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00035 #include <rosrt/malloc_wrappers.h>
00036
00037 #include <ros/assert.h>
00038 #include <ros/atomic.h>
00039
00040 #include <boost/thread.hpp>
00041
00042 #include <iostream>
00043 #include <dlfcn.h>
00044
00045 #if defined(WIN32)
00046 #define STATIC_TLS_KW __declspec(thread)
00047 #define HAS_TLS_KW 1
00048 #elif defined(__APPLE__)
00049 #define HAS_TLS_KW 0
00050 #else
00051 #define STATIC_TLS_KW __thread
00052 #define HAS_TLS_KW 1
00053 #endif
00054
00055 #if !HAS_TLS_KW
00056 #include <pthread.h>
00057 #define MAX_ALLOC_INFO 1000
00058 #endif
00059
00060 namespace rosrt
00061 {
00062 namespace detail
00063 {
00064
00065 #if HAS_TLS_KW
00066 STATIC_TLS_KW uint64_t g_mallocs = 0;
00067 STATIC_TLS_KW uint64_t g_reallocs = 0;
00068 STATIC_TLS_KW uint64_t g_callocs = 0;
00069 STATIC_TLS_KW uint64_t g_memaligns = 0;
00070 STATIC_TLS_KW uint64_t g_frees = 0;
00071 STATIC_TLS_KW uint64_t g_total_ops = 0;
00072 STATIC_TLS_KW uint64_t g_total_memory_allocated = 0;
00073 STATIC_TLS_KW bool g_break_on_alloc_or_free = false;
00074 #else // HAS_TLS_KW
00075
00076 pthread_key_t g_tls_key;
00077 bool g_tls_key_initialized = false;
00078
00079 AllocInfo g_thread_alloc_info[MAX_ALLOC_INFO];
00080 ros::atomic_bool g_alloc_info_used[MAX_ALLOC_INFO];
00081
00082 void tlsDestructor(void* mem)
00083 {
00084 AllocInfo* info = reinterpret_cast<AllocInfo*>(mem);
00085 uint32_t index = info - g_thread_alloc_info;
00086 ROS_ASSERT(index < MAX_ALLOC_INFO);
00087 g_alloc_info_used[index].store(false);
00088 }
00089
00090 struct MallocTLSInit
00091 {
00092 MallocTLSInit()
00093 {
00094 int ret = pthread_key_create(&g_tls_key, tlsDestructor);
00095 ROS_ASSERT_MSG(!ret, "Failed to create TLS");
00096
00097 for (size_t i = 0; i < MAX_ALLOC_INFO; ++i)
00098 {
00099 g_alloc_info_used[i].store(false);
00100 }
00101
00102 g_tls_key_initialized = true;
00103 }
00104
00105 ~MallocTLSInit()
00106 {
00107 g_tls_key_initialized = false;
00108
00109 pthread_key_delete(g_tls_key);
00110 }
00111 };
00112 MallocTLSInit g_malloc_tls_init;
00113
00114 AllocInfo* allocateAllocInfo()
00115 {
00116 if (!g_tls_key_initialized)
00117 {
00118 return 0;
00119 }
00120
00121 void* info = pthread_getspecific(g_tls_key);
00122 if (!info)
00123 {
00124 for (size_t i = 0; i < MAX_ALLOC_INFO; ++i)
00125 {
00126 if (g_alloc_info_used[i].exchange(true) == false)
00127 {
00128 info = g_thread_alloc_info + i;
00129 pthread_setspecific(g_tls_key, info);
00130 break;
00131 }
00132 }
00133 }
00134
00135 return reinterpret_cast<AllocInfo*>(info);
00136 }
00137
00138 #endif // !HAS_TLS_KW
00139
00140 }
00141
00142 AllocInfo getThreadAllocInfo()
00143 {
00144 AllocInfo info;
00145
00146 #if HAS_TLS_KW
00147 info.mallocs = detail::g_mallocs;
00148 info.callocs = detail::g_callocs;
00149 info.reallocs = detail::g_reallocs;
00150 info.memaligns = detail::g_memaligns;
00151 info.frees = detail::g_frees;
00152 info.total_ops = detail::g_total_ops;
00153 info.total_memory_allocated = detail::g_total_memory_allocated;
00154 info.break_on_alloc_or_free = detail::g_break_on_alloc_or_free;
00155 #else
00156 AllocInfo* tls = detail::allocateAllocInfo();
00157 if (tls)
00158 {
00159 info = *tls;
00160 }
00161 #endif
00162 return info;
00163 }
00164
00165 void resetThreadAllocInfo()
00166 {
00167 #if HAS_TLS_KW
00168 detail::g_mallocs = 0;
00169 detail::g_reallocs = 0;
00170 detail::g_callocs = 0;
00171 detail::g_memaligns = 0;
00172 detail::g_frees = 0;
00173 detail::g_total_ops = 0;
00174 detail::g_total_memory_allocated = 0;
00175 #else
00176 AllocInfo* info = detail::allocateAllocInfo();
00177 if (info)
00178 {
00179 *info = AllocInfo();
00180 }
00181 #endif
00182 }
00183
00184 void setThreadBreakOnAllocOrFree(bool b)
00185 {
00186 #if HAS_TLS_KW
00187 detail::g_break_on_alloc_or_free = b;
00188 #else
00189 AllocInfo* info = detail::allocateAllocInfo();
00190 if (info)
00191 {
00192 info->break_on_alloc_or_free = b;
00193 }
00194 #endif
00195 }
00196
00197 }
00198
00199 extern "C"
00200 {
00201
00202 typedef void* (*MallocType)(size_t size);
00203 typedef void* (*CallocType)(size_t nmemb, size_t size);
00204 typedef void* (*ReallocType)(void *ptr, size_t size);
00205 typedef void* (*MemalignType)(size_t boundary, size_t size);
00206 typedef int (*PosixMemalignType)(void **memptr, size_t alignment, size_t size);
00207 typedef void (*FreeType)(void* ptr);
00208
00209 #if HAS_TLS_KW
00210 #define UPDATE_ALLOC_INFO(result, size, type) \
00211 if (result) \
00212 { \
00213 rosrt::detail::g_total_memory_allocated += size; \
00214 } \
00215 \
00216 ++rosrt::detail::g_##type; \
00217 ++rosrt::detail::g_total_ops; \
00218 \
00219 if (rosrt::detail::g_break_on_alloc_or_free) \
00220 { \
00221 std::cerr << "Issuing break due to break_on_alloc_or_free being set" << std::endl; \
00222 ROS_ISSUE_BREAK(); \
00223 }
00224 #else
00225 #define UPDATE_ALLOC_INFO(result, size, type) \
00226 rosrt::AllocInfo* tls = rosrt::detail::allocateAllocInfo(); \
00227 if (tls) \
00228 { \
00229 if (result) \
00230 { \
00231 tls->total_memory_allocated += size; \
00232 } \
00233 \
00234 ++tls->type; \
00235 ++tls->total_ops; \
00236 \
00237 if (tls->break_on_alloc_or_free) \
00238 { \
00239 std::cerr << "Issuing break due to break_on_alloc_or_free being set" << std::endl; \
00240 ROS_ISSUE_BREAK(); \
00241 } \
00242 }
00243 #endif
00244
00245 void* malloc(size_t size)
00246 {
00247 static MallocType original_function = reinterpret_cast<MallocType>(dlsym(RTLD_NEXT, "malloc"));
00248
00249 void* result = original_function(size);
00250
00251 UPDATE_ALLOC_INFO(result, size, mallocs);
00252
00253 return result;
00254 }
00255
00256 void* __libc_malloc(size_t size)
00257 {
00258 return malloc(size);
00259 }
00260
00261 void* realloc(void* ptr, size_t size)
00262 {
00263 static ReallocType original_function = reinterpret_cast<ReallocType>(dlsym(RTLD_NEXT, "realloc"));
00264
00265 void* result = original_function(ptr, size);
00266
00267 UPDATE_ALLOC_INFO(result, size, reallocs);
00268
00269 return result;
00270 }
00271
00272 void* __libc_realloc(void* ptr, size_t size)
00273 {
00274 return realloc(ptr, size);
00275 }
00276
00277 void* memalign(size_t boundary, size_t size)
00278 {
00279 static MemalignType original_function = reinterpret_cast<MemalignType>(dlsym(RTLD_NEXT, "memalign"));
00280
00281 void* result = original_function(boundary, size);
00282
00283 UPDATE_ALLOC_INFO(result, size, memaligns);
00284
00285 return result;
00286 }
00287
00288 void* __libc_memalign(size_t boundary, size_t size)
00289 {
00290 return memalign(boundary, size);
00291 }
00292
00293 void free(void *ptr)
00294 {
00295 static FreeType original_function = reinterpret_cast<FreeType>(dlsym(RTLD_NEXT, "free"));
00296
00297 original_function(ptr);
00298
00299 uint32_t size = 0;
00300 void* result = 0;
00301 UPDATE_ALLOC_INFO(result, size, frees);
00302 }
00303
00304 void __libc_free(void* ptr)
00305 {
00306 return free(ptr);
00307 }
00308
00309
00310 static void* nullCalloc(size_t nmemb, size_t size)
00311 {
00312 return 0;
00313 }
00314
00315 void* calloc(size_t nmemb, size_t size)
00316 {
00317 static CallocType original_function = 0;
00318 if (original_function == 0)
00319 {
00320 original_function = nullCalloc;
00321 original_function = reinterpret_cast<CallocType>(dlsym(RTLD_NEXT, "calloc"));
00322 }
00323
00324 void* result = original_function(nmemb, size);
00325
00326 UPDATE_ALLOC_INFO(result, size * nmemb, callocs);
00327
00328 return result;
00329 }
00330
00331 void* __libc_calloc(size_t nmemb, size_t size)
00332 {
00333 return calloc(nmemb, size);
00334 }
00335
00336 int posix_memalign(void** ptr, size_t alignment, size_t size) {
00337 static PosixMemalignType original_function = reinterpret_cast<PosixMemalignType>(dlsym(RTLD_NEXT, "posix_memalign"));
00338
00339 int result = original_function(ptr, alignment, size);
00340
00341 UPDATE_ALLOC_INFO(!result, size, memaligns);
00342
00343 return result;
00344 }
00345
00346
00347 }
00348
00349