lib/Renderscript/RSInfo.cpp - platform/frameworks/compile/libbcc - Git at Google

 /*
  * Copyright 2012, The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 //#define LOG_NDEBUG 0
 #include "bcc/Renderscript/RSInfo.h"

 #include <dlfcn.h>

 #include <cstring>
 #include <new>
 #include <string>

 #include "bcc/Support/FileBase.h"
 #include "bcc/Support/Log.h"

 #include <cutils/properties.h>

 using namespace bcc;

 const char RSInfo::LibBCCPath[] = "/system/lib/libbcc.so";
 const char RSInfo::LibCompilerRTPath[] = "/system/lib/libcompiler_rt.so";
 const char RSInfo::LibRSPath[] = "/system/lib/libRS.so";
 const char RSInfo::LibCLCorePath[] = "/system/lib/libclcore.bc";
 #if defined(ARCH_X86_HAVE_SSE2)
 const char RSInfo::LibCLCoreX86Path[] = "/system/lib/libclcore_x86.bc";
 #endif
 #if defined(ARCH_ARM_HAVE_NEON)
 const char RSInfo::LibCLCoreNEONPath[] = "/system/lib/libclcore_neon.bc";
 #endif

 const uint8_t *RSInfo::LibBCCSHA1 = NULL;
 const uint8_t *RSInfo::LibCompilerRTSHA1 = NULL;
 const uint8_t *RSInfo::LibRSSHA1 = NULL;
 const uint8_t *RSInfo::LibCLCoreSHA1 = NULL;
 #if defined(ARCH_ARM_HAVE_NEON)
 const uint8_t *RSInfo::LibCLCoreNEONSHA1 = NULL;
 #endif

 bool RSInfo::LoadBuiltInSHA1Information() {
 #ifdef TARGET_BUILD
   if (LibBCCSHA1 != NULL) {
     // Loaded before.
     return true;
   }

   void *h = ::dlopen("/system/lib/libbcc.sha1.so", RTLD_LAZY | RTLD_NOW);
   if (h == NULL) {
     ALOGE("Failed to load SHA-1 information from shared library '"
           "/system/lib/libbcc.sha1.so'! (%s)", ::dlerror());
     return false;
   }

   LibBCCSHA1 = reinterpret_cast<const uint8_t *>(::dlsym(h, "libbcc_so_SHA1"));
   LibCompilerRTSHA1 =
       reinterpret_cast<const uint8_t *>(::dlsym(h, "libcompiler_rt_so_SHA1"));
   LibRSSHA1 = reinterpret_cast<const uint8_t *>(::dlsym(h, "libRS_so_SHA1"));
   LibCLCoreSHA1 =
       reinterpret_cast<const uint8_t *>(::dlsym(h, "libclcore_bc_SHA1"));
 #if defined(ARCH_ARM_HAVE_NEON)
   LibCLCoreNEONSHA1 =
       reinterpret_cast<const uint8_t *>(::dlsym(h, "libclcore_neon_bc_SHA1"));
 #endif

   return true;
 #else  // TARGET_BUILD
   return false;
 #endif  // TARGET_BUILD
 }

 android::String8 RSInfo::GetPath(const FileBase &pFile) {
   android::String8 result(pFile.getName().c_str());
   result.append(".info");
   return result;
 }

 #define PRINT_DEPENDENCY(PREFIX, N, X) \
         ALOGV("\t" PREFIX "Source name: %s, "                                 \
                           "SHA-1: %02x%02x%02x%02x%02x%02x%02x%02x%02x%02x"   \
                                  "%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x",  \
               (N), (X)[ 0], (X)[ 1], (X)[ 2], (X)[ 3], (X)[ 4], (X)[ 5],      \
                    (X)[ 6], (X)[ 7], (X)[ 8], (X)[ 9], (X)[10], (X)[11],      \
                    (X)[12], (X)[13], (X)[14], (X)[15], (X)[16], (X)[17],      \
                    (X)[18], (X)[19]);

 bool RSInfo::CheckDependency(const RSInfo &pInfo,
                              const char *pInputFilename,
                              const DependencyTableTy &pDeps) {
   // Built-in dependencies are libbcc.so, libRS.so and libclcore.bc plus
   // libclcore_neon.bc if NEON is available on the target device.
 #if !defined(ARCH_ARM_HAVE_NEON)
   static const unsigned NumBuiltInDependencies = 4;
 #else
   static const unsigned NumBuiltInDependencies = 5;
 #endif

   LoadBuiltInSHA1Information();

   if (pInfo.mDependencyTable.size() != (pDeps.size() + NumBuiltInDependencies)) {
     ALOGD("Number of dependencies recorded mismatch (%lu v.s. %lu) in %s!",
           static_cast<unsigned long>(pInfo.mDependencyTable.size()),
           static_cast<unsigned long>(pDeps.size()), pInputFilename);
     return false;
   } else {
     // Built-in dependencies always go first.
     const std::pair<const char *, const uint8_t *> &cache_libbcc_dep =
         pInfo.mDependencyTable[0];
     const std::pair<const char *, const uint8_t *> &cache_libcompiler_rt_dep =
         pInfo.mDependencyTable[1];
     const std::pair<const char *, const uint8_t *> &cache_libRS_dep =
         pInfo.mDependencyTable[2];
     const std::pair<const char *, const uint8_t *> &cache_libclcore_dep =
         pInfo.mDependencyTable[3];
 #if defined(ARCH_ARM_HAVE_NEON)
     const std::pair<const char *, const uint8_t *> &cache_libclcore_neon_dep =
         pInfo.mDependencyTable[4];
 #endif

     // Check libbcc.so.
     if (::memcmp(cache_libbcc_dep.second, LibBCCSHA1, SHA1_DIGEST_LENGTH) != 0) {
         ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
               LibBCCPath);
         PRINT_DEPENDENCY("current - ", LibBCCPath, LibBCCSHA1);
         PRINT_DEPENDENCY("cache - ", cache_libbcc_dep.first,
                                      cache_libbcc_dep.second);
         return false;
     }

     // Check libcompiler_rt.so.
     if (::memcmp(cache_libcompiler_rt_dep.second, LibCompilerRTSHA1,
                  SHA1_DIGEST_LENGTH) != 0) {
         ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
               LibCompilerRTPath);
         PRINT_DEPENDENCY("current - ", LibCompilerRTPath, LibCompilerRTSHA1);
         PRINT_DEPENDENCY("cache - ", cache_libcompiler_rt_dep.first,
                                      cache_libcompiler_rt_dep.second);
         return false;
     }

     // Check libRS.so.
     if (::memcmp(cache_libRS_dep.second, LibRSSHA1, SHA1_DIGEST_LENGTH) != 0) {
         ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
               LibRSPath);
         PRINT_DEPENDENCY("current - ", LibRSPath, LibRSSHA1);
         PRINT_DEPENDENCY("cache - ", cache_libRS_dep.first,
                                      cache_libRS_dep.second);
         return false;
     }

     // Check libclcore.bc.
     if (::memcmp(cache_libclcore_dep.second, LibCLCoreSHA1,
                  SHA1_DIGEST_LENGTH) != 0) {
         ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
               LibRSPath);
         PRINT_DEPENDENCY("current - ", LibCLCorePath, LibCLCoreSHA1);
         PRINT_DEPENDENCY("cache - ", cache_libclcore_dep.first,
                                      cache_libclcore_dep.second);
         return false;
     }

 #if defined(ARCH_ARM_HAVE_NEON)
     // Check libclcore_neon.bc if NEON is available.
     if (::memcmp(cache_libclcore_neon_dep.second, LibCLCoreNEONSHA1,
                  SHA1_DIGEST_LENGTH) != 0) {
         ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
               LibRSPath);
         PRINT_DEPENDENCY("current - ", LibCLCoreNEONPath, LibCLCoreNEONSHA1);
         PRINT_DEPENDENCY("cache - ", cache_libclcore_neon_dep.first,
                                      cache_libclcore_neon_dep.second);
         return false;
     }
 #endif

     for (unsigned i = 0; i < pDeps.size(); i++) {
       const std::pair<const char *, const uint8_t *> &cache_dep =
           pInfo.mDependencyTable[i + NumBuiltInDependencies];

       if ((::strcmp(pDeps[i].first, cache_dep.first) != 0) ||
           (::memcmp(pDeps[i].second, cache_dep.second,
                     SHA1_DIGEST_LENGTH) != 0)) {
         ALOGD("Cache %s is dirty due to the source it dependends on has been "
               "changed:", pInputFilename);
         PRINT_DEPENDENCY("given - ", pDeps[i].first, pDeps[i].second);
         PRINT_DEPENDENCY("cache - ", cache_dep.first, cache_dep.second);
         return false;
       }
     }
   }

   return true;
 }

 RSInfo::RSInfo(size_t pStringPoolSize) : mStringPool(NULL) {
   ::memset(&mHeader, 0, sizeof(mHeader));

   ::memcpy(mHeader.magic, RSINFO_MAGIC, sizeof(mHeader.magic));
   ::memcpy(mHeader.version, RSINFO_VERSION, sizeof(mHeader.version));

   mHeader.headerSize = sizeof(mHeader);

   mHeader.dependencyTable.itemSize = sizeof(rsinfo::DependencyTableItem);
   mHeader.pragmaList.itemSize = sizeof(rsinfo::PragmaItem);
   mHeader.objectSlotList.itemSize = sizeof(rsinfo::ObjectSlotItem);
   mHeader.exportVarNameList.itemSize = sizeof(rsinfo::ExportVarNameItem);
   mHeader.exportFuncNameList.itemSize = sizeof(rsinfo::ExportFuncNameItem);
   mHeader.exportForeachFuncList.itemSize = sizeof(rsinfo::ExportForeachFuncItem);

   if (pStringPoolSize > 0) {
     mHeader.strPoolSize = pStringPoolSize;
     mStringPool = new (std::nothrow) char [ mHeader.strPoolSize ];
     if (mStringPool == NULL) {
       ALOGE("Out of memory when allocate memory for string pool in RSInfo "
             "constructor (size: %u)!", mHeader.strPoolSize);
     }
   }
 }

 RSInfo::~RSInfo() {
   delete [] mStringPool;
 }

 bool RSInfo::layout(off_t initial_offset) {
   mHeader.dependencyTable.offset = initial_offset +
                                    mHeader.headerSize +
                                    mHeader.strPoolSize;
   mHeader.dependencyTable.count = mDependencyTable.size();

 #define AFTER(_list) ((_list).offset + (_list).itemSize * (_list).count)
   mHeader.pragmaList.offset = AFTER(mHeader.dependencyTable);
   mHeader.pragmaList.count = mPragmas.size();

   mHeader.objectSlotList.offset = AFTER(mHeader.pragmaList);
   mHeader.objectSlotList.count = mObjectSlots.size();

   mHeader.exportVarNameList.offset = AFTER(mHeader.objectSlotList);
   mHeader.exportVarNameList.count = mExportVarNames.size();

   mHeader.exportFuncNameList.offset = AFTER(mHeader.exportVarNameList);
   mHeader.exportFuncNameList.count = mExportFuncNames.size();

   mHeader.exportForeachFuncList.offset = AFTER(mHeader.exportFuncNameList);
   mHeader.exportForeachFuncList.count = mExportForeachFuncs.size();
 #undef AFTER

   return true;
 }

 void RSInfo::dump() const {
   // Hide the codes to save the code size when debugging is disabled.
 #if !LOG_NDEBUG

   // Dump header
   ALOGV("RSInfo Header:");
   ALOGV("\tIs threadable: %s", ((mHeader.isThreadable) ? "true" : "false"));
   ALOGV("\tHeader size: %u", mHeader.headerSize);
   ALOGV("\tString pool size: %u", mHeader.strPoolSize);

 #define DUMP_LIST_HEADER(_name, _header) do { \
   ALOGV(_name ":"); \
   ALOGV("\toffset: %u", (_header).offset);  \
   ALOGV("\t# of item: %u", (_header).count);  \
   ALOGV("\tsize of each item: %u", (_header).itemSize); \
 } while (false)
   DUMP_LIST_HEADER("Dependency table", mHeader.dependencyTable);
   for (DependencyTableTy::const_iterator dep_iter = mDependencyTable.begin(),
           dep_end = mDependencyTable.end(); dep_iter != dep_end; dep_iter++) {
     PRINT_DEPENDENCY("", dep_iter->first, dep_iter->second);
   }

   DUMP_LIST_HEADER("Pragma list", mHeader.pragmaList);
   for (PragmaListTy::const_iterator pragma_iter = mPragmas.begin(),
         pragma_end = mPragmas.end(); pragma_iter != pragma_end; pragma_iter++) {
     ALOGV("\tkey: %s, value: %s", pragma_iter->first, pragma_iter->second);
   }

   DUMP_LIST_HEADER("RS object slots", mHeader.objectSlotList);
   for (ObjectSlotListTy::const_iterator slot_iter = mObjectSlots.begin(),
           slot_end = mObjectSlots.end(); slot_iter != slot_end; slot_iter++) {
     ALOGV("slot: %u", *slot_iter);
   }

   DUMP_LIST_HEADER("RS export variables", mHeader.exportVarNameList);
   for (ExportVarNameListTy::const_iterator var_iter = mExportVarNames.begin(),
           var_end = mExportVarNames.end(); var_iter != var_end; var_iter++) {
     ALOGV("name: %s", *var_iter);
   }

   DUMP_LIST_HEADER("RS export functions", mHeader.exportFuncNameList);
   for (ExportFuncNameListTy::const_iterator func_iter = mExportFuncNames.begin(),
         func_end = mExportFuncNames.end(); func_iter != func_end; func_iter++) {
     ALOGV("name: %s", *func_iter);
   }

   DUMP_LIST_HEADER("RS foreach list", mHeader.exportForeachFuncList);
   for (ExportForeachFuncListTy::const_iterator
           foreach_iter = mExportForeachFuncs.begin(),
           foreach_end = mExportForeachFuncs.end(); foreach_iter != foreach_end;
           foreach_iter++) {
     ALOGV("name: %s, signature: %05x", foreach_iter->first,
                                        foreach_iter->second);
   }
 #undef DUMP_LIST_HEADER

 #endif // LOG_NDEBUG
   return;
 }

 const char *RSInfo::getStringFromPool(rsinfo::StringIndexTy pStrIdx) const {
   // String pool uses direct indexing. Ensure that the pStrIdx is within the
   // range.
   if (pStrIdx >= mHeader.strPoolSize) {
     ALOGE("String index #%u is out of range in string pool (size: %u)!",
           pStrIdx, mHeader.strPoolSize);
     return NULL;
   }
   return &mStringPool[ pStrIdx ];
 }

 rsinfo::StringIndexTy RSInfo::getStringIdxInPool(const char *pStr) const {
   // Assume we are on the flat memory architecture (i.e., the memory space is
   // continuous.)
   if ((mStringPool + mHeader.strPoolSize) < pStr) {
     ALOGE("String %s does not in the string pool!", pStr);
     return rsinfo::gInvalidStringIndex;
   }
   return (pStr - mStringPool);
 }

 RSInfo::FloatPrecision RSInfo::getFloatPrecisionRequirement() const {
   // Check to see if we have any FP precision-related pragmas.
   std::string relaxed_pragma("rs_fp_relaxed");
   std::string imprecise_pragma("rs_fp_imprecise");
   std::string full_pragma("rs_fp_full");
   bool relaxed_pragma_seen = false;
   bool imprecise_pragma_seen = false;
   RSInfo::FloatPrecision result = FP_Full;

   for (PragmaListTy::const_iterator pragma_iter = mPragmas.begin(),
            pragma_end = mPragmas.end(); pragma_iter != pragma_end;
        pragma_iter++) {
     const char *pragma_key = pragma_iter->first;
     if (!relaxed_pragma.compare(pragma_key)) {
       if (relaxed_pragma_seen || imprecise_pragma_seen) {
         ALOGE("Multiple float precision pragmas specified!");
       }
       relaxed_pragma_seen = true;
     } else if (!imprecise_pragma.compare(pragma_key)) {
       if (relaxed_pragma_seen || imprecise_pragma_seen) {
         ALOGE("Multiple float precision pragmas specified!");
       }
       imprecise_pragma_seen = true;
     }
   }

   // Imprecise is selected over Relaxed precision.
   // In the absence of both, we stick to the default Full precision.
   if (imprecise_pragma_seen) {
     result = FP_Imprecise;
   } else if (relaxed_pragma_seen) {
     result = FP_Relaxed;
   }

   // Provide an override for precsion via adb shell setprop
   // adb shell setprop debug.rs.precision rs_fp_full
   // adb shell setprop debug.rs.precision rs_fp_relaxed
   // adb shell setprop debug.rs.precision rs_fp_imprecise
   char precision_prop_buf[PROPERTY_VALUE_MAX];
   property_get("debug.rs.precision", precision_prop_buf, "");

   if (precision_prop_buf[0]) {
     if (!relaxed_pragma.compare(precision_prop_buf)) {
       ALOGI("Switching to RS FP relaxed mode via setprop");
       result = FP_Relaxed;
     } else if (!imprecise_pragma.compare(precision_prop_buf)) {
       ALOGI("Switching to RS FP imprecise mode via setprop");
       result = FP_Imprecise;
     } else if (!full_pragma.compare(precision_prop_buf)) {
       ALOGI("Switching to RS FP full mode via setprop");
       result = FP_Full;
     }
   }

   return result;
 }
	/*
	* Copyright 2012, The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	//#define LOG_NDEBUG 0
	#include "bcc/Renderscript/RSInfo.h"

	#include <dlfcn.h>

	#include <cstring>
	#include <new>
	#include <string>

	#include "bcc/Support/FileBase.h"
	#include "bcc/Support/Log.h"

	#include <cutils/properties.h>

	using namespace bcc;

	const char RSInfo::LibBCCPath[] = "/system/lib/libbcc.so";
	const char RSInfo::LibCompilerRTPath[] = "/system/lib/libcompiler_rt.so";
	const char RSInfo::LibRSPath[] = "/system/lib/libRS.so";
	const char RSInfo::LibCLCorePath[] = "/system/lib/libclcore.bc";
	#if defined(ARCH_X86_HAVE_SSE2)
	const char RSInfo::LibCLCoreX86Path[] = "/system/lib/libclcore_x86.bc";
	#endif
	#if defined(ARCH_ARM_HAVE_NEON)
	const char RSInfo::LibCLCoreNEONPath[] = "/system/lib/libclcore_neon.bc";
	#endif

	const uint8_t *RSInfo::LibBCCSHA1 = NULL;
	const uint8_t *RSInfo::LibCompilerRTSHA1 = NULL;
	const uint8_t *RSInfo::LibRSSHA1 = NULL;
	const uint8_t *RSInfo::LibCLCoreSHA1 = NULL;
	#if defined(ARCH_ARM_HAVE_NEON)
	const uint8_t *RSInfo::LibCLCoreNEONSHA1 = NULL;
	#endif

	bool RSInfo::LoadBuiltInSHA1Information() {
	#ifdef TARGET_BUILD
	if (LibBCCSHA1 != NULL) {
	// Loaded before.
	return true;
	}

	void *h = ::dlopen("/system/lib/libbcc.sha1.so", RTLD_LAZY \| RTLD_NOW);
	if (h == NULL) {
	ALOGE("Failed to load SHA-1 information from shared library '"
	"/system/lib/libbcc.sha1.so'! (%s)", ::dlerror());
	return false;
	}

	LibBCCSHA1 = reinterpret_cast<const uint8_t *>(::dlsym(h, "libbcc_so_SHA1"));
	LibCompilerRTSHA1 =
	reinterpret_cast<const uint8_t *>(::dlsym(h, "libcompiler_rt_so_SHA1"));
	LibRSSHA1 = reinterpret_cast<const uint8_t *>(::dlsym(h, "libRS_so_SHA1"));
	LibCLCoreSHA1 =
	reinterpret_cast<const uint8_t *>(::dlsym(h, "libclcore_bc_SHA1"));
	#if defined(ARCH_ARM_HAVE_NEON)
	LibCLCoreNEONSHA1 =
	reinterpret_cast<const uint8_t *>(::dlsym(h, "libclcore_neon_bc_SHA1"));
	#endif

	return true;
	#else // TARGET_BUILD
	return false;
	#endif // TARGET_BUILD
	}

	android::String8 RSInfo::GetPath(const FileBase &pFile) {
	android::String8 result(pFile.getName().c_str());
	result.append(".info");
	return result;
	}

	#define PRINT_DEPENDENCY(PREFIX, N, X) \
	ALOGV("\t" PREFIX "Source name: %s, " \
	"SHA-1: %02x%02x%02x%02x%02x%02x%02x%02x%02x%02x" \
	"%02x%02x%02x%02x%02x%02x%02x%02x%02x%02x", \
	(N), (X)[ 0], (X)[ 1], (X)[ 2], (X)[ 3], (X)[ 4], (X)[ 5], \
	(X)[ 6], (X)[ 7], (X)[ 8], (X)[ 9], (X)[10], (X)[11], \
	(X)[12], (X)[13], (X)[14], (X)[15], (X)[16], (X)[17], \
	(X)[18], (X)[19]);

	bool RSInfo::CheckDependency(const RSInfo &pInfo,
	const char *pInputFilename,
	const DependencyTableTy &pDeps) {
	// Built-in dependencies are libbcc.so, libRS.so and libclcore.bc plus
	// libclcore_neon.bc if NEON is available on the target device.
	#if !defined(ARCH_ARM_HAVE_NEON)
	static const unsigned NumBuiltInDependencies = 4;
	#else
	static const unsigned NumBuiltInDependencies = 5;
	#endif

	LoadBuiltInSHA1Information();

	if (pInfo.mDependencyTable.size() != (pDeps.size() + NumBuiltInDependencies)) {
	ALOGD("Number of dependencies recorded mismatch (%lu v.s. %lu) in %s!",
	static_cast<unsigned long>(pInfo.mDependencyTable.size()),
	static_cast<unsigned long>(pDeps.size()), pInputFilename);
	return false;
	} else {
	// Built-in dependencies always go first.
	const std::pair<const char , const uint8_t > &cache_libbcc_dep =
	pInfo.mDependencyTable[0];
	const std::pair<const char , const uint8_t > &cache_libcompiler_rt_dep =
	pInfo.mDependencyTable[1];
	const std::pair<const char , const uint8_t > &cache_libRS_dep =
	pInfo.mDependencyTable[2];
	const std::pair<const char , const uint8_t > &cache_libclcore_dep =
	pInfo.mDependencyTable[3];
	#if defined(ARCH_ARM_HAVE_NEON)
	const std::pair<const char , const uint8_t > &cache_libclcore_neon_dep =
	pInfo.mDependencyTable[4];
	#endif

	// Check libbcc.so.
	if (::memcmp(cache_libbcc_dep.second, LibBCCSHA1, SHA1_DIGEST_LENGTH) != 0) {
	ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
	LibBCCPath);
	PRINT_DEPENDENCY("current - ", LibBCCPath, LibBCCSHA1);
	PRINT_DEPENDENCY("cache - ", cache_libbcc_dep.first,
	cache_libbcc_dep.second);
	return false;
	}

	// Check libcompiler_rt.so.
	if (::memcmp(cache_libcompiler_rt_dep.second, LibCompilerRTSHA1,
	SHA1_DIGEST_LENGTH) != 0) {
	ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
	LibCompilerRTPath);
	PRINT_DEPENDENCY("current - ", LibCompilerRTPath, LibCompilerRTSHA1);
	PRINT_DEPENDENCY("cache - ", cache_libcompiler_rt_dep.first,
	cache_libcompiler_rt_dep.second);
	return false;
	}

	// Check libRS.so.
	if (::memcmp(cache_libRS_dep.second, LibRSSHA1, SHA1_DIGEST_LENGTH) != 0) {
	ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
	LibRSPath);
	PRINT_DEPENDENCY("current - ", LibRSPath, LibRSSHA1);
	PRINT_DEPENDENCY("cache - ", cache_libRS_dep.first,
	cache_libRS_dep.second);
	return false;
	}

	// Check libclcore.bc.
	if (::memcmp(cache_libclcore_dep.second, LibCLCoreSHA1,
	SHA1_DIGEST_LENGTH) != 0) {
	ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
	LibRSPath);
	PRINT_DEPENDENCY("current - ", LibCLCorePath, LibCLCoreSHA1);
	PRINT_DEPENDENCY("cache - ", cache_libclcore_dep.first,
	cache_libclcore_dep.second);
	return false;
	}

	#if defined(ARCH_ARM_HAVE_NEON)
	// Check libclcore_neon.bc if NEON is available.
	if (::memcmp(cache_libclcore_neon_dep.second, LibCLCoreNEONSHA1,
	SHA1_DIGEST_LENGTH) != 0) {
	ALOGD("Cache %s is dirty due to %s has been updated.", pInputFilename,
	LibRSPath);
	PRINT_DEPENDENCY("current - ", LibCLCoreNEONPath, LibCLCoreNEONSHA1);
	PRINT_DEPENDENCY("cache - ", cache_libclcore_neon_dep.first,
	cache_libclcore_neon_dep.second);
	return false;
	}
	#endif

	for (unsigned i = 0; i < pDeps.size(); i++) {
	const std::pair<const char , const uint8_t > &cache_dep =
	pInfo.mDependencyTable[i + NumBuiltInDependencies];

	if ((::strcmp(pDeps[i].first, cache_dep.first) != 0) \|\|
	(::memcmp(pDeps[i].second, cache_dep.second,
	SHA1_DIGEST_LENGTH) != 0)) {
	ALOGD("Cache %s is dirty due to the source it dependends on has been "
	"changed:", pInputFilename);
	PRINT_DEPENDENCY("given - ", pDeps[i].first, pDeps[i].second);
	PRINT_DEPENDENCY("cache - ", cache_dep.first, cache_dep.second);
	return false;
	}
	}
	}

	return true;
	}

	RSInfo::RSInfo(size_t pStringPoolSize) : mStringPool(NULL) {
	::memset(&mHeader, 0, sizeof(mHeader));

	::memcpy(mHeader.magic, RSINFO_MAGIC, sizeof(mHeader.magic));
	::memcpy(mHeader.version, RSINFO_VERSION, sizeof(mHeader.version));

	mHeader.headerSize = sizeof(mHeader);

	mHeader.dependencyTable.itemSize = sizeof(rsinfo::DependencyTableItem);
	mHeader.pragmaList.itemSize = sizeof(rsinfo::PragmaItem);
	mHeader.objectSlotList.itemSize = sizeof(rsinfo::ObjectSlotItem);
	mHeader.exportVarNameList.itemSize = sizeof(rsinfo::ExportVarNameItem);
	mHeader.exportFuncNameList.itemSize = sizeof(rsinfo::ExportFuncNameItem);
	mHeader.exportForeachFuncList.itemSize = sizeof(rsinfo::ExportForeachFuncItem);

	if (pStringPoolSize > 0) {
	mHeader.strPoolSize = pStringPoolSize;
	mStringPool = new (std::nothrow) char [ mHeader.strPoolSize ];
	if (mStringPool == NULL) {
	ALOGE("Out of memory when allocate memory for string pool in RSInfo "
	"constructor (size: %u)!", mHeader.strPoolSize);
	}
	}
	}

	RSInfo::~RSInfo() {
	delete [] mStringPool;
	}

	bool RSInfo::layout(off_t initial_offset) {
	mHeader.dependencyTable.offset = initial_offset +
	mHeader.headerSize +
	mHeader.strPoolSize;
	mHeader.dependencyTable.count = mDependencyTable.size();

	#define AFTER(_list) ((_list).offset + (_list).itemSize * (_list).count)
	mHeader.pragmaList.offset = AFTER(mHeader.dependencyTable);
	mHeader.pragmaList.count = mPragmas.size();

	mHeader.objectSlotList.offset = AFTER(mHeader.pragmaList);
	mHeader.objectSlotList.count = mObjectSlots.size();

	mHeader.exportVarNameList.offset = AFTER(mHeader.objectSlotList);
	mHeader.exportVarNameList.count = mExportVarNames.size();

	mHeader.exportFuncNameList.offset = AFTER(mHeader.exportVarNameList);
	mHeader.exportFuncNameList.count = mExportFuncNames.size();

	mHeader.exportForeachFuncList.offset = AFTER(mHeader.exportFuncNameList);
	mHeader.exportForeachFuncList.count = mExportForeachFuncs.size();
	#undef AFTER

	return true;
	}

	void RSInfo::dump() const {
	// Hide the codes to save the code size when debugging is disabled.
	#if !LOG_NDEBUG

	// Dump header
	ALOGV("RSInfo Header:");
	ALOGV("\tIs threadable: %s", ((mHeader.isThreadable) ? "true" : "false"));
	ALOGV("\tHeader size: %u", mHeader.headerSize);
	ALOGV("\tString pool size: %u", mHeader.strPoolSize);

	#define DUMP_LIST_HEADER(_name, _header) do { \
	ALOGV(_name ":"); \
	ALOGV("\toffset: %u", (_header).offset); \
	ALOGV("\t# of item: %u", (_header).count); \
	ALOGV("\tsize of each item: %u", (_header).itemSize); \
	} while (false)
	DUMP_LIST_HEADER("Dependency table", mHeader.dependencyTable);
	for (DependencyTableTy::const_iterator dep_iter = mDependencyTable.begin(),
	dep_end = mDependencyTable.end(); dep_iter != dep_end; dep_iter++) {
	PRINT_DEPENDENCY("", dep_iter->first, dep_iter->second);
	}

	DUMP_LIST_HEADER("Pragma list", mHeader.pragmaList);
	for (PragmaListTy::const_iterator pragma_iter = mPragmas.begin(),
	pragma_end = mPragmas.end(); pragma_iter != pragma_end; pragma_iter++) {
	ALOGV("\tkey: %s, value: %s", pragma_iter->first, pragma_iter->second);
	}

	DUMP_LIST_HEADER("RS object slots", mHeader.objectSlotList);
	for (ObjectSlotListTy::const_iterator slot_iter = mObjectSlots.begin(),
	slot_end = mObjectSlots.end(); slot_iter != slot_end; slot_iter++) {
	ALOGV("slot: %u", *slot_iter);
	}

	DUMP_LIST_HEADER("RS export variables", mHeader.exportVarNameList);
	for (ExportVarNameListTy::const_iterator var_iter = mExportVarNames.begin(),
	var_end = mExportVarNames.end(); var_iter != var_end; var_iter++) {
	ALOGV("name: %s", *var_iter);
	}

	DUMP_LIST_HEADER("RS export functions", mHeader.exportFuncNameList);
	for (ExportFuncNameListTy::const_iterator func_iter = mExportFuncNames.begin(),
	func_end = mExportFuncNames.end(); func_iter != func_end; func_iter++) {
	ALOGV("name: %s", *func_iter);
	}

	DUMP_LIST_HEADER("RS foreach list", mHeader.exportForeachFuncList);
	for (ExportForeachFuncListTy::const_iterator
	foreach_iter = mExportForeachFuncs.begin(),
	foreach_end = mExportForeachFuncs.end(); foreach_iter != foreach_end;
	foreach_iter++) {
	ALOGV("name: %s, signature: %05x", foreach_iter->first,
	foreach_iter->second);
	}
	#undef DUMP_LIST_HEADER

	#endif // LOG_NDEBUG
	return;
	}

	const char *RSInfo::getStringFromPool(rsinfo::StringIndexTy pStrIdx) const {
	// String pool uses direct indexing. Ensure that the pStrIdx is within the
	// range.
	if (pStrIdx >= mHeader.strPoolSize) {
	ALOGE("String index #%u is out of range in string pool (size: %u)!",
	pStrIdx, mHeader.strPoolSize);
	return NULL;
	}
	return &mStringPool[ pStrIdx ];
	}

	rsinfo::StringIndexTy RSInfo::getStringIdxInPool(const char *pStr) const {
	// Assume we are on the flat memory architecture (i.e., the memory space is
	// continuous.)
	if ((mStringPool + mHeader.strPoolSize) < pStr) {
	ALOGE("String %s does not in the string pool!", pStr);
	return rsinfo::gInvalidStringIndex;
	}
	return (pStr - mStringPool);
	}

	RSInfo::FloatPrecision RSInfo::getFloatPrecisionRequirement() const {
	// Check to see if we have any FP precision-related pragmas.
	std::string relaxed_pragma("rs_fp_relaxed");
	std::string imprecise_pragma("rs_fp_imprecise");
	std::string full_pragma("rs_fp_full");
	bool relaxed_pragma_seen = false;
	bool imprecise_pragma_seen = false;
	RSInfo::FloatPrecision result = FP_Full;

	for (PragmaListTy::const_iterator pragma_iter = mPragmas.begin(),
	pragma_end = mPragmas.end(); pragma_iter != pragma_end;
	pragma_iter++) {
	const char *pragma_key = pragma_iter->first;
	if (!relaxed_pragma.compare(pragma_key)) {
	if (relaxed_pragma_seen \|\| imprecise_pragma_seen) {
	ALOGE("Multiple float precision pragmas specified!");
	}
	relaxed_pragma_seen = true;
	} else if (!imprecise_pragma.compare(pragma_key)) {
	if (relaxed_pragma_seen \|\| imprecise_pragma_seen) {
	ALOGE("Multiple float precision pragmas specified!");
	}
	imprecise_pragma_seen = true;
	}
	}

	// Imprecise is selected over Relaxed precision.
	// In the absence of both, we stick to the default Full precision.
	if (imprecise_pragma_seen) {
	result = FP_Imprecise;
	} else if (relaxed_pragma_seen) {
	result = FP_Relaxed;
	}

	// Provide an override for precsion via adb shell setprop
	// adb shell setprop debug.rs.precision rs_fp_full
	// adb shell setprop debug.rs.precision rs_fp_relaxed
	// adb shell setprop debug.rs.precision rs_fp_imprecise
	char precision_prop_buf[PROPERTY_VALUE_MAX];
	property_get("debug.rs.precision", precision_prop_buf, "");

	if (precision_prop_buf[0]) {
	if (!relaxed_pragma.compare(precision_prop_buf)) {
	ALOGI("Switching to RS FP relaxed mode via setprop");
	result = FP_Relaxed;
	} else if (!imprecise_pragma.compare(precision_prop_buf)) {
	ALOGI("Switching to RS FP imprecise mode via setprop");
	result = FP_Imprecise;
	} else if (!full_pragma.compare(precision_prop_buf)) {
	ALOGI("Switching to RS FP full mode via setprop");
	result = FP_Full;
	}
	}

	return result;
	}