1 1.7 riastrad /* $NetBSD: sljitExecAllocator.c,v 1.7 2020/09/05 16:30:11 riastradh Exp $ */ 2 1.4 alnsn 3 1.1 alnsn /* 4 1.1 alnsn * Stack-less Just-In-Time compiler 5 1.1 alnsn * 6 1.6 alnsn * Copyright Zoltan Herczeg (hzmester (at) freemail.hu). All rights reserved. 7 1.1 alnsn * 8 1.1 alnsn * Redistribution and use in source and binary forms, with or without modification, are 9 1.1 alnsn * permitted provided that the following conditions are met: 10 1.1 alnsn * 11 1.1 alnsn * 1. Redistributions of source code must retain the above copyright notice, this list of 12 1.1 alnsn * conditions and the following disclaimer. 13 1.1 alnsn * 14 1.1 alnsn * 2. Redistributions in binary form must reproduce the above copyright notice, this list 15 1.1 alnsn * of conditions and the following disclaimer in the documentation and/or other materials 16 1.1 alnsn * provided with the distribution. 17 1.1 alnsn * 18 1.1 alnsn * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDER(S) AND CONTRIBUTORS ``AS IS'' AND ANY 19 1.1 alnsn * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 20 1.1 alnsn * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT 21 1.1 alnsn * SHALL THE COPYRIGHT HOLDER(S) OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, 22 1.1 alnsn * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED 23 1.1 alnsn * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR 24 1.1 alnsn * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 25 1.1 alnsn * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN 26 1.1 alnsn * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 27 1.1 alnsn */ 28 1.1 alnsn 29 1.1 alnsn /* 30 1.1 alnsn This file contains a simple executable memory allocator 31 1.1 alnsn 32 1.1 alnsn It is assumed, that executable code blocks are usually medium (or sometimes 33 1.1 alnsn large) memory blocks, and the allocator is not too frequently called (less 34 1.1 alnsn optimized than other allocators). Thus, using it as a generic allocator is 35 1.1 alnsn not suggested. 36 1.1 alnsn 37 1.1 alnsn How does it work: 38 1.1 alnsn Memory is allocated in continuous memory areas called chunks by alloc_chunk() 39 1.1 alnsn Chunk format: 40 1.1 alnsn [ block ][ block ] ... [ block ][ block terminator ] 41 1.1 alnsn 42 1.1 alnsn All blocks and the block terminator is started with block_header. The block 43 1.1 alnsn header contains the size of the previous and the next block. These sizes 44 1.1 alnsn can also contain special values. 45 1.1 alnsn Block size: 46 1.1 alnsn 0 - The block is a free_block, with a different size member. 47 1.1 alnsn 1 - The block is a block terminator. 48 1.1 alnsn n - The block is used at the moment, and the value contains its size. 49 1.1 alnsn Previous block size: 50 1.1 alnsn 0 - This is the first block of the memory chunk. 51 1.1 alnsn n - The size of the previous block. 52 1.1 alnsn 53 1.1 alnsn Using these size values we can go forward or backward on the block chain. 54 1.1 alnsn The unused blocks are stored in a chain list pointed by free_blocks. This 55 1.1 alnsn list is useful if we need to find a suitable memory area when the allocator 56 1.1 alnsn is called. 57 1.3 alnsn 58 1.1 alnsn When a block is freed, the new free block is connected to its adjacent free 59 1.1 alnsn blocks if possible. 60 1.1 alnsn 61 1.1 alnsn [ free block ][ used block ][ free block ] 62 1.1 alnsn and "used block" is freed, the three blocks are connected together: 63 1.1 alnsn [ one big free block ] 64 1.1 alnsn */ 65 1.1 alnsn 66 1.1 alnsn /* --------------------------------------------------------------------- */ 67 1.1 alnsn /* System (OS) functions */ 68 1.1 alnsn /* --------------------------------------------------------------------- */ 69 1.1 alnsn 70 1.1 alnsn /* 64 KByte. */ 71 1.1 alnsn #define CHUNK_SIZE 0x10000 72 1.1 alnsn 73 1.1 alnsn /* 74 1.1 alnsn alloc_chunk / free_chunk : 75 1.1 alnsn * allocate executable system memory chunks 76 1.1 alnsn * the size is always divisible by CHUNK_SIZE 77 1.1 alnsn allocator_grab_lock / allocator_release_lock : 78 1.1 alnsn * make the allocator thread safe 79 1.1 alnsn * can be empty if the OS (or the application) does not support threading 80 1.1 alnsn * only the allocator requires this lock, sljit is fully thread safe 81 1.1 alnsn as it only uses local variables 82 1.1 alnsn */ 83 1.1 alnsn 84 1.1 alnsn #ifdef _WIN32 85 1.1 alnsn 86 1.1 alnsn static SLJIT_INLINE void* alloc_chunk(sljit_uw size) 87 1.1 alnsn { 88 1.3 alnsn return VirtualAlloc(NULL, size, MEM_COMMIT | MEM_RESERVE, PAGE_EXECUTE_READWRITE); 89 1.1 alnsn } 90 1.1 alnsn 91 1.6 alnsn static SLJIT_INLINE void free_chunk(void *chunk, sljit_uw size) 92 1.1 alnsn { 93 1.1 alnsn SLJIT_UNUSED_ARG(size); 94 1.1 alnsn VirtualFree(chunk, 0, MEM_RELEASE); 95 1.1 alnsn } 96 1.1 alnsn 97 1.1 alnsn #else 98 1.1 alnsn 99 1.2 alnsn #ifdef _KERNEL 100 1.2 alnsn #include <sys/param.h> 101 1.2 alnsn #include <sys/module.h> /* for module_map */ 102 1.7 riastrad #include <uvm/uvm_extern.h> 103 1.2 alnsn #else 104 1.1 alnsn #include <sys/mman.h> 105 1.2 alnsn #endif 106 1.1 alnsn 107 1.1 alnsn static SLJIT_INLINE void* alloc_chunk(sljit_uw size) 108 1.1 alnsn { 109 1.2 alnsn #ifdef _KERNEL 110 1.2 alnsn return (void *)uvm_km_alloc(module_map, size, 111 1.2 alnsn PAGE_SIZE, UVM_KMF_WIRED | UVM_KMF_ZERO | UVM_KMF_EXEC); 112 1.2 alnsn #else 113 1.6 alnsn void *retval; 114 1.6 alnsn 115 1.6 alnsn #ifdef MAP_ANON 116 1.6 alnsn retval = mmap(NULL, size, PROT_READ | PROT_WRITE | PROT_EXEC, MAP_PRIVATE | MAP_ANON, -1, 0); 117 1.6 alnsn #else 118 1.6 alnsn if (dev_zero < 0) { 119 1.6 alnsn if (open_dev_zero()) 120 1.6 alnsn return NULL; 121 1.6 alnsn } 122 1.6 alnsn retval = mmap(NULL, size, PROT_READ | PROT_WRITE | PROT_EXEC, MAP_PRIVATE, dev_zero, 0); 123 1.6 alnsn #endif 124 1.6 alnsn 125 1.1 alnsn return (retval != MAP_FAILED) ? retval : NULL; 126 1.2 alnsn #endif 127 1.1 alnsn } 128 1.1 alnsn 129 1.6 alnsn static SLJIT_INLINE void free_chunk(void *chunk, sljit_uw size) 130 1.1 alnsn { 131 1.2 alnsn #ifdef _KERNEL 132 1.2 alnsn uvm_km_free(module_map, (vaddr_t)chunk, size, UVM_KMF_WIRED); 133 1.2 alnsn #else 134 1.1 alnsn munmap(chunk, size); 135 1.2 alnsn #endif 136 1.1 alnsn } 137 1.1 alnsn 138 1.1 alnsn #endif 139 1.1 alnsn 140 1.1 alnsn /* --------------------------------------------------------------------- */ 141 1.1 alnsn /* Common functions */ 142 1.1 alnsn /* --------------------------------------------------------------------- */ 143 1.1 alnsn 144 1.1 alnsn #define CHUNK_MASK (~(CHUNK_SIZE - 1)) 145 1.1 alnsn 146 1.1 alnsn struct block_header { 147 1.1 alnsn sljit_uw size; 148 1.1 alnsn sljit_uw prev_size; 149 1.1 alnsn }; 150 1.1 alnsn 151 1.1 alnsn struct free_block { 152 1.1 alnsn struct block_header header; 153 1.1 alnsn struct free_block *next; 154 1.1 alnsn struct free_block *prev; 155 1.1 alnsn sljit_uw size; 156 1.1 alnsn }; 157 1.1 alnsn 158 1.1 alnsn #define AS_BLOCK_HEADER(base, offset) \ 159 1.5 alnsn ((struct block_header*)(((sljit_u8*)base) + offset)) 160 1.1 alnsn #define AS_FREE_BLOCK(base, offset) \ 161 1.5 alnsn ((struct free_block*)(((sljit_u8*)base) + offset)) 162 1.5 alnsn #define MEM_START(base) ((void*)(((sljit_u8*)base) + sizeof(struct block_header))) 163 1.1 alnsn #define ALIGN_SIZE(size) (((size) + sizeof(struct block_header) + 7) & ~7) 164 1.1 alnsn 165 1.1 alnsn static struct free_block* free_blocks; 166 1.1 alnsn static sljit_uw allocated_size; 167 1.1 alnsn static sljit_uw total_size; 168 1.1 alnsn 169 1.1 alnsn static SLJIT_INLINE void sljit_insert_free_block(struct free_block *free_block, sljit_uw size) 170 1.1 alnsn { 171 1.1 alnsn free_block->header.size = 0; 172 1.1 alnsn free_block->size = size; 173 1.1 alnsn 174 1.1 alnsn free_block->next = free_blocks; 175 1.5 alnsn free_block->prev = NULL; 176 1.1 alnsn if (free_blocks) 177 1.1 alnsn free_blocks->prev = free_block; 178 1.1 alnsn free_blocks = free_block; 179 1.1 alnsn } 180 1.1 alnsn 181 1.1 alnsn static SLJIT_INLINE void sljit_remove_free_block(struct free_block *free_block) 182 1.1 alnsn { 183 1.1 alnsn if (free_block->next) 184 1.1 alnsn free_block->next->prev = free_block->prev; 185 1.1 alnsn 186 1.1 alnsn if (free_block->prev) 187 1.1 alnsn free_block->prev->next = free_block->next; 188 1.1 alnsn else { 189 1.1 alnsn SLJIT_ASSERT(free_blocks == free_block); 190 1.1 alnsn free_blocks = free_block->next; 191 1.1 alnsn } 192 1.1 alnsn } 193 1.1 alnsn 194 1.1 alnsn SLJIT_API_FUNC_ATTRIBUTE void* sljit_malloc_exec(sljit_uw size) 195 1.1 alnsn { 196 1.1 alnsn struct block_header *header; 197 1.1 alnsn struct block_header *next_header; 198 1.1 alnsn struct free_block *free_block; 199 1.1 alnsn sljit_uw chunk_size; 200 1.1 alnsn 201 1.1 alnsn allocator_grab_lock(); 202 1.6 alnsn if (size < (64 - sizeof(struct block_header))) 203 1.6 alnsn size = (64 - sizeof(struct block_header)); 204 1.1 alnsn size = ALIGN_SIZE(size); 205 1.1 alnsn 206 1.1 alnsn free_block = free_blocks; 207 1.1 alnsn while (free_block) { 208 1.1 alnsn if (free_block->size >= size) { 209 1.1 alnsn chunk_size = free_block->size; 210 1.1 alnsn if (chunk_size > size + 64) { 211 1.1 alnsn /* We just cut a block from the end of the free block. */ 212 1.1 alnsn chunk_size -= size; 213 1.1 alnsn free_block->size = chunk_size; 214 1.1 alnsn header = AS_BLOCK_HEADER(free_block, chunk_size); 215 1.1 alnsn header->prev_size = chunk_size; 216 1.1 alnsn AS_BLOCK_HEADER(header, size)->prev_size = size; 217 1.1 alnsn } 218 1.1 alnsn else { 219 1.1 alnsn sljit_remove_free_block(free_block); 220 1.1 alnsn header = (struct block_header*)free_block; 221 1.1 alnsn size = chunk_size; 222 1.1 alnsn } 223 1.1 alnsn allocated_size += size; 224 1.1 alnsn header->size = size; 225 1.1 alnsn allocator_release_lock(); 226 1.1 alnsn return MEM_START(header); 227 1.1 alnsn } 228 1.1 alnsn free_block = free_block->next; 229 1.1 alnsn } 230 1.1 alnsn 231 1.1 alnsn chunk_size = (size + sizeof(struct block_header) + CHUNK_SIZE - 1) & CHUNK_MASK; 232 1.1 alnsn header = (struct block_header*)alloc_chunk(chunk_size); 233 1.3 alnsn if (!header) { 234 1.3 alnsn allocator_release_lock(); 235 1.3 alnsn return NULL; 236 1.3 alnsn } 237 1.1 alnsn 238 1.1 alnsn chunk_size -= sizeof(struct block_header); 239 1.1 alnsn total_size += chunk_size; 240 1.1 alnsn 241 1.1 alnsn header->prev_size = 0; 242 1.1 alnsn if (chunk_size > size + 64) { 243 1.1 alnsn /* Cut the allocated space into a free and a used block. */ 244 1.1 alnsn allocated_size += size; 245 1.1 alnsn header->size = size; 246 1.1 alnsn chunk_size -= size; 247 1.1 alnsn 248 1.1 alnsn free_block = AS_FREE_BLOCK(header, size); 249 1.1 alnsn free_block->header.prev_size = size; 250 1.1 alnsn sljit_insert_free_block(free_block, chunk_size); 251 1.1 alnsn next_header = AS_BLOCK_HEADER(free_block, chunk_size); 252 1.1 alnsn } 253 1.1 alnsn else { 254 1.1 alnsn /* All space belongs to this allocation. */ 255 1.1 alnsn allocated_size += chunk_size; 256 1.1 alnsn header->size = chunk_size; 257 1.1 alnsn next_header = AS_BLOCK_HEADER(header, chunk_size); 258 1.1 alnsn } 259 1.1 alnsn next_header->size = 1; 260 1.1 alnsn next_header->prev_size = chunk_size; 261 1.1 alnsn allocator_release_lock(); 262 1.1 alnsn return MEM_START(header); 263 1.1 alnsn } 264 1.1 alnsn 265 1.1 alnsn SLJIT_API_FUNC_ATTRIBUTE void sljit_free_exec(void* ptr) 266 1.1 alnsn { 267 1.1 alnsn struct block_header *header; 268 1.1 alnsn struct free_block* free_block; 269 1.1 alnsn 270 1.1 alnsn allocator_grab_lock(); 271 1.3 alnsn header = AS_BLOCK_HEADER(ptr, -(sljit_sw)sizeof(struct block_header)); 272 1.1 alnsn allocated_size -= header->size; 273 1.1 alnsn 274 1.1 alnsn /* Connecting free blocks together if possible. */ 275 1.1 alnsn 276 1.1 alnsn /* If header->prev_size == 0, free_block will equal to header. 277 1.1 alnsn In this case, free_block->header.size will be > 0. */ 278 1.3 alnsn free_block = AS_FREE_BLOCK(header, -(sljit_sw)header->prev_size); 279 1.1 alnsn if (SLJIT_UNLIKELY(!free_block->header.size)) { 280 1.1 alnsn free_block->size += header->size; 281 1.1 alnsn header = AS_BLOCK_HEADER(free_block, free_block->size); 282 1.1 alnsn header->prev_size = free_block->size; 283 1.1 alnsn } 284 1.1 alnsn else { 285 1.1 alnsn free_block = (struct free_block*)header; 286 1.1 alnsn sljit_insert_free_block(free_block, header->size); 287 1.1 alnsn } 288 1.1 alnsn 289 1.1 alnsn header = AS_BLOCK_HEADER(free_block, free_block->size); 290 1.1 alnsn if (SLJIT_UNLIKELY(!header->size)) { 291 1.1 alnsn free_block->size += ((struct free_block*)header)->size; 292 1.1 alnsn sljit_remove_free_block((struct free_block*)header); 293 1.1 alnsn header = AS_BLOCK_HEADER(free_block, free_block->size); 294 1.1 alnsn header->prev_size = free_block->size; 295 1.1 alnsn } 296 1.1 alnsn 297 1.1 alnsn /* The whole chunk is free. */ 298 1.1 alnsn if (SLJIT_UNLIKELY(!free_block->header.prev_size && header->size == 1)) { 299 1.1 alnsn /* If this block is freed, we still have (allocated_size / 2) free space. */ 300 1.1 alnsn if (total_size - free_block->size > (allocated_size * 3 / 2)) { 301 1.1 alnsn total_size -= free_block->size; 302 1.1 alnsn sljit_remove_free_block(free_block); 303 1.1 alnsn free_chunk(free_block, free_block->size + sizeof(struct block_header)); 304 1.1 alnsn } 305 1.1 alnsn } 306 1.1 alnsn 307 1.1 alnsn allocator_release_lock(); 308 1.1 alnsn } 309 1.3 alnsn 310 1.3 alnsn SLJIT_API_FUNC_ATTRIBUTE void sljit_free_unused_memory_exec(void) 311 1.3 alnsn { 312 1.3 alnsn struct free_block* free_block; 313 1.3 alnsn struct free_block* next_free_block; 314 1.3 alnsn 315 1.3 alnsn allocator_grab_lock(); 316 1.3 alnsn 317 1.3 alnsn free_block = free_blocks; 318 1.3 alnsn while (free_block) { 319 1.3 alnsn next_free_block = free_block->next; 320 1.3 alnsn if (!free_block->header.prev_size && 321 1.3 alnsn AS_BLOCK_HEADER(free_block, free_block->size)->size == 1) { 322 1.3 alnsn total_size -= free_block->size; 323 1.3 alnsn sljit_remove_free_block(free_block); 324 1.3 alnsn free_chunk(free_block, free_block->size + sizeof(struct block_header)); 325 1.3 alnsn } 326 1.3 alnsn free_block = next_free_block; 327 1.3 alnsn } 328 1.3 alnsn 329 1.3 alnsn SLJIT_ASSERT((total_size && free_blocks) || (!total_size && !free_blocks)); 330 1.3 alnsn allocator_release_lock(); 331 1.3 alnsn } 332
Indexes created Fri Sep 26 20:09:58 GMT 2025