CoreFoundation/CFData.c - nest-cam/4320010/corefoundation - Git at Google

 /*
  * Copyright (c) 2008-2009 Brent Fulgham <bfulgham@gmail.org>.  All rights reserved.
  *
  * This source code is a modified version of the CoreFoundation sources released by Apple Inc. under
  * the terms of the APSL version 2.0 (see below).
  *
  * For information about changes from the original Apple source release can be found by reviewing the
  * source control system for the project at https://sourceforge.net/svn/?group_id=246198.
  *
  * The original license information is as follows:
  *
  * Copyright (c) 2008 Apple Inc. All rights reserved.
  *
  * @APPLE_LICENSE_HEADER_START@
  *
  * This file contains Original Code and/or Modifications of Original Code
  * as defined in and that are subject to the Apple Public Source License
  * Version 2.0 (the 'License'). You may not use this file except in
  * compliance with the License. Please obtain a copy of the License at
  * http://www.opensource.apple.com/apsl/ and read it before using this
  * file.
  *
  * The Original Code and all software distributed under the License are
  * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
  * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
  * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
  * Please see the License for the specific language governing rights and
  * limitations under the License.
  *
  * @APPLE_LICENSE_HEADER_END@
  */
 /*	CFData.c
 	Copyright 1998-2002, Apple, Inc. All rights reserved.
 	Responsibility: Christopher Kane
 */

 #include <CoreFoundation/CFData.h>
 #include "CFPriv.h"
 #include "CFInternal.h"
 #include <string.h>

 struct __CFData {
     CFRuntimeBase _base;
     CFIndex _length;	/* number of bytes */
     CFIndex _capacity;	/* maximum number of bytes */
     CFAllocatorRef _bytesDeallocator;	/* used only for immutable; if NULL, no deallocation */
     uint8_t *_bytes;
 };

 /* Bits 3-2 are used for mutability variation */

 CF_INLINE UInt32 __CFMutableVariety(const void *cf) {
     return __CFBitfieldGetValue(((const CFRuntimeBase *)cf)->_cfinfo[CF_INFO_BITS], 3, 2);
 }

 CF_INLINE void __CFSetMutableVariety(void *cf, UInt32 v) {
     __CFBitfieldSetValue(((CFRuntimeBase *)cf)->_cfinfo[CF_INFO_BITS], 3, 2, v);
 }

 CF_INLINE UInt32 __CFMutableVarietyFromFlags(UInt32 flags) {
     return __CFBitfieldGetValue(flags, 1, 0);
 }

 #define __CFGenericValidateMutabilityFlags(flags) \
     CFAssert2(__CFMutableVarietyFromFlags(flags) != 0x2, __kCFLogAssertion, "%s(): flags 0x%x do not correctly specify the mutable variety", __PRETTY_FUNCTION__, flags);

 CF_INLINE CFIndex __CFDataLength(CFDataRef data) {
     return data->_length;
 }

 CF_INLINE void __CFDataSetLength(CFMutableDataRef data, CFIndex v) {
     /* for a CFData, _bytesUsed == _length */
 }

 CF_INLINE CFIndex __CFDataCapacity(CFDataRef data) {
     return data->_capacity;
 }

 CF_INLINE void __CFDataSetCapacity(CFMutableDataRef data, CFIndex v) {
     /* for a CFData, _bytesNum == _capacity */
 }

 CF_INLINE CFIndex __CFDataNumBytesUsed(CFDataRef data) {
     return data->_length;
 }

 CF_INLINE void __CFDataSetNumBytesUsed(CFMutableDataRef data, CFIndex v) {
     data->_length = v;
 }

 CF_INLINE CFIndex __CFDataNumBytes(CFDataRef data) {
     return data->_capacity;
 }

 CF_INLINE void __CFDataSetNumBytes(CFMutableDataRef data, CFIndex v) {
     data->_capacity = v;
 }

 CF_INLINE CFIndex __CFDataRoundUpCapacity(CFIndex capacity) {
     if (capacity < 16) return 16;
 // CF: quite probably, this doubling should slow as the data gets larger and larger; should not use strict doubling
     return (1 << flsl(capacity));
 }

 CF_INLINE CFIndex __CFDataNumBytesForCapacity(CFIndex capacity) {
     return capacity;
 }

 static void __CFDataHandleOutOfMemory(CFTypeRef obj, CFIndex numBytes) {
     CFStringRef msg = CFStringCreateWithFormat(kCFAllocatorSystemDefault, NULL, CFSTR("Attempt to allocate %ld bytes for NS/CFData failed"), numBytes);
     CFBadErrorCallBack cb = _CFGetOutOfMemoryErrorCallBack();
     if (NULL == cb || !cb(obj, CFSTR("NS/CFData"), msg)) {
         CFLog(kCFLogLevelCritical, CFSTR("%@"), msg);
         HALT;
     }
     CFRelease(msg);
 }

 #if defined(DEBUG)
 CF_INLINE void __CFDataValidateRange(CFDataRef data, CFRange range, const char *func) {
     CFAssert2(0 <= range.location && range.location <= __CFDataLength(data), __kCFLogAssertion, "%s(): range.location index (%d) out of bounds", func, range.location);
     CFAssert2(0 <= range.length, __kCFLogAssertion, "%s(): length (%d) cannot be less than zero", func, range.length);
     CFAssert2(range.location + range.length <= __CFDataLength(data), __kCFLogAssertion, "%s(): ending index (%d) out of bounds", func, range.location + range.length);
 }
 #else
 #define __CFDataValidateRange(a,r,f)
 #endif

 static Boolean __CFDataEqual(CFTypeRef cf1, CFTypeRef cf2) {
     CFDataRef data1 = (CFDataRef)cf1;
     CFDataRef data2 = (CFDataRef)cf2;
     CFIndex length;
     length = __CFDataLength(data1);
     if (length != __CFDataLength(data2)) return false;
     return 0 == memcmp(data1->_bytes, data2->_bytes, length);
 }

 static CFHashCode __CFDataHash(CFTypeRef cf) {
     CFDataRef data = (CFDataRef)cf;
     return CFHashBytes(data->_bytes, __CFMin(__CFDataLength(data), 80));
 }

 static CFStringRef __CFDataCopyDescription(CFTypeRef cf) {
     CFDataRef data = (CFDataRef)cf;
     CFMutableStringRef result;
     CFIndex idx;
     CFIndex len;
     const uint8_t *bytes;
     len = __CFDataLength(data);
     bytes = data->_bytes;
     result = CFStringCreateMutable(CFGetAllocator(data), 0);
     CFStringAppendFormat(result, NULL, CFSTR("<CFData %p [%p]>{length = %u, capacity = %u, bytes = 0x"), cf, CFGetAllocator(data), len, __CFDataCapacity(data));
     if (24 < len) {
         for (idx = 0; idx < 16; idx += 4) {
 	    CFStringAppendFormat(result, NULL, CFSTR("%02x%02x%02x%02x"), bytes[idx], bytes[idx + 1], bytes[idx + 2], bytes[idx + 3]);
 	}
         CFStringAppend(result, CFSTR(" ... "));
         for (idx = len - 8; idx < len; idx += 4) {
 	    CFStringAppendFormat(result, NULL, CFSTR("%02x%02x%02x%02x"), bytes[idx], bytes[idx + 1], bytes[idx + 2], bytes[idx + 3]);
 	}
     } else {
         for (idx = 0; idx < len; idx++) {
 	    CFStringAppendFormat(result, NULL, CFSTR("%02x"), bytes[idx]);
 	}
     }
     CFStringAppend(result, CFSTR("}"));
     return result;
 }

 enum {
     kCFImmutable = 0x0,		/* unchangable and fixed capacity; default */
     kCFMutable = 0x1,		/* changeable and variable capacity */
     kCFFixedMutable = 0x3	/* changeable and fixed capacity */
 };

 static void __CFDataDeallocate(CFTypeRef cf) {
     CFMutableDataRef data = (CFMutableDataRef)cf;
     CFAllocatorRef allocator = __CFGetAllocator(data);
     switch (__CFMutableVariety(data)) {
     case kCFMutable:
 	_CFAllocatorDeallocateGC(allocator, data->_bytes);
 	data->_bytes = NULL;
 	break;
     case kCFFixedMutable:
 	break;
     case kCFImmutable:
 	if (NULL != data->_bytesDeallocator) {
 	    if (CF_IS_COLLECTABLE_ALLOCATOR(data->_bytesDeallocator)) {
 		// GC:  for finalization safety, let collector reclaim the buffer in the next GC cycle.
 		auto_zone_release(__CFCollectableZone, data->_bytes);
             } else {
 		CFAllocatorDeallocate(data->_bytesDeallocator, data->_bytes);
 		CFRelease(data->_bytesDeallocator);
 		data->_bytes = NULL;
 	    }
 	}
 	break;
     }
 }

 static CFTypeID __kCFDataTypeID = _kCFRuntimeNotATypeID;

 static const CFRuntimeClass __CFDataClass = {
     0,
     "CFData",
     NULL,	// init
     NULL,	// copy
     __CFDataDeallocate,
     __CFDataEqual,
     __CFDataHash,
     NULL,	//
     __CFDataCopyDescription
 };

 __private_extern__ void __CFDataInitialize(void) {
     __kCFDataTypeID = _CFRuntimeRegisterClass(&__CFDataClass);
 }

 CFTypeID CFDataGetTypeID(void) {
     return __kCFDataTypeID;
 }

 // NULL bytesDeallocator to this function does not mean the default allocator, it means
 // that there should be no deallocator, and the bytes should be copied.
 static CFMutableDataRef __CFDataInit(CFAllocatorRef allocator, CFOptionFlags flags, CFIndex capacity, const uint8_t *bytes, CFIndex length, CFAllocatorRef bytesDeallocator) {
     CFMutableDataRef memory;
     CFIndex size;
     __CFGenericValidateMutabilityFlags(flags);
     CFAssert2(0 <= capacity, __kCFLogAssertion, "%s(): capacity (%d) cannot be less than zero", __PRETTY_FUNCTION__, capacity);
     CFAssert3(kCFFixedMutable != __CFMutableVarietyFromFlags(flags) || length <= capacity, __kCFLogAssertion, "%s(): for kCFFixedMutable type, capacity (%d) must be greater than or equal to number of initial elements (%d)", __PRETTY_FUNCTION__, capacity, length);
     CFAssert2(0 <= length, __kCFLogAssertion, "%s(): length (%d) cannot be less than zero", __PRETTY_FUNCTION__, length);
     size = sizeof(struct __CFData) - sizeof(CFRuntimeBase);
     if (__CFMutableVarietyFromFlags(flags) != kCFMutable && (bytesDeallocator == NULL)) {
 	size += sizeof(uint8_t) * __CFDataNumBytesForCapacity(capacity);
     }
     if (__CFMutableVarietyFromFlags(flags) != kCFMutable) {
 	size += sizeof(uint8_t) * 15;	// for 16-byte alignment fixup
     }
     memory = (CFMutableDataRef)_CFRuntimeCreateInstance(allocator, __kCFDataTypeID, size, NULL);
     if (NULL == memory) {
 	return NULL;
     }
     __CFDataSetNumBytesUsed(memory, 0);
     __CFDataSetLength(memory, 0);
     switch (__CFMutableVarietyFromFlags(flags)) {
     case kCFMutable:
 	__CFDataSetCapacity(memory, __CFDataRoundUpCapacity(1));
 	__CFDataSetNumBytes(memory, __CFDataNumBytesForCapacity(__CFDataRoundUpCapacity(1)));
 	// GC: if allocated in the collectable zone, mark the object as needing to be scanned.
 	if (CF_IS_COLLECTABLE_ALLOCATOR(allocator)) auto_zone_set_layout_type(__CFCollectableZone, memory, AUTO_MEMORY_SCANNED);
 	// assume that allocators give 16-byte aligned memory back -- it is their responsibility
 	CF_WRITE_BARRIER_BASE_ASSIGN(allocator, memory, memory->_bytes, _CFAllocatorAllocateGC(allocator, __CFDataNumBytes(memory) * sizeof(uint8_t), 0));
 	if (__CFOASafe) __CFSetLastAllocationEventName(memory->_bytes, "CFData (store)");
 	if (NULL == memory->_bytes) {
 	    CFRelease(memory);
 	    return NULL;
 	}
 	memory->_bytesDeallocator = NULL;
 	__CFSetMutableVariety(memory, kCFMutable);
 	CFDataReplaceBytes(memory, CFRangeMake(0, 0), bytes, length);
 	break;
     case kCFFixedMutable:
 	/* Don't round up capacity */
 	__CFDataSetCapacity(memory, capacity);
 	__CFDataSetNumBytes(memory, __CFDataNumBytesForCapacity(capacity));
 	memory->_bytes = (uint8_t *)((uintptr_t)((int8_t *)memory + sizeof(struct __CFData) + 15) & ~0xF);	// 16-byte align
 	memory->_bytesDeallocator = NULL;
 	__CFSetMutableVariety(memory, kCFFixedMutable);
 	CFDataReplaceBytes(memory, CFRangeMake(0, 0), bytes, length);
 	break;
     case kCFImmutable:
 	/* Don't round up capacity */
 	__CFDataSetCapacity(memory, capacity);
 	__CFDataSetNumBytes(memory, __CFDataNumBytesForCapacity(capacity));
 	if (bytesDeallocator != NULL) {
             CF_WRITE_BARRIER_BASE_ASSIGN(allocator, memory, memory->_bytes, (uint8_t *)bytes);
 	    memory->_bytesDeallocator = (CFAllocatorRef)CFRetain(bytesDeallocator);
 	    __CFDataSetNumBytesUsed(memory, length);
 	    __CFDataSetLength(memory, length);
 	} else {
 	    memory->_bytes = (uint8_t *)((uintptr_t)((int8_t *)memory + sizeof(struct __CFData) + 15) & ~0xF);	// 16-byte align
 	    memory->_bytesDeallocator = NULL;
 	    __CFSetMutableVariety(memory, kCFFixedMutable);
 	    CFDataReplaceBytes(memory, CFRangeMake(0, 0), bytes, length);
 	}
 	break;
     }
     __CFSetMutableVariety(memory, __CFMutableVarietyFromFlags(flags));
     return memory;
 }

 CFDataRef CFDataCreate(CFAllocatorRef allocator, const uint8_t *bytes, CFIndex length) {
     return __CFDataInit(allocator, kCFImmutable, length, bytes, length, NULL);
 }

 CFDataRef CFDataCreateWithBytesNoCopy(CFAllocatorRef allocator, const uint8_t *bytes, CFIndex length, CFAllocatorRef bytesDeallocator) {
     CFAssert1((0 == length || bytes != NULL), __kCFLogAssertion, "%s(): bytes pointer cannot be NULL if length is non-zero", __PRETTY_FUNCTION__);
     if (NULL == bytesDeallocator) bytesDeallocator = __CFGetDefaultAllocator();
     return __CFDataInit(allocator, kCFImmutable, length, bytes, length, bytesDeallocator);
 }

 CFDataRef CFDataCreateCopy(CFAllocatorRef allocator, CFDataRef data) {
     CFIndex length = CFDataGetLength(data);
     return __CFDataInit(allocator, kCFImmutable, length, CFDataGetBytePtr(data), length, NULL);
 }

 CFMutableDataRef CFDataCreateMutable(CFAllocatorRef allocator, CFIndex capacity) {
     return __CFDataInit(allocator, (0 == capacity) ? kCFMutable : kCFFixedMutable, capacity, NULL, 0, NULL);
 }

 CFMutableDataRef CFDataCreateMutableCopy(CFAllocatorRef allocator, CFIndex capacity, CFDataRef data) {
     return __CFDataInit(allocator, (0 == capacity) ? kCFMutable : kCFFixedMutable, capacity, CFDataGetBytePtr(data), CFDataGetLength(data), NULL);
 }

 CFIndex CFDataGetLength(CFDataRef data) {
     CF_OBJC_FUNCDISPATCH0(__kCFDataTypeID, CFIndex, data, "length");
     __CFGenericValidateType(data, __kCFDataTypeID);
     return __CFDataLength(data);
 }

 const uint8_t *CFDataGetBytePtr(CFDataRef data) {
     CF_OBJC_FUNCDISPATCH0(__kCFDataTypeID, const uint8_t *, data, "bytes");
     __CFGenericValidateType(data, __kCFDataTypeID);
     return data->_bytes;
 }

 uint8_t *CFDataGetMutableBytePtr(CFMutableDataRef data) {
     CF_OBJC_FUNCDISPATCH0(__kCFDataTypeID, uint8_t *, data, "mutableBytes");
     CFAssert1(__CFMutableVariety(data) == kCFMutable || __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
     return data->_bytes;
 }

 void CFDataGetBytes(CFDataRef data, CFRange range, uint8_t *buffer) {
     CF_OBJC_FUNCDISPATCH2(__kCFDataTypeID, void, data, "getBytes:range:", buffer, range);
     memmove(buffer, data->_bytes + range.location, range.length);
 }

 static void __CFDataGrow(CFMutableDataRef data, CFIndex numNewValues) {
     CFIndex oldLength = __CFDataLength(data);
     CFIndex capacity = __CFDataRoundUpCapacity(oldLength + numNewValues);
     CFAllocatorRef allocator = CFGetAllocator(data);
     __CFDataSetCapacity(data, capacity);
     __CFDataSetNumBytes(data, __CFDataNumBytesForCapacity(capacity));
     void *bytes = _CFAllocatorReallocateGC(allocator, data->_bytes, __CFDataNumBytes(data) * sizeof(uint8_t), 0);
     if (NULL == bytes) __CFDataHandleOutOfMemory(data, __CFDataNumBytes(data) * sizeof(uint8_t));
     CF_WRITE_BARRIER_BASE_ASSIGN(allocator, data, data->_bytes, bytes);
     if (__CFOASafe) __CFSetLastAllocationEventName(data->_bytes, "CFData (store)");
 }

 void CFDataSetLength(CFMutableDataRef data, CFIndex length) {
     CFIndex len;
     CF_OBJC_FUNCDISPATCH1(__kCFDataTypeID, void, data, "setLength:", length);
     CFAssert1(__CFMutableVariety(data) == kCFMutable || __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
     len = __CFDataLength(data);
     switch (__CFMutableVariety(data)) {
     case kCFMutable:
 	if (len < length) {
 // CF: should only grow when new length exceeds current capacity, not whenever it exceeds the current length
 	    __CFDataGrow(data, length - len);
 	}
 	break;
     case kCFFixedMutable:
 	CFAssert1(length <= __CFDataCapacity(data), __kCFLogAssertion, "%s(): fixed-capacity data is full", __PRETTY_FUNCTION__);
 	break;
     }
     if (len < length) {
 	memset(data->_bytes + len, 0, length - len);
     }
     __CFDataSetLength(data, length);
     __CFDataSetNumBytesUsed(data, length);
 }

 void CFDataIncreaseLength(CFMutableDataRef data, CFIndex extraLength) {
     CF_OBJC_FUNCDISPATCH1(__kCFDataTypeID, void, data, "increaseLengthBy:", extraLength);
     CFAssert1(__CFMutableVariety(data) == kCFMutable || __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
     CFDataSetLength(data, __CFDataLength(data) + extraLength);
 }

 void CFDataAppendBytes(CFMutableDataRef data, const uint8_t *bytes, CFIndex length) {
     CF_OBJC_FUNCDISPATCH2(__kCFDataTypeID, void, data, "appendBytes:length:", bytes, length);
     CFAssert1(__CFMutableVariety(data) == kCFMutable || __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
     CFDataReplaceBytes(data, CFRangeMake(__CFDataLength(data), 0), bytes, length);
 }

 void CFDataDeleteBytes(CFMutableDataRef data, CFRange range) {
     CF_OBJC_FUNCDISPATCH3(__kCFDataTypeID, void, data, "replaceBytesInRange:withBytes:length:", range, NULL, 0);
     CFAssert1(__CFMutableVariety(data) == kCFMutable || __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
     CFDataReplaceBytes(data, range, NULL, 0);
 }

 void CFDataReplaceBytes(CFMutableDataRef data, CFRange range, const uint8_t *newBytes, CFIndex newLength) {
     CF_OBJC_FUNCDISPATCH3(__kCFDataTypeID, void, data, "replaceBytesInRange:withBytes:length:", range, newBytes, newLength);
     __CFGenericValidateType(data, __kCFDataTypeID);
     __CFDataValidateRange(data, range, __PRETTY_FUNCTION__);
     CFAssert1(__CFMutableVariety(data) == kCFMutable || __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
     CFAssert2(0 <= newLength, __kCFLogAssertion, "%s(): newLength (%d) cannot be less than zero", __PRETTY_FUNCTION__, newLength);

     CFIndex len = __CFDataLength(data);
     if (len < 0 || range.length < 0 || newLength < 0) HALT;
     CFIndex newCount = len - range.length + newLength;
     if (newCount < 0) HALT;

     switch (__CFMutableVariety(data)) {
     case kCFMutable:
 	if (__CFDataNumBytes(data) < newCount) {
 	    __CFDataGrow(data, newLength - range.length);
 	}
 	break;
     case kCFFixedMutable:
 	CFAssert1(newCount <= __CFDataCapacity(data), __kCFLogAssertion, "%s(): fixed-capacity data is full", __PRETTY_FUNCTION__);
 	break;
     }
     if (newLength != range.length && range.location + range.length < len) {
         memmove(data->_bytes + range.location + newLength, data->_bytes + range.location + range.length, (len - range.location - range.length) * sizeof(uint8_t));
     }
     if (0 < newLength) {
         memmove(data->_bytes + range.location, newBytes, newLength * sizeof(uint8_t));
     }
     __CFDataSetNumBytesUsed(data, newCount);
     __CFDataSetLength(data, newCount);
 }

 #undef __CFDataValidateRange
 #undef __CFGenericValidateMutabilityFlags
	/*
	* Copyright (c) 2008-2009 Brent Fulgham <bfulgham@gmail.org>. All rights reserved.
	*
	* This source code is a modified version of the CoreFoundation sources released by Apple Inc. under
	* the terms of the APSL version 2.0 (see below).
	*
	* For information about changes from the original Apple source release can be found by reviewing the
	* source control system for the project at https://sourceforge.net/svn/?group_id=246198.
	*
	* The original license information is as follows:
	*
	* Copyright (c) 2008 Apple Inc. All rights reserved.
	*
	* @APPLE_LICENSE_HEADER_START@
	*
	* This file contains Original Code and/or Modifications of Original Code
	* as defined in and that are subject to the Apple Public Source License
	* Version 2.0 (the 'License'). You may not use this file except in
	* compliance with the License. Please obtain a copy of the License at
	* http://www.opensource.apple.com/apsl/ and read it before using this
	* file.
	*
	* The Original Code and all software distributed under the License are
	* distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
	* EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
	* INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
	* Please see the License for the specific language governing rights and
	* limitations under the License.
	*
	* @APPLE_LICENSE_HEADER_END@
	*/
	/* CFData.c
	Copyright 1998-2002, Apple, Inc. All rights reserved.
	Responsibility: Christopher Kane
	*/

	#include <CoreFoundation/CFData.h>
	#include "CFPriv.h"
	#include "CFInternal.h"
	#include <string.h>

	struct __CFData {
	CFRuntimeBase _base;
	CFIndex _length; /* number of bytes */
	CFIndex _capacity; /* maximum number of bytes */
	CFAllocatorRef _bytesDeallocator; /* used only for immutable; if NULL, no deallocation */
	uint8_t *_bytes;
	};

	/* Bits 3-2 are used for mutability variation */

	CF_INLINE UInt32 __CFMutableVariety(const void *cf) {
	return __CFBitfieldGetValue(((const CFRuntimeBase *)cf)->_cfinfo[CF_INFO_BITS], 3, 2);
	}

	CF_INLINE void __CFSetMutableVariety(void *cf, UInt32 v) {
	__CFBitfieldSetValue(((CFRuntimeBase *)cf)->_cfinfo[CF_INFO_BITS], 3, 2, v);
	}

	CF_INLINE UInt32 __CFMutableVarietyFromFlags(UInt32 flags) {
	return __CFBitfieldGetValue(flags, 1, 0);
	}

	#define __CFGenericValidateMutabilityFlags(flags) \
	CFAssert2(__CFMutableVarietyFromFlags(flags) != 0x2, __kCFLogAssertion, "%s(): flags 0x%x do not correctly specify the mutable variety", __PRETTY_FUNCTION__, flags);

	CF_INLINE CFIndex __CFDataLength(CFDataRef data) {
	return data->_length;
	}

	CF_INLINE void __CFDataSetLength(CFMutableDataRef data, CFIndex v) {
	/* for a CFData, _bytesUsed == _length */
	}

	CF_INLINE CFIndex __CFDataCapacity(CFDataRef data) {
	return data->_capacity;
	}

	CF_INLINE void __CFDataSetCapacity(CFMutableDataRef data, CFIndex v) {
	/* for a CFData, _bytesNum == _capacity */
	}

	CF_INLINE CFIndex __CFDataNumBytesUsed(CFDataRef data) {
	return data->_length;
	}

	CF_INLINE void __CFDataSetNumBytesUsed(CFMutableDataRef data, CFIndex v) {
	data->_length = v;
	}

	CF_INLINE CFIndex __CFDataNumBytes(CFDataRef data) {
	return data->_capacity;
	}

	CF_INLINE void __CFDataSetNumBytes(CFMutableDataRef data, CFIndex v) {
	data->_capacity = v;
	}

	CF_INLINE CFIndex __CFDataRoundUpCapacity(CFIndex capacity) {
	if (capacity < 16) return 16;
	// CF: quite probably, this doubling should slow as the data gets larger and larger; should not use strict doubling
	return (1 << flsl(capacity));
	}

	CF_INLINE CFIndex __CFDataNumBytesForCapacity(CFIndex capacity) {
	return capacity;
	}

	static void __CFDataHandleOutOfMemory(CFTypeRef obj, CFIndex numBytes) {
	CFStringRef msg = CFStringCreateWithFormat(kCFAllocatorSystemDefault, NULL, CFSTR("Attempt to allocate %ld bytes for NS/CFData failed"), numBytes);
	CFBadErrorCallBack cb = _CFGetOutOfMemoryErrorCallBack();
	if (NULL == cb \|\| !cb(obj, CFSTR("NS/CFData"), msg)) {
	CFLog(kCFLogLevelCritical, CFSTR("%@"), msg);
	HALT;
	}
	CFRelease(msg);
	}

	#if defined(DEBUG)
	CF_INLINE void __CFDataValidateRange(CFDataRef data, CFRange range, const char *func) {
	CFAssert2(0 <= range.location && range.location <= __CFDataLength(data), __kCFLogAssertion, "%s(): range.location index (%d) out of bounds", func, range.location);
	CFAssert2(0 <= range.length, __kCFLogAssertion, "%s(): length (%d) cannot be less than zero", func, range.length);
	CFAssert2(range.location + range.length <= __CFDataLength(data), __kCFLogAssertion, "%s(): ending index (%d) out of bounds", func, range.location + range.length);
	}
	#else
	#define __CFDataValidateRange(a,r,f)
	#endif

	static Boolean __CFDataEqual(CFTypeRef cf1, CFTypeRef cf2) {
	CFDataRef data1 = (CFDataRef)cf1;
	CFDataRef data2 = (CFDataRef)cf2;
	CFIndex length;
	length = __CFDataLength(data1);
	if (length != __CFDataLength(data2)) return false;
	return 0 == memcmp(data1->_bytes, data2->_bytes, length);
	}

	static CFHashCode __CFDataHash(CFTypeRef cf) {
	CFDataRef data = (CFDataRef)cf;
	return CFHashBytes(data->_bytes, __CFMin(__CFDataLength(data), 80));
	}

	static CFStringRef __CFDataCopyDescription(CFTypeRef cf) {
	CFDataRef data = (CFDataRef)cf;
	CFMutableStringRef result;
	CFIndex idx;
	CFIndex len;
	const uint8_t *bytes;
	len = __CFDataLength(data);
	bytes = data->_bytes;
	result = CFStringCreateMutable(CFGetAllocator(data), 0);
	CFStringAppendFormat(result, NULL, CFSTR("<CFData %p [%p]>{length = %u, capacity = %u, bytes = 0x"), cf, CFGetAllocator(data), len, __CFDataCapacity(data));
	if (24 < len) {
	for (idx = 0; idx < 16; idx += 4) {
	CFStringAppendFormat(result, NULL, CFSTR("%02x%02x%02x%02x"), bytes[idx], bytes[idx + 1], bytes[idx + 2], bytes[idx + 3]);
	}
	CFStringAppend(result, CFSTR(" ... "));
	for (idx = len - 8; idx < len; idx += 4) {
	CFStringAppendFormat(result, NULL, CFSTR("%02x%02x%02x%02x"), bytes[idx], bytes[idx + 1], bytes[idx + 2], bytes[idx + 3]);
	}
	} else {
	for (idx = 0; idx < len; idx++) {
	CFStringAppendFormat(result, NULL, CFSTR("%02x"), bytes[idx]);
	}
	}
	CFStringAppend(result, CFSTR("}"));
	return result;
	}

	enum {
	kCFImmutable = 0x0, /* unchangable and fixed capacity; default */
	kCFMutable = 0x1, /* changeable and variable capacity */
	kCFFixedMutable = 0x3 /* changeable and fixed capacity */
	};

	static void __CFDataDeallocate(CFTypeRef cf) {
	CFMutableDataRef data = (CFMutableDataRef)cf;
	CFAllocatorRef allocator = __CFGetAllocator(data);
	switch (__CFMutableVariety(data)) {
	case kCFMutable:
	_CFAllocatorDeallocateGC(allocator, data->_bytes);
	data->_bytes = NULL;
	break;
	case kCFFixedMutable:
	break;
	case kCFImmutable:
	if (NULL != data->_bytesDeallocator) {
	if (CF_IS_COLLECTABLE_ALLOCATOR(data->_bytesDeallocator)) {
	// GC: for finalization safety, let collector reclaim the buffer in the next GC cycle.
	auto_zone_release(__CFCollectableZone, data->_bytes);
	} else {
	CFAllocatorDeallocate(data->_bytesDeallocator, data->_bytes);
	CFRelease(data->_bytesDeallocator);
	data->_bytes = NULL;
	}
	}
	break;
	}
	}

	static CFTypeID __kCFDataTypeID = _kCFRuntimeNotATypeID;

	static const CFRuntimeClass __CFDataClass = {
	0,
	"CFData",
	NULL, // init
	NULL, // copy
	__CFDataDeallocate,
	__CFDataEqual,
	__CFDataHash,
	NULL, //
	__CFDataCopyDescription
	};

	__private_extern__ void __CFDataInitialize(void) {
	__kCFDataTypeID = _CFRuntimeRegisterClass(&__CFDataClass);
	}

	CFTypeID CFDataGetTypeID(void) {
	return __kCFDataTypeID;
	}

	// NULL bytesDeallocator to this function does not mean the default allocator, it means
	// that there should be no deallocator, and the bytes should be copied.
	static CFMutableDataRef __CFDataInit(CFAllocatorRef allocator, CFOptionFlags flags, CFIndex capacity, const uint8_t *bytes, CFIndex length, CFAllocatorRef bytesDeallocator) {
	CFMutableDataRef memory;
	CFIndex size;
	__CFGenericValidateMutabilityFlags(flags);
	CFAssert2(0 <= capacity, __kCFLogAssertion, "%s(): capacity (%d) cannot be less than zero", __PRETTY_FUNCTION__, capacity);
	CFAssert3(kCFFixedMutable != __CFMutableVarietyFromFlags(flags) \|\| length <= capacity, __kCFLogAssertion, "%s(): for kCFFixedMutable type, capacity (%d) must be greater than or equal to number of initial elements (%d)", __PRETTY_FUNCTION__, capacity, length);
	CFAssert2(0 <= length, __kCFLogAssertion, "%s(): length (%d) cannot be less than zero", __PRETTY_FUNCTION__, length);
	size = sizeof(struct __CFData) - sizeof(CFRuntimeBase);
	if (__CFMutableVarietyFromFlags(flags) != kCFMutable && (bytesDeallocator == NULL)) {
	size += sizeof(uint8_t) * __CFDataNumBytesForCapacity(capacity);
	}
	if (__CFMutableVarietyFromFlags(flags) != kCFMutable) {
	size += sizeof(uint8_t) * 15; // for 16-byte alignment fixup
	}
	memory = (CFMutableDataRef)_CFRuntimeCreateInstance(allocator, __kCFDataTypeID, size, NULL);
	if (NULL == memory) {
	return NULL;
	}
	__CFDataSetNumBytesUsed(memory, 0);
	__CFDataSetLength(memory, 0);
	switch (__CFMutableVarietyFromFlags(flags)) {
	case kCFMutable:
	__CFDataSetCapacity(memory, __CFDataRoundUpCapacity(1));
	__CFDataSetNumBytes(memory, __CFDataNumBytesForCapacity(__CFDataRoundUpCapacity(1)));
	// GC: if allocated in the collectable zone, mark the object as needing to be scanned.
	if (CF_IS_COLLECTABLE_ALLOCATOR(allocator)) auto_zone_set_layout_type(__CFCollectableZone, memory, AUTO_MEMORY_SCANNED);
	// assume that allocators give 16-byte aligned memory back -- it is their responsibility
	CF_WRITE_BARRIER_BASE_ASSIGN(allocator, memory, memory->_bytes, _CFAllocatorAllocateGC(allocator, __CFDataNumBytes(memory) * sizeof(uint8_t), 0));
	if (__CFOASafe) __CFSetLastAllocationEventName(memory->_bytes, "CFData (store)");
	if (NULL == memory->_bytes) {
	CFRelease(memory);
	return NULL;
	}
	memory->_bytesDeallocator = NULL;
	__CFSetMutableVariety(memory, kCFMutable);
	CFDataReplaceBytes(memory, CFRangeMake(0, 0), bytes, length);
	break;
	case kCFFixedMutable:
	/* Don't round up capacity */
	__CFDataSetCapacity(memory, capacity);
	__CFDataSetNumBytes(memory, __CFDataNumBytesForCapacity(capacity));
	memory->_bytes = (uint8_t )((uintptr_t)((int8_t )memory + sizeof(struct __CFData) + 15) & ~0xF); // 16-byte align
	memory->_bytesDeallocator = NULL;
	__CFSetMutableVariety(memory, kCFFixedMutable);
	CFDataReplaceBytes(memory, CFRangeMake(0, 0), bytes, length);
	break;
	case kCFImmutable:
	/* Don't round up capacity */
	__CFDataSetCapacity(memory, capacity);
	__CFDataSetNumBytes(memory, __CFDataNumBytesForCapacity(capacity));
	if (bytesDeallocator != NULL) {
	CF_WRITE_BARRIER_BASE_ASSIGN(allocator, memory, memory->_bytes, (uint8_t *)bytes);
	memory->_bytesDeallocator = (CFAllocatorRef)CFRetain(bytesDeallocator);
	__CFDataSetNumBytesUsed(memory, length);
	__CFDataSetLength(memory, length);
	} else {
	memory->_bytes = (uint8_t )((uintptr_t)((int8_t )memory + sizeof(struct __CFData) + 15) & ~0xF); // 16-byte align
	memory->_bytesDeallocator = NULL;
	__CFSetMutableVariety(memory, kCFFixedMutable);
	CFDataReplaceBytes(memory, CFRangeMake(0, 0), bytes, length);
	}
	break;
	}
	__CFSetMutableVariety(memory, __CFMutableVarietyFromFlags(flags));
	return memory;
	}

	CFDataRef CFDataCreate(CFAllocatorRef allocator, const uint8_t *bytes, CFIndex length) {
	return __CFDataInit(allocator, kCFImmutable, length, bytes, length, NULL);
	}

	CFDataRef CFDataCreateWithBytesNoCopy(CFAllocatorRef allocator, const uint8_t *bytes, CFIndex length, CFAllocatorRef bytesDeallocator) {
	CFAssert1((0 == length \|\| bytes != NULL), __kCFLogAssertion, "%s(): bytes pointer cannot be NULL if length is non-zero", __PRETTY_FUNCTION__);
	if (NULL == bytesDeallocator) bytesDeallocator = __CFGetDefaultAllocator();
	return __CFDataInit(allocator, kCFImmutable, length, bytes, length, bytesDeallocator);
	}

	CFDataRef CFDataCreateCopy(CFAllocatorRef allocator, CFDataRef data) {
	CFIndex length = CFDataGetLength(data);
	return __CFDataInit(allocator, kCFImmutable, length, CFDataGetBytePtr(data), length, NULL);
	}

	CFMutableDataRef CFDataCreateMutable(CFAllocatorRef allocator, CFIndex capacity) {
	return __CFDataInit(allocator, (0 == capacity) ? kCFMutable : kCFFixedMutable, capacity, NULL, 0, NULL);
	}

	CFMutableDataRef CFDataCreateMutableCopy(CFAllocatorRef allocator, CFIndex capacity, CFDataRef data) {
	return __CFDataInit(allocator, (0 == capacity) ? kCFMutable : kCFFixedMutable, capacity, CFDataGetBytePtr(data), CFDataGetLength(data), NULL);
	}

	CFIndex CFDataGetLength(CFDataRef data) {
	CF_OBJC_FUNCDISPATCH0(__kCFDataTypeID, CFIndex, data, "length");
	__CFGenericValidateType(data, __kCFDataTypeID);
	return __CFDataLength(data);
	}

	const uint8_t *CFDataGetBytePtr(CFDataRef data) {
	CF_OBJC_FUNCDISPATCH0(__kCFDataTypeID, const uint8_t *, data, "bytes");
	__CFGenericValidateType(data, __kCFDataTypeID);
	return data->_bytes;
	}

	uint8_t *CFDataGetMutableBytePtr(CFMutableDataRef data) {
	CF_OBJC_FUNCDISPATCH0(__kCFDataTypeID, uint8_t *, data, "mutableBytes");
	CFAssert1(__CFMutableVariety(data) == kCFMutable \|\| __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
	return data->_bytes;
	}

	void CFDataGetBytes(CFDataRef data, CFRange range, uint8_t *buffer) {
	CF_OBJC_FUNCDISPATCH2(__kCFDataTypeID, void, data, "getBytes:range:", buffer, range);
	memmove(buffer, data->_bytes + range.location, range.length);
	}

	static void __CFDataGrow(CFMutableDataRef data, CFIndex numNewValues) {
	CFIndex oldLength = __CFDataLength(data);
	CFIndex capacity = __CFDataRoundUpCapacity(oldLength + numNewValues);
	CFAllocatorRef allocator = CFGetAllocator(data);
	__CFDataSetCapacity(data, capacity);
	__CFDataSetNumBytes(data, __CFDataNumBytesForCapacity(capacity));
	void bytes = _CFAllocatorReallocateGC(allocator, data->_bytes, __CFDataNumBytes(data) sizeof(uint8_t), 0);
	if (NULL == bytes) __CFDataHandleOutOfMemory(data, __CFDataNumBytes(data) * sizeof(uint8_t));
	CF_WRITE_BARRIER_BASE_ASSIGN(allocator, data, data->_bytes, bytes);
	if (__CFOASafe) __CFSetLastAllocationEventName(data->_bytes, "CFData (store)");
	}

	void CFDataSetLength(CFMutableDataRef data, CFIndex length) {
	CFIndex len;
	CF_OBJC_FUNCDISPATCH1(__kCFDataTypeID, void, data, "setLength:", length);
	CFAssert1(__CFMutableVariety(data) == kCFMutable \|\| __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
	len = __CFDataLength(data);
	switch (__CFMutableVariety(data)) {
	case kCFMutable:
	if (len < length) {
	// CF: should only grow when new length exceeds current capacity, not whenever it exceeds the current length
	__CFDataGrow(data, length - len);
	}
	break;
	case kCFFixedMutable:
	CFAssert1(length <= __CFDataCapacity(data), __kCFLogAssertion, "%s(): fixed-capacity data is full", __PRETTY_FUNCTION__);
	break;
	}
	if (len < length) {
	memset(data->_bytes + len, 0, length - len);
	}
	__CFDataSetLength(data, length);
	__CFDataSetNumBytesUsed(data, length);
	}

	void CFDataIncreaseLength(CFMutableDataRef data, CFIndex extraLength) {
	CF_OBJC_FUNCDISPATCH1(__kCFDataTypeID, void, data, "increaseLengthBy:", extraLength);
	CFAssert1(__CFMutableVariety(data) == kCFMutable \|\| __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
	CFDataSetLength(data, __CFDataLength(data) + extraLength);
	}

	void CFDataAppendBytes(CFMutableDataRef data, const uint8_t *bytes, CFIndex length) {
	CF_OBJC_FUNCDISPATCH2(__kCFDataTypeID, void, data, "appendBytes:length:", bytes, length);
	CFAssert1(__CFMutableVariety(data) == kCFMutable \|\| __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
	CFDataReplaceBytes(data, CFRangeMake(__CFDataLength(data), 0), bytes, length);
	}

	void CFDataDeleteBytes(CFMutableDataRef data, CFRange range) {
	CF_OBJC_FUNCDISPATCH3(__kCFDataTypeID, void, data, "replaceBytesInRange:withBytes:length:", range, NULL, 0);
	CFAssert1(__CFMutableVariety(data) == kCFMutable \|\| __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
	CFDataReplaceBytes(data, range, NULL, 0);
	}

	void CFDataReplaceBytes(CFMutableDataRef data, CFRange range, const uint8_t *newBytes, CFIndex newLength) {
	CF_OBJC_FUNCDISPATCH3(__kCFDataTypeID, void, data, "replaceBytesInRange:withBytes:length:", range, newBytes, newLength);
	__CFGenericValidateType(data, __kCFDataTypeID);
	__CFDataValidateRange(data, range, __PRETTY_FUNCTION__);
	CFAssert1(__CFMutableVariety(data) == kCFMutable \|\| __CFMutableVariety(data) == kCFFixedMutable, __kCFLogAssertion, "%s(): data is immutable", __PRETTY_FUNCTION__);
	CFAssert2(0 <= newLength, __kCFLogAssertion, "%s(): newLength (%d) cannot be less than zero", __PRETTY_FUNCTION__, newLength);

	CFIndex len = __CFDataLength(data);
	if (len < 0 \|\| range.length < 0 \|\| newLength < 0) HALT;
	CFIndex newCount = len - range.length + newLength;
	if (newCount < 0) HALT;

	switch (__CFMutableVariety(data)) {
	case kCFMutable:
	if (__CFDataNumBytes(data) < newCount) {
	__CFDataGrow(data, newLength - range.length);
	}
	break;
	case kCFFixedMutable:
	CFAssert1(newCount <= __CFDataCapacity(data), __kCFLogAssertion, "%s(): fixed-capacity data is full", __PRETTY_FUNCTION__);
	break;
	}
	if (newLength != range.length && range.location + range.length < len) {
	memmove(data->_bytes + range.location + newLength, data->_bytes + range.location + range.length, (len - range.location - range.length) * sizeof(uint8_t));
	}
	if (0 < newLength) {
	memmove(data->_bytes + range.location, newBytes, newLength * sizeof(uint8_t));
	}
	__CFDataSetNumBytesUsed(data, newCount);
	__CFDataSetLength(data, newCount);
	}

	#undef __CFDataValidateRange
	#undef __CFGenericValidateMutabilityFlags