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mem_mgr.hpp

mem_mgr.hpp 7.2 KB
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  1. /**
    2. 

  2.  * \file mem_mgr.hpp
    3. 

  3.  * \author Dhairya Malhotra, dhairya.malhotra@gmail.com
    4. 

  4.  * \date 6-30-2014
    5. 

  5.  * \brief This file contains the definition of a simple memory manager which
    6. 

  6.  * uses a pre-allocated buffer of size defined in call to the constructor.
    7. 

  7.  */
    8. 

  8. 

  9. #ifndef _PVFMM_MEM_MGR_HPP_
    10. 

  10. #define _PVFMM_MEM_MGR_HPP_
    11. 

  11. 

  12. #include <map>
    13. 

  13. #include <stack>
    14. 

  14. #include <vector>
    15. 

  15. #include <cassert>
    16. 

  16. #include <iostream>
    17. 

  17. #include <cmath>
    18. 

  18. #include <omp.h>
    19. 

  19. #include <pvfmm_common.hpp>
    20. 

  20. #include <mem_utils.hpp>
    21. 

  21. 

  22. namespace pvfmm{
    23. 

  23. namespace mem{
    24. 

  24. 

  25. class MemoryManager{
    26. 

  26. 

  27.   public:
    28. 

  28. 

  29.     MemoryManager(size_t N){
    30. 

  30.       buff_size=N;
    31. 

  31.       buff=(char*)::malloc(buff_size); assert(buff);
    32. 

  32.       n_dummy_indx=new_node();
    33. 

  33.       size_t n_indx=new_node();
    34. 

  34.       node& n_dummy=node_buff[n_dummy_indx-1];
    35. 

  35.       node& n=node_buff[n_indx-1];
    36. 

  36. 

  37.       n_dummy.size=0;
    38. 

  38.       n_dummy.free=false;
    39. 

  39.       n_dummy.prev=0;
    40. 

  40.       n_dummy.next=n_indx;
    41. 

  41.       n_dummy.mem_ptr=&buff[0];
    42. 

  42.       assert(n_indx);
    43. 

  43. 

  44.       n.size=N;
    45. 

  45.       n.free=true;
    46. 

  46.       n.prev=n_dummy_indx;
    47. 

  47.       n.next=0;
    48. 

  48.       n.mem_ptr=&buff[0];
    49. 

  49.       n.it=free_map.insert(std::make_pair(N,n_indx));
    50. 

  50. 

  51.       omp_init_lock(&omp_lock);
    52. 

  52.     }
    53. 

  53. 

  54.     ~MemoryManager(){
    55. 

  55.       node* n=&node_buff[n_dummy_indx-1];
    56. 

  56.       n=&node_buff[n->next-1];
    57. 

  57.       if(n==NULL || !n->free || n->size!=buff_size ||
    58. 

  58.           node_stack.size()!=node_buff.size()-2){
    59. 

  59.         std::cout<<"\nWarning: memory leak detected.\n";
    60. 

  60.       }
    61. 

  61. 

  62.       omp_destroy_lock(&omp_lock);
    63. 

  63.       if(buff) ::free(buff);
    64. 

  64.     }
    65. 

  65. 

  66.     void* malloc(size_t size){
    67. 

  67.       size_t alignment=MEM_ALIGN;
    68. 

  68.       assert(alignment <= 0x8000);
    69. 

  69.       if(!size) return NULL;
    70. 

  70.       size+=sizeof(size_t) + --alignment + 2;
    71. 

  71.       std::multimap<size_t, size_t>::iterator it;
    72. 

  72.       uintptr_t r=0;
    73. 

  73. 

  74.       omp_set_lock(&omp_lock);
    75. 

  75.       it=free_map.lower_bound(size);
    76. 

  76.       if(it==free_map.end()){ // Use system malloc
    77. 

  77.         r = (uintptr_t)::malloc(size);
    78. 

  78.       }else if(it->first==size){ // Found exact size block
    79. 

  79.         size_t n_indx=it->second;
    80. 

  80.         node& n=node_buff[n_indx-1];
    81. 

  81.         //assert(n.size==it->first);
    82. 

  82.         //assert(n.it==it);
    83. 

  83.         //assert(n.free);
    84. 

  84. 

  85.         n.free=false;
    86. 

  86.         free_map.erase(it);
    87. 

  87.         ((size_t*)n.mem_ptr)[0]=n_indx;
    88. 

  88.         r = (uintptr_t)&((size_t*)n.mem_ptr)[1];
    89. 

  89.       }else{ // Found larger block.
    90. 

  90.         size_t n_indx=it->second;
    91. 

  91.         size_t n_free_indx=new_node();
    92. 

  92.         node& n_free=node_buff[n_free_indx-1];
    93. 

  93.         node& n     =node_buff[n_indx-1];
    94. 

  94.         //assert(n.size==it->first);
    95. 

  95.         //assert(n.it==it);
    96. 

  96.         //assert(n.free);
    97. 

  97. 

  98.         n_free=n;
    99. 

  99.         n_free.size-=size;
    100. 

  100.         n_free.mem_ptr=(char*)n_free.mem_ptr+size;
    101. 

  101.         n_free.prev=n_indx;
    102. 

  102.         if(n_free.next){
    103. 

  103.           size_t n_next_indx=n_free.next;
    104. 

  104.           node& n_next=node_buff[n_next_indx-1];
    105. 

  105.           n_next.prev=n_free_indx;
    106. 

  106.         }
    107. 

  107. 

  108.         n.free=false;
    109. 

  109.         n.size=size;
    110. 

  110.         n.next=n_free_indx;
    111. 

  111. 

  112.         free_map.erase(it);
    113. 

  113.         n_free.it=free_map.insert(std::make_pair(n_free.size,n_free_indx));
    114. 

  114.         ((size_t*)n.mem_ptr)[0]=n_indx;
    115. 

  115.         r = (uintptr_t) &((size_t*)n.mem_ptr)[1];
    116. 

  116.       }
    117. 

  117.       omp_unset_lock(&omp_lock);
    118. 

  118. 

  119.       uintptr_t o = (uintptr_t)(r + 2 + alignment) & ~(uintptr_t)alignment;
    120. 

  120.       ((uint16_t*)o)[-1] = (uint16_t)(o-r);
    121. 

  121.       return (void*)o;
    122. 

  122.     }
    123. 

  123. 

  124.     void free(void* p_){
    125. 

  125.       if(!p_) return;
    126. 

  126.       void* p=((void*)((uintptr_t)p_-((uint16_t*)p_)[-1]));
    127. 

  127.       if(p<&buff[0] || p>=&buff[buff_size]) return ::free(p);
    128. 

  128. 

  129.       size_t n_indx=((size_t*)p)[-1];
    130. 

  130.       assert(n_indx>0 && n_indx<=node_buff.size());
    131. 

  131.       ((size_t*)p)[-1]=0;
    132. 

  132. 

  133.       omp_set_lock(&omp_lock);
    134. 

  134.       node& n=node_buff[n_indx-1];
    135. 

  135.       assert(!n.free && n.size>0 && n.mem_ptr==&((size_t*)p)[-1]);
    136. 

  136.       n.free=true;
    137. 

  137. 

  138.       if(n.prev!=0 && node_buff[n.prev-1].free){
    139. 

  139.         size_t n_prev_indx=n.prev;
    140. 

  140.         node& n_prev=node_buff[n_prev_indx-1];
    141. 

  141.         free_map.erase(n_prev.it);
    142. 

  142.         n.size+=n_prev.size;
    143. 

  143.         n.mem_ptr=n_prev.mem_ptr;
    144. 

  144.         n.prev=n_prev.prev;
    145. 

  145.         delete_node(n_prev_indx);
    146. 

  146. 

  147.         if(n.prev){
    148. 

  148.           size_t n_prev_indx=n.prev;
    149. 

  149.           node& n_prev=node_buff[n_prev_indx-1];
    150. 

  150.           n_prev.next=n_indx;
    151. 

  151.         }
    152. 

  152.       }
    153. 

  153.       if(n.next!=0 && node_buff[n.next-1].free){
    154. 

  154.         size_t n_next_indx=n.next;
    155. 

  155.         node& n_next=node_buff[n_next_indx-1];
    156. 

  156.         free_map.erase(n_next.it);
    157. 

  157.         n.size+=n_next.size;
    158. 

  158.         n.next=n_next.next;
    159. 

  159.         delete_node(n_next_indx);
    160. 

  160. 

  161.         if(n.next){
    162. 

  162.           size_t n_next_indx=n.next;
    163. 

  163.           node& n_next=node_buff[n_next_indx-1];
    164. 

  164.           n_next.prev=n_indx;
    165. 

  165.         }
    166. 

  166.       }
    167. 

  167.       n.it=free_map.insert(std::make_pair(n.size,n_indx));
    168. 

  168.       omp_unset_lock(&omp_lock);
    169. 

  169.     }
    170. 

  170. 

  171.     void print(){
    172. 

  172.       if(!buff_size) return;
    173. 

  173.       omp_set_lock(&omp_lock);
    174. 

  174. 

  175.       size_t size=0;
    176. 

  176.       size_t largest_size=0;
    177. 

  177.       node* n=&node_buff[n_dummy_indx-1];
    178. 

  178.       std::cout<<"\n|";
    179. 

  179.       while(n->next){
    180. 

  180.         n=&node_buff[n->next-1];
    181. 

  181.         if(n->free){
    182. 

  182.           std::cout<<' ';
    183. 

  183.           largest_size=std::max(largest_size,n->size);
    184. 

  184.         }
    185. 

  185.         else{
    186. 

  186.           std::cout<<'#';
    187. 

  187.           size+=n->size;
    188. 

  188.         }
    189. 

  189.       }
    190. 

  190.       std::cout<<"|  allocated="<<round(size*1000.0/buff_size)/10<<"%";
    191. 

  191.       std::cout<<"  largest_free="<<round(largest_size*1000.0/buff_size)/10<<"%\n";
    192. 

  192. 

  193.       omp_unset_lock(&omp_lock);
    194. 

  194.     }
    195. 

  195. 

  196.     static void test(){
    197. 

  197.       size_t M=2000000000;
    198. 

  198.       { // With memory manager
    199. 

  199.         size_t N=M*sizeof(double)*1.1;
    200. 

  200.         double tt;
    201. 

  201.         double* tmp;
    202. 

  202. 

  203.         std::cout<<"With memory manager: ";
    204. 

  204.         MemoryManager memgr(N);
    205. 

  205. 

  206.         for(size_t j=0;j<3;j++){
    207. 

  207.           tmp=(double*)memgr.malloc(M*sizeof(double)); assert(tmp);
    208. 

  208.           tt=omp_get_wtime();
    209. 

  209.           #pragma omp parallel for
    210. 

  210.           for(size_t i=0;i<M;i+=64) tmp[i]=i;
    211. 

  211.           tt=omp_get_wtime()-tt;
    212. 

  212.           std::cout<<tt<<' ';
    213. 

  213.           memgr.free(tmp);
    214. 

  214.         }
    215. 

  215.         std::cout<<'\n';
    216. 

  216.       }
    217. 

  217.       { // Without memory manager
    218. 

  218.         double tt;
    219. 

  219.         double* tmp;
    220. 

  220. 

  221.         //pvfmm::MemoryManager memgr(N);
    222. 

  222. 

  223.         std::cout<<"Without memory manager: ";
    224. 

  224.         for(size_t j=0;j<3;j++){
    225. 

  225.           tmp=(double*)::malloc(M*sizeof(double)); assert(tmp);
    226. 

  226.           tt=omp_get_wtime();
    227. 

  227.           #pragma omp parallel for
    228. 

  228.           for(size_t i=0;i<M;i+=64) tmp[i]=i;
    229. 

  229.           tt=omp_get_wtime()-tt;
    230. 

  230.           std::cout<<tt<<' ';
    231. 

  231.           ::free(tmp);
    232. 

  232.         }
    233. 

  233.         std::cout<<'\n';
    234. 

  234.       }
    235. 

  235.     }
    236. 

  236. 

  237.   private:
    238. 

  238. 

  239.     struct node{
    240. 

  240.       bool free;
    241. 

  241.       size_t size;
    242. 

  242.       void* mem_ptr;
    243. 

  243.       size_t prev, next;
    244. 

  244.       std::multimap<size_t, size_t>::iterator it;
    245. 

  245.     };
    246. 

  246. 

  247.     MemoryManager();
    248. 

  248. 

  249.     MemoryManager(const MemoryManager& m);
    250. 

  250. 

  251.     size_t new_node(){
    252. 

  252.       if(node_stack.empty()){
    253. 

  253.         node_buff.resize(node_buff.size()+1);
    254. 

  254.         node_stack.push(node_buff.size());
    255. 

  255.       }
    256. 

  256. 

  257.       size_t indx=node_stack.top();
    258. 

  258.       node_stack.pop();
    259. 

  259.       assert(indx);
    260. 

  260.       return indx;
    261. 

  261.     }
    262. 

  262. 

  263.     void delete_node(size_t indx){
    264. 

  264.       assert(indx);
    265. 

  265.       assert(indx<=node_buff.size());
    266. 

  266.       node& n=node_buff[indx-1];
    267. 

  267.       n.size=0;
    268. 

  268.       n.prev=0;
    269. 

  269.       n.next=0;
    270. 

  270.       n.mem_ptr=NULL;
    271. 

  271.       node_stack.push(indx);
    272. 

  272.     }
    273. 

  273. 

  274.     char* buff;
    275. 

  275.     size_t buff_size;
    276. 

  276.     std::vector<node> node_buff;
    277. 

  277.     std::stack<size_t> node_stack;
    278. 

  278.     std::multimap<size_t, size_t> free_map;
    279. 

  279.     size_t n_dummy_indx;
    280. 

  280. 

  281.     omp_lock_t omp_lock;
    282. 

  282. };
    283. 

  283. 

  284. }//end namespace
    285. 

  285. }//end namespace
    286. 

  286. 

  287. #endif //_PVFMM_MEM_MGR_HPP_
    288.