; } } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Errors //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// - (NSError *)badConfigError:(NSString *)errMsg { NSDictionary *userInfo = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:GCDAsyncSocketErrorDomain code:GCDAsyncSocketBadConfigError userInfo:userInfo]; } - (NSError *)badParamError:(NSString *)errMsg { NSDictionary *userInfo = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:GCDAsyncSocketErrorDomain code:GCDAsyncSocketBadParamError userInfo:userInfo]; } - (NSError *)gaiError:(int)gai_error { NSString *errMsg = [NSString stringWithCString:gai_strerror(gai_error) encoding:NSASCIIStringEncoding]; NSDictionary *userInfo = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:@"kCFStreamErrorDomainNetDB" code:gai_error userInfo:userInfo]; } - (NSError *)errnoErrorWithReason:(NSString *)reason { NSString *errMsg = [NSString stringWithUTF8String:strerror(errno)]; NSDictionary *userInfo = [NSDictionary dictionaryWithObjectsAndKeys:errMsg, NSLocalizedDescriptionKey, reason, NSLocalizedFailureReasonErrorKey, nil]; return [NSError errorWithDomain:NSPOSIXErrorDomain code:errno userInfo:userInfo]; } - (NSError *)errnoError { NSString *errMsg = [NSString stringWithUTF8String:strerror(errno)]; NSDictionary *userInfo = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:NSPOSIXErrorDomain code:errno userInfo:userInfo]; } - (NSError *)sslError:(OSStatus)ssl_error { NSString *msg = @"Error code definition can be found in Apple's SecureTransport.h"; NSDictionary *userInfo = [NSDictionary dictionaryWithObject:msg forKey:NSLocalizedRecoverySuggestionErrorKey]; return [NSError errorWithDomain:@"kCFStreamErrorDomainSSL" code:ssl_error userInfo:userInfo]; } - (NSError *)connectTimeoutError { NSString *errMsg = NSLocalizedStringWithDefaultValue(@"GCDAsyncSocketConnectTimeoutError", @"GCDAsyncSocket", [NSBundle mainBundle], @"Attempt to connect to host timed out", nil); NSDictionary *userInfo = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:GCDAsyncSocketErrorDomain code:GCDAsyncSocketConnectTimeoutError userInfo:userInfo]; } /** * Returns a standard AsyncSocket maxed out error. **/ - (NSError *)readMaxedOutError { NSString *errMsg = NSLocalizedStringWithDefaultValue(@"GCDAsyncSocketReadMaxedOutError", @"GCDAsyncSocket", [NSBundle mainBundle], @"Read operation reached set maximum length", nil); NSDictionary *info = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:GCDAsyncSocketErrorDomain code:GCDAsyncSocketReadMaxedOutError userInfo:info]; } /** * Returns a standard AsyncSocket write timeout error. **/ - (NSError *)readTimeoutError { NSString *errMsg = NSLocalizedStringWithDefaultValue(@"GCDAsyncSocketReadTimeoutError", @"GCDAsyncSocket", [NSBundle mainBundle], @"Read operation timed out", nil); NSDictionary *userInfo = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:GCDAsyncSocketErrorDomain code:GCDAsyncSocketReadTimeoutError userInfo:userInfo]; } /** * Returns a standard AsyncSocket write timeout error. **/ - (NSError *)writeTimeoutError { NSString *errMsg = NSLocalizedStringWithDefaultValue(@"GCDAsyncSocketWriteTimeoutError", @"GCDAsyncSocket", [NSBundle mainBundle], @"Write operation timed out", nil); NSDictionary *userInfo = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:GCDAsyncSocketErrorDomain code:GCDAsyncSocketWriteTimeoutError userInfo:userInfo]; } - (NSError *)connectionClosedError { NSString *errMsg = NSLocalizedStringWithDefaultValue(@"GCDAsyncSocketClosedError", @"GCDAsyncSocket", [NSBundle mainBundle], @"Socket closed by remote peer", nil); NSDictionary *userInfo = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:GCDAsyncSocketErrorDomain code:GCDAsyncSocketClosedError userInfo:userInfo]; } - (NSError *)otherError:(NSString *)errMsg { NSDictionary *userInfo = [NSDictionary dictionaryWithObject:errMsg forKey:NSLocalizedDescriptionKey]; return [NSError errorWithDomain:GCDAsyncSocketErrorDomain code:GCDAsyncSocketOtherError userInfo:userInfo]; } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Diagnostics //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// - (BOOL)isDisconnected { __block BOOL result = NO; dispatch_block_t block = ^{ result = (flags & kSocketStarted) ? NO : YES; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); return result; } - (BOOL)isConnected { __block BOOL result = NO; dispatch_block_t block = ^{ result = (flags & kConnected) ? YES : NO; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); return result; } - (NSString *)connectedHost { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { if (socket4FD != SOCKET_NULL) return [self connectedHostFromSocket4:socket4FD]; if (socket6FD != SOCKET_NULL) return [self connectedHostFromSocket6:socket6FD]; return nil; } else { __block NSString *result = nil; dispatch_sync(socketQueue, ^{ @autoreleasepool { if (socket4FD != SOCKET_NULL) result = [self connectedHostFromSocket4:socket4FD]; else if (socket6FD != SOCKET_NULL) result = [self connectedHostFromSocket6:socket6FD]; }}); return result; } } - (uint16_t)connectedPort { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { if (socket4FD != SOCKET_NULL) return [self connectedPortFromSocket4:socket4FD]; if (socket6FD != SOCKET_NULL) return [self connectedPortFromSocket6:socket6FD]; return 0; } else { __block uint16_t result = 0; dispatch_sync(socketQueue, ^{ // No need for autorelease pool if (socket4FD != SOCKET_NULL) result = [self connectedPortFromSocket4:socket4FD]; else if (socket6FD != SOCKET_NULL) result = [self connectedPortFromSocket6:socket6FD]; }); return result; } } - (NSString *)localHost { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { if (socket4FD != SOCKET_NULL) return [self localHostFromSocket4:socket4FD]; if (socket6FD != SOCKET_NULL) return [self localHostFromSocket6:socket6FD]; return nil; } else { __block NSString *result = nil; dispatch_sync(socketQueue, ^{ @autoreleasepool { if (socket4FD != SOCKET_NULL) result = [self localHostFromSocket4:socket4FD]; else if (socket6FD != SOCKET_NULL) result = [self localHostFromSocket6:socket6FD]; }}); return result; } } - (uint16_t)localPort { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { if (socket4FD != SOCKET_NULL) return [self localPortFromSocket4:socket4FD]; if (socket6FD != SOCKET_NULL) return [self localPortFromSocket6:socket6FD]; return 0; } else { __block uint16_t result = 0; dispatch_sync(socketQueue, ^{ // No need for autorelease pool if (socket4FD != SOCKET_NULL) result = [self localPortFromSocket4:socket4FD]; else if (socket6FD != SOCKET_NULL) result = [self localPortFromSocket6:socket6FD]; }); return result; } } - (NSString *)connectedHost4 { if (socket4FD != SOCKET_NULL) return [self connectedHostFromSocket4:socket4FD]; return nil; } - (NSString *)connectedHost6 { if (socket6FD != SOCKET_NULL) return [self connectedHostFromSocket6:socket6FD]; return nil; } - (uint16_t)connectedPort4 { if (socket4FD != SOCKET_NULL) return [self connectedPortFromSocket4:socket4FD]; return 0; } - (uint16_t)connectedPort6 { if (socket6FD != SOCKET_NULL) return [self connectedPortFromSocket6:socket6FD]; return 0; } - (NSString *)localHost4 { if (socket4FD != SOCKET_NULL) return [self localHostFromSocket4:socket4FD]; return nil; } - (NSString *)localHost6 { if (socket6FD != SOCKET_NULL) return [self localHostFromSocket6:socket6FD]; return nil; } - (uint16_t)localPort4 { if (socket4FD != SOCKET_NULL) return [self localPortFromSocket4:socket4FD]; return 0; } - (uint16_t)localPort6 { if (socket6FD != SOCKET_NULL) return [self localPortFromSocket6:socket6FD]; return 0; } - (NSString *)connectedHostFromSocket4:(int)socketFD { struct sockaddr_in sockaddr4; socklen_t sockaddr4len = sizeof(sockaddr4); if (getpeername(socketFD, (struct sockaddr *)&sockaddr4, &sockaddr4len) < 0) { return nil; } return [[self class] hostFromSockaddr4:&sockaddr4]; } - (NSString *)connectedHostFromSocket6:(int)socketFD { struct sockaddr_in6 sockaddr6; socklen_t sockaddr6len = sizeof(sockaddr6); if (getpeername(socketFD, (struct sockaddr *)&sockaddr6, &sockaddr6len) < 0) { return nil; } return [[self class] hostFromSockaddr6:&sockaddr6]; } - (uint16_t)connectedPortFromSocket4:(int)socketFD { struct sockaddr_in sockaddr4; socklen_t sockaddr4len = sizeof(sockaddr4); if (getpeername(socketFD, (struct sockaddr *)&sockaddr4, &sockaddr4len) < 0) { return 0; } return [[self class] portFromSockaddr4:&sockaddr4]; } - (uint16_t)connectedPortFromSocket6:(int)socketFD { struct sockaddr_in6 sockaddr6; socklen_t sockaddr6len = sizeof(sockaddr6); if (getpeername(socketFD, (struct sockaddr *)&sockaddr6, &sockaddr6len) < 0) { return 0; } return [[self class] portFromSockaddr6:&sockaddr6]; } - (NSString *)localHostFromSocket4:(int)socketFD { struct sockaddr_in sockaddr4; socklen_t sockaddr4len = sizeof(sockaddr4); if (getsockname(socketFD, (struct sockaddr *)&sockaddr4, &sockaddr4len) < 0) { return nil; } return [[self class] hostFromSockaddr4:&sockaddr4]; } - (NSString *)localHostFromSocket6:(int)socketFD { struct sockaddr_in6 sockaddr6; socklen_t sockaddr6len = sizeof(sockaddr6); if (getsockname(socketFD, (struct sockaddr *)&sockaddr6, &sockaddr6len) < 0) { return nil; } return [[self class] hostFromSockaddr6:&sockaddr6]; } - (uint16_t)localPortFromSocket4:(int)socketFD { struct sockaddr_in sockaddr4; socklen_t sockaddr4len = sizeof(sockaddr4); if (getsockname(socketFD, (struct sockaddr *)&sockaddr4, &sockaddr4len) < 0) { return 0; } return [[self class] portFromSockaddr4:&sockaddr4]; } - (uint16_t)localPortFromSocket6:(int)socketFD { struct sockaddr_in6 sockaddr6; socklen_t sockaddr6len = sizeof(sockaddr6); if (getsockname(socketFD, (struct sockaddr *)&sockaddr6, &sockaddr6len) < 0) { return 0; } return [[self class] portFromSockaddr6:&sockaddr6]; } - (NSData *)connectedAddress { __block NSData *result = nil; dispatch_block_t block = ^{ if (socket4FD != SOCKET_NULL) { struct sockaddr_in sockaddr4; socklen_t sockaddr4len = sizeof(sockaddr4); if (getpeername(socket4FD, (struct sockaddr *)&sockaddr4, &sockaddr4len) == 0) { result = [[NSData alloc] initWithBytes:&sockaddr4 length:sockaddr4len]; } } if (socket6FD != SOCKET_NULL) { struct sockaddr_in6 sockaddr6; socklen_t sockaddr6len = sizeof(sockaddr6); if (getpeername(socket6FD, (struct sockaddr *)&sockaddr6, &sockaddr6len) == 0) { result = [[NSData alloc] initWithBytes:&sockaddr6 length:sockaddr6len]; } } }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); return result; } - (NSData *)localAddress { __block NSData *result = nil; dispatch_block_t block = ^{ if (socket4FD != SOCKET_NULL) { struct sockaddr_in sockaddr4; socklen_t sockaddr4len = sizeof(sockaddr4); if (getsockname(socket4FD, (struct sockaddr *)&sockaddr4, &sockaddr4len) == 0) { result = [[NSData alloc] initWithBytes:&sockaddr4 length:sockaddr4len]; } } if (socket6FD != SOCKET_NULL) { struct sockaddr_in6 sockaddr6; socklen_t sockaddr6len = sizeof(sockaddr6); if (getsockname(socket6FD, (struct sockaddr *)&sockaddr6, &sockaddr6len) == 0) { result = [[NSData alloc] initWithBytes:&sockaddr6 length:sockaddr6len]; } } }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); return result; } - (BOOL)isIPv4 { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { return (socket4FD != SOCKET_NULL); } else { __block BOOL result = NO; dispatch_sync(socketQueue, ^{ result = (socket4FD != SOCKET_NULL); }); return result; } } - (BOOL)isIPv6 { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { return (socket6FD != SOCKET_NULL); } else { __block BOOL result = NO; dispatch_sync(socketQueue, ^{ result = (socket6FD != SOCKET_NULL); }); return result; } } - (BOOL)isSecure { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { return (flags & kSocketSecure) ? YES : NO; } else { __block BOOL result; dispatch_sync(socketQueue, ^{ result = (flags & kSocketSecure) ? YES : NO; }); return result; } } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Utilities //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// /** * Finds the address of an interface description. * An inteface description may be an interface name (en0, en1, lo0) or corresponding IP (192.168.4.34). * * The interface description may optionally contain a port number at the end, separated by a colon. * If a non-zero port parameter is provided, any port number in the interface description is ignored. * * The returned value is a 'struct sockaddr' wrapped in an NSMutableData object. **/ - (void)getInterfaceAddress4:(NSMutableData **)interfaceAddr4Ptr address6:(NSMutableData **)interfaceAddr6Ptr fromDescription:(NSString *)interfaceDescription port:(uint16_t)port { NSMutableData *addr4 = nil; NSMutableData *addr6 = nil; NSString *interface = nil; NSArray *components = [interfaceDescription componentsSeparatedByString:@":"]; if ([components count] > 0) { NSString *temp = [components objectAtIndex:0]; if ([temp length] > 0) { interface = temp; } } if ([components count] > 1 && port == 0) { long portL = strtol([[components objectAtIndex:1] UTF8String], NULL, 10); if (portL > 0 && portL <= UINT16_MAX) { port = (uint16_t)portL; } } if (interface == nil) { // ANY address struct sockaddr_in sockaddr4; memset(&sockaddr4, 0, sizeof(sockaddr4)); sockaddr4.sin_len = sizeof(sockaddr4); sockaddr4.sin_family = AF_INET; sockaddr4.sin_port = htons(port); sockaddr4.sin_addr.s_addr = htonl(INADDR_ANY); struct sockaddr_in6 sockaddr6; memset(&sockaddr6, 0, sizeof(sockaddr6)); sockaddr6.sin6_len = sizeof(sockaddr6); sockaddr6.sin6_family = AF_INET6; sockaddr6.sin6_port = htons(port); sockaddr6.sin6_addr = in6addr_any; addr4 = [NSMutableData dataWithBytes:&sockaddr4 length:sizeof(sockaddr4)]; addr6 = [NSMutableData dataWithBytes:&sockaddr6 length:sizeof(sockaddr6)]; } else if ([interface isEqualToString:@"localhost"] || [interface isEqualToString:@"loopback"]) { // LOOPBACK address struct sockaddr_in sockaddr4; memset(&sockaddr4, 0, sizeof(sockaddr4)); sockaddr4.sin_len = sizeof(sockaddr4); sockaddr4.sin_family = AF_INET; sockaddr4.sin_port = htons(port); sockaddr4.sin_addr.s_addr = htonl(INADDR_LOOPBACK); struct sockaddr_in6 sockaddr6; memset(&sockaddr6, 0, sizeof(sockaddr6)); sockaddr6.sin6_len = sizeof(sockaddr6); sockaddr6.sin6_family = AF_INET6; sockaddr6.sin6_port = htons(port); sockaddr6.sin6_addr = in6addr_loopback; addr4 = [NSMutableData dataWithBytes:&sockaddr4 length:sizeof(sockaddr4)]; addr6 = [NSMutableData dataWithBytes:&sockaddr6 length:sizeof(sockaddr6)]; } else { const char *iface = [interface UTF8String]; struct ifaddrs *addrs; const struct ifaddrs *cursor; if ((getifaddrs(&addrs) == 0)) { cursor = addrs; while (cursor != NULL) { if ((addr4 == nil) && (cursor->ifa_addr->sa_family == AF_INET)) { // IPv4 struct sockaddr_in nativeAddr4; memcpy(&nativeAddr4, cursor->ifa_addr, sizeof(nativeAddr4)); if (strcmp(cursor->ifa_name, iface) == 0) { // Name match nativeAddr4.sin_port = htons(port); addr4 = [NSMutableData dataWithBytes:&nativeAddr4 length:sizeof(nativeAddr4)]; } else { char ip[INET_ADDRSTRLEN]; const char *conversion = inet_ntop(AF_INET, &nativeAddr4.sin_addr, ip, sizeof(ip)); if ((conversion != NULL) && (strcmp(ip, iface) == 0)) { // IP match nativeAddr4.sin_port = htons(port); addr4 = [NSMutableData dataWithBytes:&nativeAddr4 length:sizeof(nativeAddr4)]; } } } else if ((addr6 == nil) && (cursor->ifa_addr->sa_family == AF_INET6)) { // IPv6 struct sockaddr_in6 nativeAddr6; memcpy(&nativeAddr6, cursor->ifa_addr, sizeof(nativeAddr6)); if (strcmp(cursor->ifa_name, iface) == 0) { // Name match nativeAddr6.sin6_port = htons(port); addr6 = [NSMutableData dataWithBytes:&nativeAddr6 length:sizeof(nativeAddr6)]; } else { char ip[INET6_ADDRSTRLEN]; const char *conversion = inet_ntop(AF_INET6, &nativeAddr6.sin6_addr, ip, sizeof(ip)); if ((conversion != NULL) && (strcmp(ip, iface) == 0)) { // IP match nativeAddr6.sin6_port = htons(port); addr6 = [NSMutableData dataWithBytes:&nativeAddr6 length:sizeof(nativeAddr6)]; } } } cursor = cursor->ifa_next; } freeifaddrs(addrs); } } if (interfaceAddr4Ptr) *interfaceAddr4Ptr = addr4; if (interfaceAddr6Ptr) *interfaceAddr6Ptr = addr6; } - (void)setupReadAndWriteSourcesForNewlyConnectedSocket:(int)socketFD { readSource = dispatch_source_create(DISPATCH_SOURCE_TYPE_READ, socketFD, 0, socketQueue); writeSource = dispatch_source_create(DISPATCH_SOURCE_TYPE_WRITE, socketFD, 0, socketQueue); // Setup event handlers dispatch_source_set_event_handler(readSource, ^{ @autoreleasepool { LogVerbose(@"readEventBlock"); socketFDBytesAvailable = dispatch_source_get_data(readSource); LogVerbose(@"socketFDBytesAvailable: %lu", socketFDBytesAvailable); if (socketFDBytesAvailable > 0) [self doReadData]; else [self doReadEOF]; }}); dispatch_source_set_event_handler(writeSource, ^{ @autoreleasepool { LogVerbose(@"writeEventBlock"); flags |= kSocketCanAcceptBytes; [self doWriteData]; }}); // Setup cancel handlers __block int socketFDRefCount = 2; #if NEEDS_DISPATCH_RETAIN_RELEASE dispatch_source_t theReadSource = readSource; dispatch_source_t theWriteSource = writeSource; #endif dispatch_source_set_cancel_handler(readSource, ^{ LogVerbose(@"readCancelBlock"); #if NEEDS_DISPATCH_RETAIN_RELEASE LogVerbose(@"dispatch_release(readSource)"); dispatch_release(theReadSource); #endif if (--socketFDRefCount == 0) { LogVerbose(@"close(socketFD)"); close(socketFD); } }); dispatch_source_set_cancel_handler(writeSource, ^{ LogVerbose(@"writeCancelBlock"); #if NEEDS_DISPATCH_RETAIN_RELEASE LogVerbose(@"dispatch_release(writeSource)"); dispatch_release(theWriteSource); #endif if (--socketFDRefCount == 0) { LogVerbose(@"close(socketFD)"); close(socketFD); } }); // We will not be able to read until data arrives. // But we should be able to write immediately. socketFDBytesAvailable = 0; flags &= ~kReadSourceSuspended; LogVerbose(@"dispatch_resume(readSource)"); dispatch_resume(readSource); flags |= kSocketCanAcceptBytes; flags |= kWriteSourceSuspended; } - (BOOL)usingCFStreamForTLS { #if TARGET_OS_IPHONE { if ((flags & kSocketSecure) && (flags & kUsingCFStreamForTLS)) { // Due to the fact that Apple doesn't give us the full power of SecureTransport on iOS, // we are relegated to using the slower, less powerful, and RunLoop based CFStream API. :( Boo! // // Thus we're not able to use the GCD read/write sources in this particular scenario. return YES; } } #endif return NO; } - (BOOL)usingSecureTransportForTLS { #if TARGET_OS_IPHONE { return ![self usingCFStreamForTLS]; } #endif return YES; } - (void)suspendReadSource { if (!(flags & kReadSourceSuspended)) { LogVerbose(@"dispatch_suspend(readSource)"); dispatch_suspend(readSource); flags |= kReadSourceSuspended; } } - (void)resumeReadSource { if (flags & kReadSourceSuspended) { LogVerbose(@"dispatch_resume(readSource)"); dispatch_resume(readSource); flags &= ~kReadSourceSuspended; } } - (void)suspendWriteSource { if (!(flags & kWriteSourceSuspended)) { LogVerbose(@"dispatch_suspend(writeSource)"); dispatch_suspend(writeSource); flags |= kWriteSourceSuspended; } } - (void)resumeWriteSource { if (flags & kWriteSourceSuspended) { LogVerbose(@"dispatch_resume(writeSource)"); dispatch_resume(writeSource); flags &= ~kWriteSourceSuspended; } } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Reading //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// - (void)readDataWithTimeout:(NSTimeInterval)timeout tag:(long)tag { [self readDataWithTimeout:timeout buffer:nil bufferOffset:0 maxLength:0 tag:tag]; } - (void)readDataWithTimeout:(NSTimeInterval)timeout buffer:(NSMutableData *)buffer bufferOffset:(NSUInteger)offset tag:(long)tag { [self readDataWithTimeout:timeout buffer:buffer bufferOffset:offset maxLength:0 tag:tag]; } - (void)readDataWithTimeout:(NSTimeInterval)timeout buffer:(NSMutableData *)buffer bufferOffset:(NSUInteger)offset maxLength:(NSUInteger)length tag:(long)tag { if (offset > [buffer length]) { LogWarn(@"Cannot read: offset > [buffer length]"); return; } GCDAsyncReadPacket *packet = [[GCDAsyncReadPacket alloc] initWithData:buffer startOffset:offset maxLength:length timeout:timeout readLength:0 terminator:nil tag:tag]; dispatch_async(socketQueue, ^{ @autoreleasepool { LogTrace(); if ((flags & kSocketStarted) && !(flags & kForbidReadsWrites)) { [readQueue addObject:packet]; [self maybeDequeueRead]; } }}); // Do not rely on the block being run in order to release the packet, // as the queue might get released without the block completing. } - (void)readDataToLength:(NSUInteger)length withTimeout:(NSTimeInterval)timeout tag:(long)tag { [self readDataToLength:length withTimeout:timeout buffer:nil bufferOffset:0 tag:tag]; } - (void)readDataToLength:(NSUInteger)length withTimeout:(NSTimeInterval)timeout buffer:(NSMutableData *)buffer bufferOffset:(NSUInteger)offset tag:(long)tag { if (length == 0) { LogWarn(@"Cannot read: length == 0"); return; } if (offset > [buffer length]) { LogWarn(@"Cannot read: offset > [buffer length]"); return; } GCDAsyncReadPacket *packet = [[GCDAsyncReadPacket alloc] initWithData:buffer startOffset:offset maxLength:0 timeout:timeout readLength:length terminator:nil tag:tag]; dispatch_async(socketQueue, ^{ @autoreleasepool { LogTrace(); if ((flags & kSocketStarted) && !(flags & kForbidReadsWrites)) { [readQueue addObject:packet]; [self maybeDequeueRead]; } }}); // Do not rely on the block being run in order to release the packet, // as the queue might get released without the block completing. } - (void)readDataToData:(NSData *)data withTimeout:(NSTimeInterval)timeout tag:(long)tag { [self readDataToData:data withTimeout:timeout buffer:nil bufferOffset:0 maxLength:0 tag:tag]; } - (void)readDataToData:(NSData *)data withTimeout:(NSTimeInterval)timeout buffer:(NSMutableData *)buffer bufferOffset:(NSUInteger)offset tag:(long)tag { [self readDataToData:data withTimeout:timeout buffer:buffer bufferOffset:offset maxLength:0 tag:tag]; } - (void)readDataToData:(NSData *)data withTimeout:(NSTimeInterval)timeout maxLength:(NSUInteger)length tag:(long)tag { [self readDataToData:data withTimeout:timeout buffer:nil bufferOffset:0 maxLength:length tag:tag]; } - (void)readDataToData:(NSData *)data withTimeout:(NSTimeInterval)timeout buffer:(NSMutableData *)buffer bufferOffset:(NSUInteger)offset maxLength:(NSUInteger)maxLength tag:(long)tag { if ([data length] == 0) { LogWarn(@"Cannot read: [data length] == 0"); return; } if (offset > [buffer length]) { LogWarn(@"Cannot read: offset > [buffer length]"); return; } if (maxLength > 0 && maxLength < [data length]) { LogWarn(@"Cannot read: maxLength > 0 && maxLength < [data length]"); return; } GCDAsyncReadPacket *packet = [[GCDAsyncReadPacket alloc] initWithData:buffer startOffset:offset maxLength:maxLength timeout:timeout readLength:0 terminator:data tag:tag]; dispatch_async(socketQueue, ^{ @autoreleasepool { LogTrace(); if ((flags & kSocketStarted) && !(flags & kForbidReadsWrites)) { [readQueue addObject:packet]; [self maybeDequeueRead]; } }}); // Do not rely on the block being run in order to release the packet, // as the queue might get released without the block completing. } - (float)progressOfReadReturningTag:(long *)tagPtr bytesDone:(NSUInteger *)donePtr total:(NSUInteger *)totalPtr { __block float result = 0.0F; dispatch_block_t block = ^{ if (!currentRead || ![currentRead isKindOfClass:[GCDAsyncReadPacket class]]) { // We're not reading anything right now. if (tagPtr != NULL) *tagPtr = 0; if (donePtr != NULL) *donePtr = 0; if (totalPtr != NULL) *totalPtr = 0; result = NAN; } else { // It's only possible to know the progress of our read if we're reading to a certain length. // If we're reading to data, we of course have no idea when the data will arrive. // If we're reading to timeout, then we have no idea when the next chunk of data will arrive. NSUInteger done = currentRead->bytesDone; NSUInteger total = currentRead->readLength; if (tagPtr != NULL) *tagPtr = currentRead->tag; if (donePtr != NULL) *donePtr = done; if (totalPtr != NULL) *totalPtr = total; if (total > 0) result = (float)done / (float)total; else result = 1.0F; } }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); return result; } /** * This method starts a new read, if needed. * * It is called when: * - a user requests a read * - after a read request has finished (to handle the next request) * - immediately after the socket opens to handle any pending requests * * This method also handles auto-disconnect post read/write completion. **/ - (void)maybeDequeueRead { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); // If we're not currently processing a read AND we have an available read stream if ((currentRead == nil) && (flags & kConnected)) { if ([readQueue count] > 0) { // Dequeue the next object in the write queue currentRead = [readQueue objectAtIndex:0]; [readQueue removeObjectAtIndex:0]; if ([currentRead isKindOfClass:[GCDAsyncSpecialPacket class]]) { LogVerbose(@"Dequeued GCDAsyncSpecialPacket"); // Attempt to start TLS flags |= kStartingReadTLS; // This method won't do anything unless both kStartingReadTLS and kStartingWriteTLS are set [self maybeStartTLS]; } else { LogVerbose(@"Dequeued GCDAsyncReadPacket"); // Setup read timer (if needed) [self setupReadTimerWithTimeout:currentRead->timeout]; // Immediately read, if possible [self doReadData]; } } else if (flags & kDisconnectAfterReads) { if (flags & kDisconnectAfterWrites) { if (([writeQueue count] == 0) && (currentWrite == nil)) { [self closeWithError:nil]; } } else { [self closeWithError:nil]; } } else if (flags & kSocketSecure) { [self flushSSLBuffers]; // Edge case: // // We just drained all data from the ssl buffers, // and all known data from the socket (socketFDBytesAvailable). // // If we didn't get any data from this process, // then we may have reached the end of the TCP stream. // // Be sure callbacks are enabled so we're notified about a disconnection. if ([preBuffer availableBytes] == 0) { if ([self usingCFStreamForTLS]) { // Callbacks never disabled } else { [self resumeReadSource]; } } } } } - (void)flushSSLBuffers { LogTrace(); NSAssert((flags & kSocketSecure), @"Cannot flush ssl buffers on non-secure socket"); if ([preBuffer availableBytes] > 0) { // Only flush the ssl buffers if the prebuffer is empty. // This is to avoid growing the prebuffer inifinitely large. return; } #if TARGET_OS_IPHONE if ([self usingCFStreamForTLS]) { if ((flags & kSecureSocketHasBytesAvailable) && CFReadStreamHasBytesAvailable(readStream)) { LogVerbose(@"%@ - Flushing ssl buffers into prebuffer...", THIS_METHOD); CFIndex defaultBytesToRead = (1024 * 4); [preBuffer ensureCapacityForWrite:defaultBytesToRead]; uint8_t *buffer = [preBuffer writeBuffer]; CFIndex result = CFReadStreamRead(readStream, buffer, defaultBytesToRead); LogVerbose(@"%@ - CFReadStreamRead(): result = %i", THIS_METHOD, (int)result); if (result > 0) { [preBuffer didWrite:result]; } flags &= ~kSecureSocketHasBytesAvailable; } return; } #endif #if SECURE_TRANSPORT_MAYBE_AVAILABLE __block NSUInteger estimatedBytesAvailable = 0; dispatch_block_t updateEstimatedBytesAvailable = ^{ // Figure out if there is any data available to be read // // socketFDBytesAvailable <- Number of encrypted bytes we haven't read from the bsd socket // [sslPreBuffer availableBytes] <- Number of encrypted bytes we've buffered from bsd socket // sslInternalBufSize <- Number of decrypted bytes SecureTransport has buffered // // We call the variable "estimated" because we don't know how many decrypted bytes we'll get // from the encrypted bytes in the sslPreBuffer. // However, we do know this is an upper bound on the estimation. estimatedBytesAvailable = socketFDBytesAvailable + [sslPreBuffer availableBytes]; size_t sslInternalBufSize = 0; SSLGetBufferedReadSize(sslContext, &sslInternalBufSize); estimatedBytesAvailable += sslInternalBufSize; }; updateEstimatedBytesAvailable(); if (estimatedBytesAvailable > 0) { LogVerbose(@"%@ - Flushing ssl buffers into prebuffer...", THIS_METHOD); BOOL done = NO; do { LogVerbose(@"%@ - estimatedBytesAvailable = %lu", THIS_METHOD, (unsigned long)estimatedBytesAvailable); // Make sure there's enough room in the prebuffer [preBuffer ensureCapacityForWrite:estimatedBytesAvailable]; // Read data into prebuffer uint8_t *buffer = [preBuffer writeBuffer]; size_t bytesRead = 0; OSStatus result = SSLRead(sslContext, buffer, (size_t)estimatedBytesAvailable, &bytesRead); LogVerbose(@"%@ - read from secure socket = %u", THIS_METHOD, (unsigned)bytesRead); if (bytesRead > 0) { [preBuffer didWrite:bytesRead]; } LogVerbose(@"%@ - prebuffer.length = %zu", THIS_METHOD, [preBuffer availableBytes]); if (result != noErr) { done = YES; } else { updateEstimatedBytesAvailable(); } } while (!done && estimatedBytesAvailable > 0); } #endif } - (void)doReadData { LogTrace(); // This method is called on the socketQueue. // It might be called directly, or via the readSource when data is available to be read. if ((currentRead == nil) || (flags & kReadsPaused)) { LogVerbose(@"No currentRead or kReadsPaused"); // Unable to read at this time if (flags & kSocketSecure) { // Here's the situation: // // We have an established secure connection. // There may not be a currentRead, but there might be encrypted data sitting around for us. // When the user does get around to issuing a read, that encrypted data will need to be decrypted. // // So why make the user wait? // We might as well get a head start on decrypting some data now. // // The other reason we do this has to do with detecting a socket disconnection. // The SSL/TLS protocol has it's own disconnection handshake. // So when a secure socket is closed, a "goodbye" packet comes across the wire. // We want to make sure we read the "goodbye" packet so we can properly detect the TCP disconnection. [self flushSSLBuffers]; } if ([self usingCFStreamForTLS]) { // CFReadStream only fires once when there is available data. // It won't fire again until we've invoked CFReadStreamRead. } else { // If the readSource is firing, we need to pause it // or else it will continue to fire over and over again. // // If the readSource is not firing, // we want it to continue monitoring the socket. if (socketFDBytesAvailable > 0) { [self suspendReadSource]; } } return; } BOOL hasBytesAvailable = NO; unsigned long estimatedBytesAvailable; if ([self usingCFStreamForTLS]) { #if TARGET_OS_IPHONE // Relegated to using CFStream... :( Boo! Give us a full SecureTransport stack Apple! estimatedBytesAvailable = 0; if ((flags & kSecureSocketHasBytesAvailable) && CFReadStreamHasBytesAvailable(readStream)) hasBytesAvailable = YES; else hasBytesAvailable = NO; #endif } else { #if SECURE_TRANSPORT_MAYBE_AVAILABLE estimatedBytesAvailable = socketFDBytesAvailable; if (flags & kSocketSecure) { // There are 2 buffers to be aware of here. // // We are using SecureTransport, a TLS/SSL security layer which sits atop TCP. // We issue a read to the SecureTranport API, which in turn issues a read to our SSLReadFunction. // Our SSLReadFunction then reads from the BSD socket and returns the encrypted data to SecureTransport. // SecureTransport then decrypts the data, and finally returns the decrypted data back to us. // // The first buffer is one we create. // SecureTransport often requests small amounts of data. // This has to do with the encypted packets that are coming across the TCP stream. // But it's non-optimal to do a bunch of small reads from the BSD socket. // So our SSLReadFunction reads all available data from the socket (optimizing the sys call) // and may store excess in the sslPreBuffer. estimatedBytesAvailable += [sslPreBuffer availableBytes]; // The second buffer is within SecureTransport. // As mentioned earlier, there are encrypted packets coming across the TCP stream. // SecureTransport needs the entire packet to decrypt it. // But if the entire packet produces X bytes of decrypted data, // and we only asked SecureTransport for X/2 bytes of data, // it must store the extra X/2 bytes of decrypted data for the next read. // // The SSLGetBufferedReadSize function will tell us the size of this internal buffer. // From the documentation: // // "This function does not block or cause any low-level read operations to occur." size_t sslInternalBufSize = 0; SSLGetBufferedReadSize(sslContext, &sslInternalBufSize); estimatedBytesAvailable += sslInternalBufSize; } hasBytesAvailable = (estimatedBytesAvailable > 0); #endif } if ((hasBytesAvailable == NO) && ([preBuffer availableBytes] == 0)) { LogVerbose(@"No data available to read..."); // No data available to read. if (![self usingCFStreamForTLS]) { // Need to wait for readSource to fire and notify us of // available data in the socket's internal read buffer. [self resumeReadSource]; } return; } if (flags & kStartingReadTLS) { LogVerbose(@"Waiting for SSL/TLS handshake to complete"); // The readQueue is waiting for SSL/TLS handshake to complete. if (flags & kStartingWriteTLS) { if ([self usingSecureTransportForTLS]) { #if SECURE_TRANSPORT_MAYBE_AVAILABLE // We are in the process of a SSL Handshake. // We were waiting for incoming data which has just arrived. [self ssl_continueSSLHandshake]; #endif } } else { // We are still waiting for the writeQueue to drain and start the SSL/TLS process. // We now know data is available to read. if (![self usingCFStreamForTLS]) { // Suspend the read source or else it will continue to fire nonstop. [self suspendReadSource]; } } return; } BOOL done = NO; // Completed read operation NSError *error = nil; // Error occured NSUInteger totalBytesReadForCurrentRead = 0; // // STEP 1 - READ FROM PREBUFFER // if ([preBuffer availableBytes] > 0) { // There are 3 types of read packets: // // 1) Read all available data. // 2) Read a specific length of data. // 3) Read up to a particular terminator. NSUInteger bytesToCopy; if (currentRead->term != nil) { // Read type #3 - read up to a terminator bytesToCopy = [currentRead readLengthForTermWithPreBuffer:preBuffer found:&done]; } else { // Read type #1 or #2 bytesToCopy = [currentRead readLengthForNonTermWithHint:[preBuffer availableBytes]]; } // Make sure we have enough room in the buffer for our read. [currentRead ensureCapacityForAdditionalDataOfLength:bytesToCopy]; // Copy bytes from prebuffer into packet buffer uint8_t *buffer = (uint8_t *)[currentRead->buffer mutableBytes] + currentRead->startOffset + currentRead->bytesDone; memcpy(buffer, [preBuffer readBuffer], bytesToCopy); // Remove the copied bytes from the preBuffer [preBuffer didRead:bytesToCopy]; LogVerbose(@"copied(%lu) preBufferLength(%zu)", (unsigned long)bytesToCopy, [preBuffer availableBytes]); // Update totals currentRead->bytesDone += bytesToCopy; totalBytesReadForCurrentRead += bytesToCopy; // Check to see if the read operation is done if (currentRead->readLength > 0) { // Read type #2 - read a specific length of data done = (currentRead->bytesDone == currentRead->readLength); } else if (currentRead->term != nil) { // Read type #3 - read up to a terminator // Our 'done' variable was updated via the readLengthForTermWithPreBuffer:found: method if (!done && currentRead->maxLength > 0) { // We're not done and there's a set maxLength. // Have we reached that maxLength yet? if (currentRead->bytesDone >= currentRead->maxLength) { error = [self readMaxedOutError]; } } } else { // Read type #1 - read all available data // // We're done as soon as // - we've read all available data (in prebuffer and socket) // - we've read the maxLength of read packet. done = ((currentRead->maxLength > 0) && (currentRead->bytesDone == currentRead->maxLength)); } } // // STEP 2 - READ FROM SOCKET // BOOL socketEOF = (flags & kSocketHasReadEOF) ? YES : NO; // Nothing more to via socket (end of file) BOOL waiting = !done && !error && !socketEOF && !hasBytesAvailable; // Ran out of data, waiting for more if (!done && !error && !socketEOF && !waiting && hasBytesAvailable) { NSAssert(([preBuffer availableBytes] == 0), @"Invalid logic"); // There are 3 types of read packets: // // 1) Read all available data. // 2) Read a specific length of data. // 3) Read up to a particular terminator. BOOL readIntoPreBuffer = NO; NSUInteger bytesToRead; if ([self usingCFStreamForTLS]) { // Since Apple hasn't made the full power of SecureTransport available on iOS, // we are relegated to using the slower, less powerful, RunLoop based CFStream API. // // This API doesn't tell us how much data is available on the socket to be read. // If we had that information we could optimize our memory allocations, and sys calls. // // But alas... // So we do it old school, and just read as much data from the socket as we can. NSUInteger defaultReadLength = (1024 * 32); bytesToRead = [currentRead optimalReadLengthWithDefault:defaultReadLength shouldPreBuffer:&readIntoPreBuffer]; } else { if (currentRead->term != nil) { // Read type #3 - read up to a terminator bytesToRead = [currentRead readLengthForTermWithHint:estimatedBytesAvailable shouldPreBuffer:&readIntoPreBuffer]; } else { // Read type #1 or #2 bytesToRead = [currentRead readLengthForNonTermWithHint:estimatedBytesAvailable]; } } if (bytesToRead > SIZE_MAX) // NSUInteger may be bigger than size_t (read param 3) { bytesToRead = SIZE_MAX; } // Make sure we have enough room in the buffer for our read. // // We are either reading directly into the currentRead->buffer, // or we're reading into the temporary preBuffer. uint8_t *buffer; if (readIntoPreBuffer) { [preBuffer ensureCapacityForWrite:bytesToRead]; buffer = [preBuffer writeBuffer]; } else { [currentRead ensureCapacityForAdditionalDataOfLength:bytesToRead]; buffer = (uint8_t *)[currentRead->buffer mutableBytes] + currentRead->startOffset + currentRead->bytesDone; } // Read data into buffer size_t bytesRead = 0; if (flags & kSocketSecure) { if ([self usingCFStreamForTLS]) { #if TARGET_OS_IPHONE CFIndex result = CFReadStreamRead(readStream, buffer, (CFIndex)bytesToRead); LogVerbose(@"CFReadStreamRead(): result = %i", (int)result); if (result < 0) { error = (__bridge_transfer NSError *)CFReadStreamCopyError(readStream); } else if (result == 0) { socketEOF = YES; } else { waiting = YES; bytesRead = (size_t)result; } // We only know how many decrypted bytes were read. // The actual number of bytes read was likely more due to the overhead of the encryption. // So we reset our flag, and rely on the next callback to alert us of more data. flags &= ~kSecureSocketHasBytesAvailable; #endif } else { #if SECURE_TRANSPORT_MAYBE_AVAILABLE // The documentation from Apple states: // // "a read operation might return errSSLWouldBlock, // indicating that less data than requested was actually transferred" // // However, starting around 10.7, the function will sometimes return noErr, // even if it didn't read as much data as requested. So we need to watch out for that. OSStatus result; do { void *loop_buffer = buffer + bytesRead; size_t loop_bytesToRead = (size_t)bytesToRead - bytesRead; size_t loop_bytesRead = 0; result = SSLRead(sslContext, loop_buffer, loop_bytesToRead, &loop_bytesRead); LogVerbose(@"read from secure socket = %u", (unsigned)bytesRead); bytesRead += loop_bytesRead; } while ((result == noErr) && (bytesRead < bytesToRead)); if (result != noErr) { if (result == errSSLWouldBlock) waiting = YES; else { if (result == errSSLClosedGraceful || result == errSSLClosedAbort) { // We've reached the end of the stream. // Handle this the same way we would an EOF from the socket. socketEOF = YES; sslErrCode = result; } else { error = [self sslError:result]; } } // It's possible that bytesRead > 0, even if the result was errSSLWouldBlock. // This happens when the SSLRead function is able to read some data, // but not the entire amount we requested. if (bytesRead <= 0) { bytesRead = 0; } } // Do not modify socketFDBytesAvailable. // It will be updated via the SSLReadFunction(). #endif } } else { int socketFD = (socket4FD == SOCKET_NULL) ? socket6FD : socket4FD; ssize_t result = read(socketFD, buffer, (size_t)bytesToRead); LogVerbose(@"read from socket = %i", (int)result); if (result < 0) { if (errno == EWOULDBLOCK) waiting = YES; else error = [self errnoErrorWithReason:@"Error in read() function"]; socketFDBytesAvailable = 0; } else if (result == 0) { socketEOF = YES; socketFDBytesAvailable = 0; } else { bytesRead = result; if (bytesRead < bytesToRead) { // The read returned less data than requested. // This means socketFDBytesAvailable was a bit off due to timing, // because we read from the socket right when the readSource event was firing. socketFDBytesAvailable = 0; } else { if (socketFDBytesAvailable <= bytesRead) socketFDBytesAvailable = 0; else socketFDBytesAvailable -= bytesRead; } if (socketFDBytesAvailable == 0) { waiting = YES; } } } if (bytesRead > 0) { // Check to see if the read operation is done if (currentRead->readLength > 0) { // Read type #2 - read a specific length of data // // Note: We should never be using a prebuffer when we're reading a specific length of data. NSAssert(readIntoPreBuffer == NO, @"Invalid logic"); currentRead->bytesDone += bytesRead; totalBytesReadForCurrentRead += bytesRead; done = (currentRead->bytesDone == currentRead->readLength); } else if (currentRead->term != nil) { // Read type #3 - read up to a terminator if (readIntoPreBuffer) { // We just read a big chunk of data into the preBuffer [preBuffer didWrite:bytesRead]; LogVerbose(@"read data into preBuffer - preBuffer.length = %zu", [preBuffer availableBytes]); // Search for the terminating sequence bytesToRead = [currentRead readLengthForTermWithPreBuffer:preBuffer found:&done]; LogVerbose(@"copying %lu bytes from preBuffer", (unsigned long)bytesToRead); // Ensure there's room on the read packet's buffer [currentRead ensureCapacityForAdditionalDataOfLength:bytesToRead]; // Copy bytes from prebuffer into read buffer uint8_t *readBuf = (uint8_t *)[currentRead->buffer mutableBytes] + currentRead->startOffset + currentRead->bytesDone; memcpy(readBuf, [preBuffer readBuffer], bytesToRead); // Remove the copied bytes from the prebuffer [preBuffer didRead:bytesToRead]; LogVerbose(@"preBuffer.length = %zu", [preBuffer availableBytes]); // Update totals currentRead->bytesDone += bytesToRead; totalBytesReadForCurrentRead += bytesToRead; // Our 'done' variable was updated via the readLengthForTermWithPreBuffer:found: method above } else { // We just read a big chunk of data directly into the packet's buffer. // We need to move any overflow into the prebuffer. NSInteger overflow = [currentRead searchForTermAfterPreBuffering:bytesRead]; if (overflow == 0) { // Perfect match! // Every byte we read stays in the read buffer, // and the last byte we read was the last byte of the term. currentRead->bytesDone += bytesRead; totalBytesReadForCurrentRead += bytesRead; done = YES; } else if (overflow > 0) { // The term was found within the data that we read, // and there are extra bytes that extend past the end of the term. // We need to move these excess bytes out of the read packet and into the prebuffer. NSInteger underflow = bytesRead - overflow; // Copy excess data into preBuffer LogVerbose(@"copying %ld overflow bytes into preBuffer", (long)overflow); [preBuffer ensureCapacityForWrite:overflow]; uint8_t *overflowBuffer = buffer + underflow; memcpy([preBuffer writeBuffer], overflowBuffer, overflow); [preBuffer didWrite:overflow]; LogVerbose(@"preBuffer.length = %zu", [preBuffer availableBytes]); // Note: The completeCurrentRead method will trim the buffer for us. currentRead->bytesDone += underflow; totalBytesReadForCurrentRead += underflow; done = YES; } else { // The term was not found within the data that we read. currentRead->bytesDone += bytesRead; totalBytesReadForCurrentRead += bytesRead; done = NO; } } if (!done && currentRead->maxLength > 0) { // We're not done and there's a set maxLength. // Have we reached that maxLength yet? if (currentRead->bytesDone >= currentRead->maxLength) { error = [self readMaxedOutError]; } } } else { // Read type #1 - read all available data if (readIntoPreBuffer) { // We just read a chunk of data into the preBuffer [preBuffer didWrite:bytesRead]; // Now copy the data into the read packet. // // Recall that we didn't read directly into the packet's buffer to avoid // over-allocating memory since we had no clue how much data was available to be read. // // Ensure there's room on the read packet's buffer [currentRead ensureCapacityForAdditionalDataOfLength:bytesRead]; // Copy bytes from prebuffer into read buffer uint8_t *readBuf = (uint8_t *)[currentRead->buffer mutableBytes] + currentRead->startOffset + currentRead->bytesDone; memcpy(readBuf, [preBuffer readBuffer], bytesRead); // Remove the copied bytes from the prebuffer [preBuffer didRead:bytesRead]; // Update totals currentRead->bytesDone += bytesRead; totalBytesReadForCurrentRead += bytesRead; } else { currentRead->bytesDone += bytesRead; totalBytesReadForCurrentRead += bytesRead; } done = YES; } } // if (bytesRead > 0) } // if (!done && !error && !socketEOF && !waiting && hasBytesAvailable) if (!done && currentRead->readLength == 0 && currentRead->term == nil) { // Read type #1 - read all available data // // We might arrive here if we read data from the prebuffer but not from the socket. done = (totalBytesReadForCurrentRead > 0); } // Check to see if we're done, or if we've made progress if (done) { [self completeCurrentRead]; if (!error && (!socketEOF || [preBuffer availableBytes] > 0)) { [self maybeDequeueRead]; } } else if (totalBytesReadForCurrentRead > 0) { // We're not done read type #2 or #3 yet, but we have read in some bytes if (delegateQueue && [delegate respondsToSelector:@selector(socket:didReadPartialDataOfLength:tag:)]) { __strong id theDelegate = delegate; long theReadTag = currentRead->tag; dispatch_async(delegateQueue, ^{ @autoreleasepool { [theDelegate socket:self didReadPartialDataOfLength:totalBytesReadForCurrentRead tag:theReadTag]; }}); } } // Check for errors if (error) { [self closeWithError:error]; } else if (socketEOF) { [self doReadEOF]; } else if (waiting) { if (![self usingCFStreamForTLS]) { // Monitor the socket for readability (if we're not already doing so) [self resumeReadSource]; } } // Do not add any code here without first adding return statements in the error cases above. } - (void)doReadEOF { LogTrace(); // This method may be called more than once. // If the EOF is read while there is still data in the preBuffer, // then this method may be called continually after invocations of doReadData to see if it's time to disconnect. flags |= kSocketHasReadEOF; if (flags & kSocketSecure) { // If the SSL layer has any buffered data, flush it into the preBuffer now. [self flushSSLBuffers]; } BOOL shouldDisconnect; NSError *error = nil; if ((flags & kStartingReadTLS) || (flags & kStartingWriteTLS)) { // We received an EOF during or prior to startTLS. // The SSL/TLS handshake is now impossible, so this is an unrecoverable situation. shouldDisconnect = YES; if ([self usingSecureTransportForTLS]) { #if SECURE_TRANSPORT_MAYBE_AVAILABLE error = [self sslError:errSSLClosedAbort]; #endif } } else if (flags & kReadStreamClosed) { // The preBuffer has already been drained. // The config allows half-duplex connections. // We've previously checked the socket, and it appeared writeable. // So we marked the read stream as closed and notified the delegate. // // As per the half-duplex contract, the socket will be closed when a write fails, // or when the socket is manually closed. shouldDisconnect = NO; } else if ([preBuffer availableBytes] > 0) { LogVerbose(@"Socket reached EOF, but there is still data available in prebuffer"); // Although we won't be able to read any more data from the socket, // there is existing data that has been prebuffered that we can read. shouldDisconnect = NO; } else if (config & kAllowHalfDuplexConnection) { // We just received an EOF (end of file) from the socket's read stream. // This means the remote end of the socket (the peer we're connected to) // has explicitly stated that it will not be sending us any more data. // // Query the socket to see if it is still writeable. (Perhaps the peer will continue reading data from us) int socketFD = (socket4FD == SOCKET_NULL) ? socket6FD : socket4FD; struct pollfd pfd[1]; pfd[0].fd = socketFD; pfd[0].events = POLLOUT; pfd[0].revents = 0; poll(pfd, 1, 0); if (pfd[0].revents & POLLOUT) { // Socket appears to still be writeable shouldDisconnect = NO; flags |= kReadStreamClosed; // Notify the delegate that we're going half-duplex if (delegateQueue && [delegate respondsToSelector:@selector(socketDidCloseReadStream:)]) { __strong id theDelegate = delegate; dispatch_async(delegateQueue, ^{ @autoreleasepool { [theDelegate socketDidCloseReadStream:self]; }}); } } else { shouldDisconnect = YES; } } else { shouldDisconnect = YES; } if (shouldDisconnect) { if (error == nil) { if ([self usingSecureTransportForTLS]) { #if SECURE_TRANSPORT_MAYBE_AVAILABLE if (sslErrCode != noErr && sslErrCode != errSSLClosedGraceful) { error = [self sslError:sslErrCode]; } else { error = [self connectionClosedError]; } #endif } else { error = [self connectionClosedError]; } } [self closeWithError:error]; } else { if (![self usingCFStreamForTLS]) { // Suspend the read source (if needed) [self suspendReadSource]; } } } - (void)completeCurrentRead { LogTrace(); NSAssert(currentRead, @"Trying to complete current read when there is no current read."); NSData *result; if (currentRead->bufferOwner) { // We created the buffer on behalf of the user. // Trim our buffer to be the proper size. [currentRead->buffer setLength:currentRead->bytesDone]; result = currentRead->buffer; } else { // We did NOT create the buffer. // The buffer is owned by the caller. // Only trim the buffer if we had to increase its size. if ([currentRead->buffer length] > currentRead->originalBufferLength) { NSUInteger readSize = currentRead->startOffset + currentRead->bytesDone; NSUInteger origSize = currentRead->originalBufferLength; NSUInteger buffSize = MAX(readSize, origSize); [currentRead->buffer setLength:buffSize]; } uint8_t *buffer = (uint8_t *)[currentRead->buffer mutableBytes] + currentRead->startOffset; result = [NSData dataWithBytesNoCopy:buffer length:currentRead->bytesDone freeWhenDone:NO]; } if (delegateQueue && [delegate respondsToSelector:@selector(socket:didReadData:withTag:)]) { __strong id theDelegate = delegate; GCDAsyncReadPacket *theRead = currentRead; // Ensure currentRead retained since result may not own buffer dispatch_async(delegateQueue, ^{ @autoreleasepool { [theDelegate socket:self didReadData:result withTag:theRead->tag]; }}); } [self endCurrentRead]; } - (void)endCurrentRead { if (readTimer) { dispatch_source_cancel(readTimer); readTimer = NULL; } currentRead = nil; } - (void)setupReadTimerWithTimeout:(NSTimeInterval)timeout { if (timeout >= 0.0) { readTimer = dispatch_source_create(DISPATCH_SOURCE_TYPE_TIMER, 0, 0, socketQueue); dispatch_source_set_event_handler(readTimer, ^{ @autoreleasepool { [self doReadTimeout]; }}); #if NEEDS_DISPATCH_RETAIN_RELEASE dispatch_source_t theReadTimer = readTimer; dispatch_source_set_cancel_handler(readTimer, ^{ LogVerbose(@"dispatch_release(readTimer)"); dispatch_release(theReadTimer); }); #endif dispatch_time_t tt = dispatch_time(DISPATCH_TIME_NOW, (timeout * NSEC_PER_SEC)); dispatch_source_set_timer(readTimer, tt, DISPATCH_TIME_FOREVER, 0); dispatch_resume(readTimer); } } - (void)doReadTimeout { // This is a little bit tricky. // Ideally we'd like to synchronously query the delegate about a timeout extension. // But if we do so synchronously we risk a possible deadlock. // So instead we have to do so asynchronously, and callback to ourselves from within the delegate block. flags |= kReadsPaused; if (delegateQueue && [delegate respondsToSelector:@selector(socket:shouldTimeoutReadWithTag:elapsed:bytesDone:)]) { __strong id theDelegate = delegate; GCDAsyncReadPacket *theRead = currentRead; dispatch_async(delegateQueue, ^{ @autoreleasepool { NSTimeInterval timeoutExtension = 0.0; timeoutExtension = [theDelegate socket:self shouldTimeoutReadWithTag:theRead->tag elapsed:theRead->timeout bytesDone:theRead->bytesDone]; dispatch_async(socketQueue, ^{ @autoreleasepool { [self doReadTimeoutWithExtension:timeoutExtension]; }}); }}); } else { [self doReadTimeoutWithExtension:0.0]; } } - (void)doReadTimeoutWithExtension:(NSTimeInterval)timeoutExtension { if (currentRead) { if (timeoutExtension > 0.0) { currentRead->timeout += timeoutExtension; // Reschedule the timer dispatch_time_t tt = dispatch_time(DISPATCH_TIME_NOW, (timeoutExtension * NSEC_PER_SEC)); dispatch_source_set_timer(readTimer, tt, DISPATCH_TIME_FOREVER, 0); // Unpause reads, and continue flags &= ~kReadsPaused; [self doReadData]; } else { LogVerbose(@"ReadTimeout"); [self closeWithError:[self readTimeoutError]]; } } } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Writing //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// - (void)writeData:(NSData *)data withTimeout:(NSTimeInterval)timeout tag:(long)tag { if ([data length] == 0) return; GCDAsyncWritePacket *packet = [[GCDAsyncWritePacket alloc] initWithData:data timeout:timeout tag:tag]; dispatch_async(socketQueue, ^{ @autoreleasepool { LogTrace(); if ((flags & kSocketStarted) && !(flags & kForbidReadsWrites)) { [writeQueue addObject:packet]; [self maybeDequeueWrite]; } }}); // Do not rely on the block being run in order to release the packet, // as the queue might get released without the block completing. } - (float)progressOfWriteReturningTag:(long *)tagPtr bytesDone:(NSUInteger *)donePtr total:(NSUInteger *)totalPtr { __block float result = 0.0F; dispatch_block_t block = ^{ if (!currentWrite || ![currentWrite isKindOfClass:[GCDAsyncWritePacket class]]) { // We're not writing anything right now. if (tagPtr != NULL) *tagPtr = 0; if (donePtr != NULL) *donePtr = 0; if (totalPtr != NULL) *totalPtr = 0; result = NAN; } else { NSUInteger done = currentWrite->bytesDone; NSUInteger total = [currentWrite->buffer length]; if (tagPtr != NULL) *tagPtr = currentWrite->tag; if (donePtr != NULL) *donePtr = done; if (totalPtr != NULL) *totalPtr = total; result = (float)done / (float)total; } }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); return result; } /** * Conditionally starts a new write. * * It is called when: * - a user requests a write * - after a write request has finished (to handle the next request) * - immediately after the socket opens to handle any pending requests * * This method also handles auto-disconnect post read/write completion. **/ - (void)maybeDequeueWrite { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); // If we're not currently processing a write AND we have an available write stream if ((currentWrite == nil) && (flags & kConnected)) { if ([writeQueue count] > 0) { // Dequeue the next object in the write queue currentWrite = [writeQueue objectAtIndex:0]; [writeQueue removeObjectAtIndex:0]; if ([currentWrite isKindOfClass:[GCDAsyncSpecialPacket class]]) { LogVerbose(@"Dequeued GCDAsyncSpecialPacket"); // Attempt to start TLS flags |= kStartingWriteTLS; // This method won't do anything unless both kStartingReadTLS and kStartingWriteTLS are set [self maybeStartTLS]; } else { LogVerbose(@"Dequeued GCDAsyncWritePacket"); // Setup write timer (if needed) [self setupWriteTimerWithTimeout:currentWrite->timeout]; // Immediately write, if possible [self doWriteData]; } } else if (flags & kDisconnectAfterWrites) { if (flags & kDisconnectAfterReads) { if (([readQueue count] == 0) && (currentRead == nil)) { [self closeWithError:nil]; } } else { [self closeWithError:nil]; } } } } - (void)doWriteData { LogTrace(); // This method is called by the writeSource via the socketQueue if ((currentWrite == nil) || (flags & kWritesPaused)) { LogVerbose(@"No currentWrite or kWritesPaused"); // Unable to write at this time if ([self usingCFStreamForTLS]) { // CFWriteStream only fires once when there is available data. // It won't fire again until we've invoked CFWriteStreamWrite. } else { // If the writeSource is firing, we need to pause it // or else it will continue to fire over and over again. if (flags & kSocketCanAcceptBytes) { [self suspendWriteSource]; } } return; } if (!(flags & kSocketCanAcceptBytes)) { LogVerbose(@"No space available to write..."); // No space available to write. if (![self usingCFStreamForTLS]) { // Need to wait for writeSource to fire and notify us of // available space in the socket's internal write buffer. [self resumeWriteSource]; } return; } if (flags & kStartingWriteTLS) { LogVerbose(@"Waiting for SSL/TLS handshake to complete"); // The writeQueue is waiting for SSL/TLS handshake to complete. if (flags & kStartingReadTLS) { if ([self usingSecureTransportForTLS]) { #if SECURE_TRANSPORT_MAYBE_AVAILABLE // We are in the process of a SSL Handshake. // We were waiting for available space in the socket's internal OS buffer to continue writing. [self ssl_continueSSLHandshake]; #endif } } else { // We are still waiting for the readQueue to drain and start the SSL/TLS process. // We now know we can write to the socket. if (![self usingCFStreamForTLS]) { // Suspend the write source or else it will continue to fire nonstop. [self suspendWriteSource]; } } return; } // Note: This method is not called if currentWrite is a GCDAsyncSpecialPacket (startTLS packet) BOOL waiting = NO; NSError *error = nil; size_t bytesWritten = 0; if (flags & kSocketSecure) { if ([self usingCFStreamForTLS]) { #if TARGET_OS_IPHONE // // Writing data using CFStream (over internal TLS) // const uint8_t *buffer = (const uint8_t *)[currentWrite->buffer bytes] + currentWrite->bytesDone; NSUInteger bytesToWrite = [currentWrite->buffer length] - currentWrite->bytesDone; if (bytesToWrite > SIZE_MAX) // NSUInteger may be bigger than size_t (write param 3) { bytesToWrite = SIZE_MAX; } CFIndex result = CFWriteStreamWrite(writeStream, buffer, (CFIndex)bytesToWrite); LogVerbose(@"CFWriteStreamWrite(%lu) = %li", (unsigned long)bytesToWrite, result); if (result < 0) { error = (__bridge_transfer NSError *)CFWriteStreamCopyError(writeStream); } else { bytesWritten = (size_t)result; // We always set waiting to true in this scenario. // CFStream may have altered our underlying socket to non-blocking. // Thus if we attempt to write without a callback, we may end up blocking our queue. waiting = YES; } #endif } else { #if SECURE_TRANSPORT_MAYBE_AVAILABLE // We're going to use the SSLWrite function. // // OSStatus SSLWrite(SSLContextRef context, const void *data, size_t dataLength, size_t *processed) // // Parameters: // context - An SSL session context reference. // data - A pointer to the buffer of data to write. // dataLength - The amount, in bytes, of data to write. // processed - On return, the length, in bytes, of the data actually written. // // It sounds pretty straight-forward, // but there are a few caveats you should be aware of. // // The SSLWrite method operates in a non-obvious (and rather annoying) manner. // According to the documentation: // // Because you may configure the underlying connection to operate in a non-blocking manner, // a write operation might return errSSLWouldBlock, indicating that less data than requested // was actually transferred. In this case, you should repeat the call to SSLWrite until some // other result is returned. // // This sounds perfect, but when our SSLWriteFunction returns errSSLWouldBlock, // then the SSLWrite method returns (with the proper errSSLWouldBlock return value), // but it sets processed to dataLength !! // // In other words, if the SSLWrite function doesn't completely write all the data we tell it to, // then it doesn't tell us how many bytes were actually written. So, for example, if we tell it to // write 256 bytes then it might actually write 128 bytes, but then report 0 bytes written. // // You might be wondering: // If the SSLWrite function doesn't tell us how many bytes were written, // then how in the world are we supposed to update our parameters (buffer & bytesToWrite) // for the next time we invoke SSLWrite? // // The answer is that SSLWrite cached all the data we told it to write, // and it will push out that data next time we call SSLWrite. // If we call SSLWrite with new data, it will push out the cached data first, and then the new data. // If we call SSLWrite with empty data, then it will simply push out the cached data. // // For this purpose we're going to break large writes into a series of smaller writes. // This allows us to report progress back to the delegate. OSStatus result; BOOL hasCachedDataToWrite = (sslWriteCachedLength > 0); BOOL hasNewDataToWrite = YES; if (hasCachedDataToWrite) { size_t processed = 0; result = SSLWrite(sslContext, NULL, 0, &processed); if (result == noErr) { bytesWritten = sslWriteCachedLength; sslWriteCachedLength = 0; if ([currentWrite->buffer length] == (currentWrite->bytesDone + bytesWritten)) { // We've written all data for the current write. hasNewDataToWrite = NO; } } else { if (result == errSSLWouldBlock) { waiting = YES; } else { error = [self sslError:result]; } // Can't write any new data since we were unable to write the cached data. hasNewDataToWrite = NO; } } if (hasNewDataToWrite) { const uint8_t *buffer = (const uint8_t *)[currentWrite->buffer bytes] + currentWrite->bytesDone + bytesWritten; NSUInteger bytesToWrite = [currentWrite->buffer length] - currentWrite->bytesDone - bytesWritten; if (bytesToWrite > SIZE_MAX) // NSUInteger may be bigger than size_t (write param 3) { bytesToWrite = SIZE_MAX; } size_t bytesRemaining = bytesToWrite; BOOL keepLooping = YES; while (keepLooping) { size_t sslBytesToWrite = MIN(bytesRemaining, 32768); size_t sslBytesWritten = 0; result = SSLWrite(sslContext, buffer, sslBytesToWrite, &sslBytesWritten); if (result == noErr) { buffer += sslBytesWritten; bytesWritten += sslBytesWritten; bytesRemaining -= sslBytesWritten; keepLooping = (bytesRemaining > 0); } else { if (result == errSSLWouldBlock) { waiting = YES; sslWriteCachedLength = sslBytesToWrite; } else { error = [self sslError:result]; } keepLooping = NO; } } // while (keepLooping) } // if (hasNewDataToWrite) #endif } } else { // // Writing data directly over raw socket // int socketFD = (socket4FD == SOCKET_NULL) ? socket6FD : socket4FD; const uint8_t *buffer = (const uint8_t *)[currentWrite->buffer bytes] + currentWrite->bytesDone; NSUInteger bytesToWrite = [currentWrite->buffer length] - currentWrite->bytesDone; if (bytesToWrite > SIZE_MAX) // NSUInteger may be bigger than size_t (write param 3) { bytesToWrite = SIZE_MAX; } ssize_t result = write(socketFD, buffer, (size_t)bytesToWrite); LogVerbose(@"wrote to socket = %zd", result); // Check results if (result < 0) { if (errno == EWOULDBLOCK) { waiting = YES; } else { error = [self errnoErrorWithReason:@"Error in write() function"]; } } else { bytesWritten = result; } } // We're done with our writing. // If we explictly ran into a situation where the socket told us there was no room in the buffer, // then we immediately resume listening for notifications. // // We must do this before we dequeue another write, // as that may in turn invoke this method again. // // Note that if CFStream is involved, it may have maliciously put our socket in blocking mode. if (waiting) { flags &= ~kSocketCanAcceptBytes; if (![self usingCFStreamForTLS]) { [self resumeWriteSource]; } } // Check our results BOOL done = NO; if (bytesWritten > 0) { // Update total amount read for the current write currentWrite->bytesDone += bytesWritten; LogVerbose(@"currentWrite->bytesDone = %lu", (unsigned long)currentWrite->bytesDone); // Is packet done? done = (currentWrite->bytesDone == [currentWrite->buffer length]); } if (done) { [self completeCurrentWrite]; if (!error) { [self maybeDequeueWrite]; } } else { // We were unable to finish writing the data, // so we're waiting for another callback to notify us of available space in the lower-level output buffer. if (!waiting & !error) { // This would be the case if our write was able to accept some data, but not all of it. flags &= ~kSocketCanAcceptBytes; if (![self usingCFStreamForTLS]) { [self resumeWriteSource]; } } if (bytesWritten > 0) { // We're not done with the entire write, but we have written some bytes if (delegateQueue && [delegate respondsToSelector:@selector(socket:didWritePartialDataOfLength:tag:)]) { __strong id theDelegate = delegate; long theWriteTag = currentWrite->tag; dispatch_async(delegateQueue, ^{ @autoreleasepool { [theDelegate socket:self didWritePartialDataOfLength:bytesWritten tag:theWriteTag]; }}); } } } // Check for errors if (error) { [self closeWithError:[self errnoErrorWithReason:@"Error in write() function"]]; } // Do not add any code here without first adding a return statement in the error case above. } - (void)completeCurrentWrite { LogTrace(); NSAssert(currentWrite, @"Trying to complete current write when there is no current write."); if (delegateQueue && [delegate respondsToSelector:@selector(socket:didWriteDataWithTag:)]) { __strong id theDelegate = delegate; long theWriteTag = currentWrite->tag; dispatch_async(delegateQueue, ^{ @autoreleasepool { [theDelegate socket:self didWriteDataWithTag:theWriteTag]; }}); } [self endCurrentWrite]; } - (void)endCurrentWrite { if (writeTimer) { dispatch_source_cancel(writeTimer); writeTimer = NULL; } currentWrite = nil; } - (void)setupWriteTimerWithTimeout:(NSTimeInterval)timeout { if (timeout >= 0.0) { writeTimer = dispatch_source_create(DISPATCH_SOURCE_TYPE_TIMER, 0, 0, socketQueue); dispatch_source_set_event_handler(writeTimer, ^{ @autoreleasepool { [self doWriteTimeout]; }}); #if NEEDS_DISPATCH_RETAIN_RELEASE dispatch_source_t theWriteTimer = writeTimer; dispatch_source_set_cancel_handler(writeTimer, ^{ LogVerbose(@"dispatch_release(writeTimer)"); dispatch_release(theWriteTimer); }); #endif dispatch_time_t tt = dispatch_time(DISPATCH_TIME_NOW, (timeout * NSEC_PER_SEC)); dispatch_source_set_timer(writeTimer, tt, DISPATCH_TIME_FOREVER, 0); dispatch_resume(writeTimer); } } - (void)doWriteTimeout { // This is a little bit tricky. // Ideally we'd like to synchronously query the delegate about a timeout extension. // But if we do so synchronously we risk a possible deadlock. // So instead we have to do so asynchronously, and callback to ourselves from within the delegate block. flags |= kWritesPaused; if (delegateQueue && [delegate respondsToSelector:@selector(socket:shouldTimeoutWriteWithTag:elapsed:bytesDone:)]) { __strong id theDelegate = delegate; GCDAsyncWritePacket *theWrite = currentWrite; dispatch_async(delegateQueue, ^{ @autoreleasepool { NSTimeInterval timeoutExtension = 0.0; timeoutExtension = [theDelegate socket:self shouldTimeoutWriteWithTag:theWrite->tag elapsed:theWrite->timeout bytesDone:theWrite->bytesDone]; dispatch_async(socketQueue, ^{ @autoreleasepool { [self doWriteTimeoutWithExtension:timeoutExtension]; }}); }}); } else { [self doWriteTimeoutWithExtension:0.0]; } } - (void)doWriteTimeoutWithExtension:(NSTimeInterval)timeoutExtension { if (currentWrite) { if (timeoutExtension > 0.0) { currentWrite->timeout += timeoutExtension; // Reschedule the timer dispatch_time_t tt = dispatch_time(DISPATCH_TIME_NOW, (timeoutExtension * NSEC_PER_SEC)); dispatch_source_set_timer(writeTimer, tt, DISPATCH_TIME_FOREVER, 0); // Unpause writes, and continue flags &= ~kWritesPaused; [self doWriteData]; } else { LogVerbose(@"WriteTimeout"); [self closeWithError:[self writeTimeoutError]]; } } } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Security //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// - (void)startTLS:(NSDictionary *)tlsSettings { LogTrace(); if (tlsSettings == nil) { // Passing nil/NULL to CFReadStreamSetProperty will appear to work the same as passing an empty dictionary, // but causes problems if we later try to fetch the remote host's certificate. // // To be exact, it causes the following to return NULL instead of the normal result: // CFReadStreamCopyProperty(readStream, kCFStreamPropertySSLPeerCertificates) // // So we use an empty dictionary instead, which works perfectly. tlsSettings = [NSDictionary dictionary]; } GCDAsyncSpecialPacket *packet = [[GCDAsyncSpecialPacket alloc] initWithTLSSettings:tlsSettings]; dispatch_async(socketQueue, ^{ @autoreleasepool { if ((flags & kSocketStarted) && !(flags & kQueuedTLS) && !(flags & kForbidReadsWrites)) { [readQueue addObject:packet]; [writeQueue addObject:packet]; flags |= kQueuedTLS; [self maybeDequeueRead]; [self maybeDequeueWrite]; } }}); } - (void)maybeStartTLS { // We can't start TLS until: // - All queued reads prior to the user calling startTLS are complete // - All queued writes prior to the user calling startTLS are complete // // We'll know these conditions are met when both kStartingReadTLS and kStartingWriteTLS are set if ((flags & kStartingReadTLS) && (flags & kStartingWriteTLS)) { BOOL canUseSecureTransport = YES; #if TARGET_OS_IPHONE { GCDAsyncSpecialPacket *tlsPacket = (GCDAsyncSpecialPacket *)currentRead; NSDictionary *tlsSettings = tlsPacket->tlsSettings; NSNumber *value; value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLAllowsAnyRoot]; if (value && [value boolValue] == YES) canUseSecureTransport = NO; value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLAllowsExpiredRoots]; if (value && [value boolValue] == YES) canUseSecureTransport = NO; value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLValidatesCertificateChain]; if (value && [value boolValue] == NO) canUseSecureTransport = NO; value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLAllowsExpiredCertificates]; if (value && [value boolValue] == YES) canUseSecureTransport = NO; } #endif if (IS_SECURE_TRANSPORT_AVAILABLE && canUseSecureTransport) { #if SECURE_TRANSPORT_MAYBE_AVAILABLE [self ssl_startTLS]; #endif } else { #if TARGET_OS_IPHONE [self cf_startTLS]; #endif } } } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Security via SecureTransport //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #if SECURE_TRANSPORT_MAYBE_AVAILABLE - (OSStatus)sslReadWithBuffer:(void *)buffer length:(size_t *)bufferLength { LogVerbose(@"sslReadWithBuffer:%p length:%lu", buffer, (unsigned long)*bufferLength); if ((socketFDBytesAvailable == 0) && ([sslPreBuffer availableBytes] == 0)) { LogVerbose(@"%@ - No data available to read...", THIS_METHOD); // No data available to read. // // Need to wait for readSource to fire and notify us of // available data in the socket's internal read buffer. [self resumeReadSource]; *bufferLength = 0; return errSSLWouldBlock; } size_t totalBytesRead = 0; size_t totalBytesLeftToBeRead = *bufferLength; BOOL done = NO; BOOL socketError = NO; // // STEP 1 : READ FROM SSL PRE BUFFER // size_t sslPreBufferLength = [sslPreBuffer availableBytes]; if (sslPreBufferLength > 0) { LogVerbose(@"%@: Reading from SSL pre buffer...", THIS_METHOD); size_t bytesToCopy; if (sslPreBufferLength > totalBytesLeftToBeRead) bytesToCopy = totalBytesLeftToBeRead; else bytesToCopy = sslPreBufferLength; LogVerbose(@"%@: Copying %zu bytes from sslPreBuffer", THIS_METHOD, bytesToCopy); memcpy(buffer, [sslPreBuffer readBuffer], bytesToCopy); [sslPreBuffer didRead:bytesToCopy]; LogVerbose(@"%@: sslPreBuffer.length = %zu", THIS_METHOD, [sslPreBuffer availableBytes]); totalBytesRead += bytesToCopy; totalBytesLeftToBeRead -= bytesToCopy; done = (totalBytesLeftToBeRead == 0); if (done) LogVerbose(@"%@: Complete", THIS_METHOD); } // // STEP 2 : READ FROM SOCKET // if (!done && (socketFDBytesAvailable > 0)) { LogVerbose(@"%@: Reading from socket...", THIS_METHOD); int socketFD = (socket6FD == SOCKET_NULL) ? socket4FD : socket6FD; BOOL readIntoPreBuffer; size_t bytesToRead; uint8_t *buf; if (socketFDBytesAvailable > totalBytesLeftToBeRead) { // Read all available data from socket into sslPreBuffer. // Then copy requested amount into dataBuffer. LogVerbose(@"%@: Reading into sslPreBuffer...", THIS_METHOD); [sslPreBuffer ensureCapacityForWrite:socketFDBytesAvailable]; readIntoPreBuffer = YES; bytesToRead = (size_t)socketFDBytesAvailable; buf = [sslPreBuffer writeBuffer]; } else { // Read available data from socket directly into dataBuffer. LogVerbose(@"%@: Reading directly into dataBuffer...", THIS_METHOD); readIntoPreBuffer = NO; bytesToRead = totalBytesLeftToBeRead; buf = (uint8_t *)buffer + totalBytesRead; } ssize_t result = read(socketFD, buf, bytesToRead); LogVerbose(@"%@: read from socket = %zd", THIS_METHOD, result); if (result < 0) { LogVerbose(@"%@: read errno = %i", THIS_METHOD, errno); if (errno != EWOULDBLOCK) { socketError = YES; } socketFDBytesAvailable = 0; } else if (result == 0) { LogVerbose(@"%@: read EOF", THIS_METHOD); socketError = YES; socketFDBytesAvailable = 0; } else { size_t bytesReadFromSocket = result; if (socketFDBytesAvailable > bytesReadFromSocket) socketFDBytesAvailable -= bytesReadFromSocket; else socketFDBytesAvailable = 0; if (readIntoPreBuffer) { [sslPreBuffer didWrite:bytesReadFromSocket]; size_t bytesToCopy = MIN(totalBytesLeftToBeRead, bytesReadFromSocket); LogVerbose(@"%@: Copying %zu bytes out of sslPreBuffer", THIS_METHOD, bytesToCopy); memcpy((uint8_t *)buffer + totalBytesRead, [sslPreBuffer readBuffer], bytesToCopy); [sslPreBuffer didRead:bytesToCopy]; totalBytesRead += bytesToCopy; totalBytesLeftToBeRead -= bytesToCopy; LogVerbose(@"%@: sslPreBuffer.length = %zu", THIS_METHOD, [sslPreBuffer availableBytes]); } else { totalBytesRead += bytesReadFromSocket; totalBytesLeftToBeRead -= bytesReadFromSocket; } done = (totalBytesLeftToBeRead == 0); if (done) LogVerbose(@"%@: Complete", THIS_METHOD); } } *bufferLength = totalBytesRead; if (done) return noErr; if (socketError) return errSSLClosedAbort; return errSSLWouldBlock; } - (OSStatus)sslWriteWithBuffer:(const void *)buffer length:(size_t *)bufferLength { if (!(flags & kSocketCanAcceptBytes)) { // Unable to write. // // Need to wait for writeSource to fire and notify us of // available space in the socket's internal write buffer. [self resumeWriteSource]; *bufferLength = 0; return errSSLWouldBlock; } size_t bytesToWrite = *bufferLength; size_t bytesWritten = 0; BOOL done = NO; BOOL socketError = NO; int socketFD = (socket4FD == SOCKET_NULL) ? socket6FD : socket4FD; ssize_t result = write(socketFD, buffer, bytesToWrite); if (result < 0) { if (errno != EWOULDBLOCK) { socketError = YES; } flags &= ~kSocketCanAcceptBytes; } else if (result == 0) { flags &= ~kSocketCanAcceptBytes; } else { bytesWritten = result; done = (bytesWritten == bytesToWrite); } *bufferLength = bytesWritten; if (done) return noErr; if (socketError) return errSSLClosedAbort; return errSSLWouldBlock; } static OSStatus SSLReadFunction(SSLConnectionRef connection, void *data, size_t *dataLength) { GCDAsyncSocket *asyncSocket = (__bridge GCDAsyncSocket *)connection; NSCAssert(dispatch_get_specific(asyncSocket->IsOnSocketQueueOrTargetQueueKey), @"What the deuce?"); return [asyncSocket sslReadWithBuffer:data length:dataLength]; } static OSStatus SSLWriteFunction(SSLConnectionRef connection, const void *data, size_t *dataLength) { GCDAsyncSocket *asyncSocket = (__bridge GCDAsyncSocket *)connection; NSCAssert(dispatch_get_specific(asyncSocket->IsOnSocketQueueOrTargetQueueKey), @"What the deuce?"); return [asyncSocket sslWriteWithBuffer:data length:dataLength]; } - (void)ssl_startTLS { LogTrace(); LogVerbose(@"Starting TLS (via SecureTransport)..."); OSStatus status; GCDAsyncSpecialPacket *tlsPacket = (GCDAsyncSpecialPacket *)currentRead; NSDictionary *tlsSettings = tlsPacket->tlsSettings; // Create SSLContext, and setup IO callbacks and connection ref BOOL isServer = [[tlsSettings objectForKey:(NSString *)kCFStreamSSLIsServer] boolValue]; #if TARGET_OS_IPHONE { if (isServer) sslContext = SSLCreateContext(kCFAllocatorDefault, kSSLServerSide, kSSLStreamType); else sslContext = SSLCreateContext(kCFAllocatorDefault, kSSLClientSide, kSSLStreamType); if (sslContext == NULL) { [self closeWithError:[self otherError:@"Error in SSLCreateContext"]]; return; } } #else { status = SSLNewContext(isServer, &sslContext); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLNewContext"]]; return; } } #endif status = SSLSetIOFuncs(sslContext, &SSLReadFunction, &SSLWriteFunction); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetIOFuncs"]]; return; } status = SSLSetConnection(sslContext, (__bridge SSLConnectionRef)self); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetConnection"]]; return; } // Configure SSLContext from given settings // // Checklist: // 1. kCFStreamSSLPeerName // 2. kCFStreamSSLAllowsAnyRoot // 3. kCFStreamSSLAllowsExpiredRoots // 4. kCFStreamSSLValidatesCertificateChain // 5. kCFStreamSSLAllowsExpiredCertificates // 6. kCFStreamSSLCertificates // 7. kCFStreamSSLLevel (GCDAsyncSocketSSLProtocolVersionMin / GCDAsyncSocketSSLProtocolVersionMax) // 8. GCDAsyncSocketSSLCipherSuites // 9. GCDAsyncSocketSSLDiffieHellmanParameters (Mac) id value; // 1. kCFStreamSSLPeerName value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLPeerName]; if ([value isKindOfClass:[NSString class]]) { NSString *peerName = (NSString *)value; const char *peer = [peerName UTF8String]; size_t peerLen = strlen(peer); status = SSLSetPeerDomainName(sslContext, peer, peerLen); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetPeerDomainName"]]; return; } } // 2. kCFStreamSSLAllowsAnyRoot value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLAllowsAnyRoot]; if (value) { #if TARGET_OS_IPHONE NSAssert(NO, @"Security option unavailable via SecureTransport in iOS - kCFStreamSSLAllowsAnyRoot"); #else BOOL allowsAnyRoot = [value boolValue]; status = SSLSetAllowsAnyRoot(sslContext, allowsAnyRoot); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetAllowsAnyRoot"]]; return; } #endif } // 3. kCFStreamSSLAllowsExpiredRoots value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLAllowsExpiredRoots]; if (value) { #if TARGET_OS_IPHONE NSAssert(NO, @"Security option unavailable via SecureTransport in iOS - kCFStreamSSLAllowsExpiredRoots"); #else BOOL allowsExpiredRoots = [value boolValue]; status = SSLSetAllowsExpiredRoots(sslContext, allowsExpiredRoots); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetAllowsExpiredRoots"]]; return; } #endif } // 4. kCFStreamSSLValidatesCertificateChain value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLValidatesCertificateChain]; if (value) { #if TARGET_OS_IPHONE NSAssert(NO, @"Security option unavailable via SecureTransport in iOS - kCFStreamSSLValidatesCertificateChain"); #else BOOL validatesCertChain = [value boolValue]; status = SSLSetEnableCertVerify(sslContext, validatesCertChain); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetEnableCertVerify"]]; return; } #endif } // 5. kCFStreamSSLAllowsExpiredCertificates value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLAllowsExpiredCertificates]; if (value) { #if TARGET_OS_IPHONE NSAssert(NO, @"Security option unavailable via SecureTransport in iOS - kCFStreamSSLAllowsExpiredCertificates"); #else BOOL allowsExpiredCerts = [value boolValue]; status = SSLSetAllowsExpiredCerts(sslContext, allowsExpiredCerts); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetAllowsExpiredCerts"]]; return; } #endif } // 6. kCFStreamSSLCertificates value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLCertificates]; if (value) { CFArrayRef certs = (__bridge CFArrayRef)value; status = SSLSetCertificate(sslContext, certs); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetCertificate"]]; return; } } // 7. kCFStreamSSLLevel #if TARGET_OS_IPHONE { NSString *sslLevel = [tlsSettings objectForKey:(NSString *)kCFStreamSSLLevel]; NSString *sslMinLevel = [tlsSettings objectForKey:GCDAsyncSocketSSLProtocolVersionMin]; NSString *sslMaxLevel = [tlsSettings objectForKey:GCDAsyncSocketSSLProtocolVersionMax]; if (sslLevel) { if (sslMinLevel || sslMaxLevel) { LogWarn(@"kCFStreamSSLLevel security option ignored. Overriden by " @"GCDAsyncSocketSSLProtocolVersionMin and/or GCDAsyncSocketSSLProtocolVersionMax"); } else { if ([sslLevel isEqualToString:(NSString *)kCFStreamSocketSecurityLevelSSLv3]) { sslMinLevel = sslMaxLevel = @"kSSLProtocol3"; } else if ([sslLevel isEqualToString:(NSString *)kCFStreamSocketSecurityLevelTLSv1]) { sslMinLevel = sslMaxLevel = @"kTLSProtocol1"; } else { LogWarn(@"Unable to match kCFStreamSSLLevel security option to valid SSL protocol min/max"); } } } if (sslMinLevel || sslMaxLevel) { OSStatus status1 = noErr; OSStatus status2 = noErr; SSLProtocol (^sslProtocolForString)(NSString*) = ^SSLProtocol (NSString *protocolStr) { if ([protocolStr isEqualToString:@"kSSLProtocol3"]) return kSSLProtocol3; if ([protocolStr isEqualToString:@"kTLSProtocol1"]) return kTLSProtocol1; if ([protocolStr isEqualToString:@"kTLSProtocol11"]) return kTLSProtocol11; if ([protocolStr isEqualToString:@"kTLSProtocol12"]) return kTLSProtocol12; return kSSLProtocolUnknown; }; SSLProtocol minProtocol = sslProtocolForString(sslMinLevel); SSLProtocol maxProtocol = sslProtocolForString(sslMaxLevel); if (minProtocol != kSSLProtocolUnknown) { status1 = SSLSetProtocolVersionMin(sslContext, minProtocol); } if (maxProtocol != kSSLProtocolUnknown) { status2 = SSLSetProtocolVersionMax(sslContext, maxProtocol); } if (status1 != noErr || status2 != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetProtocolVersionMinMax"]]; return; } } } #else { value = [tlsSettings objectForKey:(NSString *)kCFStreamSSLLevel]; if (value) { NSString *sslLevel = (NSString *)value; OSStatus status1 = noErr; OSStatus status2 = noErr; OSStatus status3 = noErr; if ([sslLevel isEqualToString:(NSString *)kCFStreamSocketSecurityLevelSSLv2]) { // kCFStreamSocketSecurityLevelSSLv2: // // Specifies that SSL version 2 be set as the security protocol. status1 = SSLSetProtocolVersionEnabled(sslContext, kSSLProtocolAll, NO); status2 = SSLSetProtocolVersionEnabled(sslContext, kSSLProtocol2, YES); } else if ([sslLevel isEqualToString:(NSString *)kCFStreamSocketSecurityLevelSSLv3]) { // kCFStreamSocketSecurityLevelSSLv3: // // Specifies that SSL version 3 be set as the security protocol. // If SSL version 3 is not available, specifies that SSL version 2 be set as the security protocol. status1 = SSLSetProtocolVersionEnabled(sslContext, kSSLProtocolAll, NO); status2 = SSLSetProtocolVersionEnabled(sslContext, kSSLProtocol2, YES); status3 = SSLSetProtocolVersionEnabled(sslContext, kSSLProtocol3, YES); } else if ([sslLevel isEqualToString:(NSString *)kCFStreamSocketSecurityLevelTLSv1]) { // kCFStreamSocketSecurityLevelTLSv1: // // Specifies that TLS version 1 be set as the security protocol. status1 = SSLSetProtocolVersionEnabled(sslContext, kSSLProtocolAll, NO); status2 = SSLSetProtocolVersionEnabled(sslContext, kTLSProtocol1, YES); } else if ([sslLevel isEqualToString:(NSString *)kCFStreamSocketSecurityLevelNegotiatedSSL]) { // kCFStreamSocketSecurityLevelNegotiatedSSL: // // Specifies that the highest level security protocol that can be negotiated be used. status1 = SSLSetProtocolVersionEnabled(sslContext, kSSLProtocolAll, YES); } if (status1 != noErr || status2 != noErr || status3 != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetProtocolVersionEnabled"]]; return; } } } #endif // 8. GCDAsyncSocketSSLCipherSuites value = [tlsSettings objectForKey:GCDAsyncSocketSSLCipherSuites]; if (value) { NSArray *cipherSuites = (NSArray *)value; NSUInteger numberCiphers = [cipherSuites count]; SSLCipherSuite ciphers[numberCiphers]; NSUInteger cipherIndex; for (cipherIndex = 0; cipherIndex < numberCiphers; cipherIndex++) { NSNumber *cipherObject = [cipherSuites objectAtIndex:cipherIndex]; ciphers[cipherIndex] = [cipherObject shortValue]; } status = SSLSetEnabledCiphers(sslContext, ciphers, numberCiphers); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetEnabledCiphers"]]; return; } } // 9. GCDAsyncSocketSSLDiffieHellmanParameters #if !TARGET_OS_IPHONE value = [tlsSettings objectForKey:GCDAsyncSocketSSLDiffieHellmanParameters]; if (value) { NSData *diffieHellmanData = (NSData *)value; status = SSLSetDiffieHellmanParams(sslContext, [diffieHellmanData bytes], [diffieHellmanData length]); if (status != noErr) { [self closeWithError:[self otherError:@"Error in SSLSetDiffieHellmanParams"]]; return; } } #endif // Setup the sslPreBuffer // // Any data in the preBuffer needs to be moved into the sslPreBuffer, // as this data is now part of the secure read stream. sslPreBuffer = [[GCDAsyncSocketPreBuffer alloc] initWithCapacity:(1024 * 4)]; size_t preBufferLength = [preBuffer availableBytes]; if (preBufferLength > 0) { [sslPreBuffer ensureCapacityForWrite:preBufferLength]; memcpy([sslPreBuffer writeBuffer], [preBuffer readBuffer], preBufferLength); [preBuffer didRead:preBufferLength]; [sslPreBuffer didWrite:preBufferLength]; } sslErrCode = noErr; // Start the SSL Handshake process [self ssl_continueSSLHandshake]; } - (void)ssl_continueSSLHandshake { LogTrace(); // If the return value is noErr, the session is ready for normal secure communication. // If the return value is errSSLWouldBlock, the SSLHandshake function must be called again. // Otherwise, the return value indicates an error code. OSStatus status = SSLHandshake(sslContext); if (status == noErr) { LogVerbose(@"SSLHandshake complete"); flags &= ~kStartingReadTLS; flags &= ~kStartingWriteTLS; flags |= kSocketSecure; if (delegateQueue && [delegate respondsToSelector:@selector(socketDidSecure:)]) { __strong id theDelegate = delegate; dispatch_async(delegateQueue, ^{ @autoreleasepool { [theDelegate socketDidSecure:self]; }}); } [self endCurrentRead]; [self endCurrentWrite]; [self maybeDequeueRead]; [self maybeDequeueWrite]; } else if (status == errSSLWouldBlock) { LogVerbose(@"SSLHandshake continues..."); // Handshake continues... // // This method will be called again from doReadData or doWriteData. } else { [self closeWithError:[self sslError:status]]; } } #endif //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Security via CFStream //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #if TARGET_OS_IPHONE - (void)cf_finishSSLHandshake { LogTrace(); if ((flags & kStartingReadTLS) && (flags & kStartingWriteTLS)) { flags &= ~kStartingReadTLS; flags &= ~kStartingWriteTLS; flags |= kSocketSecure; if (delegateQueue && [delegate respondsToSelector:@selector(socketDidSecure:)]) { __strong id theDelegate = delegate; dispatch_async(delegateQueue, ^{ @autoreleasepool { [theDelegate socketDidSecure:self]; }}); } [self endCurrentRead]; [self endCurrentWrite]; [self maybeDequeueRead]; [self maybeDequeueWrite]; } } - (void)cf_abortSSLHandshake:(NSError *)error { LogTrace(); if ((flags & kStartingReadTLS) && (flags & kStartingWriteTLS)) { flags &= ~kStartingReadTLS; flags &= ~kStartingWriteTLS; [self closeWithError:error]; } } - (void)cf_startTLS { LogTrace(); LogVerbose(@"Starting TLS (via CFStream)..."); if ([preBuffer availableBytes] > 0) { NSString *msg = @"Invalid TLS transition. Handshake has already been read from socket."; [self closeWithError:[self otherError:msg]]; return; } [self suspendReadSource]; [self suspendWriteSource]; socketFDBytesAvailable = 0; flags &= ~kSocketCanAcceptBytes; flags &= ~kSecureSocketHasBytesAvailable; flags |= kUsingCFStreamForTLS; if (![self createReadAndWriteStream]) { [self closeWithError:[self otherError:@"Error in CFStreamCreatePairWithSocket"]]; return; } if (![self registerForStreamCallbacksIncludingReadWrite:YES]) { [self closeWithError:[self otherError:@"Error in CFStreamSetClient"]]; return; } if (![self addStreamsToRunLoop]) { [self closeWithError:[self otherError:@"Error in CFStreamScheduleWithRunLoop"]]; return; } NSAssert([currentRead isKindOfClass:[GCDAsyncSpecialPacket class]], @"Invalid read packet for startTLS"); NSAssert([currentWrite isKindOfClass:[GCDAsyncSpecialPacket class]], @"Invalid write packet for startTLS"); GCDAsyncSpecialPacket *tlsPacket = (GCDAsyncSpecialPacket *)currentRead; CFDictionaryRef tlsSettings = (__bridge CFDictionaryRef)tlsPacket->tlsSettings; // Getting an error concerning kCFStreamPropertySSLSettings ? // You need to add the CFNetwork framework to your iOS application. BOOL r1 = CFReadStreamSetProperty(readStream, kCFStreamPropertySSLSettings, tlsSettings); BOOL r2 = CFWriteStreamSetProperty(writeStream, kCFStreamPropertySSLSettings, tlsSettings); // For some reason, starting around the time of iOS 4.3, // the first call to set the kCFStreamPropertySSLSettings will return true, // but the second will return false. // // Order doesn't seem to matter. // So you could call CFReadStreamSetProperty and then CFWriteStreamSetProperty, or you could reverse the order. // Either way, the first call will return true, and the second returns false. // // Interestingly, this doesn't seem to affect anything. // Which is not altogether unusual, as the documentation seems to suggest that (for many settings) // setting it on one side of the stream automatically sets it for the other side of the stream. // // Although there isn't anything in the documentation to suggest that the second attempt would fail. // // Furthermore, this only seems to affect streams that are negotiating a security upgrade. // In other words, the socket gets connected, there is some back-and-forth communication over the unsecure // connection, and then a startTLS is issued. // So this mostly affects newer protocols (XMPP, IMAP) as opposed to older protocols (HTTPS). if (!r1 && !r2) // Yes, the && is correct - workaround for apple bug. { [self closeWithError:[self otherError:@"Error in CFStreamSetProperty"]]; return; } if (![self openStreams]) { [self closeWithError:[self otherError:@"Error in CFStreamOpen"]]; return; } LogVerbose(@"Waiting for SSL Handshake to complete..."); } #endif //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark CFStream //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #if TARGET_OS_IPHONE + (void)startCFStreamThreadIfNeeded { static dispatch_once_t predicate; dispatch_once(&predicate, ^{ cfstreamThread = [[NSThread alloc] initWithTarget:self selector:@selector(cfstreamThread) object:nil]; [cfstreamThread start]; }); } + (void)cfstreamThread { @autoreleasepool { [[NSThread currentThread] setName:GCDAsyncSocketThreadName]; LogInfo(@"CFStreamThread: Started"); // We can't run the run loop unless it has an associated input source or a timer. // So we'll just create a timer that will never fire - unless the server runs for decades. [NSTimer scheduledTimerWithTimeInterval:[[NSDate distantFuture] timeIntervalSinceNow] target:self selector:@selector(doNothingAtAll:) userInfo:nil repeats:YES]; [[NSRunLoop currentRunLoop] run]; LogInfo(@"CFStreamThread: Stopped"); }} + (void)scheduleCFStreams:(GCDAsyncSocket *)asyncSocket { LogTrace(); NSAssert([NSThread currentThread] == cfstreamThread, @"Invoked on wrong thread"); CFRunLoopRef runLoop = CFRunLoopGetCurrent(); if (asyncSocket->readStream) CFReadStreamScheduleWithRunLoop(asyncSocket->readStream, runLoop, kCFRunLoopDefaultMode); if (asyncSocket->writeStream) CFWriteStreamScheduleWithRunLoop(asyncSocket->writeStream, runLoop, kCFRunLoopDefaultMode); } + (void)unscheduleCFStreams:(GCDAsyncSocket *)asyncSocket { LogTrace(); NSAssert([NSThread currentThread] == cfstreamThread, @"Invoked on wrong thread"); CFRunLoopRef runLoop = CFRunLoopGetCurrent(); if (asyncSocket->readStream) CFReadStreamUnscheduleFromRunLoop(asyncSocket->readStream, runLoop, kCFRunLoopDefaultMode); if (asyncSocket->writeStream) CFWriteStreamUnscheduleFromRunLoop(asyncSocket->writeStream, runLoop, kCFRunLoopDefaultMode); } static void CFReadStreamCallback (CFReadStreamRef stream, CFStreamEventType type, void *pInfo) { GCDAsyncSocket *asyncSocket = (__bridge GCDAsyncSocket *)pInfo; switch(type) { case kCFStreamEventHasBytesAvailable: { dispatch_async(asyncSocket->socketQueue, ^{ @autoreleasepool { LogCVerbose(@"CFReadStreamCallback - HasBytesAvailable"); if (asyncSocket->readStream != stream) return_from_block; if ((asyncSocket->flags & kStartingReadTLS) && (asyncSocket->flags & kStartingWriteTLS)) { // If we set kCFStreamPropertySSLSettings before we opened the streams, this might be a lie. // (A callback related to the tcp stream, but not to the SSL layer). if (CFReadStreamHasBytesAvailable(asyncSocket->readStream)) { asyncSocket->flags |= kSecureSocketHasBytesAvailable; [asyncSocket cf_finishSSLHandshake]; } } else { asyncSocket->flags |= kSecureSocketHasBytesAvailable; [asyncSocket doReadData]; } }}); break; } default: { NSError *error = (__bridge_transfer NSError *)CFReadStreamCopyError(stream); if (error == nil && type == kCFStreamEventEndEncountered) { error = [asyncSocket connectionClosedError]; } dispatch_async(asyncSocket->socketQueue, ^{ @autoreleasepool { LogCVerbose(@"CFReadStreamCallback - Other"); if (asyncSocket->readStream != stream) return_from_block; if ((asyncSocket->flags & kStartingReadTLS) && (asyncSocket->flags & kStartingWriteTLS)) { [asyncSocket cf_abortSSLHandshake:error]; } else { [asyncSocket closeWithError:error]; } }}); break; } } } static void CFWriteStreamCallback (CFWriteStreamRef stream, CFStreamEventType type, void *pInfo) { GCDAsyncSocket *asyncSocket = (__bridge GCDAsyncSocket *)pInfo; switch(type) { case kCFStreamEventCanAcceptBytes: { dispatch_async(asyncSocket->socketQueue, ^{ @autoreleasepool { LogCVerbose(@"CFWriteStreamCallback - CanAcceptBytes"); if (asyncSocket->writeStream != stream) return_from_block; if ((asyncSocket->flags & kStartingReadTLS) && (asyncSocket->flags & kStartingWriteTLS)) { // If we set kCFStreamPropertySSLSettings before we opened the streams, this might be a lie. // (A callback related to the tcp stream, but not to the SSL layer). if (CFWriteStreamCanAcceptBytes(asyncSocket->writeStream)) { asyncSocket->flags |= kSocketCanAcceptBytes; [asyncSocket cf_finishSSLHandshake]; } } else { asyncSocket->flags |= kSocketCanAcceptBytes; [asyncSocket doWriteData]; } }}); break; } default: { NSError *error = (__bridge_transfer NSError *)CFWriteStreamCopyError(stream); if (error == nil && type == kCFStreamEventEndEncountered) { error = [asyncSocket connectionClosedError]; } dispatch_async(asyncSocket->socketQueue, ^{ @autoreleasepool { LogCVerbose(@"CFWriteStreamCallback - Other"); if (asyncSocket->writeStream != stream) return_from_block; if ((asyncSocket->flags & kStartingReadTLS) && (asyncSocket->flags & kStartingWriteTLS)) { [asyncSocket cf_abortSSLHandshake:error]; } else { [asyncSocket closeWithError:error]; } }}); break; } } } - (BOOL)createReadAndWriteStream { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); if (readStream || writeStream) { // Streams already created return YES; } int socketFD = (socket6FD == SOCKET_NULL) ? socket4FD : socket6FD; if (socketFD == SOCKET_NULL) { // Cannot create streams without a file descriptor return NO; } if (![self isConnected]) { // Cannot create streams until file descriptor is connected return NO; } LogVerbose(@"Creating read and write stream..."); CFStreamCreatePairWithSocket(NULL, (CFSocketNativeHandle)socketFD, &readStream, &writeStream); // The kCFStreamPropertyShouldCloseNativeSocket property should be false by default (for our case). // But let's not take any chances. if (readStream) CFReadStreamSetProperty(readStream, kCFStreamPropertyShouldCloseNativeSocket, kCFBooleanFalse); if (writeStream) CFWriteStreamSetProperty(writeStream, kCFStreamPropertyShouldCloseNativeSocket, kCFBooleanFalse); if ((readStream == NULL) || (writeStream == NULL)) { LogWarn(@"Unable to create read and write stream..."); if (readStream) { CFReadStreamClose(readStream); CFRelease(readStream); readStream = NULL; } if (writeStream) { CFWriteStreamClose(writeStream); CFRelease(writeStream); writeStream = NULL; } return NO; } return YES; } - (BOOL)registerForStreamCallbacksIncludingReadWrite:(BOOL)includeReadWrite { LogVerbose(@"%@ %@", THIS_METHOD, (includeReadWrite ? @"YES" : @"NO")); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); NSAssert((readStream != NULL && writeStream != NULL), @"Read/Write stream is null"); streamContext.version = 0; streamContext.info = (__bridge void *)(self); streamContext.retain = nil; streamContext.release = nil; streamContext.copyDescription = nil; CFOptionFlags readStreamEvents = kCFStreamEventErrorOccurred | kCFStreamEventEndEncountered; if (includeReadWrite) readStreamEvents |= kCFStreamEventHasBytesAvailable; if (!CFReadStreamSetClient(readStream, readStreamEvents, &CFReadStreamCallback, &streamContext)) { return NO; } CFOptionFlags writeStreamEvents = kCFStreamEventErrorOccurred | kCFStreamEventEndEncountered; if (includeReadWrite) writeStreamEvents |= kCFStreamEventCanAcceptBytes; if (!CFWriteStreamSetClient(writeStream, writeStreamEvents, &CFWriteStreamCallback, &streamContext)) { return NO; } return YES; } - (BOOL)addStreamsToRunLoop { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); NSAssert((readStream != NULL && writeStream != NULL), @"Read/Write stream is null"); if (!(flags & kAddedStreamsToRunLoop)) { LogVerbose(@"Adding streams to runloop..."); [[self class] startCFStreamThreadIfNeeded]; [[self class] performSelector:@selector(scheduleCFStreams:) onThread:cfstreamThread withObject:self waitUntilDone:YES]; flags |= kAddedStreamsToRunLoop; } return YES; } - (void)removeStreamsFromRunLoop { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); NSAssert((readStream != NULL && writeStream != NULL), @"Read/Write stream is null"); if (flags & kAddedStreamsToRunLoop) { LogVerbose(@"Removing streams from runloop..."); [[self class] performSelector:@selector(unscheduleCFStreams:) onThread:cfstreamThread withObject:self waitUntilDone:YES]; flags &= ~kAddedStreamsToRunLoop; } } - (BOOL)openStreams { LogTrace(); NSAssert(dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey), @"Must be dispatched on socketQueue"); NSAssert((readStream != NULL && writeStream != NULL), @"Read/Write stream is null"); CFStreamStatus readStatus = CFReadStreamGetStatus(readStream); CFStreamStatus writeStatus = CFWriteStreamGetStatus(writeStream); if ((readStatus == kCFStreamStatusNotOpen) || (writeStatus == kCFStreamStatusNotOpen)) { LogVerbose(@"Opening read and write stream..."); BOOL r1 = CFReadStreamOpen(readStream); BOOL r2 = CFWriteStreamOpen(writeStream); if (!r1 || !r2) { LogError(@"Error in CFStreamOpen"); return NO; } } return YES; } #endif //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Advanced //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// /** * See header file for big discussion of this method. **/ - (BOOL)autoDisconnectOnClosedReadStream { // Note: YES means kAllowHalfDuplexConnection is OFF if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { return ((config & kAllowHalfDuplexConnection) == 0); } else { __block BOOL result; dispatch_sync(socketQueue, ^{ result = ((config & kAllowHalfDuplexConnection) == 0); }); return result; } } /** * See header file for big discussion of this method. **/ - (void)setAutoDisconnectOnClosedReadStream:(BOOL)flag { // Note: YES means kAllowHalfDuplexConnection is OFF dispatch_block_t block = ^{ if (flag) config &= ~kAllowHalfDuplexConnection; else config |= kAllowHalfDuplexConnection; }; if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_async(socketQueue, block); } /** * See header file for big discussion of this method. **/ - (void)markSocketQueueTargetQueue:(dispatch_queue_t)socketNewTargetQueue { void *nonNullUnusedPointer = (__bridge void *)self; dispatch_queue_set_specific(socketNewTargetQueue, IsOnSocketQueueOrTargetQueueKey, nonNullUnusedPointer, NULL); } /** * See header file for big discussion of this method. **/ - (void)unmarkSocketQueueTargetQueue:(dispatch_queue_t)socketOldTargetQueue { dispatch_queue_set_specific(socketOldTargetQueue, IsOnSocketQueueOrTargetQueueKey, NULL, NULL); } /** * See header file for big discussion of this method. **/ - (void)performBlock:(dispatch_block_t)block { if (dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) block(); else dispatch_sync(socketQueue, block); } /** * Questions? Have you read the header file? **/ - (int)socketFD { if (!dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { LogWarn(@"%@ - Method only available from within the context of a performBlock: invocation", THIS_METHOD); return SOCKET_NULL; } if (socket4FD != SOCKET_NULL) return socket4FD; else return socket6FD; } /** * Questions? Have you read the header file? **/ - (int)socket4FD { if (!dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { LogWarn(@"%@ - Method only available from within the context of a performBlock: invocation", THIS_METHOD); return SOCKET_NULL; } return socket4FD; } /** * Questions? Have you read the header file? **/ - (int)socket6FD { if (!dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { LogWarn(@"%@ - Method only available from within the context of a performBlock: invocation", THIS_METHOD); return SOCKET_NULL; } return socket6FD; } #if TARGET_OS_IPHONE /** * Questions? Have you read the header file? **/ - (CFReadStreamRef)readStream { if (!dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { LogWarn(@"%@ - Method only available from within the context of a performBlock: invocation", THIS_METHOD); return NULL; } if (readStream == NULL) [self createReadAndWriteStream]; return readStream; } /** * Questions? Have you read the header file? **/ - (CFWriteStreamRef)writeStream { if (!dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { LogWarn(@"%@ - Method only available from within the context of a performBlock: invocation", THIS_METHOD); return NULL; } if (writeStream == NULL) [self createReadAndWriteStream]; return writeStream; } - (BOOL)enableBackgroundingOnSocketWithCaveat:(BOOL)caveat { if (![self createReadAndWriteStream]) { // Error occured creating streams (perhaps socket isn't open) return NO; } BOOL r1, r2; LogVerbose(@"Enabling backgrouding on socket"); r1 = CFReadStreamSetProperty(readStream, kCFStreamNetworkServiceType, kCFStreamNetworkServiceTypeVoIP); r2 = CFWriteStreamSetProperty(writeStream, kCFStreamNetworkServiceType, kCFStreamNetworkServiceTypeVoIP); if (!r1 || !r2) { return NO; } if (!caveat) { if (![self openStreams]) { return NO; } } return YES; } /** * Questions? Have you read the header file? **/ - (BOOL)enableBackgroundingOnSocket { LogTrace(); if (!dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { LogWarn(@"%@ - Method only available from within the context of a performBlock: invocation", THIS_METHOD); return NO; } return [self enableBackgroundingOnSocketWithCaveat:NO]; } - (BOOL)enableBackgroundingOnSocketWithCaveat // Deprecated in iOS 4.??? { // This method was created as a workaround for a bug in iOS. // Apple has since fixed this bug. // I'm not entirely sure which version of iOS they fixed it in... LogTrace(); if (!dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { LogWarn(@"%@ - Method only available from within the context of a performBlock: invocation", THIS_METHOD); return NO; } return [self enableBackgroundingOnSocketWithCaveat:YES]; } #endif #if SECURE_TRANSPORT_MAYBE_AVAILABLE - (SSLContextRef)sslContext { if (!dispatch_get_specific(IsOnSocketQueueOrTargetQueueKey)) { LogWarn(@"%@ - Method only available from within the context of a performBlock: invocation", THIS_METHOD); return NULL; } return sslContext; } #endif //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #pragma mark Class Methods //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// + (NSString *)hostFromSockaddr4:(const struct sockaddr_in *)pSockaddr4 { char addrBuf[INET_ADDRSTRLEN]; if (inet_ntop(AF_INET, &pSockaddr4->sin_addr, addrBuf, (socklen_t)sizeof(addrBuf)) == NULL) { addrBuf[0] = '\0'; } return [NSString stringWithCString:addrBuf encoding:NSASCIIStringEncoding]; } + (NSString *)hostFromSockaddr6:(const struct sockaddr_in6 *)pSockaddr6 { char addrBuf[INET6_ADDRSTRLEN]; if (inet_ntop(AF_INET6, &pSockaddr6->sin6_addr, addrBuf, (socklen_t)sizeof(addrBuf)) == NULL) { addrBuf[0] = '\0'; } return [NSString stringWithCString:addrBuf encoding:NSASCIIStringEncoding]; } + (uint16_t)portFromSockaddr4:(const struct sockaddr_in *)pSockaddr4 { return ntohs(pSockaddr4->sin_port); } + (uint16_t)portFromSockaddr6:(const struct sockaddr_in6 *)pSockaddr6 { return ntohs(pSockaddr6->sin6_port); } + (NSString *)hostFromAddress:(NSData *)address { NSString *host; if ([self getHost:&host port:NULL fromAddress:address]) return host; else return nil; } + (uint16_t)portFromAddress:(NSData *)address { uint16_t port; if ([self getHost:NULL port:&port fromAddress:address]) return port; else return 0; } + (BOOL)getHost:(NSString **)hostPtr port:(uint16_t *)portPtr fromAddress:(NSData *)address { if ([address length] >= sizeof(struct sockaddr)) { const struct sockaddr *sockaddrX = [address bytes]; if (sockaddrX->sa_family == AF_INET) { if ([address length] >= sizeof(struct sockaddr_in)) { struct sockaddr_in sockaddr4; memcpy(&sockaddr4, sockaddrX, sizeof(sockaddr4)); if (hostPtr) *hostPtr = [self hostFromSockaddr4:&sockaddr4]; if (portPtr) *portPtr = [self portFromSockaddr4:&sockaddr4]; return YES; } } else if (sockaddrX->sa_family == AF_INET6) { if ([address length] >= sizeof(struct sockaddr_in6)) { struct sockaddr_in6 sockaddr6; memcpy(&sockaddr6, sockaddrX, sizeof(sockaddr6)); if (hostPtr) *hostPtr = [self hostFromSockaddr6:&sockaddr6]; if (portPtr) *portPtr = [self portFromSockaddr6:&sockaddr6]; return YES; } } } return NO; } + (NSData *)CRLFData { return [NSData dataWithBytes:"\x0D\x0A" length:2]; } + (NSData *)CRData { return [NSData dataWithBytes:"\x0D" length:1]; } + (NSData *)LFData { return [NSData dataWithBytes:"\x0A" length:1]; } + (NSData *)ZeroData { return [NSData dataWithBytes:"" length:1]; } @end