/**************************************************************************** * mm/mm_heap/mm_initialize.c * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. The * ASF licenses this file to you 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. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include "mm_heap/mm.h" #include "kasan/kasan.h" /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ #if CONFIG_MM_HEAP_MEMPOOL_THRESHOLD != 0 # define MEMPOOL_NPOOLS (CONFIG_MM_HEAP_MEMPOOL_THRESHOLD / MM_MIN_CHUNK) #endif /**************************************************************************** * Private Functions ****************************************************************************/ #if CONFIG_MM_HEAP_MEMPOOL_THRESHOLD != 0 && CONFIG_MM_BACKTRACE >= 0 /**************************************************************************** * Name: mempool_memalign * * Description: * This function call mm_memalign and set mm_backtrace pid to free pid * avoid repeated calculation. ****************************************************************************/ static FAR void *mempool_memalign(FAR void *arg, size_t alignment, size_t size) { FAR struct mm_allocnode_s *node; FAR void *ret; ret = mm_memalign(arg, alignment, size); if (ret) { node = (FAR struct mm_allocnode_s *) ((uintptr_t)ret - MM_SIZEOF_ALLOCNODE); node->pid = PID_MM_MEMPOOL; } return ret; } #else # define mempool_memalign mm_memalign #endif /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: mm_addregion * * Description: * This function adds a region of contiguous memory to the selected heap. * * Input Parameters: * heap - The selected heap * heapstart - Start of the heap region * heapsize - Size of the heap region * * Returned Value: * None * * Assumptions: * ****************************************************************************/ void mm_addregion(FAR struct mm_heap_s *heap, FAR void *heapstart, size_t heapsize) { FAR struct mm_freenode_s *node; uintptr_t heapbase; uintptr_t heapend; #if CONFIG_MM_REGIONS > 1 int IDX; IDX = heap->mm_nregions; /* Writing past CONFIG_MM_REGIONS would have catastrophic consequences */ DEBUGASSERT(IDX < CONFIG_MM_REGIONS); if (IDX >= CONFIG_MM_REGIONS) { return; } #else # define IDX 0 #endif #if defined(CONFIG_MM_SMALL) && !defined(CONFIG_SMALL_MEMORY) /* If the MCU handles wide addresses but the memory manager is configured * for a small heap, then verify that the caller is not doing something * crazy. */ DEBUGASSERT(heapsize <= MMSIZE_MAX + 1); #endif /* Register to KASan for access check */ kasan_register(heapstart, &heapsize); DEBUGVERIFY(mm_lock(heap)); /* Adjust the provided heap start and size. * * Note: (uintptr_t)node + MM_SIZEOF_ALLOCNODE is what's actually * returned to the malloc user, which should have natural alignment. * (that is, in this implementation, MM_MIN_CHUNK-alignment.) */ heapbase = MM_ALIGN_UP((uintptr_t)heapstart + 2 * MM_SIZEOF_ALLOCNODE) - 2 * MM_SIZEOF_ALLOCNODE; heapend = MM_ALIGN_DOWN((uintptr_t)heapstart + (uintptr_t)heapsize); heapsize = heapend - heapbase; #if defined(CONFIG_FS_PROCFS) && \ !defined(CONFIG_FS_PROCFS_EXCLUDE_MEMINFO) && \ (defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__)) minfo("[%s] Region %d: base=%p size=%zu\n", heap->mm_procfs.name, IDX + 1, heapstart, heapsize); #else minfo("Region %d: base=%p size=%zu\n", IDX + 1, heapstart, heapsize); #endif /* Add the size of this region to the total size of the heap */ heap->mm_heapsize += heapsize; /* Create two "allocated" guard nodes at the beginning and end of * the heap. These only serve to keep us from allocating outside * of the heap. * * And create one free node between the guard nodes that contains * all available memory. */ heap->mm_heapstart[IDX] = (FAR struct mm_allocnode_s *)heapbase; MM_ADD_BACKTRACE(heap, heap->mm_heapstart[IDX]); heap->mm_heapstart[IDX]->size = MM_SIZEOF_ALLOCNODE | MM_ALLOC_BIT; node = (FAR struct mm_freenode_s *) (heapbase + MM_SIZEOF_ALLOCNODE); DEBUGASSERT((((uintptr_t)node + MM_SIZEOF_ALLOCNODE) % MM_ALIGN) == 0); node->size = heapsize - 2 * MM_SIZEOF_ALLOCNODE; heap->mm_heapend[IDX] = (FAR struct mm_allocnode_s *) (heapend - MM_SIZEOF_ALLOCNODE); heap->mm_heapend[IDX]->size = MM_SIZEOF_ALLOCNODE | MM_ALLOC_BIT | MM_PREVFREE_BIT; heap->mm_heapend[IDX]->preceding = node->size; MM_ADD_BACKTRACE(heap, heap->mm_heapend[IDX]); #undef IDX #if CONFIG_MM_REGIONS > 1 heap->mm_nregions++; #endif /* Add the single, large free node to the nodelist */ mm_addfreechunk(heap, node); mm_unlock(heap); } /**************************************************************************** * Name: mm_initialize * * Description: * Initialize the selected heap data structures, providing the initial * heap region. * * Input Parameters: * name - The heap procfs name * heap - The selected heap * heapstart - Start of the initial heap region * heapsize - Size of the initial heap region * * Returned Value: * Return the address of a new heap instance. * * Assumptions: * ****************************************************************************/ FAR struct mm_heap_s *mm_initialize(FAR const char *name, FAR void *heapstart, size_t heapsize) { #if CONFIG_MM_HEAP_MEMPOOL_THRESHOLD != 0 size_t poolsize[MEMPOOL_NPOOLS]; #endif FAR struct mm_heap_s *heap; uintptr_t heap_adj; int i; minfo("Heap: name=%s, start=%p size=%zu\n", name, heapstart, heapsize); /* First ensure the memory to be used is aligned */ heap_adj = MM_ALIGN_UP((uintptr_t)heapstart); heapsize -= heap_adj - (uintptr_t)heapstart; /* Reserve a block space for mm_heap_s context */ DEBUGASSERT(heapsize > sizeof(struct mm_heap_s)); heap = (FAR struct mm_heap_s *)heap_adj; heapsize -= sizeof(struct mm_heap_s); heapstart = (FAR char *)heap_adj + sizeof(struct mm_heap_s); DEBUGASSERT(MM_MIN_CHUNK >= MM_SIZEOF_ALLOCNODE); /* Set up global variables */ memset(heap, 0, sizeof(struct mm_heap_s)); /* Initialize the node array */ for (i = 1; i < MM_NNODES; i++) { heap->mm_nodelist[i - 1].flink = &heap->mm_nodelist[i]; heap->mm_nodelist[i].blink = &heap->mm_nodelist[i - 1]; } /* Initialize the malloc mutex to one (to support one-at- * a-time access to private data sets). */ nxmutex_init(&heap->mm_lock); #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_MEMINFO) # if defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__) heap->mm_procfs.name = name; heap->mm_procfs.heap = heap; # ifdef CONFIG_MM_BACKTRACE_DEFAULT heap->mm_procfs.backtrace = true; # endif # endif #endif /* Add the initial region of memory to the heap */ mm_addregion(heap, heapstart, heapsize); #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_MEMINFO) # if defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__) procfs_register_meminfo(&heap->mm_procfs); # endif #endif /* Initialize the multiple mempool in heap */ #if CONFIG_MM_HEAP_MEMPOOL_THRESHOLD != 0 for (i = 0; i < MEMPOOL_NPOOLS; i++) { poolsize[i] = (i + 1) * MM_MIN_CHUNK; } heap->mm_mpool = mempool_multiple_init(name, poolsize, MEMPOOL_NPOOLS, (mempool_multiple_alloc_t)mempool_memalign, (mempool_multiple_alloc_size_t)mm_malloc_size, (mempool_multiple_free_t)mm_free, heap, CONFIG_MM_HEAP_MEMPOOL_CHUNK_SIZE, CONFIG_MM_HEAP_MEMPOOL_EXPAND_SIZE, CONFIG_MM_HEAP_MEMPOOL_DICTIONARY_EXPAND_SIZE); #endif return heap; } /**************************************************************************** * Name: mm_uninitialize * * Description: * Uninitialize the selected heap data structures. * * Input Parameters: * heap - The heap to uninitialize * * Returned Value: * None * ****************************************************************************/ void mm_uninitialize(FAR struct mm_heap_s *heap) { #if CONFIG_MM_HEAP_MEMPOOL_THRESHOLD != 0 mempool_multiple_deinit(heap->mm_mpool); #endif #if defined(CONFIG_FS_PROCFS) && !defined(CONFIG_FS_PROCFS_EXCLUDE_MEMINFO) # if defined(CONFIG_BUILD_FLAT) || defined(__KERNEL__) procfs_unregister_meminfo(&heap->mm_procfs); # endif #endif nxmutex_destroy(&heap->mm_lock); }