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1 /*
2  * Copyright (C) 2016 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 //#define LOG_NDEBUG 0
18 #define LOG_TAG "C2AllocatorIon"
19 #include <utils/Log.h>
20 
21 #include <list>
22 
23 #include <ion/ion.h>
24 #include <sys/mman.h>
25 #include <unistd.h> // getpagesize, size_t, close, dup
26 
27 #include <C2AllocatorIon.h>
28 #include <C2Buffer.h>
29 #include <C2Debug.h>
30 #include <C2ErrnoUtils.h>
31 
32 namespace android {
33 
34 namespace {
35     constexpr size_t USAGE_LRU_CACHE_SIZE = 1024;
36 }
37 
38 /* size_t <=> int(lo), int(hi) conversions */
size2intLo(size_t s)39 constexpr inline int size2intLo(size_t s) {
40     return int(s & 0xFFFFFFFF);
41 }
42 
size2intHi(size_t s)43 constexpr inline int size2intHi(size_t s) {
44     // cast to uint64_t as size_t may be 32 bits wide
45     return int((uint64_t(s) >> 32) & 0xFFFFFFFF);
46 }
47 
ints2size(int intLo,int intHi)48 constexpr inline size_t ints2size(int intLo, int intHi) {
49     // convert in 2 stages to 64 bits as intHi may be negative
50     return size_t(unsigned(intLo)) | size_t(uint64_t(unsigned(intHi)) << 32);
51 }
52 
53 /* ========================================= ION HANDLE ======================================== */
54 /**
55  * ION handle
56  *
57  * There can be only a sole ion client per process, this is captured in the ion fd that is passed
58  * to the constructor, but this should be managed by the ion buffer allocator/mapper.
59  *
60  * ion uses ion_user_handle_t for buffers. We don't store this in the native handle as
61  * it requires an ion_free to decref. Instead, we share the buffer to get an fd that also holds
62  * a refcount.
63  *
64  * This handle will not capture mapped fd-s as updating that would require a global mutex.
65  */
66 
67 struct C2HandleIon : public C2Handle {
68     // ion handle owns ionFd(!) and bufferFd
C2HandleIonandroid::C2HandleIon69     C2HandleIon(int bufferFd, size_t size)
70         : C2Handle(cHeader),
71           mFds{ bufferFd },
72           mInts{ int(size & 0xFFFFFFFF), int((uint64_t(size) >> 32) & 0xFFFFFFFF), kMagic } { }
73 
74     static bool isValid(const C2Handle * const o);
75 
bufferFdandroid::C2HandleIon76     int bufferFd() const { return mFds.mBuffer; }
sizeandroid::C2HandleIon77     size_t size() const {
78         return size_t(unsigned(mInts.mSizeLo))
79                 | size_t(uint64_t(unsigned(mInts.mSizeHi)) << 32);
80     }
81 
82 protected:
83     struct {
84         int mBuffer; // shared ion buffer
85     } mFds;
86     struct {
87         int mSizeLo; // low 32-bits of size
88         int mSizeHi; // high 32-bits of size
89         int mMagic;
90     } mInts;
91 
92 private:
93     typedef C2HandleIon _type;
94     enum {
95         kMagic = '\xc2io\x00',
96         numFds = sizeof(mFds) / sizeof(int),
97         numInts = sizeof(mInts) / sizeof(int),
98         version = sizeof(C2Handle)
99     };
100     //constexpr static C2Handle cHeader = { version, numFds, numInts, {} };
101     const static C2Handle cHeader;
102 };
103 
104 const C2Handle C2HandleIon::cHeader = {
105     C2HandleIon::version,
106     C2HandleIon::numFds,
107     C2HandleIon::numInts,
108     {}
109 };
110 
111 // static
isValid(const C2Handle * const o)112 bool C2HandleIon::isValid(const C2Handle * const o) {
113     if (!o || memcmp(o, &cHeader, sizeof(cHeader))) {
114         return false;
115     }
116     const C2HandleIon *other = static_cast<const C2HandleIon*>(o);
117     return other->mInts.mMagic == kMagic;
118 }
119 
120 // TODO: is the dup of an ion fd identical to ion_share?
121 
122 /* ======================================= ION ALLOCATION ====================================== */
123 class C2AllocationIon : public C2LinearAllocation {
124 public:
125     /* Interface methods */
126     virtual c2_status_t map(
127         size_t offset, size_t size, C2MemoryUsage usage, C2Fence *fence,
128         void **addr /* nonnull */) override;
129     virtual c2_status_t unmap(void *addr, size_t size, C2Fence *fenceFd) override;
130     virtual ~C2AllocationIon() override;
131     virtual const C2Handle *handle() const override;
132     virtual id_t getAllocatorId() const override;
133     virtual bool equals(const std::shared_ptr<C2LinearAllocation> &other) const override;
134 
135     // internal methods
136     C2AllocationIon(int ionFd, size_t size, size_t align, unsigned heapMask, unsigned flags, C2Allocator::id_t id);
137     C2AllocationIon(int ionFd, size_t size, int shareFd, C2Allocator::id_t id);
138 
139     c2_status_t status() const;
140 
141 protected:
142     class Impl;
143     Impl *mImpl;
144 
145     // TODO: we could make this encapsulate shared_ptr and copiable
146     C2_DO_NOT_COPY(C2AllocationIon);
147 };
148 
149 class C2AllocationIon::Impl {
150 private:
151     /**
152      * Constructs an ion allocation.
153      *
154      * \note We always create an ion allocation, even if the allocation or import fails
155      * so that we can capture the error.
156      *
157      * \param ionFd     ion client (ownership transferred to created object)
158      * \param capacity  size of allocation
159      * \param bufferFd  buffer handle (ownership transferred to created object). Must be
160      *                  invalid if err is not 0.
161      * \param buffer    ion buffer user handle (ownership transferred to created object). Must be
162      *                  invalid if err is not 0.
163      * \param err       errno during buffer allocation or import
164      */
Impl(int ionFd,size_t capacity,int bufferFd,ion_user_handle_t buffer,C2Allocator::id_t id,int err)165     Impl(int ionFd, size_t capacity, int bufferFd, ion_user_handle_t buffer, C2Allocator::id_t id, int err)
166         : mIonFd(ionFd),
167           mHandle(bufferFd, capacity),
168           mBuffer(buffer),
169           mId(id),
170           mInit(c2_map_errno<ENOMEM, EACCES, EINVAL>(err)),
171           mMapFd(-1) {
172         if (mInit != C2_OK) {
173             // close ionFd now on error
174             if (mIonFd >= 0) {
175                 close(mIonFd);
176                 mIonFd = -1;
177             }
178             // C2_CHECK(bufferFd < 0);
179             // C2_CHECK(buffer < 0);
180         }
181     }
182 
183 public:
184     /**
185      * Constructs an ion allocation by importing a shared buffer fd.
186      *
187      * \param ionFd     ion client (ownership transferred to created object)
188      * \param capacity  size of allocation
189      * \param bufferFd  buffer handle (ownership transferred to created object)
190      *
191      * \return created ion allocation (implementation) which may be invalid if the
192      * import failed.
193      */
Import(int ionFd,size_t capacity,int bufferFd,C2Allocator::id_t id)194     static Impl *Import(int ionFd, size_t capacity, int bufferFd, C2Allocator::id_t id) {
195         ion_user_handle_t buffer = -1;
196         int ret = ion_import(ionFd, bufferFd, &buffer);
197         return new Impl(ionFd, capacity, bufferFd, buffer, id, ret);
198     }
199 
200     /**
201      * Constructs an ion allocation by allocating an ion buffer.
202      *
203      * \param ionFd     ion client (ownership transferred to created object)
204      * \param size      size of allocation
205      * \param align     desired alignment of allocation
206      * \param heapMask  mask of heaps considered
207      * \param flags     ion allocation flags
208      *
209      * \return created ion allocation (implementation) which may be invalid if the
210      * allocation failed.
211      */
Alloc(int ionFd,size_t size,size_t align,unsigned heapMask,unsigned flags,C2Allocator::id_t id)212     static Impl *Alloc(int ionFd, size_t size, size_t align, unsigned heapMask, unsigned flags, C2Allocator::id_t id) {
213         int bufferFd = -1;
214         ion_user_handle_t buffer = -1;
215         size_t alignedSize = align == 0 ? size : (size + align - 1) & ~(align - 1);
216         int ret = ion_alloc(ionFd, alignedSize, align, heapMask, flags, &buffer);
217         ALOGV("ion_alloc(ionFd = %d, size = %zu, align = %zu, prot = %d, flags = %d) "
218               "returned (%d) ; buffer = %d",
219               ionFd, alignedSize, align, heapMask, flags, ret, buffer);
220         if (ret == 0) {
221             // get buffer fd for native handle constructor
222             ret = ion_share(ionFd, buffer, &bufferFd);
223             if (ret != 0) {
224                 ion_free(ionFd, buffer);
225                 buffer = -1;
226             }
227         }
228         return new Impl(ionFd, alignedSize, bufferFd, buffer, id, ret);
229     }
230 
map(size_t offset,size_t size,C2MemoryUsage usage,C2Fence * fence,void ** addr)231     c2_status_t map(size_t offset, size_t size, C2MemoryUsage usage, C2Fence *fence, void **addr) {
232         (void)fence; // TODO: wait for fence
233         *addr = nullptr;
234         if (!mMappings.empty()) {
235             ALOGV("multiple map");
236             // TODO: technically we should return DUPLICATE here, but our block views don't
237             // actually unmap, so we end up remapping an ion buffer multiple times.
238             //
239             // return C2_DUPLICATE;
240         }
241         if (size == 0) {
242             return C2_BAD_VALUE;
243         }
244 
245         int prot = PROT_NONE;
246         int flags = MAP_SHARED;
247         if (usage.expected & C2MemoryUsage::CPU_READ) {
248             prot |= PROT_READ;
249         }
250         if (usage.expected & C2MemoryUsage::CPU_WRITE) {
251             prot |= PROT_WRITE;
252         }
253 
254         size_t alignmentBytes = offset % PAGE_SIZE;
255         size_t mapOffset = offset - alignmentBytes;
256         size_t mapSize = size + alignmentBytes;
257         Mapping map = { nullptr, alignmentBytes, mapSize };
258 
259         c2_status_t err = C2_OK;
260         if (mMapFd == -1) {
261             int ret = ion_map(mIonFd, mBuffer, mapSize, prot,
262                               flags, mapOffset, (unsigned char**)&map.addr, &mMapFd);
263             ALOGV("ion_map(ionFd = %d, handle = %d, size = %zu, prot = %d, flags = %d, "
264                   "offset = %zu) returned (%d)",
265                   mIonFd, mBuffer, mapSize, prot, flags, mapOffset, ret);
266             if (ret) {
267                 mMapFd = -1;
268                 map.addr = *addr = nullptr;
269                 err = c2_map_errno<EINVAL>(-ret);
270             } else {
271                 *addr = (uint8_t *)map.addr + alignmentBytes;
272             }
273         } else {
274             map.addr = mmap(nullptr, mapSize, prot, flags, mMapFd, mapOffset);
275             ALOGV("mmap(size = %zu, prot = %d, flags = %d, mapFd = %d, offset = %zu) "
276                   "returned (%d)",
277                   mapSize, prot, flags, mMapFd, mapOffset, errno);
278             if (map.addr == MAP_FAILED) {
279                 map.addr = *addr = nullptr;
280                 err = c2_map_errno<EINVAL>(errno);
281             } else {
282                 *addr = (uint8_t *)map.addr + alignmentBytes;
283             }
284         }
285         if (map.addr) {
286             mMappings.push_back(map);
287         }
288         return err;
289     }
290 
unmap(void * addr,size_t size,C2Fence * fence)291     c2_status_t unmap(void *addr, size_t size, C2Fence *fence) {
292         if (mMapFd < 0 || mMappings.empty()) {
293             ALOGD("tried to unmap unmapped buffer");
294             return C2_NOT_FOUND;
295         }
296         for (auto it = mMappings.begin(); it != mMappings.end(); ++it) {
297             if (addr != (uint8_t *)it->addr + it->alignmentBytes ||
298                     size + it->alignmentBytes != it->size) {
299                 continue;
300             }
301             int err = munmap(it->addr, it->size);
302             if (err != 0) {
303                 ALOGD("munmap failed");
304                 return c2_map_errno<EINVAL>(errno);
305             }
306             if (fence) {
307                 *fence = C2Fence(); // not using fences
308             }
309             (void)mMappings.erase(it);
310             ALOGV("successfully unmapped: %d", mBuffer);
311             return C2_OK;
312         }
313         ALOGD("unmap failed to find specified map");
314         return C2_BAD_VALUE;
315     }
316 
~Impl()317     ~Impl() {
318         if (!mMappings.empty()) {
319             ALOGD("Dangling mappings!");
320             for (const Mapping &map : mMappings) {
321                 (void)munmap(map.addr, map.size);
322             }
323         }
324         if (mMapFd >= 0) {
325             close(mMapFd);
326             mMapFd = -1;
327         }
328         if (mInit == C2_OK) {
329             (void)ion_free(mIonFd, mBuffer);
330             native_handle_close(&mHandle);
331         }
332         if (mIonFd >= 0) {
333             close(mIonFd);
334         }
335     }
336 
status() const337     c2_status_t status() const {
338         return mInit;
339     }
340 
handle() const341     const C2Handle *handle() const {
342         return &mHandle;
343     }
344 
getAllocatorId() const345     C2Allocator::id_t getAllocatorId() const {
346         return mId;
347     }
348 
ionHandle() const349     ion_user_handle_t ionHandle() const {
350         return mBuffer;
351     }
352 
353 private:
354     int mIonFd;
355     C2HandleIon mHandle;
356     ion_user_handle_t mBuffer;
357     C2Allocator::id_t mId;
358     c2_status_t mInit;
359     int mMapFd; // only one for now
360     struct Mapping {
361         void *addr;
362         size_t alignmentBytes;
363         size_t size;
364     };
365     std::list<Mapping> mMappings;
366 };
367 
map(size_t offset,size_t size,C2MemoryUsage usage,C2Fence * fence,void ** addr)368 c2_status_t C2AllocationIon::map(
369     size_t offset, size_t size, C2MemoryUsage usage, C2Fence *fence, void **addr) {
370     return mImpl->map(offset, size, usage, fence, addr);
371 }
372 
unmap(void * addr,size_t size,C2Fence * fence)373 c2_status_t C2AllocationIon::unmap(void *addr, size_t size, C2Fence *fence) {
374     return mImpl->unmap(addr, size, fence);
375 }
376 
status() const377 c2_status_t C2AllocationIon::status() const {
378     return mImpl->status();
379 }
380 
getAllocatorId() const381 C2Allocator::id_t C2AllocationIon::getAllocatorId() const {
382     return mImpl->getAllocatorId();
383 }
384 
equals(const std::shared_ptr<C2LinearAllocation> & other) const385 bool C2AllocationIon::equals(const std::shared_ptr<C2LinearAllocation> &other) const {
386     if (!other || other->getAllocatorId() != getAllocatorId()) {
387         return false;
388     }
389     // get user handle to compare objects
390     std::shared_ptr<C2AllocationIon> otherAsIon = std::static_pointer_cast<C2AllocationIon>(other);
391     return mImpl->ionHandle() == otherAsIon->mImpl->ionHandle();
392 }
393 
handle() const394 const C2Handle *C2AllocationIon::handle() const {
395     return mImpl->handle();
396 }
397 
~C2AllocationIon()398 C2AllocationIon::~C2AllocationIon() {
399     delete mImpl;
400 }
401 
C2AllocationIon(int ionFd,size_t size,size_t align,unsigned heapMask,unsigned flags,C2Allocator::id_t id)402 C2AllocationIon::C2AllocationIon(int ionFd, size_t size, size_t align,
403                                  unsigned heapMask, unsigned flags, C2Allocator::id_t id)
404     : C2LinearAllocation(size),
405       mImpl(Impl::Alloc(ionFd, size, align, heapMask, flags, id)) { }
406 
C2AllocationIon(int ionFd,size_t size,int shareFd,C2Allocator::id_t id)407 C2AllocationIon::C2AllocationIon(int ionFd, size_t size, int shareFd, C2Allocator::id_t id)
408     : C2LinearAllocation(size),
409       mImpl(Impl::Import(ionFd, size, shareFd, id)) { }
410 
411 /* ======================================= ION ALLOCATOR ====================================== */
C2AllocatorIon(id_t id)412 C2AllocatorIon::C2AllocatorIon(id_t id)
413     : mInit(C2_OK),
414       mIonFd(ion_open()) {
415     if (mIonFd < 0) {
416         switch (errno) {
417         case ENOENT:    mInit = C2_OMITTED; break;
418         default:        mInit = c2_map_errno<EACCES>(errno); break;
419         }
420     } else {
421         C2MemoryUsage minUsage = { 0, 0 };
422         C2MemoryUsage maxUsage = { C2MemoryUsage::CPU_READ, C2MemoryUsage::CPU_WRITE };
423         Traits traits = { "android.allocator.ion", id, LINEAR, minUsage, maxUsage };
424         mTraits = std::make_shared<Traits>(traits);
425         mBlockSize = ::getpagesize();
426     }
427 }
428 
~C2AllocatorIon()429 C2AllocatorIon::~C2AllocatorIon() {
430     if (mInit == C2_OK) {
431         ion_close(mIonFd);
432     }
433 }
434 
getId() const435 C2Allocator::id_t C2AllocatorIon::getId() const {
436     std::lock_guard<std::mutex> lock(mUsageMapperLock);
437     return mTraits->id;
438 }
439 
getName() const440 C2String C2AllocatorIon::getName() const {
441     std::lock_guard<std::mutex> lock(mUsageMapperLock);
442     return mTraits->name;
443 }
444 
getTraits() const445 std::shared_ptr<const C2Allocator::Traits> C2AllocatorIon::getTraits() const {
446     std::lock_guard<std::mutex> lock(mUsageMapperLock);
447     return mTraits;
448 }
449 
setUsageMapper(const UsageMapperFn & mapper,uint64_t minUsage,uint64_t maxUsage,uint64_t blockSize)450 void C2AllocatorIon::setUsageMapper(
451         const UsageMapperFn &mapper, uint64_t minUsage, uint64_t maxUsage, uint64_t blockSize) {
452     std::lock_guard<std::mutex> lock(mUsageMapperLock);
453     mUsageMapperCache.clear();
454     mUsageMapperLru.clear();
455     mUsageMapper = mapper;
456     Traits traits = {
457         mTraits->name, mTraits->id, LINEAR,
458         C2MemoryUsage(minUsage), C2MemoryUsage(maxUsage)
459     };
460     mTraits = std::make_shared<Traits>(traits);
461     mBlockSize = blockSize;
462 }
463 
operator ()(const MapperKey & k) const464 std::size_t C2AllocatorIon::MapperKeyHash::operator()(const MapperKey &k) const {
465     return std::hash<uint64_t>{}(k.first) ^ std::hash<size_t>{}(k.second);
466 }
467 
mapUsage(C2MemoryUsage usage,size_t capacity,size_t * align,unsigned * heapMask,unsigned * flags)468 c2_status_t C2AllocatorIon::mapUsage(
469         C2MemoryUsage usage, size_t capacity, size_t *align, unsigned *heapMask, unsigned *flags) {
470     std::lock_guard<std::mutex> lock(mUsageMapperLock);
471     c2_status_t res = C2_OK;
472     // align capacity
473     capacity = (capacity + mBlockSize - 1) & ~(mBlockSize - 1);
474     MapperKey key = std::make_pair(usage.expected, capacity);
475     auto entry = mUsageMapperCache.find(key);
476     if (entry == mUsageMapperCache.end()) {
477         if (mUsageMapper) {
478             res = mUsageMapper(usage, capacity, align, heapMask, flags);
479         } else {
480             *align = 0; // TODO make this 1
481             *heapMask = ~0; // default mask
482             *flags = 0; // default flags
483             res = C2_NO_INIT;
484         }
485         // add usage to cache
486         MapperValue value = std::make_tuple(*align, *heapMask, *flags, res);
487         mUsageMapperLru.emplace_front(key, value);
488         mUsageMapperCache.emplace(std::make_pair(key, mUsageMapperLru.begin()));
489         if (mUsageMapperCache.size() > USAGE_LRU_CACHE_SIZE) {
490             // remove LRU entry
491             MapperKey lruKey = mUsageMapperLru.front().first;
492             mUsageMapperCache.erase(lruKey);
493             mUsageMapperLru.pop_back();
494         }
495     } else {
496         // move entry to MRU
497         mUsageMapperLru.splice(mUsageMapperLru.begin(), mUsageMapperLru, entry->second);
498         const MapperValue &value = entry->second->second;
499         std::tie(*align, *heapMask, *flags, res) = value;
500     }
501     return res;
502 }
503 
newLinearAllocation(uint32_t capacity,C2MemoryUsage usage,std::shared_ptr<C2LinearAllocation> * allocation)504 c2_status_t C2AllocatorIon::newLinearAllocation(
505         uint32_t capacity, C2MemoryUsage usage, std::shared_ptr<C2LinearAllocation> *allocation) {
506     if (allocation == nullptr) {
507         return C2_BAD_VALUE;
508     }
509 
510     allocation->reset();
511     if (mInit != C2_OK) {
512         return mInit;
513     }
514 
515     size_t align = 0;
516     unsigned heapMask = ~0;
517     unsigned flags = 0;
518     c2_status_t ret = mapUsage(usage, capacity, &align, &heapMask, &flags);
519     if (ret && ret != C2_NO_INIT) {
520         return ret;
521     }
522 
523     std::shared_ptr<C2AllocationIon> alloc
524         = std::make_shared<C2AllocationIon>(dup(mIonFd), capacity, align, heapMask, flags, mTraits->id);
525     ret = alloc->status();
526     if (ret == C2_OK) {
527         *allocation = alloc;
528     }
529     return ret;
530 }
531 
priorLinearAllocation(const C2Handle * handle,std::shared_ptr<C2LinearAllocation> * allocation)532 c2_status_t C2AllocatorIon::priorLinearAllocation(
533         const C2Handle *handle, std::shared_ptr<C2LinearAllocation> *allocation) {
534     *allocation = nullptr;
535     if (mInit != C2_OK) {
536         return mInit;
537     }
538 
539     if (!C2HandleIon::isValid(handle)) {
540         return C2_BAD_VALUE;
541     }
542 
543     // TODO: get capacity and validate it
544     const C2HandleIon *h = static_cast<const C2HandleIon*>(handle);
545     std::shared_ptr<C2AllocationIon> alloc
546         = std::make_shared<C2AllocationIon>(dup(mIonFd), h->size(), h->bufferFd(), mTraits->id);
547     c2_status_t ret = alloc->status();
548     if (ret == C2_OK) {
549         *allocation = alloc;
550         native_handle_delete(const_cast<native_handle_t*>(
551                 reinterpret_cast<const native_handle_t*>(handle)));
552     }
553     return ret;
554 }
555 
isValid(const C2Handle * const o)556 bool C2AllocatorIon::isValid(const C2Handle* const o) {
557     return C2HandleIon::isValid(o);
558 }
559 
560 } // namespace android
561 
562