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504214c4 | 1 | /** @file\r |
504214c4 LG |
2 | UEFI Memory page management functions.\r |
3 | \r | |
9a701955 | 4 | Copyright (c) 2007 - 2017, Intel Corporation. All rights reserved.<BR>\r |
cd5ebaa0 | 5 | This program and the accompanying materials\r |
23c98c94 | 6 | are licensed and made available under the terms and conditions of the BSD License\r |
7 | which accompanies this distribution. The full text of the license may be found at\r | |
8 | http://opensource.org/licenses/bsd-license.php\r | |
9 | \r | |
10 | THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,\r | |
11 | WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.\r | |
28a00297 | 12 | \r |
504214c4 | 13 | **/\r |
28a00297 | 14 | \r |
9c4ac31c | 15 | #include "DxeMain.h"\r |
ec90508b | 16 | #include "Imem.h"\r |
e63da9f0 | 17 | #include "HeapGuard.h"\r |
28a00297 | 18 | \r |
28a00297 | 19 | //\r |
d45fd260 | 20 | // Entry for tracking the memory regions for each memory type to coalesce similar memory types\r |
28a00297 | 21 | //\r |
22 | typedef struct {\r | |
23 | EFI_PHYSICAL_ADDRESS BaseAddress;\r | |
24 | EFI_PHYSICAL_ADDRESS MaximumAddress;\r | |
25 | UINT64 CurrentNumberOfPages;\r | |
b74350e9 | 26 | UINT64 NumberOfPages;\r |
28a00297 | 27 | UINTN InformationIndex;\r |
b74350e9 | 28 | BOOLEAN Special;\r |
29 | BOOLEAN Runtime;\r | |
d613c2a8 | 30 | } EFI_MEMORY_TYPE_STATISTICS;\r |
28a00297 | 31 | \r |
32 | //\r | |
33 | // MemoryMap - The current memory map\r | |
34 | //\r | |
35 | UINTN mMemoryMapKey = 0;\r | |
36 | \r | |
28a00297 | 37 | #define MAX_MAP_DEPTH 6\r |
dc8d93ca | 38 | \r |
39 | ///\r | |
40 | /// mMapDepth - depth of new descriptor stack\r | |
41 | ///\r | |
28a00297 | 42 | UINTN mMapDepth = 0;\r |
dc8d93ca | 43 | ///\r |
44 | /// mMapStack - space to use as temp storage to build new map descriptors\r | |
45 | ///\r | |
28a00297 | 46 | MEMORY_MAP mMapStack[MAX_MAP_DEPTH];\r |
47 | UINTN mFreeMapStack = 0;\r | |
dc8d93ca | 48 | ///\r |
49 | /// This list maintain the free memory map list\r | |
50 | ///\r | |
e94a9ff7 | 51 | LIST_ENTRY mFreeMemoryMapEntryList = INITIALIZE_LIST_HEAD_VARIABLE (mFreeMemoryMapEntryList);\r |
52 | BOOLEAN mMemoryTypeInformationInitialized = FALSE;\r | |
28a00297 | 53 | \r |
d613c2a8 | 54 | EFI_MEMORY_TYPE_STATISTICS mMemoryTypeStatistics[EfiMaxMemoryType + 1] = {\r |
f3f2e05d | 55 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, TRUE, FALSE }, // EfiReservedMemoryType\r |
56 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE }, // EfiLoaderCode\r | |
57 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE }, // EfiLoaderData\r | |
58 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE }, // EfiBootServicesCode\r | |
59 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE }, // EfiBootServicesData\r | |
60 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, TRUE, TRUE }, // EfiRuntimeServicesCode\r | |
61 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, TRUE, TRUE }, // EfiRuntimeServicesData\r | |
62 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE }, // EfiConventionalMemory\r | |
63 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE }, // EfiUnusableMemory\r | |
64 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, TRUE, FALSE }, // EfiACPIReclaimMemory\r | |
65 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, TRUE, FALSE }, // EfiACPIMemoryNVS\r | |
66 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE }, // EfiMemoryMappedIO\r | |
67 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE }, // EfiMemoryMappedIOPortSpace\r | |
68 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, TRUE, TRUE }, // EfiPalCode\r | |
a671a012 | 69 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE }, // EfiPersistentMemory\r |
f3f2e05d | 70 | { 0, MAX_ADDRESS, 0, 0, EfiMaxMemoryType, FALSE, FALSE } // EfiMaxMemoryType\r |
28a00297 | 71 | };\r |
72 | \r | |
f3f2e05d | 73 | EFI_PHYSICAL_ADDRESS mDefaultMaximumAddress = MAX_ADDRESS;\r |
2345e7d4 | 74 | EFI_PHYSICAL_ADDRESS mDefaultBaseAddress = MAX_ADDRESS;\r |
28a00297 | 75 | \r |
76 | EFI_MEMORY_TYPE_INFORMATION gMemoryTypeInformation[EfiMaxMemoryType + 1] = {\r | |
77 | { EfiReservedMemoryType, 0 },\r | |
78 | { EfiLoaderCode, 0 },\r | |
79 | { EfiLoaderData, 0 },\r | |
80 | { EfiBootServicesCode, 0 },\r | |
81 | { EfiBootServicesData, 0 },\r | |
82 | { EfiRuntimeServicesCode, 0 },\r | |
83 | { EfiRuntimeServicesData, 0 },\r | |
84 | { EfiConventionalMemory, 0 },\r | |
85 | { EfiUnusableMemory, 0 },\r | |
86 | { EfiACPIReclaimMemory, 0 },\r | |
87 | { EfiACPIMemoryNVS, 0 },\r | |
88 | { EfiMemoryMappedIO, 0 },\r | |
89 | { EfiMemoryMappedIOPortSpace, 0 },\r | |
90 | { EfiPalCode, 0 },\r | |
a671a012 | 91 | { EfiPersistentMemory, 0 },\r |
28a00297 | 92 | { EfiMaxMemoryType, 0 }\r |
93 | };\r | |
54ea99a7 | 94 | //\r |
95 | // Only used when load module at fixed address feature is enabled. True means the memory is alreay successfully allocated\r | |
96 | // and ready to load the module in to specified address.or else, the memory is not ready and module will be loaded at a \r | |
97 | // address assigned by DXE core.\r | |
98 | //\r | |
99 | GLOBAL_REMOVE_IF_UNREFERENCED BOOLEAN gLoadFixedAddressCodeMemoryReady = FALSE;\r | |
d9177625 | 100 | \r |
162ed594 | 101 | /**\r |
d9177625 | 102 | Enter critical section by gaining lock on gMemoryLock.\r |
162ed594 | 103 | \r |
104 | **/\r | |
23c98c94 | 105 | VOID\r |
d9177625 | 106 | CoreAcquireMemoryLock (\r |
107 | VOID\r | |
108 | )\r | |
109 | {\r | |
110 | CoreAcquireLock (&gMemoryLock);\r | |
111 | }\r | |
112 | \r | |
113 | \r | |
114 | \r | |
115 | /**\r | |
116 | Exit critical section by releasing lock on gMemoryLock.\r | |
117 | \r | |
118 | **/\r | |
119 | VOID\r | |
120 | CoreReleaseMemoryLock (\r | |
28a00297 | 121 | VOID\r |
d9177625 | 122 | )\r |
123 | {\r | |
124 | CoreReleaseLock (&gMemoryLock);\r | |
125 | }\r | |
126 | \r | |
127 | \r | |
128 | \r | |
129 | \r | |
130 | /**\r | |
131 | Internal function. Removes a descriptor entry.\r | |
132 | \r | |
133 | @param Entry The entry to remove\r | |
134 | \r | |
135 | **/\r | |
136 | VOID\r | |
137 | RemoveMemoryMapEntry (\r | |
138 | IN OUT MEMORY_MAP *Entry\r | |
139 | )\r | |
140 | {\r | |
141 | RemoveEntryList (&Entry->Link);\r | |
142 | Entry->Link.ForwardLink = NULL;\r | |
143 | \r | |
144 | if (Entry->FromPages) {\r | |
145 | //\r | |
146 | // Insert the free memory map descriptor to the end of mFreeMemoryMapEntryList\r | |
147 | //\r | |
148 | InsertTailList (&mFreeMemoryMapEntryList, &Entry->Link);\r | |
149 | }\r | |
150 | }\r | |
162ed594 | 151 | \r |
152 | /**\r | |
153 | Internal function. Adds a ranges to the memory map.\r | |
154 | The range must not already exist in the map.\r | |
155 | \r | |
022c6d45 | 156 | @param Type The type of memory range to add\r |
157 | @param Start The starting address in the memory range Must be\r | |
158 | paged aligned\r | |
159 | @param End The last address in the range Must be the last\r | |
160 | byte of a page\r | |
161 | @param Attribute The attributes of the memory range to add\r | |
28a00297 | 162 | \r |
162ed594 | 163 | **/\r |
28a00297 | 164 | VOID\r |
165 | CoreAddRange (\r | |
166 | IN EFI_MEMORY_TYPE Type,\r | |
167 | IN EFI_PHYSICAL_ADDRESS Start,\r | |
168 | IN EFI_PHYSICAL_ADDRESS End,\r | |
169 | IN UINT64 Attribute\r | |
d9177625 | 170 | )\r |
171 | {\r | |
172 | LIST_ENTRY *Link;\r | |
173 | MEMORY_MAP *Entry;\r | |
28a00297 | 174 | \r |
d9177625 | 175 | ASSERT ((Start & EFI_PAGE_MASK) == 0);\r |
176 | ASSERT (End > Start) ;\r | |
162ed594 | 177 | \r |
d9177625 | 178 | ASSERT_LOCKED (&gMemoryLock);\r |
28a00297 | 179 | \r |
d9177625 | 180 | DEBUG ((DEBUG_PAGE, "AddRange: %lx-%lx to %d\n", Start, End, Type));\r |
d436d5ca | 181 | \r |
182 | //\r | |
183 | // If memory of type EfiConventionalMemory is being added that includes the page \r | |
184 | // starting at address 0, then zero the page starting at address 0. This has \r | |
185 | // two benifits. It helps find NULL pointer bugs and it also maximizes \r | |
186 | // compatibility with operating systems that may evaluate memory in this page \r | |
187 | // for legacy data structures. If memory of any other type is added starting \r | |
188 | // at address 0, then do not zero the page at address 0 because the page is being \r | |
189 | // used for other purposes.\r | |
190 | // \r | |
191 | if (Type == EfiConventionalMemory && Start == 0 && (End >= EFI_PAGE_SIZE - 1)) {\r | |
a7181d95 JW |
192 | if ((PcdGet8 (PcdNullPointerDetectionPropertyMask) & BIT0) == 0) {\r |
193 | SetMem ((VOID *)(UINTN)Start, EFI_PAGE_SIZE, 0);\r | |
194 | }\r | |
d436d5ca | 195 | }\r |
196 | \r | |
d9177625 | 197 | //\r |
198 | // Memory map being altered so updated key\r | |
199 | //\r | |
200 | mMemoryMapKey += 1;\r | |
162ed594 | 201 | \r |
d9177625 | 202 | //\r |
203 | // UEFI 2.0 added an event group for notificaiton on memory map changes.\r | |
204 | // So we need to signal this Event Group every time the memory map changes.\r | |
205 | // If we are in EFI 1.10 compatability mode no event groups will be\r | |
206 | // found and nothing will happen we we call this function. These events\r | |
207 | // will get signaled but since a lock is held around the call to this\r | |
6393d9c8 | 208 | // function the notificaiton events will only be called after this function\r |
d9177625 | 209 | // returns and the lock is released.\r |
210 | //\r | |
211 | CoreNotifySignalList (&gEfiEventMemoryMapChangeGuid);\r | |
162ed594 | 212 | \r |
d9177625 | 213 | //\r |
214 | // Look for adjoining memory descriptor\r | |
215 | //\r | |
28a00297 | 216 | \r |
d9177625 | 217 | // Two memory descriptors can only be merged if they have the same Type\r |
218 | // and the same Attribute\r | |
219 | //\r | |
162ed594 | 220 | \r |
d9177625 | 221 | Link = gMemoryMap.ForwardLink;\r |
222 | while (Link != &gMemoryMap) {\r | |
223 | Entry = CR (Link, MEMORY_MAP, Link, MEMORY_MAP_SIGNATURE);\r | |
224 | Link = Link->ForwardLink;\r | |
162ed594 | 225 | \r |
d9177625 | 226 | if (Entry->Type != Type) {\r |
227 | continue;\r | |
228 | }\r | |
229 | \r | |
230 | if (Entry->Attribute != Attribute) {\r | |
231 | continue;\r | |
232 | }\r | |
233 | \r | |
234 | if (Entry->End + 1 == Start) {\r | |
235 | \r | |
236 | Start = Entry->Start;\r | |
237 | RemoveMemoryMapEntry (Entry);\r | |
238 | \r | |
239 | } else if (Entry->Start == End + 1) {\r | |
240 | \r | |
241 | End = Entry->End;\r | |
242 | RemoveMemoryMapEntry (Entry);\r | |
243 | }\r | |
244 | }\r | |
245 | \r | |
246 | //\r | |
247 | // Add descriptor\r | |
248 | //\r | |
249 | \r | |
250 | mMapStack[mMapDepth].Signature = MEMORY_MAP_SIGNATURE;\r | |
251 | mMapStack[mMapDepth].FromPages = FALSE;\r | |
252 | mMapStack[mMapDepth].Type = Type;\r | |
253 | mMapStack[mMapDepth].Start = Start;\r | |
254 | mMapStack[mMapDepth].End = End;\r | |
255 | mMapStack[mMapDepth].VirtualStart = 0;\r | |
256 | mMapStack[mMapDepth].Attribute = Attribute;\r | |
257 | InsertTailList (&gMemoryMap, &mMapStack[mMapDepth].Link);\r | |
258 | \r | |
259 | mMapDepth += 1;\r | |
260 | ASSERT (mMapDepth < MAX_MAP_DEPTH);\r | |
261 | \r | |
262 | return ;\r | |
263 | }\r | |
022c6d45 | 264 | \r |
162ed594 | 265 | /**\r |
266 | Internal function. Deque a descriptor entry from the mFreeMemoryMapEntryList.\r | |
267 | If the list is emtry, then allocate a new page to refuel the list.\r | |
268 | Please Note this algorithm to allocate the memory map descriptor has a property\r | |
269 | that the memory allocated for memory entries always grows, and will never really be freed\r | |
270 | For example, if the current boot uses 2000 memory map entries at the maximum point, but\r | |
271 | ends up with only 50 at the time the OS is booted, then the memory associated with the 1950\r | |
272 | memory map entries is still allocated from EfiBootServicesMemory.\r | |
273 | \r | |
274 | \r | |
275 | @return The Memory map descriptor dequed from the mFreeMemoryMapEntryList\r | |
276 | \r | |
277 | **/\r | |
28a00297 | 278 | MEMORY_MAP *\r |
279 | AllocateMemoryMapEntry (\r | |
280 | VOID\r | |
d9177625 | 281 | )\r |
282 | {\r | |
283 | MEMORY_MAP* FreeDescriptorEntries;\r | |
284 | MEMORY_MAP* Entry;\r | |
285 | UINTN Index;\r | |
286 | \r | |
287 | if (IsListEmpty (&mFreeMemoryMapEntryList)) {\r | |
288 | //\r | |
289 | // The list is empty, to allocate one page to refuel the list\r | |
290 | //\r | |
e63da9f0 JW |
291 | FreeDescriptorEntries = CoreAllocatePoolPages (\r |
292 | EfiBootServicesData,\r | |
d4731a98 | 293 | EFI_SIZE_TO_PAGES (DEFAULT_PAGE_ALLOCATION_GRANULARITY),\r |
e63da9f0 JW |
294 | DEFAULT_PAGE_ALLOCATION_GRANULARITY,\r |
295 | FALSE\r | |
296 | );\r | |
d4731a98 | 297 | if (FreeDescriptorEntries != NULL) {\r |
d9177625 | 298 | //\r |
299 | // Enque the free memmory map entries into the list\r | |
300 | //\r | |
d4731a98 | 301 | for (Index = 0; Index < DEFAULT_PAGE_ALLOCATION_GRANULARITY / sizeof(MEMORY_MAP); Index++) {\r |
d9177625 | 302 | FreeDescriptorEntries[Index].Signature = MEMORY_MAP_SIGNATURE;\r |
303 | InsertTailList (&mFreeMemoryMapEntryList, &FreeDescriptorEntries[Index].Link);\r | |
304 | }\r | |
305 | } else {\r | |
306 | return NULL;\r | |
307 | }\r | |
308 | }\r | |
309 | //\r | |
310 | // dequeue the first descriptor from the list\r | |
311 | //\r | |
312 | Entry = CR (mFreeMemoryMapEntryList.ForwardLink, MEMORY_MAP, Link, MEMORY_MAP_SIGNATURE);\r | |
313 | RemoveEntryList (&Entry->Link);\r | |
314 | \r | |
315 | return Entry;\r | |
316 | }\r | |
022c6d45 | 317 | \r |
162ed594 | 318 | \r |
319 | /**\r | |
d9177625 | 320 | Internal function. Moves any memory descriptors that are on the\r |
321 | temporary descriptor stack to heap.\r | |
162ed594 | 322 | \r |
323 | **/\r | |
28a00297 | 324 | VOID\r |
d9177625 | 325 | CoreFreeMemoryMapStack (\r |
28a00297 | 326 | VOID\r |
327 | )\r | |
28a00297 | 328 | {\r |
d9177625 | 329 | MEMORY_MAP *Entry;\r |
330 | MEMORY_MAP *Entry2;\r | |
331 | LIST_ENTRY *Link2;\r | |
28a00297 | 332 | \r |
d9177625 | 333 | ASSERT_LOCKED (&gMemoryLock);\r |
28a00297 | 334 | \r |
d9177625 | 335 | //\r |
336 | // If already freeing the map stack, then return\r | |
337 | //\r | |
338 | if (mFreeMapStack != 0) {\r | |
339 | return ;\r | |
340 | }\r | |
162ed594 | 341 | \r |
d9177625 | 342 | //\r |
343 | // Move the temporary memory descriptor stack into pool\r | |
344 | //\r | |
345 | mFreeMapStack += 1;\r | |
162ed594 | 346 | \r |
d9177625 | 347 | while (mMapDepth != 0) {\r |
348 | //\r | |
349 | // Deque an memory map entry from mFreeMemoryMapEntryList\r | |
350 | //\r | |
351 | Entry = AllocateMemoryMapEntry ();\r | |
352 | \r | |
353 | ASSERT (Entry);\r | |
354 | \r | |
355 | //\r | |
356 | // Update to proper entry\r | |
357 | //\r | |
358 | mMapDepth -= 1;\r | |
359 | \r | |
360 | if (mMapStack[mMapDepth].Link.ForwardLink != NULL) {\r | |
361 | \r | |
362 | //\r | |
363 | // Move this entry to general memory\r | |
364 | //\r | |
365 | RemoveEntryList (&mMapStack[mMapDepth].Link);\r | |
366 | mMapStack[mMapDepth].Link.ForwardLink = NULL;\r | |
367 | \r | |
368 | CopyMem (Entry , &mMapStack[mMapDepth], sizeof (MEMORY_MAP));\r | |
369 | Entry->FromPages = TRUE;\r | |
370 | \r | |
371 | //\r | |
372 | // Find insertion location\r | |
373 | //\r | |
374 | for (Link2 = gMemoryMap.ForwardLink; Link2 != &gMemoryMap; Link2 = Link2->ForwardLink) {\r | |
375 | Entry2 = CR (Link2, MEMORY_MAP, Link, MEMORY_MAP_SIGNATURE);\r | |
376 | if (Entry2->FromPages && Entry2->Start > Entry->Start) {\r | |
377 | break;\r | |
378 | }\r | |
379 | }\r | |
380 | \r | |
381 | InsertTailList (Link2, &Entry->Link);\r | |
382 | \r | |
383 | } else {\r | |
384 | //\r | |
385 | // This item of mMapStack[mMapDepth] has already been dequeued from gMemoryMap list,\r | |
386 | // so here no need to move it to memory.\r | |
387 | //\r | |
388 | InsertTailList (&mFreeMemoryMapEntryList, &Entry->Link);\r | |
389 | }\r | |
390 | }\r | |
28a00297 | 391 | \r |
d9177625 | 392 | mFreeMapStack -= 1;\r |
393 | }\r | |
162ed594 | 394 | \r |
395 | /**\r | |
396 | Find untested but initialized memory regions in GCD map and convert them to be DXE allocatable.\r | |
397 | \r | |
398 | **/\r | |
2345e7d4 | 399 | BOOLEAN\r |
28a00297 | 400 | PromoteMemoryResource (\r |
401 | VOID\r | |
402 | )\r | |
28a00297 | 403 | {\r |
2345e7d4 | 404 | LIST_ENTRY *Link;\r |
405 | EFI_GCD_MAP_ENTRY *Entry;\r | |
406 | BOOLEAN Promoted;\r | |
28a00297 | 407 | \r |
d45fd260 | 408 | DEBUG ((DEBUG_PAGE, "Promote the memory resource\n"));\r |
022c6d45 | 409 | \r |
28a00297 | 410 | CoreAcquireGcdMemoryLock ();\r |
022c6d45 | 411 | \r |
2345e7d4 | 412 | Promoted = FALSE;\r |
28a00297 | 413 | Link = mGcdMemorySpaceMap.ForwardLink;\r |
414 | while (Link != &mGcdMemorySpaceMap) {\r | |
415 | \r | |
416 | Entry = CR (Link, EFI_GCD_MAP_ENTRY, Link, EFI_GCD_MAP_SIGNATURE);\r | |
417 | \r | |
418 | if (Entry->GcdMemoryType == EfiGcdMemoryTypeReserved &&\r | |
f3f2e05d | 419 | Entry->EndAddress < MAX_ADDRESS &&\r |
28a00297 | 420 | (Entry->Capabilities & (EFI_MEMORY_PRESENT | EFI_MEMORY_INITIALIZED | EFI_MEMORY_TESTED)) ==\r |
421 | (EFI_MEMORY_PRESENT | EFI_MEMORY_INITIALIZED)) {\r | |
422 | //\r | |
423 | // Update the GCD map\r | |
424 | //\r | |
74705ca5 SZ |
425 | if ((Entry->Capabilities & EFI_MEMORY_MORE_RELIABLE) == EFI_MEMORY_MORE_RELIABLE) {\r |
426 | Entry->GcdMemoryType = EfiGcdMemoryTypeMoreReliable;\r | |
427 | } else {\r | |
428 | Entry->GcdMemoryType = EfiGcdMemoryTypeSystemMemory;\r | |
429 | }\r | |
28a00297 | 430 | Entry->Capabilities |= EFI_MEMORY_TESTED;\r |
431 | Entry->ImageHandle = gDxeCoreImageHandle;\r | |
432 | Entry->DeviceHandle = NULL;\r | |
433 | \r | |
434 | //\r | |
435 | // Add to allocable system memory resource\r | |
022c6d45 | 436 | //\r |
28a00297 | 437 | \r |
438 | CoreAddRange (\r | |
022c6d45 | 439 | EfiConventionalMemory,\r |
440 | Entry->BaseAddress,\r | |
441 | Entry->EndAddress,\r | |
28a00297 | 442 | Entry->Capabilities & ~(EFI_MEMORY_PRESENT | EFI_MEMORY_INITIALIZED | EFI_MEMORY_TESTED | EFI_MEMORY_RUNTIME)\r |
443 | );\r | |
444 | CoreFreeMemoryMapStack ();\r | |
022c6d45 | 445 | \r |
2345e7d4 | 446 | Promoted = TRUE;\r |
28a00297 | 447 | }\r |
448 | \r | |
449 | Link = Link->ForwardLink;\r | |
450 | }\r | |
022c6d45 | 451 | \r |
28a00297 | 452 | CoreReleaseGcdMemoryLock ();\r |
022c6d45 | 453 | \r |
2345e7d4 | 454 | return Promoted;\r |
28a00297 | 455 | }\r |
54ea99a7 | 456 | /**\r |
457 | This function try to allocate Runtime code & Boot time code memory range. If LMFA enabled, 2 patchable PCD \r | |
458 | PcdLoadFixAddressRuntimeCodePageNumber & PcdLoadFixAddressBootTimeCodePageNumber which are set by tools will record the \r | |
459 | size of boot time and runtime code.\r | |
28a00297 | 460 | \r |
54ea99a7 | 461 | **/\r |
462 | VOID\r | |
463 | CoreLoadingFixedAddressHook (\r | |
464 | VOID\r | |
465 | )\r | |
466 | {\r | |
467 | UINT32 RuntimeCodePageNumber;\r | |
468 | UINT32 BootTimeCodePageNumber;\r | |
469 | EFI_PHYSICAL_ADDRESS RuntimeCodeBase;\r | |
470 | EFI_PHYSICAL_ADDRESS BootTimeCodeBase;\r | |
471 | EFI_STATUS Status;\r | |
472 | \r | |
473 | //\r | |
474 | // Make sure these 2 areas are not initialzied.\r | |
475 | //\r | |
476 | if (!gLoadFixedAddressCodeMemoryReady) { \r | |
477 | RuntimeCodePageNumber = PcdGet32(PcdLoadFixAddressRuntimeCodePageNumber);\r | |
478 | BootTimeCodePageNumber= PcdGet32(PcdLoadFixAddressBootTimeCodePageNumber);\r | |
479 | RuntimeCodeBase = (EFI_PHYSICAL_ADDRESS)(gLoadModuleAtFixAddressConfigurationTable.DxeCodeTopAddress - EFI_PAGES_TO_SIZE (RuntimeCodePageNumber));\r | |
480 | BootTimeCodeBase = (EFI_PHYSICAL_ADDRESS)(RuntimeCodeBase - EFI_PAGES_TO_SIZE (BootTimeCodePageNumber));\r | |
481 | //\r | |
482 | // Try to allocate runtime memory.\r | |
483 | //\r | |
484 | Status = CoreAllocatePages (\r | |
485 | AllocateAddress,\r | |
486 | EfiRuntimeServicesCode,\r | |
487 | RuntimeCodePageNumber,\r | |
488 | &RuntimeCodeBase\r | |
489 | );\r | |
490 | if (EFI_ERROR(Status)) {\r | |
491 | //\r | |
492 | // Runtime memory allocation failed \r | |
493 | //\r | |
494 | return;\r | |
495 | }\r | |
496 | //\r | |
497 | // Try to allocate boot memory.\r | |
498 | //\r | |
499 | Status = CoreAllocatePages (\r | |
500 | AllocateAddress,\r | |
501 | EfiBootServicesCode,\r | |
502 | BootTimeCodePageNumber,\r | |
503 | &BootTimeCodeBase\r | |
504 | );\r | |
505 | if (EFI_ERROR(Status)) {\r | |
506 | //\r | |
507 | // boot memory allocation failed. Free Runtime code range and will try the allocation again when \r | |
508 | // new memory range is installed.\r | |
509 | //\r | |
510 | CoreFreePages (\r | |
511 | RuntimeCodeBase,\r | |
512 | RuntimeCodePageNumber\r | |
513 | );\r | |
514 | return;\r | |
515 | }\r | |
516 | gLoadFixedAddressCodeMemoryReady = TRUE;\r | |
517 | } \r | |
518 | return;\r | |
519 | } \r | |
28a00297 | 520 | \r |
162ed594 | 521 | /**\r |
28a00297 | 522 | Called to initialize the memory map and add descriptors to\r |
523 | the current descriptor list.\r | |
28a00297 | 524 | The first descriptor that is added must be general usable\r |
525 | memory as the addition allocates heap.\r | |
526 | \r | |
022c6d45 | 527 | @param Type The type of memory to add\r |
528 | @param Start The starting address in the memory range Must be\r | |
529 | page aligned\r | |
530 | @param NumberOfPages The number of pages in the range\r | |
531 | @param Attribute Attributes of the memory to add\r | |
28a00297 | 532 | \r |
162ed594 | 533 | @return None. The range is added to the memory map\r |
28a00297 | 534 | \r |
162ed594 | 535 | **/\r |
536 | VOID\r | |
537 | CoreAddMemoryDescriptor (\r | |
538 | IN EFI_MEMORY_TYPE Type,\r | |
539 | IN EFI_PHYSICAL_ADDRESS Start,\r | |
540 | IN UINT64 NumberOfPages,\r | |
541 | IN UINT64 Attribute\r | |
542 | )\r | |
28a00297 | 543 | {\r |
544 | EFI_PHYSICAL_ADDRESS End;\r | |
545 | EFI_STATUS Status;\r | |
546 | UINTN Index;\r | |
547 | UINTN FreeIndex;\r | |
54ea99a7 | 548 | \r |
28a00297 | 549 | if ((Start & EFI_PAGE_MASK) != 0) {\r |
550 | return;\r | |
551 | }\r | |
552 | \r | |
8ee25f48 | 553 | if (Type >= EfiMaxMemoryType && Type < MEMORY_TYPE_OEM_RESERVED_MIN) {\r |
28a00297 | 554 | return;\r |
555 | }\r | |
28a00297 | 556 | CoreAcquireMemoryLock ();\r |
557 | End = Start + LShiftU64 (NumberOfPages, EFI_PAGE_SHIFT) - 1;\r | |
558 | CoreAddRange (Type, Start, End, Attribute);\r | |
559 | CoreFreeMemoryMapStack ();\r | |
560 | CoreReleaseMemoryLock ();\r | |
561 | \r | |
7eb927db | 562 | ApplyMemoryProtectionPolicy (EfiMaxMemoryType, Type, Start,\r |
4879e130 | 563 | LShiftU64 (NumberOfPages, EFI_PAGE_SHIFT));\r |
7eb927db | 564 | \r |
54ea99a7 | 565 | //\r |
566 | // If Loading Module At Fixed Address feature is enabled. try to allocate memory with Runtime code & Boot time code type\r | |
567 | //\r | |
852081fc | 568 | if (PcdGet64(PcdLoadModuleAtFixAddressEnable) != 0) {\r |
54ea99a7 | 569 | CoreLoadingFixedAddressHook();\r |
570 | }\r | |
571 | \r | |
28a00297 | 572 | //\r |
573 | // Check to see if the statistics for the different memory types have already been established\r | |
574 | //\r | |
575 | if (mMemoryTypeInformationInitialized) {\r | |
576 | return;\r | |
577 | }\r | |
578 | \r | |
54ea99a7 | 579 | \r |
28a00297 | 580 | //\r |
581 | // Loop through each memory type in the order specified by the gMemoryTypeInformation[] array\r | |
582 | //\r | |
583 | for (Index = 0; gMemoryTypeInformation[Index].Type != EfiMaxMemoryType; Index++) {\r | |
584 | //\r | |
585 | // Make sure the memory type in the gMemoryTypeInformation[] array is valid\r | |
586 | //\r | |
587 | Type = (EFI_MEMORY_TYPE) (gMemoryTypeInformation[Index].Type);\r | |
3d78c020 | 588 | if ((UINT32)Type > EfiMaxMemoryType) {\r |
28a00297 | 589 | continue;\r |
590 | }\r | |
28a00297 | 591 | if (gMemoryTypeInformation[Index].NumberOfPages != 0) {\r |
592 | //\r | |
593 | // Allocate pages for the current memory type from the top of available memory\r | |
594 | //\r | |
595 | Status = CoreAllocatePages (\r | |
596 | AllocateAnyPages,\r | |
597 | Type,\r | |
598 | gMemoryTypeInformation[Index].NumberOfPages,\r | |
599 | &mMemoryTypeStatistics[Type].BaseAddress\r | |
600 | );\r | |
601 | if (EFI_ERROR (Status)) {\r | |
602 | //\r | |
022c6d45 | 603 | // If an error occurs allocating the pages for the current memory type, then\r |
28a00297 | 604 | // free all the pages allocates for the previous memory types and return. This\r |
605 | // operation with be retied when/if more memory is added to the system\r | |
606 | //\r | |
607 | for (FreeIndex = 0; FreeIndex < Index; FreeIndex++) {\r | |
608 | //\r | |
609 | // Make sure the memory type in the gMemoryTypeInformation[] array is valid\r | |
610 | //\r | |
611 | Type = (EFI_MEMORY_TYPE) (gMemoryTypeInformation[FreeIndex].Type);\r | |
3d78c020 | 612 | if ((UINT32)Type > EfiMaxMemoryType) {\r |
28a00297 | 613 | continue;\r |
614 | }\r | |
615 | \r | |
616 | if (gMemoryTypeInformation[FreeIndex].NumberOfPages != 0) {\r | |
617 | CoreFreePages (\r | |
022c6d45 | 618 | mMemoryTypeStatistics[Type].BaseAddress,\r |
28a00297 | 619 | gMemoryTypeInformation[FreeIndex].NumberOfPages\r |
620 | );\r | |
621 | mMemoryTypeStatistics[Type].BaseAddress = 0;\r | |
f3f2e05d | 622 | mMemoryTypeStatistics[Type].MaximumAddress = MAX_ADDRESS;\r |
28a00297 | 623 | }\r |
624 | }\r | |
625 | return;\r | |
626 | }\r | |
627 | \r | |
628 | //\r | |
629 | // Compute the address at the top of the current statistics\r | |
630 | //\r | |
022c6d45 | 631 | mMemoryTypeStatistics[Type].MaximumAddress =\r |
632 | mMemoryTypeStatistics[Type].BaseAddress +\r | |
28a00297 | 633 | LShiftU64 (gMemoryTypeInformation[Index].NumberOfPages, EFI_PAGE_SHIFT) - 1;\r |
634 | \r | |
635 | //\r | |
022c6d45 | 636 | // If the current base address is the lowest address so far, then update the default\r |
28a00297 | 637 | // maximum address\r |
638 | //\r | |
639 | if (mMemoryTypeStatistics[Type].BaseAddress < mDefaultMaximumAddress) {\r | |
640 | mDefaultMaximumAddress = mMemoryTypeStatistics[Type].BaseAddress - 1;\r | |
641 | }\r | |
642 | }\r | |
643 | }\r | |
644 | \r | |
645 | //\r | |
646 | // There was enough system memory for all the the memory types were allocated. So,\r | |
647 | // those memory areas can be freed for future allocations, and all future memory\r | |
648 | // allocations can occur within their respective bins\r | |
649 | //\r | |
650 | for (Index = 0; gMemoryTypeInformation[Index].Type != EfiMaxMemoryType; Index++) {\r | |
651 | //\r | |
652 | // Make sure the memory type in the gMemoryTypeInformation[] array is valid\r | |
653 | //\r | |
654 | Type = (EFI_MEMORY_TYPE) (gMemoryTypeInformation[Index].Type);\r | |
3d78c020 | 655 | if ((UINT32)Type > EfiMaxMemoryType) {\r |
28a00297 | 656 | continue;\r |
657 | }\r | |
28a00297 | 658 | if (gMemoryTypeInformation[Index].NumberOfPages != 0) {\r |
659 | CoreFreePages (\r | |
022c6d45 | 660 | mMemoryTypeStatistics[Type].BaseAddress,\r |
28a00297 | 661 | gMemoryTypeInformation[Index].NumberOfPages\r |
662 | );\r | |
b74350e9 | 663 | mMemoryTypeStatistics[Type].NumberOfPages = gMemoryTypeInformation[Index].NumberOfPages;\r |
28a00297 | 664 | gMemoryTypeInformation[Index].NumberOfPages = 0;\r |
665 | }\r | |
666 | }\r | |
667 | \r | |
668 | //\r | |
669 | // If the number of pages reserved for a memory type is 0, then all allocations for that type\r | |
670 | // should be in the default range.\r | |
671 | //\r | |
672 | for (Type = (EFI_MEMORY_TYPE) 0; Type < EfiMaxMemoryType; Type++) {\r | |
673 | for (Index = 0; gMemoryTypeInformation[Index].Type != EfiMaxMemoryType; Index++) {\r | |
674 | if (Type == (EFI_MEMORY_TYPE)gMemoryTypeInformation[Index].Type) {\r | |
675 | mMemoryTypeStatistics[Type].InformationIndex = Index;\r | |
676 | }\r | |
677 | }\r | |
678 | mMemoryTypeStatistics[Type].CurrentNumberOfPages = 0;\r | |
f3f2e05d | 679 | if (mMemoryTypeStatistics[Type].MaximumAddress == MAX_ADDRESS) {\r |
28a00297 | 680 | mMemoryTypeStatistics[Type].MaximumAddress = mDefaultMaximumAddress;\r |
681 | }\r | |
682 | }\r | |
683 | \r | |
684 | mMemoryTypeInformationInitialized = TRUE;\r | |
685 | }\r | |
686 | \r | |
687 | \r | |
162ed594 | 688 | /**\r |
771ee501 EC |
689 | Internal function. Converts a memory range to the specified type or attributes.\r |
690 | The range must exist in the memory map. Either ChangingType or\r | |
691 | ChangingAttributes must be set, but not both.\r | |
162ed594 | 692 | \r |
022c6d45 | 693 | @param Start The first address of the range Must be page\r |
694 | aligned\r | |
695 | @param NumberOfPages The number of pages to convert\r | |
771ee501 | 696 | @param ChangingType Boolean indicating that type value should be changed\r |
022c6d45 | 697 | @param NewType The new type for the memory range\r |
771ee501 EC |
698 | @param ChangingAttributes Boolean indicating that attributes value should be changed\r |
699 | @param NewAttributes The new attributes for the memory range\r | |
162ed594 | 700 | \r |
022c6d45 | 701 | @retval EFI_INVALID_PARAMETER Invalid parameter\r |
702 | @retval EFI_NOT_FOUND Could not find a descriptor cover the specified\r | |
703 | range or convertion not allowed.\r | |
704 | @retval EFI_SUCCESS Successfully converts the memory range to the\r | |
162ed594 | 705 | specified type.\r |
706 | \r | |
707 | **/\r | |
28a00297 | 708 | EFI_STATUS\r |
771ee501 | 709 | CoreConvertPagesEx (\r |
28a00297 | 710 | IN UINT64 Start,\r |
711 | IN UINT64 NumberOfPages,\r | |
771ee501 EC |
712 | IN BOOLEAN ChangingType,\r |
713 | IN EFI_MEMORY_TYPE NewType,\r | |
714 | IN BOOLEAN ChangingAttributes,\r | |
715 | IN UINT64 NewAttributes\r | |
28a00297 | 716 | )\r |
28a00297 | 717 | {\r |
718 | \r | |
719 | UINT64 NumberOfBytes;\r | |
720 | UINT64 End;\r | |
721 | UINT64 RangeEnd;\r | |
722 | UINT64 Attribute;\r | |
771ee501 | 723 | EFI_MEMORY_TYPE MemType;\r |
28a00297 | 724 | LIST_ENTRY *Link;\r |
725 | MEMORY_MAP *Entry;\r | |
726 | \r | |
727 | Entry = NULL;\r | |
728 | NumberOfBytes = LShiftU64 (NumberOfPages, EFI_PAGE_SHIFT);\r | |
729 | End = Start + NumberOfBytes - 1;\r | |
730 | \r | |
731 | ASSERT (NumberOfPages);\r | |
732 | ASSERT ((Start & EFI_PAGE_MASK) == 0);\r | |
733 | ASSERT (End > Start) ;\r | |
734 | ASSERT_LOCKED (&gMemoryLock);\r | |
771ee501 | 735 | ASSERT ( (ChangingType == FALSE) || (ChangingAttributes == FALSE) );\r |
28a00297 | 736 | \r |
f0459afe | 737 | if (NumberOfPages == 0 || ((Start & EFI_PAGE_MASK) != 0) || (Start >= End)) {\r |
28a00297 | 738 | return EFI_INVALID_PARAMETER;\r |
739 | }\r | |
740 | \r | |
741 | //\r | |
742 | // Convert the entire range\r | |
743 | //\r | |
744 | \r | |
745 | while (Start < End) {\r | |
746 | \r | |
747 | //\r | |
748 | // Find the entry that the covers the range\r | |
749 | //\r | |
750 | for (Link = gMemoryMap.ForwardLink; Link != &gMemoryMap; Link = Link->ForwardLink) {\r | |
751 | Entry = CR (Link, MEMORY_MAP, Link, MEMORY_MAP_SIGNATURE);\r | |
752 | \r | |
753 | if (Entry->Start <= Start && Entry->End > Start) {\r | |
754 | break;\r | |
755 | }\r | |
756 | }\r | |
757 | \r | |
758 | if (Link == &gMemoryMap) {\r | |
162ed594 | 759 | DEBUG ((DEBUG_ERROR | DEBUG_PAGE, "ConvertPages: failed to find range %lx - %lx\n", Start, End));\r |
28a00297 | 760 | return EFI_NOT_FOUND;\r |
761 | }\r | |
762 | \r | |
3f2ae009 AB |
763 | //\r |
764 | // If we are converting the type of the range from EfiConventionalMemory to\r | |
765 | // another type, we have to ensure that the entire range is covered by a\r | |
766 | // single entry.\r | |
767 | //\r | |
768 | if (ChangingType && (NewType != EfiConventionalMemory)) {\r | |
769 | if (Entry->End < End) {\r | |
770 | DEBUG ((DEBUG_ERROR | DEBUG_PAGE, "ConvertPages: range %lx - %lx covers multiple entries\n", Start, End));\r | |
771 | return EFI_NOT_FOUND;\r | |
772 | }\r | |
773 | }\r | |
28a00297 | 774 | //\r |
775 | // Convert range to the end, or to the end of the descriptor\r | |
776 | // if that's all we've got\r | |
777 | //\r | |
778 | RangeEnd = End;\r | |
525aded9 | 779 | \r |
780 | ASSERT (Entry != NULL);\r | |
28a00297 | 781 | if (Entry->End < End) {\r |
782 | RangeEnd = Entry->End;\r | |
783 | }\r | |
784 | \r | |
771ee501 EC |
785 | if (ChangingType) {\r |
786 | DEBUG ((DEBUG_PAGE, "ConvertRange: %lx-%lx to type %d\n", Start, RangeEnd, NewType));\r | |
787 | }\r | |
788 | if (ChangingAttributes) {\r | |
789 | DEBUG ((DEBUG_PAGE, "ConvertRange: %lx-%lx to attr %lx\n", Start, RangeEnd, NewAttributes));\r | |
022c6d45 | 790 | }\r |
28a00297 | 791 | \r |
771ee501 EC |
792 | if (ChangingType) {\r |
793 | //\r | |
794 | // Debug code - verify conversion is allowed\r | |
795 | //\r | |
796 | if (!(NewType == EfiConventionalMemory ? 1 : 0) ^ (Entry->Type == EfiConventionalMemory ? 1 : 0)) {\r | |
9a701955 SZ |
797 | DEBUG ((DEBUG_ERROR | DEBUG_PAGE, "ConvertPages: Incompatible memory types, "));\r |
798 | if (Entry->Type == EfiConventionalMemory) {\r | |
799 | DEBUG ((DEBUG_ERROR | DEBUG_PAGE, "the pages to free have been freed\n"));\r | |
800 | } else {\r | |
801 | DEBUG ((DEBUG_ERROR | DEBUG_PAGE, "the pages to allocate have been allocated\n"));\r | |
802 | }\r | |
771ee501 EC |
803 | return EFI_NOT_FOUND;\r |
804 | }\r | |
805 | \r | |
806 | //\r | |
807 | // Update counters for the number of pages allocated to each memory type\r | |
808 | //\r | |
809 | if ((UINT32)Entry->Type < EfiMaxMemoryType) {\r | |
810 | if ((Start >= mMemoryTypeStatistics[Entry->Type].BaseAddress && Start <= mMemoryTypeStatistics[Entry->Type].MaximumAddress) ||\r | |
811 | (Start >= mDefaultBaseAddress && Start <= mDefaultMaximumAddress) ) {\r | |
812 | if (NumberOfPages > mMemoryTypeStatistics[Entry->Type].CurrentNumberOfPages) {\r | |
813 | mMemoryTypeStatistics[Entry->Type].CurrentNumberOfPages = 0;\r | |
814 | } else {\r | |
815 | mMemoryTypeStatistics[Entry->Type].CurrentNumberOfPages -= NumberOfPages;\r | |
816 | }\r | |
28a00297 | 817 | }\r |
818 | }\r | |
28a00297 | 819 | \r |
771ee501 EC |
820 | if ((UINT32)NewType < EfiMaxMemoryType) {\r |
821 | if ((Start >= mMemoryTypeStatistics[NewType].BaseAddress && Start <= mMemoryTypeStatistics[NewType].MaximumAddress) ||\r | |
822 | (Start >= mDefaultBaseAddress && Start <= mDefaultMaximumAddress) ) {\r | |
823 | mMemoryTypeStatistics[NewType].CurrentNumberOfPages += NumberOfPages;\r | |
824 | if (mMemoryTypeStatistics[NewType].CurrentNumberOfPages > gMemoryTypeInformation[mMemoryTypeStatistics[NewType].InformationIndex].NumberOfPages) {\r | |
825 | gMemoryTypeInformation[mMemoryTypeStatistics[NewType].InformationIndex].NumberOfPages = (UINT32)mMemoryTypeStatistics[NewType].CurrentNumberOfPages;\r | |
826 | }\r | |
28a00297 | 827 | }\r |
828 | }\r | |
829 | }\r | |
830 | \r | |
831 | //\r | |
832 | // Pull range out of descriptor\r | |
833 | //\r | |
834 | if (Entry->Start == Start) {\r | |
022c6d45 | 835 | \r |
28a00297 | 836 | //\r |
837 | // Clip start\r | |
838 | //\r | |
839 | Entry->Start = RangeEnd + 1;\r | |
840 | \r | |
841 | } else if (Entry->End == RangeEnd) {\r | |
022c6d45 | 842 | \r |
28a00297 | 843 | //\r |
844 | // Clip end\r | |
845 | //\r | |
846 | Entry->End = Start - 1;\r | |
847 | \r | |
848 | } else {\r | |
849 | \r | |
850 | //\r | |
851 | // Pull it out of the center, clip current\r | |
852 | //\r | |
022c6d45 | 853 | \r |
28a00297 | 854 | //\r |
855 | // Add a new one\r | |
856 | //\r | |
857 | mMapStack[mMapDepth].Signature = MEMORY_MAP_SIGNATURE;\r | |
858 | mMapStack[mMapDepth].FromPages = FALSE;\r | |
859 | mMapStack[mMapDepth].Type = Entry->Type;\r | |
860 | mMapStack[mMapDepth].Start = RangeEnd+1;\r | |
861 | mMapStack[mMapDepth].End = Entry->End;\r | |
862 | \r | |
863 | //\r | |
864 | // Inherit Attribute from the Memory Descriptor that is being clipped\r | |
865 | //\r | |
866 | mMapStack[mMapDepth].Attribute = Entry->Attribute;\r | |
867 | \r | |
868 | Entry->End = Start - 1;\r | |
869 | ASSERT (Entry->Start < Entry->End);\r | |
870 | \r | |
871 | Entry = &mMapStack[mMapDepth];\r | |
872 | InsertTailList (&gMemoryMap, &Entry->Link);\r | |
873 | \r | |
874 | mMapDepth += 1;\r | |
875 | ASSERT (mMapDepth < MAX_MAP_DEPTH);\r | |
876 | }\r | |
877 | \r | |
878 | //\r | |
022c6d45 | 879 | // The new range inherits the same Attribute as the Entry\r |
771ee501 | 880 | // it is being cut out of unless attributes are being changed\r |
28a00297 | 881 | //\r |
771ee501 EC |
882 | if (ChangingType) {\r |
883 | Attribute = Entry->Attribute;\r | |
884 | MemType = NewType;\r | |
885 | } else {\r | |
886 | Attribute = NewAttributes;\r | |
887 | MemType = Entry->Type;\r | |
888 | }\r | |
28a00297 | 889 | \r |
890 | //\r | |
891 | // If the descriptor is empty, then remove it from the map\r | |
892 | //\r | |
893 | if (Entry->Start == Entry->End + 1) {\r | |
894 | RemoveMemoryMapEntry (Entry);\r | |
895 | Entry = NULL;\r | |
896 | }\r | |
022c6d45 | 897 | \r |
28a00297 | 898 | //\r |
899 | // Add our new range in\r | |
900 | //\r | |
771ee501 EC |
901 | CoreAddRange (MemType, Start, RangeEnd, Attribute);\r |
902 | if (ChangingType && (MemType == EfiConventionalMemory)) {\r | |
425d2569 JW |
903 | //\r |
904 | // Avoid calling DEBUG_CLEAR_MEMORY() for an address of 0 because this\r | |
905 | // macro will ASSERT() if address is 0. Instead, CoreAddRange() guarantees\r | |
906 | // that the page starting at address 0 is always filled with zeros.\r | |
907 | //\r | |
9a340872 | 908 | if (Start == 0) {\r |
909 | if (RangeEnd > EFI_PAGE_SIZE) {\r | |
910 | DEBUG_CLEAR_MEMORY ((VOID *)(UINTN) EFI_PAGE_SIZE, (UINTN) (RangeEnd - EFI_PAGE_SIZE + 1));\r | |
911 | }\r | |
912 | } else {\r | |
425d2569 | 913 | DEBUG_CLEAR_MEMORY ((VOID *)(UINTN) Start, (UINTN) (RangeEnd - Start + 1));\r |
9a340872 | 914 | }\r |
38c7df98 | 915 | }\r |
28a00297 | 916 | \r |
917 | //\r | |
918 | // Move any map descriptor stack to general pool\r | |
919 | //\r | |
920 | CoreFreeMemoryMapStack ();\r | |
921 | \r | |
922 | //\r | |
923 | // Bump the starting address, and convert the next range\r | |
924 | //\r | |
925 | Start = RangeEnd + 1;\r | |
926 | }\r | |
927 | \r | |
928 | //\r | |
929 | // Converted the whole range, done\r | |
930 | //\r | |
931 | \r | |
932 | return EFI_SUCCESS;\r | |
933 | }\r | |
934 | \r | |
935 | \r | |
771ee501 EC |
936 | /**\r |
937 | Internal function. Converts a memory range to the specified type.\r | |
938 | The range must exist in the memory map.\r | |
939 | \r | |
940 | @param Start The first address of the range Must be page\r | |
941 | aligned\r | |
942 | @param NumberOfPages The number of pages to convert\r | |
943 | @param NewType The new type for the memory range\r | |
944 | \r | |
945 | @retval EFI_INVALID_PARAMETER Invalid parameter\r | |
946 | @retval EFI_NOT_FOUND Could not find a descriptor cover the specified\r | |
947 | range or convertion not allowed.\r | |
948 | @retval EFI_SUCCESS Successfully converts the memory range to the\r | |
949 | specified type.\r | |
950 | \r | |
951 | **/\r | |
952 | EFI_STATUS\r | |
953 | CoreConvertPages (\r | |
954 | IN UINT64 Start,\r | |
955 | IN UINT64 NumberOfPages,\r | |
956 | IN EFI_MEMORY_TYPE NewType\r | |
957 | )\r | |
958 | {\r | |
959 | return CoreConvertPagesEx(Start, NumberOfPages, TRUE, NewType, FALSE, 0);\r | |
960 | }\r | |
961 | \r | |
962 | \r | |
963 | /**\r | |
964 | Internal function. Converts a memory range to use new attributes.\r | |
965 | \r | |
966 | @param Start The first address of the range Must be page\r | |
967 | aligned\r | |
968 | @param NumberOfPages The number of pages to convert\r | |
969 | @param NewAttributes The new attributes value for the range.\r | |
970 | \r | |
771ee501 EC |
971 | **/\r |
972 | VOID\r | |
973 | CoreUpdateMemoryAttributes (\r | |
974 | IN EFI_PHYSICAL_ADDRESS Start,\r | |
975 | IN UINT64 NumberOfPages,\r | |
976 | IN UINT64 NewAttributes\r | |
977 | )\r | |
978 | {\r | |
979 | CoreAcquireMemoryLock ();\r | |
980 | \r | |
981 | //\r | |
982 | // Update the attributes to the new value\r | |
983 | //\r | |
984 | CoreConvertPagesEx(Start, NumberOfPages, FALSE, (EFI_MEMORY_TYPE)0, TRUE, NewAttributes);\r | |
985 | \r | |
986 | CoreReleaseMemoryLock ();\r | |
987 | }\r | |
988 | \r | |
162ed594 | 989 | \r |
990 | /**\r | |
991 | Internal function. Finds a consecutive free page range below\r | |
992 | the requested address.\r | |
993 | \r | |
022c6d45 | 994 | @param MaxAddress The address that the range must be below\r |
35f9e94e | 995 | @param MinAddress The address that the range must be above\r |
022c6d45 | 996 | @param NumberOfPages Number of pages needed\r |
997 | @param NewType The type of memory the range is going to be\r | |
998 | turned into\r | |
999 | @param Alignment Bits to align with\r | |
e63da9f0 | 1000 | @param NeedGuard Flag to indicate Guard page is needed or not\r |
162ed594 | 1001 | \r |
1002 | @return The base address of the range, or 0 if the range was not found\r | |
1003 | \r | |
1004 | **/\r | |
28a00297 | 1005 | UINT64\r |
1006 | CoreFindFreePagesI (\r | |
1007 | IN UINT64 MaxAddress,\r | |
2345e7d4 | 1008 | IN UINT64 MinAddress,\r |
28a00297 | 1009 | IN UINT64 NumberOfPages,\r |
1010 | IN EFI_MEMORY_TYPE NewType,\r | |
e63da9f0 JW |
1011 | IN UINTN Alignment,\r |
1012 | IN BOOLEAN NeedGuard\r | |
28a00297 | 1013 | )\r |
28a00297 | 1014 | {\r |
1015 | UINT64 NumberOfBytes;\r | |
1016 | UINT64 Target;\r | |
1017 | UINT64 DescStart;\r | |
1018 | UINT64 DescEnd;\r | |
1019 | UINT64 DescNumberOfBytes;\r | |
1020 | LIST_ENTRY *Link;\r | |
1021 | MEMORY_MAP *Entry;\r | |
1022 | \r | |
1023 | if ((MaxAddress < EFI_PAGE_MASK) ||(NumberOfPages == 0)) {\r | |
1024 | return 0;\r | |
1025 | }\r | |
1026 | \r | |
1027 | if ((MaxAddress & EFI_PAGE_MASK) != EFI_PAGE_MASK) {\r | |
022c6d45 | 1028 | \r |
28a00297 | 1029 | //\r |
1030 | // If MaxAddress is not aligned to the end of a page\r | |
1031 | //\r | |
022c6d45 | 1032 | \r |
28a00297 | 1033 | //\r |
1034 | // Change MaxAddress to be 1 page lower\r | |
1035 | //\r | |
1036 | MaxAddress -= (EFI_PAGE_MASK + 1);\r | |
022c6d45 | 1037 | \r |
28a00297 | 1038 | //\r |
1039 | // Set MaxAddress to a page boundary\r | |
1040 | //\r | |
6e1e5405 | 1041 | MaxAddress &= ~(UINT64)EFI_PAGE_MASK;\r |
022c6d45 | 1042 | \r |
28a00297 | 1043 | //\r |
1044 | // Set MaxAddress to end of the page\r | |
1045 | //\r | |
1046 | MaxAddress |= EFI_PAGE_MASK;\r | |
1047 | }\r | |
1048 | \r | |
1049 | NumberOfBytes = LShiftU64 (NumberOfPages, EFI_PAGE_SHIFT);\r | |
1050 | Target = 0;\r | |
1051 | \r | |
1052 | for (Link = gMemoryMap.ForwardLink; Link != &gMemoryMap; Link = Link->ForwardLink) {\r | |
1053 | Entry = CR (Link, MEMORY_MAP, Link, MEMORY_MAP_SIGNATURE);\r | |
022c6d45 | 1054 | \r |
28a00297 | 1055 | //\r |
1056 | // If it's not a free entry, don't bother with it\r | |
1057 | //\r | |
1058 | if (Entry->Type != EfiConventionalMemory) {\r | |
1059 | continue;\r | |
1060 | }\r | |
1061 | \r | |
1062 | DescStart = Entry->Start;\r | |
1063 | DescEnd = Entry->End;\r | |
1064 | \r | |
1065 | //\r | |
2345e7d4 | 1066 | // If desc is past max allowed address or below min allowed address, skip it\r |
28a00297 | 1067 | //\r |
2345e7d4 | 1068 | if ((DescStart >= MaxAddress) || (DescEnd < MinAddress)) {\r |
28a00297 | 1069 | continue;\r |
1070 | }\r | |
1071 | \r | |
1072 | //\r | |
1073 | // If desc ends past max allowed address, clip the end\r | |
1074 | //\r | |
1075 | if (DescEnd >= MaxAddress) {\r | |
1076 | DescEnd = MaxAddress;\r | |
1077 | }\r | |
1078 | \r | |
1079 | DescEnd = ((DescEnd + 1) & (~(Alignment - 1))) - 1;\r | |
1080 | \r | |
1365bedd HG |
1081 | // Skip if DescEnd is less than DescStart after alignment clipping\r |
1082 | if (DescEnd < DescStart) {\r | |
1083 | continue;\r | |
1084 | }\r | |
1085 | \r | |
28a00297 | 1086 | //\r |
022c6d45 | 1087 | // Compute the number of bytes we can used from this\r |
28a00297 | 1088 | // descriptor, and see it's enough to satisfy the request\r |
1089 | //\r | |
1090 | DescNumberOfBytes = DescEnd - DescStart + 1;\r | |
1091 | \r | |
1092 | if (DescNumberOfBytes >= NumberOfBytes) {\r | |
2345e7d4 | 1093 | //\r |
1094 | // If the start of the allocated range is below the min address allowed, skip it\r | |
1095 | //\r | |
1096 | if ((DescEnd - NumberOfBytes + 1) < MinAddress) {\r | |
1097 | continue;\r | |
1098 | }\r | |
28a00297 | 1099 | \r |
1100 | //\r | |
1101 | // If this is the best match so far remember it\r | |
1102 | //\r | |
1103 | if (DescEnd > Target) {\r | |
e63da9f0 JW |
1104 | if (NeedGuard) {\r |
1105 | DescEnd = AdjustMemoryS (\r | |
1106 | DescEnd + 1 - DescNumberOfBytes,\r | |
1107 | DescNumberOfBytes,\r | |
1108 | NumberOfBytes\r | |
1109 | );\r | |
1110 | if (DescEnd == 0) {\r | |
1111 | continue;\r | |
1112 | }\r | |
1113 | }\r | |
1114 | \r | |
28a00297 | 1115 | Target = DescEnd;\r |
1116 | }\r | |
1117 | }\r | |
022c6d45 | 1118 | }\r |
28a00297 | 1119 | \r |
1120 | //\r | |
1121 | // If this is a grow down, adjust target to be the allocation base\r | |
1122 | //\r | |
1123 | Target -= NumberOfBytes - 1;\r | |
1124 | \r | |
1125 | //\r | |
1126 | // If we didn't find a match, return 0\r | |
1127 | //\r | |
1128 | if ((Target & EFI_PAGE_MASK) != 0) {\r | |
1129 | return 0;\r | |
1130 | }\r | |
1131 | \r | |
1132 | return Target;\r | |
1133 | }\r | |
1134 | \r | |
162ed594 | 1135 | \r |
1136 | /**\r | |
1137 | Internal function. Finds a consecutive free page range below\r | |
1138 | the requested address\r | |
1139 | \r | |
022c6d45 | 1140 | @param MaxAddress The address that the range must be below\r |
1141 | @param NoPages Number of pages needed\r | |
1142 | @param NewType The type of memory the range is going to be\r | |
1143 | turned into\r | |
1144 | @param Alignment Bits to align with\r | |
e63da9f0 | 1145 | @param NeedGuard Flag to indicate Guard page is needed or not\r |
162ed594 | 1146 | \r |
1147 | @return The base address of the range, or 0 if the range was not found.\r | |
1148 | \r | |
1149 | **/\r | |
28a00297 | 1150 | UINT64\r |
1151 | FindFreePages (\r | |
1152 | IN UINT64 MaxAddress,\r | |
1153 | IN UINT64 NoPages,\r | |
1154 | IN EFI_MEMORY_TYPE NewType,\r | |
e63da9f0 JW |
1155 | IN UINTN Alignment,\r |
1156 | IN BOOLEAN NeedGuard\r | |
28a00297 | 1157 | )\r |
28a00297 | 1158 | {\r |
2345e7d4 | 1159 | UINT64 Start;\r |
28a00297 | 1160 | \r |
2345e7d4 | 1161 | //\r |
1162 | // Attempt to find free pages in the preferred bin based on the requested memory type\r | |
1163 | //\r | |
3d78c020 | 1164 | if ((UINT32)NewType < EfiMaxMemoryType && MaxAddress >= mMemoryTypeStatistics[NewType].MaximumAddress) {\r |
2345e7d4 | 1165 | Start = CoreFindFreePagesI (\r |
1166 | mMemoryTypeStatistics[NewType].MaximumAddress, \r | |
1167 | mMemoryTypeStatistics[NewType].BaseAddress, \r | |
1168 | NoPages, \r | |
1169 | NewType, \r | |
e63da9f0 JW |
1170 | Alignment,\r |
1171 | NeedGuard\r | |
2345e7d4 | 1172 | );\r |
1173 | if (Start != 0) {\r | |
1174 | return Start;\r | |
1175 | }\r | |
1176 | }\r | |
28a00297 | 1177 | \r |
2345e7d4 | 1178 | //\r |
1179 | // Attempt to find free pages in the default allocation bin\r | |
1180 | //\r | |
1181 | if (MaxAddress >= mDefaultMaximumAddress) {\r | |
e63da9f0 JW |
1182 | Start = CoreFindFreePagesI (mDefaultMaximumAddress, 0, NoPages, NewType,\r |
1183 | Alignment, NeedGuard);\r | |
2345e7d4 | 1184 | if (Start != 0) {\r |
1185 | if (Start < mDefaultBaseAddress) {\r | |
1186 | mDefaultBaseAddress = Start;\r | |
1187 | }\r | |
1188 | return Start;\r | |
28a00297 | 1189 | }\r |
1190 | }\r | |
1191 | \r | |
2345e7d4 | 1192 | //\r |
1193 | // The allocation did not succeed in any of the prefered bins even after \r | |
1194 | // promoting resources. Attempt to find free pages anywhere is the requested \r | |
1195 | // address range. If this allocation fails, then there are not enough \r | |
1196 | // resources anywhere to satisfy the request.\r | |
1197 | //\r | |
e63da9f0 JW |
1198 | Start = CoreFindFreePagesI (MaxAddress, 0, NoPages, NewType, Alignment,\r |
1199 | NeedGuard);\r | |
2345e7d4 | 1200 | if (Start != 0) {\r |
1201 | return Start;\r | |
1202 | }\r | |
28a00297 | 1203 | \r |
2345e7d4 | 1204 | //\r |
1205 | // If allocations from the preferred bins fail, then attempt to promote memory resources.\r | |
1206 | //\r | |
1207 | if (!PromoteMemoryResource ()) {\r | |
1208 | return 0;\r | |
28a00297 | 1209 | }\r |
1210 | \r | |
2345e7d4 | 1211 | //\r |
1212 | // If any memory resources were promoted, then re-attempt the allocation\r | |
1213 | //\r | |
e63da9f0 | 1214 | return FindFreePages (MaxAddress, NoPages, NewType, Alignment, NeedGuard);\r |
28a00297 | 1215 | }\r |
1216 | \r | |
1217 | \r | |
162ed594 | 1218 | /**\r |
1219 | Allocates pages from the memory map.\r | |
1220 | \r | |
022c6d45 | 1221 | @param Type The type of allocation to perform\r |
1222 | @param MemoryType The type of memory to turn the allocated pages\r | |
1223 | into\r | |
1224 | @param NumberOfPages The number of pages to allocate\r | |
1225 | @param Memory A pointer to receive the base allocated memory\r | |
1226 | address\r | |
e63da9f0 | 1227 | @param NeedGuard Flag to indicate Guard page is needed or not\r |
162ed594 | 1228 | \r |
1229 | @return Status. On success, Memory is filled in with the base address allocated\r | |
022c6d45 | 1230 | @retval EFI_INVALID_PARAMETER Parameters violate checking rules defined in\r |
1231 | spec.\r | |
1232 | @retval EFI_NOT_FOUND Could not allocate pages match the requirement.\r | |
1233 | @retval EFI_OUT_OF_RESOURCES No enough pages to allocate.\r | |
162ed594 | 1234 | @retval EFI_SUCCESS Pages successfully allocated.\r |
1235 | \r | |
1236 | **/\r | |
28a00297 | 1237 | EFI_STATUS\r |
1238 | EFIAPI\r | |
84edd20b | 1239 | CoreInternalAllocatePages (\r |
28a00297 | 1240 | IN EFI_ALLOCATE_TYPE Type,\r |
1241 | IN EFI_MEMORY_TYPE MemoryType,\r | |
1242 | IN UINTN NumberOfPages,\r | |
e63da9f0 JW |
1243 | IN OUT EFI_PHYSICAL_ADDRESS *Memory,\r |
1244 | IN BOOLEAN NeedGuard\r | |
28a00297 | 1245 | )\r |
28a00297 | 1246 | {\r |
1247 | EFI_STATUS Status;\r | |
1248 | UINT64 Start;\r | |
c2a07a10 SZ |
1249 | UINT64 NumberOfBytes;\r |
1250 | UINT64 End;\r | |
28a00297 | 1251 | UINT64 MaxAddress;\r |
1252 | UINTN Alignment;\r | |
1253 | \r | |
3d78c020 | 1254 | if ((UINT32)Type >= MaxAllocateType) {\r |
28a00297 | 1255 | return EFI_INVALID_PARAMETER;\r |
1256 | }\r | |
1257 | \r | |
8ee25f48 | 1258 | if ((MemoryType >= EfiMaxMemoryType && MemoryType < MEMORY_TYPE_OEM_RESERVED_MIN) ||\r |
a671a012 | 1259 | (MemoryType == EfiConventionalMemory) || (MemoryType == EfiPersistentMemory)) {\r |
28a00297 | 1260 | return EFI_INVALID_PARAMETER;\r |
1261 | }\r | |
1262 | \r | |
3e058701 ED |
1263 | if (Memory == NULL) {\r |
1264 | return EFI_INVALID_PARAMETER;\r | |
1265 | }\r | |
1266 | \r | |
d4731a98 | 1267 | Alignment = DEFAULT_PAGE_ALLOCATION_GRANULARITY;\r |
28a00297 | 1268 | \r |
1269 | if (MemoryType == EfiACPIReclaimMemory ||\r | |
1270 | MemoryType == EfiACPIMemoryNVS ||\r | |
1271 | MemoryType == EfiRuntimeServicesCode ||\r | |
1272 | MemoryType == EfiRuntimeServicesData) {\r | |
1273 | \r | |
d4731a98 | 1274 | Alignment = RUNTIME_PAGE_ALLOCATION_GRANULARITY;\r |
28a00297 | 1275 | }\r |
1276 | \r | |
1277 | if (Type == AllocateAddress) {\r | |
1278 | if ((*Memory & (Alignment - 1)) != 0) {\r | |
1279 | return EFI_NOT_FOUND;\r | |
1280 | }\r | |
1281 | }\r | |
1282 | \r | |
1283 | NumberOfPages += EFI_SIZE_TO_PAGES (Alignment) - 1;\r | |
1284 | NumberOfPages &= ~(EFI_SIZE_TO_PAGES (Alignment) - 1);\r | |
1285 | \r | |
1286 | //\r | |
022c6d45 | 1287 | // If this is for below a particular address, then\r |
28a00297 | 1288 | //\r |
1289 | Start = *Memory;\r | |
022c6d45 | 1290 | \r |
28a00297 | 1291 | //\r |
1292 | // The max address is the max natively addressable address for the processor\r | |
1293 | //\r | |
f3f2e05d | 1294 | MaxAddress = MAX_ADDRESS;\r |
022c6d45 | 1295 | \r |
c2a07a10 SZ |
1296 | //\r |
1297 | // Check for Type AllocateAddress,\r | |
1298 | // if NumberOfPages is 0 or\r | |
1299 | // if (NumberOfPages << EFI_PAGE_SHIFT) is above MAX_ADDRESS or\r | |
1300 | // if (Start + NumberOfBytes) rolls over 0 or\r | |
1301 | // if Start is above MAX_ADDRESS or\r | |
1302 | // if End is above MAX_ADDRESS,\r | |
1303 | // return EFI_NOT_FOUND.\r | |
1304 | //\r | |
1305 | if (Type == AllocateAddress) {\r | |
1306 | if ((NumberOfPages == 0) ||\r | |
1307 | (NumberOfPages > RShiftU64 (MaxAddress, EFI_PAGE_SHIFT))) {\r | |
1308 | return EFI_NOT_FOUND;\r | |
1309 | }\r | |
1310 | NumberOfBytes = LShiftU64 (NumberOfPages, EFI_PAGE_SHIFT);\r | |
1311 | End = Start + NumberOfBytes - 1;\r | |
1312 | \r | |
1313 | if ((Start >= End) ||\r | |
1314 | (Start > MaxAddress) || \r | |
1315 | (End > MaxAddress)) {\r | |
1316 | return EFI_NOT_FOUND;\r | |
1317 | }\r | |
1318 | }\r | |
1319 | \r | |
28a00297 | 1320 | if (Type == AllocateMaxAddress) {\r |
1321 | MaxAddress = Start;\r | |
1322 | }\r | |
1323 | \r | |
1324 | CoreAcquireMemoryLock ();\r | |
022c6d45 | 1325 | \r |
28a00297 | 1326 | //\r |
1327 | // If not a specific address, then find an address to allocate\r | |
1328 | //\r | |
1329 | if (Type != AllocateAddress) {\r | |
e63da9f0 JW |
1330 | Start = FindFreePages (MaxAddress, NumberOfPages, MemoryType, Alignment,\r |
1331 | NeedGuard);\r | |
28a00297 | 1332 | if (Start == 0) {\r |
1333 | Status = EFI_OUT_OF_RESOURCES;\r | |
1334 | goto Done;\r | |
1335 | }\r | |
1336 | }\r | |
1337 | \r | |
1338 | //\r | |
1339 | // Convert pages from FreeMemory to the requested type\r | |
1340 | //\r | |
e63da9f0 JW |
1341 | if (NeedGuard) {\r |
1342 | Status = CoreConvertPagesWithGuard(Start, NumberOfPages, MemoryType);\r | |
1343 | } else {\r | |
1344 | Status = CoreConvertPages(Start, NumberOfPages, MemoryType);\r | |
1345 | }\r | |
28a00297 | 1346 | \r |
1347 | Done:\r | |
1348 | CoreReleaseMemoryLock ();\r | |
1349 | \r | |
1350 | if (!EFI_ERROR (Status)) {\r | |
e63da9f0 JW |
1351 | if (NeedGuard) {\r |
1352 | SetGuardForMemory (Start, NumberOfPages);\r | |
1353 | }\r | |
28a00297 | 1354 | *Memory = Start;\r |
1355 | }\r | |
1356 | \r | |
1357 | return Status;\r | |
1358 | }\r | |
1359 | \r | |
84edd20b SZ |
1360 | /**\r |
1361 | Allocates pages from the memory map.\r | |
1362 | \r | |
1363 | @param Type The type of allocation to perform\r | |
1364 | @param MemoryType The type of memory to turn the allocated pages\r | |
1365 | into\r | |
1366 | @param NumberOfPages The number of pages to allocate\r | |
1367 | @param Memory A pointer to receive the base allocated memory\r | |
1368 | address\r | |
1369 | \r | |
1370 | @return Status. On success, Memory is filled in with the base address allocated\r | |
1371 | @retval EFI_INVALID_PARAMETER Parameters violate checking rules defined in\r | |
1372 | spec.\r | |
1373 | @retval EFI_NOT_FOUND Could not allocate pages match the requirement.\r | |
1374 | @retval EFI_OUT_OF_RESOURCES No enough pages to allocate.\r | |
1375 | @retval EFI_SUCCESS Pages successfully allocated.\r | |
1376 | \r | |
1377 | **/\r | |
1378 | EFI_STATUS\r | |
1379 | EFIAPI\r | |
1380 | CoreAllocatePages (\r | |
1381 | IN EFI_ALLOCATE_TYPE Type,\r | |
1382 | IN EFI_MEMORY_TYPE MemoryType,\r | |
1383 | IN UINTN NumberOfPages,\r | |
1384 | OUT EFI_PHYSICAL_ADDRESS *Memory\r | |
1385 | )\r | |
1386 | {\r | |
1387 | EFI_STATUS Status;\r | |
e63da9f0 | 1388 | BOOLEAN NeedGuard;\r |
84edd20b | 1389 | \r |
e63da9f0 JW |
1390 | NeedGuard = IsPageTypeToGuard (MemoryType, Type) && !mOnGuarding;\r |
1391 | Status = CoreInternalAllocatePages (Type, MemoryType, NumberOfPages, Memory,\r | |
1392 | NeedGuard);\r | |
84edd20b | 1393 | if (!EFI_ERROR (Status)) {\r |
1d60fe96 SZ |
1394 | CoreUpdateProfile (\r |
1395 | (EFI_PHYSICAL_ADDRESS) (UINTN) RETURN_ADDRESS (0),\r | |
1396 | MemoryProfileActionAllocatePages,\r | |
1397 | MemoryType,\r | |
1398 | EFI_PAGES_TO_SIZE (NumberOfPages),\r | |
1399 | (VOID *) (UINTN) *Memory,\r | |
1400 | NULL\r | |
1401 | );\r | |
74a88770 | 1402 | InstallMemoryAttributesTableOnMemoryAllocation (MemoryType);\r |
7eb927db AB |
1403 | ApplyMemoryProtectionPolicy (EfiConventionalMemory, MemoryType, *Memory,\r |
1404 | EFI_PAGES_TO_SIZE (NumberOfPages));\r | |
84edd20b SZ |
1405 | }\r |
1406 | return Status;\r | |
1407 | }\r | |
28a00297 | 1408 | \r |
162ed594 | 1409 | /**\r |
1410 | Frees previous allocated pages.\r | |
1411 | \r | |
022c6d45 | 1412 | @param Memory Base address of memory being freed\r |
1413 | @param NumberOfPages The number of pages to free\r | |
925f0d1a | 1414 | @param MemoryType Pointer to memory type\r |
162ed594 | 1415 | \r |
022c6d45 | 1416 | @retval EFI_NOT_FOUND Could not find the entry that covers the range\r |
1417 | @retval EFI_INVALID_PARAMETER Address not aligned\r | |
162ed594 | 1418 | @return EFI_SUCCESS -Pages successfully freed.\r |
1419 | \r | |
1420 | **/\r | |
022c6d45 | 1421 | EFI_STATUS\r |
28a00297 | 1422 | EFIAPI\r |
84edd20b | 1423 | CoreInternalFreePages (\r |
28a00297 | 1424 | IN EFI_PHYSICAL_ADDRESS Memory,\r |
925f0d1a SZ |
1425 | IN UINTN NumberOfPages,\r |
1426 | OUT EFI_MEMORY_TYPE *MemoryType OPTIONAL\r | |
28a00297 | 1427 | )\r |
28a00297 | 1428 | {\r |
1429 | EFI_STATUS Status;\r | |
1430 | LIST_ENTRY *Link;\r | |
1431 | MEMORY_MAP *Entry;\r | |
1432 | UINTN Alignment;\r | |
e63da9f0 | 1433 | BOOLEAN IsGuarded;\r |
28a00297 | 1434 | \r |
1435 | //\r | |
1436 | // Free the range\r | |
1437 | //\r | |
1438 | CoreAcquireMemoryLock ();\r | |
1439 | \r | |
1440 | //\r | |
1441 | // Find the entry that the covers the range\r | |
1442 | //\r | |
e63da9f0 | 1443 | IsGuarded = FALSE;\r |
28a00297 | 1444 | Entry = NULL;\r |
1445 | for (Link = gMemoryMap.ForwardLink; Link != &gMemoryMap; Link = Link->ForwardLink) {\r | |
1446 | Entry = CR(Link, MEMORY_MAP, Link, MEMORY_MAP_SIGNATURE);\r | |
1447 | if (Entry->Start <= Memory && Entry->End > Memory) {\r | |
1448 | break;\r | |
1449 | }\r | |
1450 | }\r | |
1451 | if (Link == &gMemoryMap) {\r | |
a5ca8fa7 | 1452 | Status = EFI_NOT_FOUND;\r |
1453 | goto Done;\r | |
28a00297 | 1454 | }\r |
1455 | \r | |
d4731a98 | 1456 | Alignment = DEFAULT_PAGE_ALLOCATION_GRANULARITY;\r |
28a00297 | 1457 | \r |
525aded9 | 1458 | ASSERT (Entry != NULL);\r |
28a00297 | 1459 | if (Entry->Type == EfiACPIReclaimMemory ||\r |
1460 | Entry->Type == EfiACPIMemoryNVS ||\r | |
1461 | Entry->Type == EfiRuntimeServicesCode ||\r | |
1462 | Entry->Type == EfiRuntimeServicesData) {\r | |
1463 | \r | |
d4731a98 | 1464 | Alignment = RUNTIME_PAGE_ALLOCATION_GRANULARITY;\r |
28a00297 | 1465 | \r |
1466 | }\r | |
1467 | \r | |
1468 | if ((Memory & (Alignment - 1)) != 0) {\r | |
a5ca8fa7 | 1469 | Status = EFI_INVALID_PARAMETER;\r |
1470 | goto Done;\r | |
28a00297 | 1471 | }\r |
1472 | \r | |
1473 | NumberOfPages += EFI_SIZE_TO_PAGES (Alignment) - 1;\r | |
1474 | NumberOfPages &= ~(EFI_SIZE_TO_PAGES (Alignment) - 1);\r | |
1475 | \r | |
925f0d1a SZ |
1476 | if (MemoryType != NULL) {\r |
1477 | *MemoryType = Entry->Type;\r | |
1478 | }\r | |
1479 | \r | |
e63da9f0 JW |
1480 | IsGuarded = IsPageTypeToGuard (Entry->Type, AllocateAnyPages) &&\r |
1481 | IsMemoryGuarded (Memory);\r | |
1482 | if (IsGuarded) {\r | |
1483 | Status = CoreConvertPagesWithGuard (Memory, NumberOfPages,\r | |
1484 | EfiConventionalMemory);\r | |
1485 | } else {\r | |
1486 | Status = CoreConvertPages (Memory, NumberOfPages, EfiConventionalMemory);\r | |
28a00297 | 1487 | }\r |
1488 | \r | |
a5ca8fa7 | 1489 | Done:\r |
1490 | CoreReleaseMemoryLock ();\r | |
28a00297 | 1491 | return Status;\r |
1492 | }\r | |
1493 | \r | |
84edd20b SZ |
1494 | /**\r |
1495 | Frees previous allocated pages.\r | |
1496 | \r | |
1497 | @param Memory Base address of memory being freed\r | |
1498 | @param NumberOfPages The number of pages to free\r | |
1499 | \r | |
1500 | @retval EFI_NOT_FOUND Could not find the entry that covers the range\r | |
1501 | @retval EFI_INVALID_PARAMETER Address not aligned\r | |
1502 | @return EFI_SUCCESS -Pages successfully freed.\r | |
1503 | \r | |
1504 | **/\r | |
1505 | EFI_STATUS\r | |
1506 | EFIAPI\r | |
1507 | CoreFreePages (\r | |
1508 | IN EFI_PHYSICAL_ADDRESS Memory,\r | |
1509 | IN UINTN NumberOfPages\r | |
1510 | )\r | |
1511 | {\r | |
925f0d1a SZ |
1512 | EFI_STATUS Status;\r |
1513 | EFI_MEMORY_TYPE MemoryType;\r | |
736a692e | 1514 | \r |
925f0d1a | 1515 | Status = CoreInternalFreePages (Memory, NumberOfPages, &MemoryType);\r |
736a692e | 1516 | if (!EFI_ERROR (Status)) {\r |
1d60fe96 SZ |
1517 | CoreUpdateProfile (\r |
1518 | (EFI_PHYSICAL_ADDRESS) (UINTN) RETURN_ADDRESS (0),\r | |
1519 | MemoryProfileActionFreePages,\r | |
1520 | MemoryType,\r | |
1521 | EFI_PAGES_TO_SIZE (NumberOfPages),\r | |
1522 | (VOID *) (UINTN) Memory,\r | |
1523 | NULL\r | |
1524 | );\r | |
74a88770 | 1525 | InstallMemoryAttributesTableOnMemoryAllocation (MemoryType);\r |
7eb927db AB |
1526 | ApplyMemoryProtectionPolicy (MemoryType, EfiConventionalMemory, Memory,\r |
1527 | EFI_PAGES_TO_SIZE (NumberOfPages));\r | |
736a692e HT |
1528 | }\r |
1529 | return Status;\r | |
1530 | }\r | |
84edd20b | 1531 | \r |
2345e7d4 | 1532 | /**\r |
1533 | This function checks to see if the last memory map descriptor in a memory map\r | |
1534 | can be merged with any of the other memory map descriptors in a memorymap.\r | |
1535 | Memory descriptors may be merged if they are adjacent and have the same type\r | |
1536 | and attributes.\r | |
1537 | \r | |
1538 | @param MemoryMap A pointer to the start of the memory map.\r | |
1539 | @param MemoryMapDescriptor A pointer to the last descriptor in MemoryMap.\r | |
1540 | @param DescriptorSize The size, in bytes, of an individual\r | |
1541 | EFI_MEMORY_DESCRIPTOR.\r | |
1542 | \r | |
1543 | @return A pointer to the next available descriptor in MemoryMap\r | |
1544 | \r | |
1545 | **/\r | |
1546 | EFI_MEMORY_DESCRIPTOR *\r | |
1547 | MergeMemoryMapDescriptor (\r | |
1548 | IN EFI_MEMORY_DESCRIPTOR *MemoryMap,\r | |
1549 | IN EFI_MEMORY_DESCRIPTOR *MemoryMapDescriptor,\r | |
1550 | IN UINTN DescriptorSize\r | |
1551 | )\r | |
1552 | {\r | |
1553 | //\r | |
1554 | // Traverse the array of descriptors in MemoryMap\r | |
1555 | //\r | |
1556 | for (; MemoryMap != MemoryMapDescriptor; MemoryMap = NEXT_MEMORY_DESCRIPTOR (MemoryMap, DescriptorSize)) {\r | |
1557 | //\r | |
1558 | // Check to see if the Type fields are identical.\r | |
1559 | //\r | |
1560 | if (MemoryMap->Type != MemoryMapDescriptor->Type) {\r | |
1561 | continue;\r | |
1562 | }\r | |
1563 | \r | |
1564 | //\r | |
1565 | // Check to see if the Attribute fields are identical.\r | |
1566 | //\r | |
1567 | if (MemoryMap->Attribute != MemoryMapDescriptor->Attribute) {\r | |
1568 | continue;\r | |
1569 | }\r | |
1570 | \r | |
1571 | //\r | |
1572 | // Check to see if MemoryMapDescriptor is immediately above MemoryMap\r | |
1573 | //\r | |
1574 | if (MemoryMap->PhysicalStart + EFI_PAGES_TO_SIZE ((UINTN)MemoryMap->NumberOfPages) == MemoryMapDescriptor->PhysicalStart) { \r | |
1575 | //\r | |
1576 | // Merge MemoryMapDescriptor into MemoryMap\r | |
1577 | //\r | |
1578 | MemoryMap->NumberOfPages += MemoryMapDescriptor->NumberOfPages;\r | |
1579 | \r | |
1580 | //\r | |
1581 | // Return MemoryMapDescriptor as the next available slot int he MemoryMap array\r | |
1582 | //\r | |
1583 | return MemoryMapDescriptor;\r | |
1584 | }\r | |
1585 | \r | |
1586 | //\r | |
1587 | // Check to see if MemoryMapDescriptor is immediately below MemoryMap\r | |
1588 | //\r | |
1589 | if (MemoryMap->PhysicalStart - EFI_PAGES_TO_SIZE ((UINTN)MemoryMapDescriptor->NumberOfPages) == MemoryMapDescriptor->PhysicalStart) {\r | |
1590 | //\r | |
1591 | // Merge MemoryMapDescriptor into MemoryMap\r | |
1592 | //\r | |
1593 | MemoryMap->PhysicalStart = MemoryMapDescriptor->PhysicalStart;\r | |
1594 | MemoryMap->VirtualStart = MemoryMapDescriptor->VirtualStart;\r | |
1595 | MemoryMap->NumberOfPages += MemoryMapDescriptor->NumberOfPages;\r | |
1596 | \r | |
1597 | //\r | |
1598 | // Return MemoryMapDescriptor as the next available slot int he MemoryMap array\r | |
1599 | //\r | |
1600 | return MemoryMapDescriptor;\r | |
1601 | }\r | |
1602 | }\r | |
1603 | \r | |
1604 | //\r | |
1605 | // MemoryMapDescrtiptor could not be merged with any descriptors in MemoryMap.\r | |
1606 | //\r | |
1607 | // Return the slot immediately after MemoryMapDescriptor as the next available \r | |
1608 | // slot in the MemoryMap array\r | |
1609 | //\r | |
1610 | return NEXT_MEMORY_DESCRIPTOR (MemoryMapDescriptor, DescriptorSize);\r | |
1611 | }\r | |
28a00297 | 1612 | \r |
162ed594 | 1613 | /**\r |
1614 | This function returns a copy of the current memory map. The map is an array of\r | |
1615 | memory descriptors, each of which describes a contiguous block of memory.\r | |
1616 | \r | |
022c6d45 | 1617 | @param MemoryMapSize A pointer to the size, in bytes, of the\r |
1618 | MemoryMap buffer. On input, this is the size of\r | |
1619 | the buffer allocated by the caller. On output,\r | |
1620 | it is the size of the buffer returned by the\r | |
1621 | firmware if the buffer was large enough, or the\r | |
1622 | size of the buffer needed to contain the map if\r | |
1623 | the buffer was too small.\r | |
1624 | @param MemoryMap A pointer to the buffer in which firmware places\r | |
1625 | the current memory map.\r | |
1626 | @param MapKey A pointer to the location in which firmware\r | |
1627 | returns the key for the current memory map.\r | |
1628 | @param DescriptorSize A pointer to the location in which firmware\r | |
1629 | returns the size, in bytes, of an individual\r | |
1630 | EFI_MEMORY_DESCRIPTOR.\r | |
1631 | @param DescriptorVersion A pointer to the location in which firmware\r | |
1632 | returns the version number associated with the\r | |
1633 | EFI_MEMORY_DESCRIPTOR.\r | |
1634 | \r | |
1635 | @retval EFI_SUCCESS The memory map was returned in the MemoryMap\r | |
1636 | buffer.\r | |
1637 | @retval EFI_BUFFER_TOO_SMALL The MemoryMap buffer was too small. The current\r | |
1638 | buffer size needed to hold the memory map is\r | |
1639 | returned in MemoryMapSize.\r | |
162ed594 | 1640 | @retval EFI_INVALID_PARAMETER One of the parameters has an invalid value.\r |
1641 | \r | |
1642 | **/\r | |
28a00297 | 1643 | EFI_STATUS\r |
1644 | EFIAPI\r | |
1645 | CoreGetMemoryMap (\r | |
1646 | IN OUT UINTN *MemoryMapSize,\r | |
1647 | IN OUT EFI_MEMORY_DESCRIPTOR *MemoryMap,\r | |
1648 | OUT UINTN *MapKey,\r | |
1649 | OUT UINTN *DescriptorSize,\r | |
1650 | OUT UINT32 *DescriptorVersion\r | |
1651 | )\r | |
28a00297 | 1652 | {\r |
1653 | EFI_STATUS Status;\r | |
022c6d45 | 1654 | UINTN Size;\r |
1655 | UINTN BufferSize;\r | |
ba2c0527 | 1656 | UINTN NumberOfEntries;\r |
28a00297 | 1657 | LIST_ENTRY *Link;\r |
022c6d45 | 1658 | MEMORY_MAP *Entry;\r |
1659 | EFI_GCD_MAP_ENTRY *GcdMapEntry;\r | |
46a65f18 | 1660 | EFI_GCD_MAP_ENTRY MergeGcdMapEntry;\r |
b74350e9 | 1661 | EFI_MEMORY_TYPE Type;\r |
2345e7d4 | 1662 | EFI_MEMORY_DESCRIPTOR *MemoryMapStart;\r |
e38451cd | 1663 | EFI_MEMORY_DESCRIPTOR *MemoryMapEnd;\r |
28a00297 | 1664 | \r |
1665 | //\r | |
1666 | // Make sure the parameters are valid\r | |
1667 | //\r | |
1668 | if (MemoryMapSize == NULL) {\r | |
1669 | return EFI_INVALID_PARAMETER;\r | |
1670 | }\r | |
022c6d45 | 1671 | \r |
28a00297 | 1672 | CoreAcquireGcdMemoryLock ();\r |
022c6d45 | 1673 | \r |
28a00297 | 1674 | //\r |
ba2c0527 | 1675 | // Count the number of Reserved and runtime MMIO entries\r |
a671a012 | 1676 | // And, count the number of Persistent entries.\r |
28a00297 | 1677 | //\r |
ba2c0527 | 1678 | NumberOfEntries = 0;\r |
28a00297 | 1679 | for (Link = mGcdMemorySpaceMap.ForwardLink; Link != &mGcdMemorySpaceMap; Link = Link->ForwardLink) {\r |
1680 | GcdMapEntry = CR (Link, EFI_GCD_MAP_ENTRY, Link, EFI_GCD_MAP_SIGNATURE);\r | |
35ac962b | 1681 | if ((GcdMapEntry->GcdMemoryType == EfiGcdMemoryTypePersistent) || \r |
ba2c0527 LG |
1682 | (GcdMapEntry->GcdMemoryType == EfiGcdMemoryTypeReserved) ||\r |
1683 | ((GcdMapEntry->GcdMemoryType == EfiGcdMemoryTypeMemoryMappedIo) &&\r | |
1684 | ((GcdMapEntry->Attributes & EFI_MEMORY_RUNTIME) == EFI_MEMORY_RUNTIME))) {\r | |
1685 | NumberOfEntries ++;\r | |
a671a012 | 1686 | }\r |
28a00297 | 1687 | }\r |
1688 | \r | |
1689 | Size = sizeof (EFI_MEMORY_DESCRIPTOR);\r | |
1690 | \r | |
1691 | //\r | |
1692 | // Make sure Size != sizeof(EFI_MEMORY_DESCRIPTOR). This will\r | |
1693 | // prevent people from having pointer math bugs in their code.\r | |
1694 | // now you have to use *DescriptorSize to make things work.\r | |
1695 | //\r | |
1696 | Size += sizeof(UINT64) - (Size % sizeof (UINT64));\r | |
1697 | \r | |
1698 | if (DescriptorSize != NULL) {\r | |
1699 | *DescriptorSize = Size;\r | |
1700 | }\r | |
022c6d45 | 1701 | \r |
28a00297 | 1702 | if (DescriptorVersion != NULL) {\r |
1703 | *DescriptorVersion = EFI_MEMORY_DESCRIPTOR_VERSION;\r | |
1704 | }\r | |
1705 | \r | |
1706 | CoreAcquireMemoryLock ();\r | |
1707 | \r | |
1708 | //\r | |
1709 | // Compute the buffer size needed to fit the entire map\r | |
1710 | //\r | |
ba2c0527 | 1711 | BufferSize = Size * NumberOfEntries;\r |
28a00297 | 1712 | for (Link = gMemoryMap.ForwardLink; Link != &gMemoryMap; Link = Link->ForwardLink) {\r |
1713 | BufferSize += Size;\r | |
1714 | }\r | |
1715 | \r | |
1716 | if (*MemoryMapSize < BufferSize) {\r | |
1717 | Status = EFI_BUFFER_TOO_SMALL;\r | |
1718 | goto Done;\r | |
1719 | }\r | |
1720 | \r | |
1721 | if (MemoryMap == NULL) {\r | |
1722 | Status = EFI_INVALID_PARAMETER;\r | |
1723 | goto Done;\r | |
1724 | }\r | |
1725 | \r | |
1726 | //\r | |
1727 | // Build the map\r | |
1728 | //\r | |
383c303c | 1729 | ZeroMem (MemoryMap, BufferSize);\r |
2345e7d4 | 1730 | MemoryMapStart = MemoryMap;\r |
28a00297 | 1731 | for (Link = gMemoryMap.ForwardLink; Link != &gMemoryMap; Link = Link->ForwardLink) {\r |
1732 | Entry = CR (Link, MEMORY_MAP, Link, MEMORY_MAP_SIGNATURE);\r | |
1733 | ASSERT (Entry->VirtualStart == 0);\r | |
1734 | \r | |
b74350e9 | 1735 | //\r |
1736 | // Convert internal map into an EFI_MEMORY_DESCRIPTOR\r | |
1737 | //\r | |
28a00297 | 1738 | MemoryMap->Type = Entry->Type;\r |
1739 | MemoryMap->PhysicalStart = Entry->Start;\r | |
1740 | MemoryMap->VirtualStart = Entry->VirtualStart;\r | |
1741 | MemoryMap->NumberOfPages = RShiftU64 (Entry->End - Entry->Start + 1, EFI_PAGE_SHIFT);\r | |
b74350e9 | 1742 | //\r |
1743 | // If the memory type is EfiConventionalMemory, then determine if the range is part of a\r | |
022c6d45 | 1744 | // memory type bin and needs to be converted to the same memory type as the rest of the\r |
1745 | // memory type bin in order to minimize EFI Memory Map changes across reboots. This\r | |
b74350e9 | 1746 | // improves the chances for a successful S4 resume in the presence of minor page allocation\r |
1747 | // differences across reboots.\r | |
1748 | //\r | |
1749 | if (MemoryMap->Type == EfiConventionalMemory) {\r | |
1750 | for (Type = (EFI_MEMORY_TYPE) 0; Type < EfiMaxMemoryType; Type++) {\r | |
1751 | if (mMemoryTypeStatistics[Type].Special &&\r | |
1752 | mMemoryTypeStatistics[Type].NumberOfPages > 0 &&\r | |
1753 | Entry->Start >= mMemoryTypeStatistics[Type].BaseAddress &&\r | |
e94a9ff7 | 1754 | Entry->End <= mMemoryTypeStatistics[Type].MaximumAddress) {\r |
b74350e9 | 1755 | MemoryMap->Type = Type;\r |
1756 | }\r | |
1757 | }\r | |
1758 | }\r | |
1759 | MemoryMap->Attribute = Entry->Attribute;\r | |
10fe0d81 RN |
1760 | if (MemoryMap->Type < EfiMaxMemoryType) {\r |
1761 | if (mMemoryTypeStatistics[MemoryMap->Type].Runtime) {\r | |
1762 | MemoryMap->Attribute |= EFI_MEMORY_RUNTIME;\r | |
1763 | }\r | |
28a00297 | 1764 | }\r |
022c6d45 | 1765 | \r |
2345e7d4 | 1766 | //\r |
1767 | // Check to see if the new Memory Map Descriptor can be merged with an \r | |
1768 | // existing descriptor if they are adjacent and have the same attributes\r | |
1769 | //\r | |
1770 | MemoryMap = MergeMemoryMapDescriptor (MemoryMapStart, MemoryMap, Size);\r | |
28a00297 | 1771 | }\r |
1772 | \r | |
46a65f18 LG |
1773 | \r |
1774 | ZeroMem (&MergeGcdMapEntry, sizeof (MergeGcdMapEntry));\r | |
1775 | GcdMapEntry = NULL;\r | |
1776 | for (Link = mGcdMemorySpaceMap.ForwardLink; ; Link = Link->ForwardLink) {\r | |
1777 | if (Link != &mGcdMemorySpaceMap) {\r | |
1778 | //\r | |
1779 | // Merge adjacent same type and attribute GCD memory range\r | |
1780 | //\r | |
1781 | GcdMapEntry = CR (Link, EFI_GCD_MAP_ENTRY, Link, EFI_GCD_MAP_SIGNATURE);\r | |
1782 | \r | |
1783 | if ((MergeGcdMapEntry.Capabilities == GcdMapEntry->Capabilities) && \r | |
1784 | (MergeGcdMapEntry.Attributes == GcdMapEntry->Attributes) &&\r | |
1785 | (MergeGcdMapEntry.GcdMemoryType == GcdMapEntry->GcdMemoryType) &&\r | |
1786 | (MergeGcdMapEntry.GcdIoType == GcdMapEntry->GcdIoType)) {\r | |
1787 | MergeGcdMapEntry.EndAddress = GcdMapEntry->EndAddress;\r | |
1788 | continue;\r | |
1789 | }\r | |
1790 | }\r | |
1791 | \r | |
1792 | if ((MergeGcdMapEntry.GcdMemoryType == EfiGcdMemoryTypeReserved) ||\r | |
1793 | ((MergeGcdMapEntry.GcdMemoryType == EfiGcdMemoryTypeMemoryMappedIo) &&\r | |
1794 | ((MergeGcdMapEntry.Attributes & EFI_MEMORY_RUNTIME) == EFI_MEMORY_RUNTIME))) {\r | |
1795 | //\r | |
1796 | // Page Align GCD range is required. When it is converted to EFI_MEMORY_DESCRIPTOR, \r | |
1797 | // it will be recorded as page PhysicalStart and NumberOfPages. \r | |
1798 | //\r | |
1799 | ASSERT ((MergeGcdMapEntry.BaseAddress & EFI_PAGE_MASK) == 0);\r | |
1800 | ASSERT (((MergeGcdMapEntry.EndAddress - MergeGcdMapEntry.BaseAddress + 1) & EFI_PAGE_MASK) == 0);\r | |
1801 | \r | |
ba2c0527 LG |
1802 | // \r |
1803 | // Create EFI_MEMORY_DESCRIPTOR for every Reserved and runtime MMIO GCD entries\r | |
1804 | //\r | |
46a65f18 | 1805 | MemoryMap->PhysicalStart = MergeGcdMapEntry.BaseAddress;\r |
ba2c0527 | 1806 | MemoryMap->VirtualStart = 0;\r |
46a65f18 LG |
1807 | MemoryMap->NumberOfPages = RShiftU64 ((MergeGcdMapEntry.EndAddress - MergeGcdMapEntry.BaseAddress + 1), EFI_PAGE_SHIFT);\r |
1808 | MemoryMap->Attribute = (MergeGcdMapEntry.Attributes & ~EFI_MEMORY_PORT_IO) | \r | |
1809 | (MergeGcdMapEntry.Capabilities & (EFI_MEMORY_RP | EFI_MEMORY_WP | EFI_MEMORY_XP | EFI_MEMORY_RO |\r | |
ff0c6d66 | 1810 | EFI_MEMORY_UC | EFI_MEMORY_UCE | EFI_MEMORY_WC | EFI_MEMORY_WT | EFI_MEMORY_WB));\r |
ba2c0527 | 1811 | \r |
46a65f18 | 1812 | if (MergeGcdMapEntry.GcdMemoryType == EfiGcdMemoryTypeReserved) {\r |
ba2c0527 | 1813 | MemoryMap->Type = EfiReservedMemoryType;\r |
46a65f18 LG |
1814 | } else if (MergeGcdMapEntry.GcdMemoryType == EfiGcdMemoryTypeMemoryMappedIo) {\r |
1815 | if ((MergeGcdMapEntry.Attributes & EFI_MEMORY_PORT_IO) == EFI_MEMORY_PORT_IO) {\r | |
ba2c0527 LG |
1816 | MemoryMap->Type = EfiMemoryMappedIOPortSpace;\r |
1817 | } else {\r | |
1818 | MemoryMap->Type = EfiMemoryMappedIO;\r | |
28a00297 | 1819 | }\r |
28a00297 | 1820 | }\r |
ba2c0527 LG |
1821 | \r |
1822 | //\r | |
1823 | // Check to see if the new Memory Map Descriptor can be merged with an \r | |
1824 | // existing descriptor if they are adjacent and have the same attributes\r | |
1825 | //\r | |
1826 | MemoryMap = MergeMemoryMapDescriptor (MemoryMapStart, MemoryMap, Size);\r | |
28a00297 | 1827 | }\r |
a671a012 | 1828 | \r |
35ac962b | 1829 | if (MergeGcdMapEntry.GcdMemoryType == EfiGcdMemoryTypePersistent) {\r |
46a65f18 LG |
1830 | //\r |
1831 | // Page Align GCD range is required. When it is converted to EFI_MEMORY_DESCRIPTOR, \r | |
1832 | // it will be recorded as page PhysicalStart and NumberOfPages. \r | |
1833 | //\r | |
1834 | ASSERT ((MergeGcdMapEntry.BaseAddress & EFI_PAGE_MASK) == 0);\r | |
1835 | ASSERT (((MergeGcdMapEntry.EndAddress - MergeGcdMapEntry.BaseAddress + 1) & EFI_PAGE_MASK) == 0);\r | |
1836 | \r | |
a671a012 LG |
1837 | // \r |
1838 | // Create EFI_MEMORY_DESCRIPTOR for every Persistent GCD entries\r | |
1839 | //\r | |
46a65f18 | 1840 | MemoryMap->PhysicalStart = MergeGcdMapEntry.BaseAddress;\r |
a671a012 | 1841 | MemoryMap->VirtualStart = 0;\r |
46a65f18 LG |
1842 | MemoryMap->NumberOfPages = RShiftU64 ((MergeGcdMapEntry.EndAddress - MergeGcdMapEntry.BaseAddress + 1), EFI_PAGE_SHIFT);\r |
1843 | MemoryMap->Attribute = MergeGcdMapEntry.Attributes | EFI_MEMORY_NV | \r | |
1844 | (MergeGcdMapEntry.Capabilities & (EFI_MEMORY_RP | EFI_MEMORY_WP | EFI_MEMORY_XP | EFI_MEMORY_RO |\r | |
ff0c6d66 | 1845 | EFI_MEMORY_UC | EFI_MEMORY_UCE | EFI_MEMORY_WC | EFI_MEMORY_WT | EFI_MEMORY_WB));\r |
a671a012 LG |
1846 | MemoryMap->Type = EfiPersistentMemory;\r |
1847 | \r | |
1848 | //\r | |
1849 | // Check to see if the new Memory Map Descriptor can be merged with an \r | |
1850 | // existing descriptor if they are adjacent and have the same attributes\r | |
1851 | //\r | |
1852 | MemoryMap = MergeMemoryMapDescriptor (MemoryMapStart, MemoryMap, Size);\r | |
1853 | }\r | |
46a65f18 LG |
1854 | if (Link == &mGcdMemorySpaceMap) {\r |
1855 | //\r | |
1856 | // break loop when arrive at head.\r | |
1857 | //\r | |
1858 | break;\r | |
1859 | }\r | |
1860 | if (GcdMapEntry != NULL) {\r | |
1861 | //\r | |
1862 | // Copy new GCD map entry for the following GCD range merge\r | |
1863 | //\r | |
1864 | CopyMem (&MergeGcdMapEntry, GcdMapEntry, sizeof (MergeGcdMapEntry));\r | |
1865 | }\r | |
28a00297 | 1866 | }\r |
022c6d45 | 1867 | \r |
2345e7d4 | 1868 | //\r |
1869 | // Compute the size of the buffer actually used after all memory map descriptor merge operations\r | |
1870 | //\r | |
1871 | BufferSize = ((UINT8 *)MemoryMap - (UINT8 *)MemoryMapStart);\r | |
1872 | \r | |
e38451cd JW |
1873 | //\r |
1874 | // Note: Some OSs will treat EFI_MEMORY_DESCRIPTOR.Attribute as really\r | |
1875 | // set attributes and change memory paging attribute accordingly.\r | |
1876 | // But current EFI_MEMORY_DESCRIPTOR.Attribute is assigned by\r | |
1877 | // value from Capabilities in GCD memory map. This might cause\r | |
1878 | // boot problems. Clearing all paging related capabilities can\r | |
1879 | // workaround it. Following code is supposed to be removed once\r | |
1880 | // the usage of EFI_MEMORY_DESCRIPTOR.Attribute is clarified in\r | |
1881 | // UEFI spec and adopted by both EDK-II Core and all supported\r | |
1882 | // OSs.\r | |
1883 | //\r | |
1884 | MemoryMapEnd = MemoryMap;\r | |
1885 | MemoryMap = MemoryMapStart;\r | |
1886 | while (MemoryMap < MemoryMapEnd) {\r | |
1887 | MemoryMap->Attribute &= ~(UINT64)(EFI_MEMORY_RP | EFI_MEMORY_RO |\r | |
1888 | EFI_MEMORY_XP);\r | |
1889 | MemoryMap = NEXT_MEMORY_DESCRIPTOR (MemoryMap, Size);\r | |
1890 | }\r | |
646127c1 JW |
1891 | MergeMemoryMap (MemoryMapStart, &BufferSize, Size);\r |
1892 | MemoryMapEnd = (EFI_MEMORY_DESCRIPTOR *)((UINT8 *)MemoryMapStart + BufferSize);\r | |
e38451cd | 1893 | \r |
28a00297 | 1894 | Status = EFI_SUCCESS;\r |
1895 | \r | |
1896 | Done:\r | |
022c6d45 | 1897 | //\r |
1898 | // Update the map key finally\r | |
1899 | //\r | |
28a00297 | 1900 | if (MapKey != NULL) {\r |
1901 | *MapKey = mMemoryMapKey;\r | |
1902 | }\r | |
022c6d45 | 1903 | \r |
e439df50 | 1904 | CoreReleaseMemoryLock ();\r |
1905 | \r | |
1906 | CoreReleaseGcdMemoryLock ();\r | |
1907 | \r | |
28a00297 | 1908 | *MemoryMapSize = BufferSize;\r |
022c6d45 | 1909 | \r |
e63da9f0 JW |
1910 | DEBUG_CODE (\r |
1911 | if (PcdGet8 (PcdHeapGuardPropertyMask) & (BIT1|BIT0)) {\r | |
1912 | DumpGuardedMemoryBitmap ();\r | |
1913 | }\r | |
1914 | );\r | |
1915 | \r | |
28a00297 | 1916 | return Status;\r |
1917 | }\r | |
1918 | \r | |
28a00297 | 1919 | \r |
162ed594 | 1920 | /**\r |
28a00297 | 1921 | Internal function. Used by the pool functions to allocate pages\r |
1922 | to back pool allocation requests.\r | |
1923 | \r | |
022c6d45 | 1924 | @param PoolType The type of memory for the new pool pages\r |
1925 | @param NumberOfPages No of pages to allocate\r | |
1926 | @param Alignment Bits to align.\r | |
e63da9f0 | 1927 | @param NeedGuard Flag to indicate Guard page is needed or not\r |
28a00297 | 1928 | \r |
162ed594 | 1929 | @return The allocated memory, or NULL\r |
28a00297 | 1930 | \r |
162ed594 | 1931 | **/\r |
1932 | VOID *\r | |
1933 | CoreAllocatePoolPages (\r | |
1934 | IN EFI_MEMORY_TYPE PoolType,\r | |
1935 | IN UINTN NumberOfPages,\r | |
e63da9f0 JW |
1936 | IN UINTN Alignment,\r |
1937 | IN BOOLEAN NeedGuard\r | |
162ed594 | 1938 | )\r |
28a00297 | 1939 | {\r |
1940 | UINT64 Start;\r | |
1941 | \r | |
1942 | //\r | |
1943 | // Find the pages to convert\r | |
1944 | //\r | |
e63da9f0 JW |
1945 | Start = FindFreePages (MAX_ADDRESS, NumberOfPages, PoolType, Alignment,\r |
1946 | NeedGuard);\r | |
28a00297 | 1947 | \r |
1948 | //\r | |
1949 | // Convert it to boot services data\r | |
1950 | //\r | |
1951 | if (Start == 0) {\r | |
7df7393f | 1952 | DEBUG ((DEBUG_ERROR | DEBUG_PAGE, "AllocatePoolPages: failed to allocate %d pages\n", (UINT32)NumberOfPages));\r |
28a00297 | 1953 | } else {\r |
e63da9f0 JW |
1954 | if (NeedGuard) {\r |
1955 | CoreConvertPagesWithGuard (Start, NumberOfPages, PoolType);\r | |
1956 | } else {\r | |
1957 | CoreConvertPages (Start, NumberOfPages, PoolType);\r | |
1958 | }\r | |
28a00297 | 1959 | }\r |
1960 | \r | |
e94a9ff7 | 1961 | return (VOID *)(UINTN) Start;\r |
28a00297 | 1962 | }\r |
1963 | \r | |
162ed594 | 1964 | \r |
1965 | /**\r | |
1966 | Internal function. Frees pool pages allocated via AllocatePoolPages ()\r | |
1967 | \r | |
022c6d45 | 1968 | @param Memory The base address to free\r |
162ed594 | 1969 | @param NumberOfPages The number of pages to free\r |
1970 | \r | |
1971 | **/\r | |
28a00297 | 1972 | VOID\r |
1973 | CoreFreePoolPages (\r | |
1974 | IN EFI_PHYSICAL_ADDRESS Memory,\r | |
1975 | IN UINTN NumberOfPages\r | |
1976 | )\r | |
28a00297 | 1977 | {\r |
1978 | CoreConvertPages (Memory, NumberOfPages, EfiConventionalMemory);\r | |
1979 | }\r | |
1980 | \r | |
1981 | \r | |
28a00297 | 1982 | \r |
162ed594 | 1983 | /**\r |
1984 | Make sure the memory map is following all the construction rules,\r | |
28a00297 | 1985 | it is the last time to check memory map error before exit boot services.\r |
1986 | \r | |
022c6d45 | 1987 | @param MapKey Memory map key\r |
28a00297 | 1988 | \r |
022c6d45 | 1989 | @retval EFI_INVALID_PARAMETER Memory map not consistent with construction\r |
1990 | rules.\r | |
162ed594 | 1991 | @retval EFI_SUCCESS Valid memory map.\r |
28a00297 | 1992 | \r |
162ed594 | 1993 | **/\r |
1994 | EFI_STATUS\r | |
1995 | CoreTerminateMemoryMap (\r | |
1996 | IN UINTN MapKey\r | |
1997 | )\r | |
28a00297 | 1998 | {\r |
1999 | EFI_STATUS Status;\r | |
2000 | LIST_ENTRY *Link;\r | |
2001 | MEMORY_MAP *Entry;\r | |
2002 | \r | |
2003 | Status = EFI_SUCCESS;\r | |
2004 | \r | |
2005 | CoreAcquireMemoryLock ();\r | |
2006 | \r | |
2007 | if (MapKey == mMemoryMapKey) {\r | |
2008 | \r | |
2009 | //\r | |
2010 | // Make sure the memory map is following all the construction rules\r | |
2011 | // This is the last chance we will be able to display any messages on\r | |
2012 | // the console devices.\r | |
2013 | //\r | |
2014 | \r | |
2015 | for (Link = gMemoryMap.ForwardLink; Link != &gMemoryMap; Link = Link->ForwardLink) {\r | |
2016 | Entry = CR(Link, MEMORY_MAP, Link, MEMORY_MAP_SIGNATURE);\r | |
7d17a6a1 AB |
2017 | if (Entry->Type < EfiMaxMemoryType) {\r |
2018 | if (mMemoryTypeStatistics[Entry->Type].Runtime) {\r | |
2019 | ASSERT (Entry->Type != EfiACPIReclaimMemory);\r | |
2020 | ASSERT (Entry->Type != EfiACPIMemoryNVS);\r | |
d4731a98 | 2021 | if ((Entry->Start & (RUNTIME_PAGE_ALLOCATION_GRANULARITY - 1)) != 0) {\r |
7d17a6a1 AB |
2022 | DEBUG((DEBUG_ERROR | DEBUG_PAGE, "ExitBootServices: A RUNTIME memory entry is not on a proper alignment.\n"));\r |
2023 | Status = EFI_INVALID_PARAMETER;\r | |
2024 | goto Done;\r | |
2025 | }\r | |
d4731a98 | 2026 | if (((Entry->End + 1) & (RUNTIME_PAGE_ALLOCATION_GRANULARITY - 1)) != 0) {\r |
7d17a6a1 AB |
2027 | DEBUG((DEBUG_ERROR | DEBUG_PAGE, "ExitBootServices: A RUNTIME memory entry is not on a proper alignment.\n"));\r |
2028 | Status = EFI_INVALID_PARAMETER;\r | |
2029 | goto Done;\r | |
2030 | }\r | |
28a00297 | 2031 | }\r |
2032 | }\r | |
2033 | }\r | |
2034 | \r | |
2035 | //\r | |
2036 | // The map key they gave us matches what we expect. Fall through and\r | |
2037 | // return success. In an ideal world we would clear out all of\r | |
2038 | // EfiBootServicesCode and EfiBootServicesData. However this function\r | |
2039 | // is not the last one called by ExitBootServices(), so we have to\r | |
2040 | // preserve the memory contents.\r | |
2041 | //\r | |
2042 | } else {\r | |
2043 | Status = EFI_INVALID_PARAMETER;\r | |
2044 | }\r | |
2045 | \r | |
d45fd260 | 2046 | Done:\r |
28a00297 | 2047 | CoreReleaseMemoryLock ();\r |
2048 | \r | |
2049 | return Status;\r | |
2050 | }\r | |
2051 | \r | |
2052 | \r | |
2053 | \r | |
2054 | \r | |
2055 | \r | |
2056 | \r | |
2057 | \r | |
2058 | \r | |
162ed594 | 2059 | \r |