1 /*
2 * Copyright (C) 2011-2012 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 #include "rsCpuCore.h"
18 #include "rsCpuScript.h"
19 #include "rsCpuExecutable.h"
20
21 #ifdef RS_COMPATIBILITY_LIB
22 #include <stdio.h>
23 #include <sys/stat.h>
24 #include <unistd.h>
25 #else
26 #include "rsCppUtils.h"
27
28 #include <bcc/Config.h>
29 #include <bcinfo/MetadataExtractor.h>
30
31 #include <zlib.h>
32 #include <sys/file.h>
33 #include <sys/types.h>
34 #include <unistd.h>
35
36 #include <string>
37 #include <vector>
38 #endif
39
40 #include <set>
41 #include <string>
42 #include <dlfcn.h>
43 #include <stdlib.h>
44 #include <string.h>
45 #include <iostream>
46 #include <sstream>
47
48 namespace {
49
50 static const bool kDebugGlobalVariables = false;
51
allocationLODIsNull(const android::renderscript::Allocation * alloc)52 static bool allocationLODIsNull(const android::renderscript::Allocation *alloc) {
53 // Even if alloc != nullptr, mallocPtr could be null if
54 // IO_OUTPUT/IO_INPUT with no bound surface.
55 return alloc && alloc->mHal.drvState.lod[0].mallocPtr == nullptr;
56 }
57
58 #ifndef RS_COMPATIBILITY_LIB
59
setCompileArguments(std::vector<const char * > * args,const std::string & bcFileName,const char * cacheDir,const char * resName,const char * core_lib,bool useRSDebugContext,const char * bccPluginName,bool emitGlobalInfo,int optLevel,bool emitGlobalInfoSkipConstant)60 static void setCompileArguments(std::vector<const char*>* args,
61 const std::string& bcFileName,
62 const char* cacheDir, const char* resName,
63 const char* core_lib, bool useRSDebugContext,
64 const char* bccPluginName, bool emitGlobalInfo,
65 int optLevel, bool emitGlobalInfoSkipConstant) {
66 rsAssert(cacheDir && resName && core_lib);
67 args->push_back(android::renderscript::RsdCpuScriptImpl::BCC_EXE_PATH);
68 args->push_back("-unroll-runtime");
69 args->push_back("-scalarize-load-store");
70 if (emitGlobalInfo) {
71 args->push_back("-rs-global-info");
72 if (emitGlobalInfoSkipConstant) {
73 args->push_back("-rs-global-info-skip-constant");
74 }
75 }
76 args->push_back("-o");
77 args->push_back(resName);
78 args->push_back("-output_path");
79 args->push_back(cacheDir);
80 args->push_back("-bclib");
81 args->push_back(core_lib);
82 args->push_back("-mtriple");
83 args->push_back(DEFAULT_TARGET_TRIPLE_STRING);
84 args->push_back("-O");
85
86 switch (optLevel) {
87 case 0:
88 args->push_back("0");
89 break;
90 case 3:
91 args->push_back("3");
92 break;
93 default:
94 ALOGW("Expected optimization level of 0 or 3. Received %d", optLevel);
95 args->push_back("3");
96 break;
97 }
98
99 // Enable workaround for A53 codegen by default.
100 #if defined(__aarch64__) && !defined(DISABLE_A53_WORKAROUND)
101 args->push_back("-aarch64-fix-cortex-a53-835769");
102 #endif
103
104 // Execute the bcc compiler.
105 if (useRSDebugContext) {
106 args->push_back("-rs-debug-ctx");
107 } else {
108 // Only load additional libraries for compiles that don't use
109 // the debug context.
110 if (bccPluginName && strlen(bccPluginName) > 0) {
111 #ifdef __ANDROID__
112 // For Android, -plugin option must be used in order to load the
113 // vendor plugin from the sphal namespace.
114 args->push_back("-plugin");
115 #else
116 args->push_back("-load");
117 #endif
118 args->push_back(bccPluginName);
119 }
120 }
121
122 args->push_back("-fPIC");
123 args->push_back("-embedRSInfo");
124
125 args->push_back(bcFileName.c_str());
126 args->push_back(nullptr);
127 }
128
compileBitcode(const std::string & bcFileName,const char * bitcode,size_t bitcodeSize,std::vector<const char * > & compileArguments)129 static bool compileBitcode(const std::string &bcFileName,
130 const char *bitcode,
131 size_t bitcodeSize,
132 std::vector<const char *> &compileArguments) {
133 rsAssert(bitcode && bitcodeSize);
134
135 FILE *bcfile = fopen(bcFileName.c_str(), "we");
136 if (!bcfile) {
137 ALOGE("Could not write to %s", bcFileName.c_str());
138 return false;
139 }
140 size_t nwritten = fwrite(bitcode, 1, bitcodeSize, bcfile);
141 fclose(bcfile);
142 if (nwritten != bitcodeSize) {
143 ALOGE("Could not write %zu bytes to %s", bitcodeSize,
144 bcFileName.c_str());
145 return false;
146 }
147
148 return android::renderscript::rsuExecuteCommand(
149 android::renderscript::RsdCpuScriptImpl::BCC_EXE_PATH,
150 compileArguments.size()-1, compileArguments.data());
151 }
152
153 // The checksum is unnecessary under a few conditions, since the primary
154 // use-case for it is debugging. If we are loading something from the
155 // system partition (read-only), we know that it was precompiled as part of
156 // application ahead of time (and thus the checksum is completely
157 // unnecessary). The checksum is also unnecessary on release (non-debug)
158 // builds, as the only way to get a shared object is to have compiled the
159 // script once already. On a release build, there is no way to adjust the
160 // other libraries/dependencies, and so the only reason to recompile would
161 // be for a source APK change or an OTA. In either case, the APK would be
162 // reinstalled, which would already clear the code_cache/ directory.
isChecksumNeeded(const char * cacheDir)163 bool isChecksumNeeded(const char *cacheDir) {
164 static const std::string sysLibPathVndk = getVndkSysLibPath();
165 if ((::strcmp(SYSLIBPATH, cacheDir) == 0) ||
166 (::strcmp(sysLibPathVndk.c_str(), cacheDir) == 0) ||
167 (::strcmp(SYSLIBPATH_VENDOR, cacheDir) == 0))
168 return false;
169 char buf[PROP_VALUE_MAX];
170 android::renderscript::property_get("ro.debuggable", buf, "");
171 return (buf[0] == '1');
172 }
173
addFileToChecksum(const char * fileName,uint32_t & checksum)174 bool addFileToChecksum(const char *fileName, uint32_t &checksum) {
175 int FD = open(fileName, O_RDONLY | O_CLOEXEC);
176 if (FD == -1) {
177 ALOGE("Cannot open file \'%s\' to compute checksum", fileName);
178 return false;
179 }
180
181 char buf[256];
182 while (true) {
183 ssize_t nread = read(FD, buf, sizeof(buf));
184 if (nread < 0) { // bail out on failed read
185 ALOGE("Error while computing checksum for file \'%s\'", fileName);
186 return false;
187 }
188
189 checksum = adler32(checksum, (const unsigned char *) buf, nread);
190 if (static_cast<size_t>(nread) < sizeof(buf)) // EOF
191 break;
192 }
193
194 if (close(FD) != 0) {
195 ALOGE("Cannot close file \'%s\' after computing checksum", fileName);
196 return false;
197 }
198 return true;
199 }
200
201 #endif // !defined(RS_COMPATIBILITY_LIB)
202 } // namespace
203
204 namespace android {
205 namespace renderscript {
206
207 #ifndef RS_COMPATIBILITY_LIB
208
constructBuildChecksum(uint8_t const * bitcode,size_t bitcodeSize,const char * commandLine,const char ** bccFiles,size_t numFiles)209 uint32_t constructBuildChecksum(uint8_t const *bitcode, size_t bitcodeSize,
210 const char *commandLine,
211 const char** bccFiles, size_t numFiles) {
212 uint32_t checksum = adler32(0L, Z_NULL, 0);
213
214 // include checksum of bitcode
215 if (bitcode != nullptr && bitcodeSize > 0) {
216 checksum = adler32(checksum, bitcode, bitcodeSize);
217 }
218
219 // include checksum of command line arguments
220 checksum = adler32(checksum, (const unsigned char *) commandLine,
221 strlen(commandLine));
222
223 // include checksum of bccFiles
224 for (size_t i = 0; i < numFiles; i++) {
225 const char* bccFile = bccFiles[i];
226 if (bccFile[0] != 0 && !addFileToChecksum(bccFile, checksum)) {
227 // return empty checksum instead of something partial/corrupt
228 return 0;
229 }
230 }
231
232 return checksum;
233 }
234
235 #endif // !RS_COMPATIBILITY_LIB
236
RsdCpuScriptImpl(RsdCpuReferenceImpl * ctx,const Script * s)237 RsdCpuScriptImpl::RsdCpuScriptImpl(RsdCpuReferenceImpl *ctx, const Script *s) {
238 mCtx = ctx;
239 mScript = s;
240
241 mScriptSO = nullptr;
242
243 mRoot = nullptr;
244 mRootExpand = nullptr;
245 mInit = nullptr;
246 mFreeChildren = nullptr;
247 mScriptExec = nullptr;
248
249 mBoundAllocs = nullptr;
250 mIntrinsicData = nullptr;
251 mIsThreadable = true;
252
253 mBuildChecksum = 0;
254 mChecksumNeeded = false;
255 }
256
storeRSInfoFromSO()257 bool RsdCpuScriptImpl::storeRSInfoFromSO() {
258 // The shared object may have an invalid build checksum.
259 // Validate and fail early.
260 mScriptExec = ScriptExecutable::createFromSharedObject(
261 mScriptSO, mChecksumNeeded ? mBuildChecksum : 0);
262
263 if (mScriptExec == nullptr) {
264 return false;
265 }
266
267 mRoot = (RootFunc_t) dlsym(mScriptSO, "root");
268 if (mRoot) {
269 //ALOGE("Found root(): %p", mRoot);
270 }
271 mRootExpand = (RootFunc_t) dlsym(mScriptSO, "root.expand");
272 if (mRootExpand) {
273 //ALOGE("Found root.expand(): %p", mRootExpand);
274 }
275 mInit = (InitOrDtorFunc_t) dlsym(mScriptSO, "init");
276 if (mInit) {
277 //ALOGE("Found init(): %p", mInit);
278 }
279 mFreeChildren = (InitOrDtorFunc_t) dlsym(mScriptSO, ".rs.dtor");
280 if (mFreeChildren) {
281 //ALOGE("Found .rs.dtor(): %p", mFreeChildren);
282 }
283
284 size_t varCount = mScriptExec->getExportedVariableCount();
285 if (varCount > 0) {
286 mBoundAllocs = new Allocation *[varCount];
287 memset(mBoundAllocs, 0, varCount * sizeof(*mBoundAllocs));
288 }
289
290 mIsThreadable = mScriptExec->getThreadable();
291 //ALOGE("Script isThreadable? %d", mIsThreadable);
292
293 if (kDebugGlobalVariables) {
294 mScriptExec->dumpGlobalInfo();
295 }
296
297 return true;
298 }
299
init(char const * resName,char const * cacheDir,uint8_t const * bitcode,size_t bitcodeSize,uint32_t flags,char const * bccPluginName)300 bool RsdCpuScriptImpl::init(char const *resName, char const *cacheDir,
301 uint8_t const *bitcode, size_t bitcodeSize,
302 uint32_t flags, char const *bccPluginName) {
303 //ALOGE("rsdScriptCreate %p %p %p %p %i %i %p", rsc, resName, cacheDir,
304 // bitcode, bitcodeSize, flags, lookupFunc);
305 //ALOGE("rsdScriptInit %p %p", rsc, script);
306
307 mCtx->lockMutex();
308 #ifndef RS_COMPATIBILITY_LIB
309 bool useRSDebugContext = false;
310
311 bcinfo::MetadataExtractor bitcodeMetadata((const char *) bitcode, bitcodeSize);
312 if (!bitcodeMetadata.extract()) {
313 ALOGE("Could not extract metadata from bitcode");
314 mCtx->unlockMutex();
315 return false;
316 }
317
318 const char* core_lib = findCoreLib(bitcodeMetadata, (const char*)bitcode, bitcodeSize);
319
320 if (mCtx->getContext()->getContextType() == RS_CONTEXT_TYPE_DEBUG) {
321 useRSDebugContext = true;
322 }
323
324 int optLevel = mCtx->getContext()->getOptLevel();
325
326 std::string bcFileName(cacheDir);
327 bcFileName.append("/");
328 bcFileName.append(resName);
329 bcFileName.append(".bc");
330
331 std::vector<const char*> compileArguments;
332 bool emitGlobalInfo = mCtx->getEmbedGlobalInfo();
333 bool emitGlobalInfoSkipConstant = mCtx->getEmbedGlobalInfoSkipConstant();
334 setCompileArguments(&compileArguments, bcFileName, cacheDir, resName, core_lib,
335 useRSDebugContext, bccPluginName, emitGlobalInfo,
336 optLevel, emitGlobalInfoSkipConstant);
337
338 mChecksumNeeded = isChecksumNeeded(cacheDir);
339 if (mChecksumNeeded) {
340 std::vector<const char *> bccFiles = { BCC_EXE_PATH,
341 core_lib,
342 };
343
344 // The last argument of compileArguments is a nullptr, so remove 1 from
345 // the size.
346 std::unique_ptr<const char> compileCommandLine(
347 rsuJoinStrings(compileArguments.size()-1, compileArguments.data()));
348
349 mBuildChecksum = constructBuildChecksum(bitcode, bitcodeSize,
350 compileCommandLine.get(),
351 bccFiles.data(), bccFiles.size());
352
353 if (mBuildChecksum == 0) {
354 // cannot compute checksum but verification is enabled
355 mCtx->unlockMutex();
356 return false;
357 }
358 }
359 else {
360 // add a dummy/constant as a checksum if verification is disabled
361 mBuildChecksum = 0xabadcafe;
362 }
363
364 // Append build checksum to commandline
365 // Handle the terminal nullptr in compileArguments
366 compileArguments.pop_back();
367 compileArguments.push_back("-build-checksum");
368 std::stringstream ss;
369 ss << std::hex << mBuildChecksum;
370 std::string checksumStr(ss.str());
371 compileArguments.push_back(checksumStr.c_str());
372 compileArguments.push_back(nullptr);
373
374 const bool reuse = !is_force_recompile() && !useRSDebugContext;
375 if (reuse) {
376 mScriptSO = SharedLibraryUtils::loadSharedLibrary(cacheDir, resName);
377
378 // Read RS info from the shared object to detect checksum mismatch
379 if (mScriptSO != nullptr && !storeRSInfoFromSO()) {
380 dlclose(mScriptSO);
381 mScriptSO = nullptr;
382 }
383 }
384
385 // If reuse is desired and we can't, it's either not there or out of date.
386 // We compile the bit code and try loading again.
387 if (mScriptSO == nullptr) {
388 if (!compileBitcode(bcFileName, (const char*)bitcode, bitcodeSize,
389 compileArguments))
390 {
391 ALOGE("bcc: FAILS to compile '%s'", resName);
392 mCtx->unlockMutex();
393 return false;
394 }
395
396 std::string SOPath;
397
398 if (!SharedLibraryUtils::createSharedLibrary(
399 mCtx->getContext()->getDriverName(), cacheDir, resName, reuse,
400 &SOPath)) {
401 ALOGE("Linker: Failed to link object file '%s'", resName);
402 mCtx->unlockMutex();
403 return false;
404 }
405
406 if (reuse) {
407 mScriptSO = SharedLibraryUtils::loadSharedLibrary(cacheDir, resName);
408 } else {
409 mScriptSO = SharedLibraryUtils::loadAndDeleteSharedLibrary(SOPath.c_str());
410 }
411 if (mScriptSO == nullptr) {
412 ALOGE("Unable to load '%s'", resName);
413 mCtx->unlockMutex();
414 return false;
415 }
416
417 // Read RS symbol information from the .so.
418 if (!storeRSInfoFromSO()) {
419 goto error;
420 }
421 }
422
423 mBitcodeFilePath.assign(bcFileName.c_str());
424
425 #else // RS_COMPATIBILITY_LIB is defined
426 const char *nativeLibDir = mCtx->getContext()->getNativeLibDir();
427 mScriptSO = SharedLibraryUtils::loadSharedLibrary(cacheDir, resName, nativeLibDir);
428
429 if (!mScriptSO) {
430 goto error;
431 }
432
433 if (!storeRSInfoFromSO()) {
434 goto error;
435 }
436 #endif
437 mCtx->unlockMutex();
438 return true;
439
440 error:
441
442 mCtx->unlockMutex();
443 if (mScriptSO) {
444 dlclose(mScriptSO);
445 mScriptSO = nullptr;
446 }
447 return false;
448 }
449
450 #ifndef RS_COMPATIBILITY_LIB
451
findCoreLib(const bcinfo::MetadataExtractor & ME,const char * bitcode,size_t bitcodeSize)452 const char* RsdCpuScriptImpl::findCoreLib(const bcinfo::MetadataExtractor& ME, const char* bitcode,
453 size_t bitcodeSize) {
454 const char* defaultLib = SYSLIBPATH_BC"/libclcore.bc";
455
456 // If we're debugging, use the debug library.
457 if (mCtx->getContext()->getContextType() == RS_CONTEXT_TYPE_DEBUG) {
458 if (ME.hasDebugInfo()) {
459 return SYSLIBPATH_BC"/libclcore_debug_g.bc";
460 }
461 return SYSLIBPATH_BC"/libclcore_debug.bc";
462 }
463
464 if (ME.hasDebugInfo()) {
465 return SYSLIBPATH_BC"/libclcore_g.bc";
466 }
467
468 // If a callback has been registered to specify a library, use that.
469 RSSelectRTCallback selectRTCallback = mCtx->getSelectRTCallback();
470 if (selectRTCallback != nullptr) {
471 return selectRTCallback((const char*)bitcode, bitcodeSize);
472 }
473
474 // Check for a platform specific library
475 #if defined(ARCH_ARM_HAVE_NEON) && !defined(DISABLE_CLCORE_NEON)
476 enum bcinfo::RSFloatPrecision prec = ME.getRSFloatPrecision();
477 if (prec == bcinfo::RS_FP_Relaxed) {
478 // NEON-capable ARMv7a devices can use an accelerated math library
479 // for all reduced precision scripts.
480 // ARMv8 does not use NEON, as ASIMD can be used with all precision
481 // levels.
482 return SYSLIBPATH_BC"/libclcore_neon.bc";
483 } else {
484 return defaultLib;
485 }
486 #elif defined(__i386__) || defined(__x86_64__)
487 // x86 devices will use an optimized library.
488 return SYSLIBPATH_BC"/libclcore_x86.bc";
489 #else
490 return defaultLib;
491 #endif
492 }
493
494 #endif
495
populateScript(Script * script)496 void RsdCpuScriptImpl::populateScript(Script *script) {
497 // Copy info over to runtime
498 script->mHal.info.exportedFunctionCount = mScriptExec->getExportedFunctionCount();
499 script->mHal.info.exportedReduceCount = mScriptExec->getExportedReduceCount();
500 script->mHal.info.exportedForEachCount = mScriptExec->getExportedForEachCount();
501 script->mHal.info.exportedVariableCount = mScriptExec->getExportedVariableCount();
502 script->mHal.info.exportedPragmaCount = mScriptExec->getPragmaCount();;
503 script->mHal.info.exportedPragmaKeyList = mScriptExec->getPragmaKeys();
504 script->mHal.info.exportedPragmaValueList = mScriptExec->getPragmaValues();
505
506 // Bug, need to stash in metadata
507 if (mRootExpand) {
508 script->mHal.info.root = mRootExpand;
509 } else {
510 script->mHal.info.root = mRoot;
511 }
512 }
513
514 // Set up the launch dimensions, and write the values of the launch
515 // dimensions into the mtls start/end fields.
516 //
517 // Inputs:
518 // baseDim - base shape of the input
519 // sc - used to constrain the launch dimensions
520 //
521 // Returns:
522 // True on success, false on failure to set up
setUpMtlsDimensions(MTLaunchStructCommon * mtls,const RsLaunchDimensions & baseDim,const RsScriptCall * sc)523 bool RsdCpuScriptImpl::setUpMtlsDimensions(MTLaunchStructCommon *mtls,
524 const RsLaunchDimensions &baseDim,
525 const RsScriptCall *sc) {
526 rsAssert(mtls);
527
528 #define SET_UP_DIMENSION(DIM_FIELD, SC_FIELD) do { \
529 if (!sc || (sc->SC_FIELD##End == 0)) { \
530 mtls->end.DIM_FIELD = baseDim.DIM_FIELD; \
531 } else { \
532 mtls->start.DIM_FIELD = \
533 rsMin(baseDim.DIM_FIELD, sc->SC_FIELD##Start); \
534 mtls->end.DIM_FIELD = \
535 rsMin(baseDim.DIM_FIELD, sc->SC_FIELD##End); \
536 if (mtls->start.DIM_FIELD >= mtls->end.DIM_FIELD) { \
537 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT, \
538 "Failed to launch kernel; Invalid " \
539 #SC_FIELD "Start or " #SC_FIELD "End."); \
540 return false; \
541 } \
542 }} while(0)
543
544 SET_UP_DIMENSION(x, x);
545 SET_UP_DIMENSION(y, y);
546 SET_UP_DIMENSION(z, z);
547 // Checks and setup of fields other than x, y, z are ignored, since those
548 // fields are not used in the runtime and are not visible in the Java API.
549 #undef SET_UP_DIMENSION
550
551 return true;
552 }
553
554 // Preliminary work to prepare a general reduce-style kernel for launch.
reduceMtlsSetup(const Allocation ** ains,uint32_t inLen,const Allocation * aout,const RsScriptCall * sc,MTLaunchStructReduce * mtls)555 bool RsdCpuScriptImpl::reduceMtlsSetup(const Allocation ** ains,
556 uint32_t inLen,
557 const Allocation * aout,
558 const RsScriptCall *sc,
559 MTLaunchStructReduce *mtls) {
560 rsAssert(ains && (inLen >= 1) && aout);
561 memset(mtls, 0, sizeof(MTLaunchStructReduce));
562 mtls->dimPtr = &mtls->redp.dim;
563
564 for (int index = inLen; --index >= 0;) {
565 if (allocationLODIsNull(ains[index])) {
566 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT,
567 "reduce called with null in allocations");
568 return false;
569 }
570 }
571
572 if (allocationLODIsNull(aout)) {
573 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT,
574 "reduce called with null out allocation");
575 return false;
576 }
577
578 const Allocation *ain0 = ains[0];
579 const Type *inType = ain0->getType();
580
581 mtls->redp.dim.x = inType->getDimX();
582 mtls->redp.dim.y = inType->getDimY();
583 mtls->redp.dim.z = inType->getDimZ();
584
585 for (int Index = inLen; --Index >= 1;) {
586 if (!ain0->hasSameDims(ains[Index])) {
587 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT,
588 "Failed to launch reduction kernel;"
589 "dimensions of input allocations do not match.");
590 return false;
591 }
592 }
593
594 if (!setUpMtlsDimensions(mtls, mtls->redp.dim, sc)) {
595 return false;
596 }
597
598 // The X & Y walkers always want 0-1 min even if dim is not present
599 mtls->end.x = rsMax((uint32_t)1, mtls->end.x);
600 mtls->end.y = rsMax((uint32_t)1, mtls->end.y);
601
602 mtls->rs = mCtx;
603
604 mtls->mSliceNum = 0;
605 mtls->mSliceSize = 1;
606 mtls->isThreadable = mIsThreadable;
607
608 // Set up output,
609 mtls->redp.outLen = 1;
610 mtls->redp.outPtr[0] = (uint8_t *)aout->mHal.drvState.lod[0].mallocPtr;
611 mtls->redp.outStride[0] = aout->getType()->getElementSizeBytes();
612
613 // Set up input.
614 memcpy(mtls->ains, ains, inLen * sizeof(ains[0]));
615 mtls->redp.inLen = inLen;
616 for (int index = inLen; --index >= 0;) {
617 mtls->redp.inPtr[index] = (const uint8_t*)ains[index]->mHal.drvState.lod[0].mallocPtr;
618 mtls->redp.inStride[index] = ains[index]->getType()->getElementSizeBytes();
619 }
620
621 // All validation passed, ok to launch threads
622 return true;
623 }
624
625 // Preliminary work to prepare a forEach-style kernel for launch.
forEachMtlsSetup(const Allocation ** ains,uint32_t inLen,Allocation * aout,const void * usr,uint32_t usrLen,const RsScriptCall * sc,MTLaunchStructForEach * mtls)626 bool RsdCpuScriptImpl::forEachMtlsSetup(const Allocation ** ains,
627 uint32_t inLen,
628 Allocation * aout,
629 const void * usr, uint32_t usrLen,
630 const RsScriptCall *sc,
631 MTLaunchStructForEach *mtls) {
632 if (ains == nullptr && inLen != 0) {
633 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT,
634 "rsForEach called with none-zero inLen with null in allocations");
635 return false;
636 }
637
638 memset(mtls, 0, sizeof(MTLaunchStructForEach));
639 mtls->dimPtr = &mtls->fep.dim;
640
641 for (int index = inLen; --index >= 0;) {
642 if (allocationLODIsNull(ains[index])) {
643 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT,
644 "rsForEach called with null in allocations");
645 return false;
646 }
647 }
648
649 if (allocationLODIsNull(aout)) {
650 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT,
651 "rsForEach called with null out allocations");
652 return false;
653 }
654
655 // The only situation where ains[j] is null is when inLen==1 and j==0;
656 // and that can only happen for an old-style kernel in API level 11~13,
657 // where the input allocation cannot be skipped if the output allocation is specified.
658 if (inLen != 0)
659 rsAssert((inLen == 1) || (ains[0] != nullptr));
660
661 if (inLen > 0 && ains[0]) {
662 const Allocation *ain0 = ains[0];
663 const Type *inType = ain0->getType();
664
665 mtls->fep.dim.x = inType->getDimX();
666 mtls->fep.dim.y = inType->getDimY();
667 mtls->fep.dim.z = inType->getDimZ();
668
669 for (int Index = inLen; --Index >= 1;) {
670 if (!ain0->hasSameDims(ains[Index])) {
671 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT,
672 "Failed to launch kernel; dimensions of input "
673 "allocations do not match.");
674 return false;
675 }
676 }
677 } else if (aout != nullptr) {
678 const Type *outType = aout->getType();
679
680 mtls->fep.dim.x = outType->getDimX();
681 mtls->fep.dim.y = outType->getDimY();
682 mtls->fep.dim.z = outType->getDimZ();
683
684 } else if (sc != nullptr) {
685 mtls->fep.dim.x = sc->xEnd;
686 mtls->fep.dim.y = sc->yEnd;
687 mtls->fep.dim.z = 0;
688 } else {
689 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT,
690 "rsForEach called with null allocations");
691 return false;
692 }
693
694 if (inLen > 0 && aout != nullptr) {
695 if (ains[0] && !ains[0]->hasSameDims(aout)) {
696 mCtx->getContext()->setError(RS_ERROR_BAD_SCRIPT,
697 "Failed to launch kernel; dimensions of input and output allocations do not match.");
698
699 return false;
700 }
701 }
702
703 if (!setUpMtlsDimensions(mtls, mtls->fep.dim, sc)) {
704 return false;
705 }
706
707 // The X & Y walkers always want 0-1 min even if dim is not present
708 mtls->end.x = rsMax((uint32_t)1, mtls->end.x);
709 mtls->end.y = rsMax((uint32_t)1, mtls->end.y);
710 mtls->rs = mCtx;
711 if (ains) {
712 memcpy(mtls->ains, ains, inLen * sizeof(ains[0]));
713 }
714 mtls->aout[0] = aout;
715 mtls->fep.usr = usr;
716 mtls->fep.usrLen = usrLen;
717 mtls->mSliceSize = 1;
718 mtls->mSliceNum = 0;
719
720 mtls->isThreadable = mIsThreadable;
721
722 if (inLen > 0) {
723 mtls->fep.inLen = inLen;
724 for (int index = inLen; --index >= 0;) {
725 if (ains[index] == nullptr) {
726 // In old style kernels, the first and only input allocation could be null.
727 // Not allowed in newer styles.
728 rsAssert(inLen == 1 && index == 0);
729 continue;
730 }
731 mtls->fep.inPtr[index] = (const uint8_t*)ains[index]->mHal.drvState.lod[0].mallocPtr;
732 mtls->fep.inStride[index] = ains[index]->getType()->getElementSizeBytes();
733 }
734 }
735
736 if (aout != nullptr) {
737 mtls->fep.outPtr[0] = (uint8_t *)aout->mHal.drvState.lod[0].mallocPtr;
738 mtls->fep.outStride[0] = aout->getType()->getElementSizeBytes();
739 }
740
741 // All validation passed, ok to launch threads
742 return true;
743 }
744
745
invokeForEach(uint32_t slot,const Allocation ** ains,uint32_t inLen,Allocation * aout,const void * usr,uint32_t usrLen,const RsScriptCall * sc)746 void RsdCpuScriptImpl::invokeForEach(uint32_t slot,
747 const Allocation ** ains,
748 uint32_t inLen,
749 Allocation * aout,
750 const void * usr,
751 uint32_t usrLen,
752 const RsScriptCall *sc) {
753
754 MTLaunchStructForEach mtls;
755
756 if (forEachMtlsSetup(ains, inLen, aout, usr, usrLen, sc, &mtls)) {
757 forEachKernelSetup(slot, &mtls);
758
759 RsdCpuScriptImpl * oldTLS = mCtx->setTLS(this);
760 mCtx->launchForEach(ains, inLen, aout, sc, &mtls);
761 mCtx->setTLS(oldTLS);
762 }
763 }
764
invokeReduce(uint32_t slot,const Allocation ** ains,uint32_t inLen,Allocation * aout,const RsScriptCall * sc)765 void RsdCpuScriptImpl::invokeReduce(uint32_t slot,
766 const Allocation ** ains, uint32_t inLen,
767 Allocation *aout,
768 const RsScriptCall *sc) {
769 MTLaunchStructReduce mtls;
770
771 if (reduceMtlsSetup(ains, inLen, aout, sc, &mtls)) {
772 reduceKernelSetup(slot, &mtls);
773 RsdCpuScriptImpl *oldTLS = mCtx->setTLS(this);
774 mCtx->launchReduce(ains, inLen, aout, &mtls);
775 mCtx->setTLS(oldTLS);
776 }
777 }
778
forEachKernelSetup(uint32_t slot,MTLaunchStructForEach * mtls)779 void RsdCpuScriptImpl::forEachKernelSetup(uint32_t slot, MTLaunchStructForEach *mtls) {
780 mtls->script = this;
781 mtls->fep.slot = slot;
782 mtls->kernel = mScriptExec->getForEachFunction(slot);
783 rsAssert(mtls->kernel != nullptr);
784 }
785
reduceKernelSetup(uint32_t slot,MTLaunchStructReduce * mtls)786 void RsdCpuScriptImpl::reduceKernelSetup(uint32_t slot, MTLaunchStructReduce *mtls) {
787 mtls->script = this;
788 mtls->redp.slot = slot;
789
790 const ReduceDescription *desc = mScriptExec->getReduceDescription(slot);
791 mtls->accumFunc = desc->accumFunc;
792 mtls->initFunc = desc->initFunc; // might legally be nullptr
793 mtls->combFunc = desc->combFunc; // might legally be nullptr
794 mtls->outFunc = desc->outFunc; // might legally be nullptr
795 mtls->accumSize = desc->accumSize;
796
797 rsAssert(mtls->accumFunc != nullptr);
798 }
799
invokeRoot()800 int RsdCpuScriptImpl::invokeRoot() {
801 RsdCpuScriptImpl * oldTLS = mCtx->setTLS(this);
802 int ret = mRoot();
803 mCtx->setTLS(oldTLS);
804 return ret;
805 }
806
invokeInit()807 void RsdCpuScriptImpl::invokeInit() {
808 if (mInit) {
809 mInit();
810 }
811 }
812
invokeFreeChildren()813 void RsdCpuScriptImpl::invokeFreeChildren() {
814 if (mFreeChildren) {
815 mFreeChildren();
816 }
817 }
818
invokeFunction(uint32_t slot,const void * params,size_t paramLength)819 void RsdCpuScriptImpl::invokeFunction(uint32_t slot, const void *params,
820 size_t paramLength) {
821 //ALOGE("invoke %i %p %zu", slot, params, paramLength);
822 void * ap = nullptr;
823
824 #if defined(__x86_64__)
825 // The invoked function could have input parameter of vector type for example float4 which
826 // requires void* params to be 16 bytes aligned when using SSE instructions for x86_64 platform.
827 // So try to align void* params before passing them into RS exported function.
828
829 if ((uint8_t)(uint64_t)params & 0x0F) {
830 if ((ap = (void*)memalign(16, paramLength)) != nullptr) {
831 memcpy(ap, params, paramLength);
832 } else {
833 ALOGE("x86_64: invokeFunction memalign error, still use params which"
834 " is not 16 bytes aligned.");
835 }
836 }
837 #endif
838
839 RsdCpuScriptImpl * oldTLS = mCtx->setTLS(this);
840 reinterpret_cast<void (*)(const void *, uint32_t)>(
841 mScriptExec->getInvokeFunction(slot))(ap? (const void *) ap: params, paramLength);
842
843 #if defined(__x86_64__)
844 free(ap);
845 #endif
846
847 mCtx->setTLS(oldTLS);
848 }
849
setGlobalVar(uint32_t slot,const void * data,size_t dataLength)850 void RsdCpuScriptImpl::setGlobalVar(uint32_t slot, const void *data, size_t dataLength) {
851 //rsAssert(!script->mFieldIsObject[slot]);
852 //ALOGE("setGlobalVar %i %p %zu", slot, data, dataLength);
853
854 //if (mIntrinsicID) {
855 //mIntrinsicFuncs.setVar(dc, script, drv->mIntrinsicData, slot, data, dataLength);
856 //return;
857 //}
858
859 int32_t *destPtr = reinterpret_cast<int32_t *>(mScriptExec->getFieldAddress(slot));
860 if (!destPtr) {
861 //ALOGV("Calling setVar on slot = %i which is null", slot);
862 return;
863 }
864
865 memcpy(destPtr, data, dataLength);
866 }
867
getGlobalVar(uint32_t slot,void * data,size_t dataLength)868 void RsdCpuScriptImpl::getGlobalVar(uint32_t slot, void *data, size_t dataLength) {
869 //rsAssert(!script->mFieldIsObject[slot]);
870 //ALOGE("getGlobalVar %i %p %zu", slot, data, dataLength);
871
872 int32_t *srcPtr = reinterpret_cast<int32_t *>(mScriptExec->getFieldAddress(slot));
873 if (!srcPtr) {
874 //ALOGV("Calling setVar on slot = %i which is null", slot);
875 return;
876 }
877 memcpy(data, srcPtr, dataLength);
878 }
879
880
setGlobalVarWithElemDims(uint32_t slot,const void * data,size_t dataLength,const Element * elem,const uint32_t * dims,size_t dimLength)881 void RsdCpuScriptImpl::setGlobalVarWithElemDims(uint32_t slot, const void *data, size_t dataLength,
882 const Element *elem,
883 const uint32_t *dims, size_t dimLength) {
884 int32_t *destPtr = reinterpret_cast<int32_t *>(mScriptExec->getFieldAddress(slot));
885 if (!destPtr) {
886 //ALOGV("Calling setVar on slot = %i which is null", slot);
887 return;
888 }
889
890 // We want to look at dimension in terms of integer components,
891 // but dimLength is given in terms of bytes.
892 dimLength /= sizeof(int);
893
894 // Only a single dimension is currently supported.
895 rsAssert(dimLength == 1);
896 if (dimLength == 1) {
897 // First do the increment loop.
898 size_t stride = elem->getSizeBytes();
899 const char *cVal = reinterpret_cast<const char *>(data);
900 for (uint32_t i = 0; i < dims[0]; i++) {
901 elem->incRefs(cVal);
902 cVal += stride;
903 }
904
905 // Decrement loop comes after (to prevent race conditions).
906 char *oldVal = reinterpret_cast<char *>(destPtr);
907 for (uint32_t i = 0; i < dims[0]; i++) {
908 elem->decRefs(oldVal);
909 oldVal += stride;
910 }
911 }
912
913 memcpy(destPtr, data, dataLength);
914 }
915
setGlobalBind(uint32_t slot,Allocation * data)916 void RsdCpuScriptImpl::setGlobalBind(uint32_t slot, Allocation *data) {
917
918 //rsAssert(!script->mFieldIsObject[slot]);
919 //ALOGE("setGlobalBind %i %p", slot, data);
920
921 int32_t *destPtr = reinterpret_cast<int32_t *>(mScriptExec->getFieldAddress(slot));
922 if (!destPtr) {
923 //ALOGV("Calling setVar on slot = %i which is null", slot);
924 return;
925 }
926
927 void *ptr = nullptr;
928 mBoundAllocs[slot] = data;
929 if (data) {
930 ptr = data->mHal.drvState.lod[0].mallocPtr;
931 }
932 memcpy(destPtr, &ptr, sizeof(void *));
933 }
934
setGlobalObj(uint32_t slot,ObjectBase * data)935 void RsdCpuScriptImpl::setGlobalObj(uint32_t slot, ObjectBase *data) {
936
937 //rsAssert(script->mFieldIsObject[slot]);
938 //ALOGE("setGlobalObj %i %p", slot, data);
939
940 int32_t *destPtr = reinterpret_cast<int32_t *>(mScriptExec->getFieldAddress(slot));
941 if (!destPtr) {
942 //ALOGV("Calling setVar on slot = %i which is null", slot);
943 return;
944 }
945
946 rsrSetObject(mCtx->getContext(), (rs_object_base *)destPtr, data);
947 }
948
getFieldName(uint32_t slot) const949 const char* RsdCpuScriptImpl::getFieldName(uint32_t slot) const {
950 return mScriptExec->getFieldName(slot);
951 }
952
~RsdCpuScriptImpl()953 RsdCpuScriptImpl::~RsdCpuScriptImpl() {
954 delete mScriptExec;
955 delete[] mBoundAllocs;
956 if (mScriptSO) {
957 dlclose(mScriptSO);
958 }
959 }
960
getAllocationForPointer(const void * ptr) const961 Allocation * RsdCpuScriptImpl::getAllocationForPointer(const void *ptr) const {
962 if (!ptr) {
963 return nullptr;
964 }
965
966 for (uint32_t ct=0; ct < mScript->mHal.info.exportedVariableCount; ct++) {
967 Allocation *a = mBoundAllocs[ct];
968 if (!a) continue;
969 if (a->mHal.drvState.lod[0].mallocPtr == ptr) {
970 return a;
971 }
972 }
973 ALOGE("rsGetAllocation, failed to find %p", ptr);
974 return nullptr;
975 }
976
getGlobalEntries() const977 int RsdCpuScriptImpl::getGlobalEntries() const {
978 return mScriptExec->getGlobalEntries();
979 }
980
getGlobalName(int i) const981 const char * RsdCpuScriptImpl::getGlobalName(int i) const {
982 return mScriptExec->getGlobalName(i);
983 }
984
getGlobalAddress(int i) const985 const void * RsdCpuScriptImpl::getGlobalAddress(int i) const {
986 return mScriptExec->getGlobalAddress(i);
987 }
988
getGlobalSize(int i) const989 size_t RsdCpuScriptImpl::getGlobalSize(int i) const {
990 return mScriptExec->getGlobalSize(i);
991 }
992
getGlobalProperties(int i) const993 uint32_t RsdCpuScriptImpl::getGlobalProperties(int i) const {
994 return mScriptExec->getGlobalProperties(i);
995 }
996
preLaunch(uint32_t slot,const Allocation ** ains,uint32_t inLen,Allocation * aout,const void * usr,uint32_t usrLen,const RsScriptCall * sc)997 void RsdCpuScriptImpl::preLaunch(uint32_t slot, const Allocation ** ains,
998 uint32_t inLen, Allocation * aout,
999 const void * usr, uint32_t usrLen,
1000 const RsScriptCall *sc) {}
1001
postLaunch(uint32_t slot,const Allocation ** ains,uint32_t inLen,Allocation * aout,const void * usr,uint32_t usrLen,const RsScriptCall * sc)1002 void RsdCpuScriptImpl::postLaunch(uint32_t slot, const Allocation ** ains,
1003 uint32_t inLen, Allocation * aout,
1004 const void * usr, uint32_t usrLen,
1005 const RsScriptCall *sc) {}
1006
1007
1008 } // namespace renderscript
1009 } // namespace android
1010