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1/*
2 * Copyright (c) 1998-2000 Apple Computer, Inc. All rights reserved.
3 *
4 * @APPLE_LICENSE_HEADER_START@
5 *
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6 * The contents of this file constitute Original Code as defined in and
7 * are subject to the Apple Public Source License Version 1.1 (the
8 * "License"). You may not use this file except in compliance with the
9 * License. Please obtain a copy of the License at
10 * http://www.apple.com/publicsource and read it before using this file.
1c79356b 11 *
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12 * This Original Code and all software distributed under the License are
13 * distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER
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14 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
15 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
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16 * FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT. Please see the
17 * License for the specific language governing rights and limitations
18 * under the License.
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19 *
20 * @APPLE_LICENSE_HEADER_END@
21 */
22#ifndef _IOMEMORYDESCRIPTOR_H
23#define _IOMEMORYDESCRIPTOR_H
24
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25#include <sys/cdefs.h>
26
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27#include <IOKit/IOTypes.h>
28#include <libkern/c++/OSContainers.h>
29
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30__BEGIN_DECLS
31#include <mach/memory_object_types.h>
32__END_DECLS
33
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34struct IOPhysicalRange
35{
36 IOPhysicalAddress address;
37 IOByteCount length;
38};
39
40class IOMemoryMap;
55e303ae 41class IOMapper;
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42
43/*
44 * Direction of transfer, with respect to the described memory.
45 */
46enum IODirection
47{
48 kIODirectionNone = 0x0, // same as VM_PROT_NONE
49 kIODirectionIn = 0x1, // User land 'read', same as VM_PROT_READ
50 kIODirectionOut = 0x2, // User land 'write', same as VM_PROT_WRITE
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51 kIODirectionOutIn = kIODirectionOut | kIODirectionIn,
52 kIODirectionInOut = kIODirectionIn | kIODirectionOut
53};
54
55/*
91447636 56 * IOOptionBits used in the withOptions variant
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57 */
58enum {
59 kIOMemoryDirectionMask = 0x00000007,
60 kIOMemoryAutoPrepare = 0x00000008, // Shared with Buffer MD
61
62 kIOMemoryTypeVirtual = 0x00000010,
63 kIOMemoryTypePhysical = 0x00000020,
64 kIOMemoryTypeUPL = 0x00000030,
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65 kIOMemoryTypePersistentMD = 0x00000040, // Persistent Memory Descriptor
66 kIOMemoryTypeUIO = 0x00000050,
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67 kIOMemoryTypeMask = 0x000000f0,
68
69 kIOMemoryAsReference = 0x00000100,
70 kIOMemoryBufferPageable = 0x00000400,
71 kIOMemoryDontMap = 0x00000800,
72 kIOMemoryPersistent = 0x00010000
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73};
74
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75#define kIOMapperNone ((IOMapper *) -1)
76#define kIOMapperSystem ((IOMapper *) 0)
77
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78enum
79{
80 kIOMemoryPurgeableKeepCurrent = 1,
81 kIOMemoryPurgeableNonVolatile = 2,
82 kIOMemoryPurgeableVolatile = 3,
83 kIOMemoryPurgeableEmpty = 4
84};
85enum
86{
87 kIOMemoryIncoherentIOFlush = 1,
88 kIOMemoryIncoherentIOStore = 2,
89};
90
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91/*! @class IOMemoryDescriptor : public OSObject
92 @abstract An abstract base class defining common methods for describing physical or virtual memory.
93 @discussion The IOMemoryDescriptor object represents a buffer or range of memory, specified as one or more physical or virtual address ranges. It contains methods to return the memory's physically contiguous segments (fragments), for use with the IOMemoryCursor, and methods to map the memory into any address space with caching and placed mapping options. */
94
95class IOMemoryDescriptor : public OSObject
96{
97 friend class _IOMemoryMap;
98 friend class IOSubMemoryDescriptor;
99
100 OSDeclareDefaultStructors(IOMemoryDescriptor);
101
102protected:
103/*! @struct ExpansionData
104 @discussion This structure will be used to expand the capablilties of this class in the future.
105 */
0b4e3aa0 106 struct ExpansionData {
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107 void * devicePager;
108 unsigned int pagerContig:1;
109 unsigned int unused:31;
110 IOMemoryDescriptor * memory;
0b4e3aa0 111 };
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112
113/*! @var reserved
114 Reserved for future use. (Internal use only) */
115 ExpansionData * reserved;
116
117protected:
118 OSSet * _mappings;
119 IOOptionBits _flags;
120 void * _memEntry;
121
55e303ae 122 IODirection _direction; /* DEPRECATED: use _flags instead. direction of transfer */
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123 IOByteCount _length; /* length of all ranges */
124 IOOptionBits _tag;
125
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126public:
127
128 virtual IOPhysicalAddress getSourceSegment( IOByteCount offset,
129 IOByteCount * length );
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130 OSMetaClassDeclareReservedUsed(IOMemoryDescriptor, 0);
131
132/*! @function initWithOptions
133 @abstract Master initialiser for all variants of memory descriptors. For a more complete description see IOMemoryDescriptor::withOptions.
134 @discussion Note this function can be used to re-init a previously created memory descriptor.
135 @result true on success, false on failure. */
136 virtual bool initWithOptions(void * buffers,
137 UInt32 count,
138 UInt32 offset,
139 task_t task,
140 IOOptionBits options,
141 IOMapper * mapper = 0);
142 OSMetaClassDeclareReservedUsed(IOMemoryDescriptor, 1);
143
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144 virtual addr64_t getPhysicalSegment64( IOByteCount offset,
145 IOByteCount * length );
55e303ae 146 OSMetaClassDeclareReservedUsed(IOMemoryDescriptor, 2);
0b4e3aa0 147
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148
149/*! @function setPurgeable
150 @abstract Control the purgeable status of a memory descriptors memory.
151 @discussion Buffers may be allocated with the ability to have their purgeable status changed - IOBufferMemoryDescriptor with the kIOMemoryPurgeable option, VM_FLAGS_PURGEABLE may be passed to vm_allocate() in user space to allocate such buffers. The purgeable status of such a buffer may be controlled with setPurgeable(). The process of making a purgeable memory descriptor non-volatile and determining its previous state is atomic - if a purgeable memory descriptor is made nonvolatile and the old state is returned as kIOMemoryPurgeableVolatile, then the memory's previous contents are completely intact and will remain so until the memory is made volatile again. If the old state is returned as kIOMemoryPurgeableEmpty then the memory was reclaimed while it was in a volatile state and its previous contents have been lost.
152 @param newState - the desired new purgeable state of the memory:<br>
153 kIOMemoryPurgeableKeepCurrent - make no changes to the memory's purgeable state.<br>
154 kIOMemoryPurgeableVolatile - make the memory volatile - the memory may be reclaimed by the VM system without saving its contents to backing store.<br>
155 kIOMemoryPurgeableNonVolatile - make the memory nonvolatile - the memory is treated as with usual allocations and must be saved to backing store if paged.<br>
156 kIOMemoryPurgeableEmpty - make the memory volatile, and discard any pages allocated to it.
157 @param oldState - if non-NULL, the previous purgeable state of the memory is returned here:<br>
158 kIOMemoryPurgeableNonVolatile - the memory was nonvolatile.<br>
159 kIOMemoryPurgeableVolatile - the memory was volatile but its content has not been discarded by the VM system.<br>
160 kIOMemoryPurgeableEmpty - the memory was volatile and has been discarded by the VM system.<br>
161 @result An IOReturn code. */
162
163 virtual IOReturn setPurgeable( IOOptionBits newState,
164 IOOptionBits * oldState );
165 OSMetaClassDeclareReservedUsed(IOMemoryDescriptor, 3);
166
167/*! @function performOperation
168 @abstract Perform an operation on the memory descriptor's memory.
169 @discussion This method performs some operation on a range of the memory descriptor's memory. When a memory descriptor's memory is not mapped, it should be more efficient to use this method than mapping the memory to perform the operation virtually.
170 @param options The operation to perform on the memory:<br>
171 kIOMemoryIncoherentIOFlush - pass this option to store to memory and flush any data in the processor cache for the memory range, with synchronization to ensure the data has passed through all levels of processor cache. It may not be supported on all architectures. This type of flush may be used for non-coherent I/O such as AGP - it is NOT required for PCI coherent operations. The memory descriptor must have been previously prepared.<br>
172 kIOMemoryIncoherentIOStore - pass this option to store to memory any data in the processor cache for the memory range, with synchronization to ensure the data has passed through all levels of processor cache. It may not be supported on all architectures. This type of flush may be used for non-coherent I/O such as AGP - it is NOT required for PCI coherent operations. The memory descriptor must have been previously prepared.
173 @param offset A byte offset into the memory descriptor's memory.
174 @param length The length of the data range.
175 @result An IOReturn code. */
176
177 virtual IOReturn performOperation( IOOptionBits options,
178 IOByteCount offset, IOByteCount length );
179 OSMetaClassDeclareReservedUsed(IOMemoryDescriptor, 4);
180
1c79356b 181private:
55e303ae 182
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183 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 5);
184 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 6);
185 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 7);
186 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 8);
187 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 9);
188 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 10);
189 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 11);
190 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 12);
191 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 13);
192 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 14);
193 OSMetaClassDeclareReservedUnused(IOMemoryDescriptor, 15);
194
195protected:
196 virtual void free();
197public:
198 static void initialize( void );
199
200public:
201/*! @function withAddress
202 @abstract Create an IOMemoryDescriptor to describe one virtual range of the kernel task.
203 @discussion This method creates and initializes an IOMemoryDescriptor for memory consisting of a single virtual memory range mapped into the kernel map.
204 @param address The virtual address of the first byte in the memory.
205 @param withLength The length of memory.
206 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
207 @result The created IOMemoryDescriptor on success, to be released by the caller, or zero on failure. */
208
209 static IOMemoryDescriptor * withAddress(void * address,
210 IOByteCount withLength,
211 IODirection withDirection);
212
213/*! @function withAddress
214 @abstract Create an IOMemoryDescriptor to describe one virtual range of the specified map.
215 @discussion This method creates and initializes an IOMemoryDescriptor for memory consisting of a single virtual memory range mapped into the specified map.
216 @param address The virtual address of the first byte in the memory.
217 @param withLength The length of memory.
218 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
219 @param withTask The task the virtual ranges are mapped into.
220 @result The created IOMemoryDescriptor on success, to be released by the caller, or zero on failure. */
221
222 static IOMemoryDescriptor * withAddress(vm_address_t address,
223 IOByteCount withLength,
224 IODirection withDirection,
225 task_t withTask);
226
227/*! @function withPhysicalAddress
228 @abstract Create an IOMemoryDescriptor to describe one physical range.
229 @discussion This method creates and initializes an IOMemoryDescriptor for memory consisting of a single physical memory range.
230 @param address The physical address of the first byte in the memory.
231 @param withLength The length of memory.
232 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
233 @result The created IOMemoryDescriptor on success, to be released by the caller, or zero on failure. */
234
235 static IOMemoryDescriptor * withPhysicalAddress(
236 IOPhysicalAddress address,
237 IOByteCount withLength,
238 IODirection withDirection );
239
240/*! @function withRanges
241 @abstract Create an IOMemoryDescriptor to describe one or more virtual ranges.
242 @discussion This method creates and initializes an IOMemoryDescriptor for memory consisting of an array of virtual memory ranges each mapped into a specified source task.
243 @param ranges An array of IOVirtualRange structures which specify the virtual ranges in the specified map which make up the memory to be described.
244 @param withCount The member count of the ranges array.
245 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
246 @param withTask The task each of the virtual ranges are mapped into.
247 @param asReference If false, the IOMemoryDescriptor object will make a copy of the ranges array, otherwise, the array will be used in situ, avoiding an extra allocation.
248 @result The created IOMemoryDescriptor on success, to be released by the caller, or zero on failure. */
249
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250 static IOMemoryDescriptor * withRanges(IOVirtualRange * ranges,
251 UInt32 withCount,
252 IODirection withDirection,
253 task_t withTask,
254 bool asReference = false);
255
256/*! @function withOptions
257 @abstract Master initialiser for all variants of memory descriptors.
258 @discussion This method creates and initializes an IOMemoryDescriptor for memory it has three main variants: Virtual, Physical & mach UPL. These variants are selected with the options parameter, see below. This memory descriptor needs to be prepared before it can be used to extract data from the memory described. However we temporarily have setup a mechanism that automatically prepares kernel_task memory descriptors at creation time.
259
260
261 @param buffers A pointer to an array of IOVirtualRanges or IOPhysicalRanges if the options:type is Virtual or Physical. For type UPL it is a upl_t returned by the mach/memory_object_types.h apis, primarily used internally by the UBC.
262
263 @param count options:type = Virtual or Physical count contains a count of the number of entires in the buffers array. For options:type = UPL this field contains a total length.
264
265 @param offset Only used when options:type = UPL, in which case this field contains an offset for the memory within the buffers upl.
266
267 @param task Only used options:type = Virtual, The task each of the virtual ranges are mapped into.
268
269 @param options
270 kIOMemoryDirectionMask (options:direction) This nibble indicates the I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
271 kIOMemoryTypeMask (options:type) kIOMemoryTypeVirtual, kIOMemoryTypePhysical, kIOMemoryTypeUPL Indicates that what type of memory basic memory descriptor to use. This sub-field also controls the interpretation of the buffers, count, offset & task parameters.
272 kIOMemoryAsReference For options:type = Virtual or Physical this indicate that the memory descriptor need not copy the ranges array into local memory. This is an optimisation to try to minimise unnecessary allocations.
273 kIOMemoryBufferPageable Only used by the IOBufferMemoryDescriptor as an indication that the kernel virtual memory is in fact pageable and we need to use the kernel pageable submap rather than the default map.
274 kIOMemoryNoAutoPrepare Indicates that the temporary AutoPrepare of kernel_task memory should not be performed.
275
276 @param mapper Which IOMapper should be used to map the in-memory physical addresses into I/O space addresses. Defaults to 0 which indicates that the system mapper is to be used, if present.
277
278 @result The created IOMemoryDescriptor on success, to be released by the caller, or zero on failure. */
279
280 static IOMemoryDescriptor *withOptions(void * buffers,
281 UInt32 count,
282 UInt32 offset,
283 task_t task,
284 IOOptionBits options,
285 IOMapper * mapper = 0);
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286
287/*! @function withPhysicalRanges
288 @abstract Create an IOMemoryDescriptor to describe one or more physical ranges.
289 @discussion This method creates and initializes an IOMemoryDescriptor for memory consisting of an array of physical memory ranges.
290 @param ranges An array of IOPhysicalRange structures which specify the physical ranges which make up the memory to be described.
291 @param withCount The member count of the ranges array.
292 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
293 @param asReference If false, the IOMemoryDescriptor object will make a copy of the ranges array, otherwise, the array will be used in situ, avoiding an extra allocation.
294 @result The created IOMemoryDescriptor on success, to be released by the caller, or zero on failure. */
295
296 static IOMemoryDescriptor * withPhysicalRanges(
297 IOPhysicalRange * ranges,
298 UInt32 withCount,
55e303ae 299 IODirection withDirection,
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300 bool asReference = false);
301
302/*! @function withSubRange
303 @abstract Create an IOMemoryDescriptor to describe a subrange of an existing descriptor.
304 @discussion This method creates and initializes an IOMemoryDescriptor for memory consisting of a subrange of the specified memory descriptor. The parent memory descriptor is retained by the new descriptor.
305 @param of The parent IOMemoryDescriptor of which a subrange is to be used for the new descriptor, which will be retained by the subrange IOMemoryDescriptor.
306 @param offset A byte offset into the parent memory descriptor's memory.
307 @param length The length of the subrange.
308 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures. This is used over the direction of the parent descriptor.
309 @result The created IOMemoryDescriptor on success, to be released by the caller, or zero on failure. */
310
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311 static IOMemoryDescriptor * withSubRange(IOMemoryDescriptor *of,
312 IOByteCount offset,
313 IOByteCount length,
314 IODirection withDirection);
1c79356b 315
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316/*! @function withPersistentMemoryDescriptor
317 @abstract Copy constructor that generates a new memory descriptor if the backing memory for the same task's virtual address and length has changed.
318 @discussion If the original memory descriptor's address and length is still backed by the same real memory, i.e. the user hasn't deallocated and the reallocated memory at the same address then the original memory descriptor is returned with a additional reference. Otherwise we build a totally new memory descriptor with the same characteristics as the previous one but with a new view of the vm. Note not legal to call this function with anything except an IOGeneralMemoryDescriptor that was created with the kIOMemoryPersistent option.
319 @param originalMD The memory descriptor to be duplicated.
320 @result Either the original memory descriptor with an additional retain or a new memory descriptor, 0 for a bad original memory descriptor or some other resource shortage. */
321 static IOMemoryDescriptor *
322 withPersistentMemoryDescriptor(IOMemoryDescriptor *originalMD);
323
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324/*! @function initWithAddress
325 @abstract Initialize or reinitialize an IOMemoryDescriptor to describe one virtual range of the kernel task.
326 @discussion This method initializes an IOMemoryDescriptor for memory consisting of a single virtual memory range mapped into the kernel map. An IOMemoryDescriptor can be re-used by calling initWithAddress or initWithRanges again on an existing instance -- note this behavior is not commonly supported in other IOKit classes, although it is supported here.
327 @param address The virtual address of the first byte in the memory.
328 @param withLength The length of memory.
329 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
330 @result true on success, false on failure. */
331
332 virtual bool initWithAddress(void * address,
333 IOByteCount withLength,
334 IODirection withDirection) = 0;
335
336/*! @function initWithAddress
337 @abstract Initialize or reinitialize an IOMemoryDescriptor to describe one virtual range of the specified map.
338 @discussion This method initializes an IOMemoryDescriptor for memory consisting of a single virtual memory range mapped into the specified map. An IOMemoryDescriptor can be re-used by calling initWithAddress or initWithRanges again on an existing instance -- note this behavior is not commonly supported in other IOKit classes, although it is supported here.
339 @param address The virtual address of the first byte in the memory.
340 @param withLength The length of memory.
341 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
342 @param withTask The task the virtual ranges are mapped into.
343 @result true on success, false on failure. */
344
345 virtual bool initWithAddress(vm_address_t address,
346 IOByteCount withLength,
347 IODirection withDirection,
348 task_t withTask) = 0;
349
350/*! @function initWithPhysicalAddress
351 @abstract Initialize or reinitialize an IOMemoryDescriptor to describe one physical range.
352 @discussion This method initializes an IOMemoryDescriptor for memory consisting of a single physical memory range. An IOMemoryDescriptor can be re-used by calling initWithAddress or initWithRanges again on an existing instance -- note this behavior is not commonly supported in other IOKit classes, although it is supported here.
353 @param address The physical address of the first byte in the memory.
354 @param withLength The length of memory.
355 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
356 @result true on success, false on failure. */
357
358 virtual bool initWithPhysicalAddress(
359 IOPhysicalAddress address,
360 IOByteCount withLength,
361 IODirection withDirection ) = 0;
362
363/*! @function initWithRanges
364 @abstract Initialize or reinitialize an IOMemoryDescriptor to describe one or more virtual ranges.
365 @discussion This method initializes an IOMemoryDescriptor for memory consisting of an array of virtual memory ranges each mapped into a specified source task. An IOMemoryDescriptor can be re-used by calling initWithAddress or initWithRanges again on an existing instance -- note this behavior is not commonly supported in other IOKit classes, although it is supported here.
366 @param ranges An array of IOVirtualRange structures which specify the virtual ranges in the specified map which make up the memory to be described.
367 @param withCount The member count of the ranges array.
368 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
369 @param withTask The task each of the virtual ranges are mapped into.
370 @param asReference If false, the IOMemoryDescriptor object will make a copy of the ranges array, otherwise, the array will be used in situ, avoiding an extra allocation.
371 @result true on success, false on failure. */
372
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373 virtual bool initWithRanges(IOVirtualRange * ranges,
374 UInt32 withCount,
375 IODirection withDirection,
376 task_t withTask,
377 bool asReference = false) = 0;
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378
379/*! @function initWithPhysicalRanges
380 @abstract Initialize or reinitialize an IOMemoryDescriptor to describe one or more physical ranges.
381 @discussion This method initializes an IOMemoryDescriptor for memory consisting of an array of physical memory ranges. An IOMemoryDescriptor can be re-used by calling initWithAddress or initWithRanges again on an existing instance -- note this behavior is not commonly supported in other IOKit classes, although it is supported here.
382 @param ranges An array of IOPhysicalRange structures which specify the physical ranges which make up the memory to be described.
383 @param withCount The member count of the ranges array.
384 @param withDirection An I/O direction to be associated with the descriptor, which may affect the operation of the prepare and complete methods on some architectures.
385 @param asReference If false, the IOMemoryDescriptor object will make a copy of the ranges array, otherwise, the array will be used in situ, avoiding an extra allocation.
386 @result true on success, false on failure. */
387
388 virtual bool initWithPhysicalRanges(IOPhysicalRange * ranges,
389 UInt32 withCount,
390 IODirection withDirection,
391 bool asReference = false) = 0;
392
393/*! @function getDirection
394 @abstract Accessor to get the direction the memory descriptor was created with.
395 @discussion This method returns the direction the memory descriptor was created with.
396 @result The direction. */
397
398 virtual IODirection getDirection() const;
399
400/*! @function getLength
401 @abstract Accessor to get the length of the memory descriptor (over all its ranges).
402 @discussion This method returns the total length of the memory described by the descriptor, ie. the sum of its ranges' lengths.
403 @result The byte count. */
404
405 virtual IOByteCount getLength() const;
406
407/*! @function setTag
408 @abstract Set the tag for the memory descriptor.
409 @discussion This method sets the tag for the memory descriptor. Tag bits are not interpreted by IOMemoryDescriptor.
410 @param tag The tag. */
411
412 virtual void setTag( IOOptionBits tag );
413
414/*! @function getTag
415 @abstract Accessor to the retrieve the tag for the memory descriptor.
416 @discussion This method returns the tag for the memory descriptor. Tag bits are not interpreted by IOMemoryDescriptor.
417 @result The tag. */
418
419 virtual IOOptionBits getTag( void );
420
421/*! @function readBytes
422 @abstract Copy data from the memory descriptor's buffer to the specified buffer.
423 @discussion This method copies data from the memory descriptor's memory at the given offset, to the caller's buffer.
424 @param offset A byte offset into the memory descriptor's memory.
425 @param bytes The caller supplied buffer to copy the data to.
426 @param withLength The length of the data to copy.
427 @result The number of bytes copied, zero will be returned if the specified offset is beyond the length of the descriptor. */
428
429 virtual IOByteCount readBytes(IOByteCount offset,
0b4e3aa0 430 void * bytes, IOByteCount withLength);
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431
432/*! @function writeBytes
433 @abstract Copy data to the memory descriptor's buffer from the specified buffer.
434 @discussion This method copies data to the memory descriptor's memory at the given offset, from the caller's buffer.
435 @param offset A byte offset into the memory descriptor's memory.
436 @param bytes The caller supplied buffer to copy the data from.
437 @param withLength The length of the data to copy.
438 @result The number of bytes copied, zero will be returned if the specified offset is beyond the length of the descriptor. */
439
440 virtual IOByteCount writeBytes(IOByteCount offset,
0b4e3aa0 441 const void * bytes, IOByteCount withLength);
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442
443/*! @function getPhysicalSegment
444 @abstract Break a memory descriptor into its physically contiguous segments.
445 @discussion This method returns the physical address of the byte at the given offset into the memory, and optionally the length of the physically contiguous segment from that offset.
446 @param offset A byte offset into the memory whose physical address to return.
447 @param length If non-zero, getPhysicalSegment will store here the length of the physically contiguous segement at the given offset.
448 @result A physical address, or zero if the offset is beyond the length of the memory. */
449
450 virtual IOPhysicalAddress getPhysicalSegment(IOByteCount offset,
451 IOByteCount * length) = 0;
452
453/*! @function getPhysicalAddress
454 @abstract Return the physical address of the first byte in the memory.
455 @discussion This method returns the physical address of the first byte in the memory. It is most useful on memory known to be physically contiguous.
456 @result A physical address. */
457
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458 /* inline */ IOPhysicalAddress getPhysicalAddress();
459 /* { return( getPhysicalSegment( 0, 0 )); } */
1c79356b 460
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461 /* DEPRECATED */ /* USE INSTEAD: map(), readBytes(), writeBytes() */
462 /* DEPRECATED */ virtual void * getVirtualSegment(IOByteCount offset,
463 /* DEPRECATED */ IOByteCount * length) = 0;
464 /* DEPRECATED */ /* USE INSTEAD: map(), readBytes(), writeBytes() */
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465
466/*! @function prepare
467 @abstract Prepare the memory for an I/O transfer.
55e303ae 468 @discussion This involves paging in the memory, if necessary, and wiring it down for the duration of the transfer. The complete() method completes the processing of the memory after the I/O transfer finishes. Note that the prepare call is not thread safe and it is expected that the client will more easily be able to guarantee single threading a particular memory descriptor.
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469 @param forDirection The direction of the I/O just completed, or kIODirectionNone for the direction specified by the memory descriptor.
470 @result An IOReturn code. */
471
472 virtual IOReturn prepare(IODirection forDirection = kIODirectionNone) = 0;
473
474/*! @function complete
475 @abstract Complete processing of the memory after an I/O transfer finishes.
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476 @discussion This method should not be called unless a prepare was previously issued; the prepare() and complete() must occur in pairs, before and after an I/O transfer involving pageable memory. In 10.3 or greater systems the direction argument to complete is not longer respected. The direction is totally determined at prepare() time.
477 @param forDirection DEPRECATED The direction of the I/O just completed, or kIODirectionNone for the direction specified by the memory descriptor.
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478 @result An IOReturn code. */
479
480 virtual IOReturn complete(IODirection forDirection = kIODirectionNone) = 0;
481
482 /*
483 * Mapping functions.
484 */
485
486/*! @function map
487 @abstract Maps a IOMemoryDescriptor into a task.
488 @discussion This is the general purpose method to map all or part of the memory described by a memory descriptor into a task at any available address, or at a fixed address if possible. Caching & read-only options may be set for the mapping. The mapping is represented as a returned reference to a IOMemoryMap object, which may be shared if the mapping is compatible with an existing mapping of the IOMemoryDescriptor. The IOMemoryMap object returned should be released only when the caller has finished accessing the mapping, as freeing the object destroys the mapping.
489 @param intoTask Sets the target task for the mapping. Pass kernel_task for the kernel address space.
490 @param atAddress If a placed mapping is requested, atAddress specifies its address, and the kIOMapAnywhere should not be set. Otherwise, atAddress is ignored.
491 @param options Mapping options are defined in IOTypes.h,<br>
492 kIOMapAnywhere should be passed if the mapping can be created anywhere. If not set, the atAddress parameter sets the location of the mapping, if it is available in the target map.<br>
493 kIOMapDefaultCache to inhibit the cache in I/O areas, kIOMapCopybackCache in general purpose RAM.<br>
494 kIOMapInhibitCache, kIOMapWriteThruCache, kIOMapCopybackCache to set the appropriate caching.<br>
495 kIOMapReadOnly to allow only read only accesses to the memory - writes will cause and access fault.<br>
496 kIOMapReference will only succeed if the mapping already exists, and the IOMemoryMap object is just an extra reference, ie. no new mapping will be created.<br>
91447636 497 kIOMapUnique allows a special kind of mapping to be created that may be used with the IOMemoryMap::redirect() API. These mappings will not be shared as is the default - there will always be a unique mapping created for the caller, not an existing mapping with an extra reference.<br>
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498 @param offset Is a beginning offset into the IOMemoryDescriptor's memory where the mapping starts. Zero is the default to map all the memory.
499 @param length Is the length of the mapping requested for a subset of the IOMemoryDescriptor. Zero is the default to map all the memory.
500 @result A reference to an IOMemoryMap object representing the mapping, which can supply the virtual address of the mapping and other information. The mapping may be shared with multiple callers - multiple maps are avoided if a compatible one exists. The IOMemoryMap object returned should be released only when the caller has finished accessing the mapping, as freeing the object destroys the mapping. The IOMemoryMap instance also retains the IOMemoryDescriptor it maps while it exists. */
501
502 virtual IOMemoryMap * map(
503 task_t intoTask,
504 IOVirtualAddress atAddress,
505 IOOptionBits options,
506 IOByteCount offset = 0,
507 IOByteCount length = 0 );
508
509/*! @function map
510 @abstract Maps a IOMemoryDescriptor into the kernel map.
511 @discussion This is a shortcut method to map all the memory described by a memory descriptor into the kernel map at any available address. See the full version of the map method for further details.
512 @param options Mapping options as in the full version of the map method, with kIOMapAnywhere assumed.
513 @result See the full version of the map method. */
514
515 virtual IOMemoryMap * map(
516 IOOptionBits options = 0 );
517
518/*! @function setMapping
519 @abstract Establishes an already existing mapping.
520 @discussion This method tells the IOMemoryDescriptor about a mapping that exists, but was created elsewhere. It allows later callers of the map method to share this externally created mapping. The IOMemoryMap object returned is created to represent it. This method is not commonly needed.
521 @param task Address space in which the mapping exists.
522 @param mapAddress Virtual address of the mapping.
523 @param options Caching and read-only attributes of the mapping.
524 @result A IOMemoryMap object created to represent the mapping. */
525
526 virtual IOMemoryMap * setMapping(
527 task_t task,
528 IOVirtualAddress mapAddress,
529 IOOptionBits options = 0 );
530
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531 // Following methods are private implementation
532
533 // make virtual
534 IOReturn redirect( task_t safeTask, bool redirect );
535
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536 IOReturn handleFault(
537 void * pager,
538 vm_map_t addressMap,
539 IOVirtualAddress address,
540 IOByteCount sourceOffset,
541 IOByteCount length,
542 IOOptionBits options );
543
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544protected:
545 virtual IOMemoryMap * makeMapping(
546 IOMemoryDescriptor * owner,
547 task_t intoTask,
548 IOVirtualAddress atAddress,
549 IOOptionBits options,
550 IOByteCount offset,
551 IOByteCount length );
552
553 virtual void addMapping(
554 IOMemoryMap * mapping );
555
556 virtual void removeMapping(
557 IOMemoryMap * mapping );
558
559 virtual IOReturn doMap(
560 vm_map_t addressMap,
561 IOVirtualAddress * atAddress,
562 IOOptionBits options,
563 IOByteCount sourceOffset = 0,
564 IOByteCount length = 0 );
565
566 virtual IOReturn doUnmap(
567 vm_map_t addressMap,
568 IOVirtualAddress logical,
569 IOByteCount length );
570};
571
572/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
573
574/*! @class IOMemoryMap : public OSObject
575 @abstract An abstract base class defining common methods for describing a memory mapping.
576 @discussion The IOMemoryMap object represents a mapped range of memory, described by a IOMemoryDescriptor. The mapping may be in the kernel or a non-kernel task and has processor cache mode attributes. IOMemoryMap instances are created by IOMemoryDescriptor when it creates mappings in its map method, and returned to the caller. */
577
578class IOMemoryMap : public OSObject
579{
580 OSDeclareAbstractStructors(IOMemoryMap)
581
582public:
583/*! @function getVirtualAddress
584 @abstract Accessor to the virtual address of the first byte in the mapping.
585 @discussion This method returns the virtual address of the first byte in the mapping.
586 @result A virtual address. */
587
588 virtual IOVirtualAddress getVirtualAddress() = 0;
589
590/*! @function getPhysicalSegment
591 @abstract Break a mapping into its physically contiguous segments.
592 @discussion This method returns the physical address of the byte at the given offset into the mapping, and optionally the length of the physically contiguous segment from that offset. It functions similarly to IOMemoryDescriptor::getPhysicalSegment.
593 @param offset A byte offset into the mapping whose physical address to return.
594 @param length If non-zero, getPhysicalSegment will store here the length of the physically contiguous segement at the given offset.
595 @result A physical address, or zero if the offset is beyond the length of the mapping. */
596
597 virtual IOPhysicalAddress getPhysicalSegment(IOByteCount offset,
598 IOByteCount * length) = 0;
599
600/*! @function getPhysicalAddress
601 @abstract Return the physical address of the first byte in the mapping.
602 @discussion This method returns the physical address of the first byte in the mapping. It is most useful on mappings known to be physically contiguous.
603 @result A physical address. */
604
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605 /* inline */ IOPhysicalAddress getPhysicalAddress();
606 /* { return( getPhysicalSegment( 0, 0 )); } */
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607
608/*! @function getLength
609 @abstract Accessor to the length of the mapping.
610 @discussion This method returns the length of the mapping.
611 @result A byte count. */
612
613 virtual IOByteCount getLength() = 0;
614
615/*! @function getAddressTask
616 @abstract Accessor to the task of the mapping.
617 @discussion This method returns the mach task the mapping exists in.
618 @result A mach task_t. */
619
620 virtual task_t getAddressTask() = 0;
621
622/*! @function getMemoryDescriptor
623 @abstract Accessor to the IOMemoryDescriptor the mapping was created from.
624 @discussion This method returns the IOMemoryDescriptor the mapping was created from.
625 @result An IOMemoryDescriptor reference, which is valid while the IOMemoryMap object is retained. It should not be released by the caller. */
626
627 virtual IOMemoryDescriptor * getMemoryDescriptor() = 0;
628
629/*! @function getMapOptions
630 @abstract Accessor to the options the mapping was created with.
631 @discussion This method returns the options to IOMemoryDescriptor::map the mapping was created with.
632 @result Options for the mapping, including cache settings. */
633
634 virtual IOOptionBits getMapOptions() = 0;
635
636/*! @function unmap
637 @abstract Force the IOMemoryMap to unmap, without destroying the object.
638 @discussion IOMemoryMap instances will unmap themselves upon free, ie. when the last client with a reference calls release. This method forces the IOMemoryMap to destroy the mapping it represents, regardless of the number of clients. It is not generally used.
639 @result An IOReturn code. */
640
641 virtual IOReturn unmap() = 0;
642
55e303ae 643 virtual void taskDied() = 0;
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644
645/*! @function redirect
646 @abstract Replace the memory mapped in a process with new backing memory.
647 @discussion An IOMemoryMap created with the kIOMapUnique option to IOMemoryDescriptor::map() can remapped to a new IOMemoryDescriptor backing object. If the new IOMemoryDescriptor is specified as NULL, client access to the memory map is blocked until a new backing object has been set. By blocking access and copying data, the caller can create atomic copies of the memory while the client is potentially reading or writing the memory.
648 @param newBackingMemory The IOMemoryDescriptor that represents the physical memory that is to be now mapped in the virtual range the IOMemoryMap represents. If newBackingMemory is NULL, any access to the mapping will hang (in vm_fault()) until access has been restored by a new call to redirect() with non-NULL newBackingMemory argument.
649 @param options Mapping options are defined in IOTypes.h, and are documented in IOMemoryDescriptor::map()
650 @param offset As with IOMemoryDescriptor::map(), a beginning offset into the IOMemoryDescriptor's memory where the mapping starts. Zero is the default.
651 @result An IOReturn code. */
652
653 virtual IOReturn redirect(IOMemoryDescriptor * newBackingMemory,
654 IOOptionBits options,
655 IOByteCount offset = 0) = 0;
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656};
657
658/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
659
e3027f41 660// The following classes are private implementation of IOMemoryDescriptor - they
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661// should not be referenced directly, just through the public API's in the
662// IOMemoryDescriptor class. For example, an IOGeneralMemoryDescriptor instance
663// might be created by IOMemoryDescriptor::withAddress(), but there should be
664// no need to reference as anything but a generic IOMemoryDescriptor *.
e3027f41 665
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666// Also these flags should not overlap with the options to
667// IOMemoryDescriptor::initWithRanges(... IOOptionsBits options);
668
1c79356b 669enum {
55e303ae 670 kIOMemoryPreparedReadOnly = 0x00008000,
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671};
672
673class IOGeneralMemoryDescriptor : public IOMemoryDescriptor
674{
675 OSDeclareDefaultStructors(IOGeneralMemoryDescriptor);
676
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677public:
678 union Ranges {
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679 IOVirtualRange * v;
680 IOPhysicalRange * p;
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681 void *uio;
682 };
683protected:
684 Ranges _ranges;
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685 unsigned _rangesCount; /* number of address ranges in list */
686 bool _rangesIsAllocated; /* is list allocated by us? */
687
688 task_t _task; /* task where all ranges are mapped to */
689
690 union {
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691 IOVirtualRange v;
692 IOPhysicalRange p;
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693 } _singleRange; /* storage space for a single range */
694
695 unsigned _wireCount; /* number of outstanding wires */
696
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697 /* DEPRECATED */ vm_address_t _cachedVirtualAddress; /* a cached virtual-to-physical */
698
699 /* DEPRECATED */ IOPhysicalAddress _cachedPhysicalAddress;
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700
701 bool _initialized; /* has superclass been initialized? */
702
703 virtual void free();
704
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705
706private:
91447636 707 // Internal APIs may be made virtual at some time in the future.
55e303ae 708 IOReturn wireVirtual(IODirection forDirection);
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709 void *createNamedEntry();
710
55e303ae 711
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712 /* DEPRECATED */ IOByteCount _position; /* absolute position over all ranges */
713 /* DEPRECATED */ virtual void setPosition(IOByteCount position);
1c79356b 714
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715/*
716 * DEPRECATED IOByteCount _positionAtIndex; // relative position within range #n
717 *
718 * Re-use the _positionAtIndex as a count of the number of pages in
719 * this memory descriptor. Convieniently vm_address_t is an unsigned integer
720 * type so I can get away without having to change the type.
721 */
722 unsigned int _pages;
723
724/* DEPRECATED */ unsigned _positionAtOffset; //range #n in which position is now
725
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726 OSData *_memoryEntries;
727
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728 /* DEPRECATED */ vm_offset_t _kernPtrAligned;
729 /* DEPRECATED */ unsigned _kernPtrAtIndex;
730 /* DEPRECATED */ IOByteCount _kernSize;
55e303ae 731
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732 /* DEPRECATED */ virtual void mapIntoKernel(unsigned rangeIndex);
733 /* DEPRECATED */ virtual void unmapFromKernel();
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734
735public:
736 /*
737 * IOMemoryDescriptor required methods
738 */
739
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740 // Master initaliser
741 virtual bool initWithOptions(void * buffers,
742 UInt32 count,
743 UInt32 offset,
744 task_t task,
745 IOOptionBits options,
746 IOMapper * mapper = 0);
d7e50217 747
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748 // Secondary initialisers
749 virtual bool initWithAddress(void * address,
750 IOByteCount withLength,
751 IODirection withDirection);
752
753 virtual bool initWithAddress(vm_address_t address,
1c79356b 754 IOByteCount withLength,
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755 IODirection withDirection,
756 task_t withTask);
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757
758 virtual bool initWithPhysicalAddress(
759 IOPhysicalAddress address,
760 IOByteCount withLength,
761 IODirection withDirection );
762
763 virtual bool initWithRanges( IOVirtualRange * ranges,
764 UInt32 withCount,
765 IODirection withDirection,
766 task_t withTask,
767 bool asReference = false);
768
769 virtual bool initWithPhysicalRanges(IOPhysicalRange * ranges,
770 UInt32 withCount,
771 IODirection withDirection,
772 bool asReference = false);
773
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774 virtual IOPhysicalAddress getPhysicalSegment(IOByteCount offset,
775 IOByteCount * length);
776
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777 virtual IOPhysicalAddress getSourceSegment(IOByteCount offset,
778 IOByteCount * length);
779
780 /* DEPRECATED */ virtual void * getVirtualSegment(IOByteCount offset,
781 /* DEPRECATED */ IOByteCount * length);
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782
783 virtual IOReturn prepare(IODirection forDirection = kIODirectionNone);
784
785 virtual IOReturn complete(IODirection forDirection = kIODirectionNone);
786
787 virtual IOReturn doMap(
788 vm_map_t addressMap,
789 IOVirtualAddress * atAddress,
790 IOOptionBits options,
791 IOByteCount sourceOffset = 0,
792 IOByteCount length = 0 );
793
794 virtual IOReturn doUnmap(
795 vm_map_t addressMap,
796 IOVirtualAddress logical,
797 IOByteCount length );
9bccf70c 798 virtual bool serialize(OSSerialize *s) const;
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799
800 // Factory method for cloning a persistent IOMD, see IOMemoryDescriptor
801 static IOMemoryDescriptor *
802 withPersistentMemoryDescriptor(IOGeneralMemoryDescriptor *originalMD);
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803};
804
805/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
806
807class IOSubMemoryDescriptor : public IOMemoryDescriptor
808{
9bccf70c 809 friend class IOMemoryDescriptor;
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810
811 OSDeclareDefaultStructors(IOSubMemoryDescriptor);
812
813protected:
814 IOMemoryDescriptor * _parent;
815 IOByteCount _start;
816
817 virtual void free();
818
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819 virtual bool initWithAddress(void * address,
820 IOByteCount withLength,
821 IODirection withDirection);
822
823 virtual bool initWithAddress(vm_address_t address,
824 IOByteCount withLength,
825 IODirection withDirection,
826 task_t withTask);
827
828 virtual bool initWithPhysicalAddress(
829 IOPhysicalAddress address,
830 IOByteCount withLength,
831 IODirection withDirection );
832
833 virtual bool initWithRanges( IOVirtualRange * ranges,
834 UInt32 withCount,
835 IODirection withDirection,
836 task_t withTask,
837 bool asReference = false);
838
839 virtual bool initWithPhysicalRanges(IOPhysicalRange * ranges,
840 UInt32 withCount,
841 IODirection withDirection,
842 bool asReference = false);
843
844 IOMemoryDescriptor::withAddress;
845 IOMemoryDescriptor::withPhysicalAddress;
846 IOMemoryDescriptor::withPhysicalRanges;
847 IOMemoryDescriptor::withRanges;
848 IOMemoryDescriptor::withSubRange;
849
850public:
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851 /*
852 * Initialize or reinitialize an IOSubMemoryDescriptor to describe
853 * a subrange of an existing descriptor.
854 *
855 * An IOSubMemoryDescriptor can be re-used by calling initSubRange
856 * again on an existing instance -- note that this behavior is not
857 * commonly supported in other IOKit classes, although it is here.
858 */
859 virtual bool initSubRange( IOMemoryDescriptor * parent,
860 IOByteCount offset, IOByteCount length,
861 IODirection withDirection );
862
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863 /*
864 * IOMemoryDescriptor required methods
865 */
866
867 virtual IOPhysicalAddress getPhysicalSegment(IOByteCount offset,
868 IOByteCount * length);
869
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870 virtual IOPhysicalAddress getSourceSegment(IOByteCount offset,
871 IOByteCount * length);
872
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873 virtual IOByteCount readBytes(IOByteCount offset,
874 void * bytes, IOByteCount withLength);
875
876 virtual IOByteCount writeBytes(IOByteCount offset,
877 const void * bytes, IOByteCount withLength);
878
879 virtual void * getVirtualSegment(IOByteCount offset,
880 IOByteCount * length);
881
882 virtual IOReturn prepare(IODirection forDirection = kIODirectionNone);
883
884 virtual IOReturn complete(IODirection forDirection = kIODirectionNone);
885
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886 // make virtual
887 IOReturn redirect( task_t safeTask, bool redirect );
888
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889 virtual bool serialize(OSSerialize *s) const;
890
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891 virtual IOReturn setPurgeable( IOOptionBits newState,
892 IOOptionBits * oldState );
893 virtual IOReturn performOperation( IOOptionBits options,
894 IOByteCount offset, IOByteCount length );
895
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896protected:
897 virtual IOMemoryMap * makeMapping(
898 IOMemoryDescriptor * owner,
899 task_t intoTask,
900 IOVirtualAddress atAddress,
901 IOOptionBits options,
902 IOByteCount offset,
903 IOByteCount length );
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904
905 virtual IOReturn doMap(
906 vm_map_t addressMap,
907 IOVirtualAddress * atAddress,
908 IOOptionBits options,
909 IOByteCount sourceOffset = 0,
910 IOByteCount length = 0 );
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911};
912
913/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
914
915#endif /* !_IOMEMORYDESCRIPTOR_H */