/* ---------------------------------------------------------------------------- Copyright (c) 2018-2023, Microsoft Research, Daan Leijen This is free software; you can redistribute it and/or modify it under the terms of the MIT license. A copy of the license can be found in the file "LICENSE" at the root of this distribution. -----------------------------------------------------------------------------*/ // This file is included in `src/prim/prim.c` #include "mimalloc.h" #include "mimalloc/internal.h" #include "mimalloc/atomic.h" #include "mimalloc/prim.h" #include // sbrk() //--------------------------------------------- // Initialize //--------------------------------------------- void _mi_prim_mem_init( mi_os_mem_config_t* config ) { config->page_size = 64*MI_KiB; // WebAssembly has a fixed page size: 64KiB config->alloc_granularity = 16; config->has_overcommit = false; config->must_free_whole = true; config->has_virtual_reserve = false; } //--------------------------------------------- // Free //--------------------------------------------- int _mi_prim_free(void* addr, size_t size ) { MI_UNUSED(addr); MI_UNUSED(size); // wasi heap cannot be shrunk return 0; } //--------------------------------------------- // Allocation: sbrk or memory_grow //--------------------------------------------- #if defined(MI_USE_SBRK) static void* mi_memory_grow( size_t size ) { void* p = sbrk(size); if (p == (void*)(-1)) return NULL; #if !defined(__wasi__) // on wasi this is always zero initialized already (?) memset(p,0,size); #endif return p; } #elif defined(__wasi__) static void* mi_memory_grow( size_t size ) { size_t base = (size > 0 ? __builtin_wasm_memory_grow(0,_mi_divide_up(size, _mi_os_page_size())) : __builtin_wasm_memory_size(0)); if (base == SIZE_MAX) return NULL; return (void*)(base * _mi_os_page_size()); } #endif #if defined(MI_USE_PTHREADS) static pthread_mutex_t mi_heap_grow_mutex = PTHREAD_MUTEX_INITIALIZER; #endif static void* mi_prim_mem_grow(size_t size, size_t try_alignment) { void* p = NULL; if (try_alignment <= 1) { // `sbrk` is not thread safe in general so try to protect it (we could skip this on WASM but leave it in for now) #if defined(MI_USE_PTHREADS) pthread_mutex_lock(&mi_heap_grow_mutex); #endif p = mi_memory_grow(size); #if defined(MI_USE_PTHREADS) pthread_mutex_unlock(&mi_heap_grow_mutex); #endif } else { void* base = NULL; size_t alloc_size = 0; // to allocate aligned use a lock to try to avoid thread interaction // between getting the current size and actual allocation // (also, `sbrk` is not thread safe in general) #if defined(MI_USE_PTHREADS) pthread_mutex_lock(&mi_heap_grow_mutex); #endif { void* current = mi_memory_grow(0); // get current size if (current != NULL) { void* aligned_current = mi_align_up_ptr(current, try_alignment); // and align from there to minimize wasted space alloc_size = _mi_align_up( ((uint8_t*)aligned_current - (uint8_t*)current) + size, _mi_os_page_size()); base = mi_memory_grow(alloc_size); } } #if defined(MI_USE_PTHREADS) pthread_mutex_unlock(&mi_heap_grow_mutex); #endif if (base != NULL) { p = mi_align_up_ptr(base, try_alignment); if ((uint8_t*)p + size > (uint8_t*)base + alloc_size) { // another thread used wasm_memory_grow/sbrk in-between and we do not have enough // space after alignment. Give up (and waste the space as we cannot shrink :-( ) // (in `mi_os_mem_alloc_aligned` this will fall back to overallocation to align) p = NULL; } } } /* if (p == NULL) { _mi_warning_message("unable to allocate sbrk/wasm_memory_grow OS memory (%zu bytes, %zu alignment)\n", size, try_alignment); errno = ENOMEM; return NULL; } */ mi_assert_internal( p == NULL || try_alignment == 0 || (uintptr_t)p % try_alignment == 0 ); return p; } // Note: the `try_alignment` is just a hint and the returned pointer is not guaranteed to be aligned. int _mi_prim_alloc(size_t size, size_t try_alignment, bool commit, bool allow_large, bool* is_large, bool* is_zero, void** addr) { MI_UNUSED(allow_large); MI_UNUSED(commit); *is_large = false; *is_zero = false; *addr = mi_prim_mem_grow(size, try_alignment); return (*addr != NULL ? 0 : ENOMEM); } //--------------------------------------------- // Commit/Reset/Protect //--------------------------------------------- int _mi_prim_commit(void* addr, size_t size, bool* is_zero) { MI_UNUSED(addr); MI_UNUSED(size); *is_zero = false; return 0; } int _mi_prim_decommit(void* addr, size_t size, bool* needs_recommit) { MI_UNUSED(addr); MI_UNUSED(size); *needs_recommit = false; return 0; } int _mi_prim_reset(void* addr, size_t size) { MI_UNUSED(addr); MI_UNUSED(size); return 0; } int _mi_prim_protect(void* addr, size_t size, bool protect) { MI_UNUSED(addr); MI_UNUSED(size); MI_UNUSED(protect); return 0; } //--------------------------------------------- // Huge pages and NUMA nodes //--------------------------------------------- int _mi_prim_alloc_huge_os_pages(void* hint_addr, size_t size, int numa_node, bool* is_zero, void** addr) { MI_UNUSED(hint_addr); MI_UNUSED(size); MI_UNUSED(numa_node); *is_zero = true; *addr = NULL; return ENOSYS; } size_t _mi_prim_numa_node(void) { return 0; } size_t _mi_prim_numa_node_count(void) { return 1; } //---------------------------------------------------------------- // Clock //---------------------------------------------------------------- #include #if defined(CLOCK_REALTIME) || defined(CLOCK_MONOTONIC) mi_msecs_t _mi_prim_clock_now(void) { struct timespec t; #ifdef CLOCK_MONOTONIC clock_gettime(CLOCK_MONOTONIC, &t); #else clock_gettime(CLOCK_REALTIME, &t); #endif return ((mi_msecs_t)t.tv_sec * 1000) + ((mi_msecs_t)t.tv_nsec / 1000000); } #else // low resolution timer mi_msecs_t _mi_prim_clock_now(void) { #if !defined(CLOCKS_PER_SEC) || (CLOCKS_PER_SEC == 1000) || (CLOCKS_PER_SEC == 0) return (mi_msecs_t)clock(); #elif (CLOCKS_PER_SEC < 1000) return (mi_msecs_t)clock() * (1000 / (mi_msecs_t)CLOCKS_PER_SEC); #else return (mi_msecs_t)clock() / ((mi_msecs_t)CLOCKS_PER_SEC / 1000); #endif } #endif //---------------------------------------------------------------- // Process info //---------------------------------------------------------------- void _mi_prim_process_info(mi_process_info_t* pinfo) { // use defaults MI_UNUSED(pinfo); } //---------------------------------------------------------------- // Output //---------------------------------------------------------------- void _mi_prim_out_stderr( const char* msg ) { fputs(msg,stderr); } //---------------------------------------------------------------- // Environment //---------------------------------------------------------------- bool _mi_prim_getenv(const char* name, char* result, size_t result_size) { // cannot call getenv() when still initializing the C runtime. if (_mi_preloading()) return false; const char* s = getenv(name); if (s == NULL) { // we check the upper case name too. char buf[64+1]; size_t len = _mi_strnlen(name,sizeof(buf)-1); for (size_t i = 0; i < len; i++) { buf[i] = _mi_toupper(name[i]); } buf[len] = 0; s = getenv(buf); } if (s == NULL || _mi_strnlen(s,result_size) >= result_size) return false; _mi_strlcpy(result, s, result_size); return true; } //---------------------------------------------------------------- // Random //---------------------------------------------------------------- bool _mi_prim_random_buf(void* buf, size_t buf_len) { return false; } //---------------------------------------------------------------- // Thread init/done //---------------------------------------------------------------- void _mi_prim_thread_init_auto_done(void) { // nothing } void _mi_prim_thread_done_auto_done(void) { // nothing } void _mi_prim_thread_associate_default_heap(mi_heap_t* heap) { MI_UNUSED(heap); }