Mercurial > lcfOS
view cos/kernel/malloc.c @ 125:1ee5f36b34ed
Added tag stm32f4discovery flash with python for changeset d38729d35c4d
author | Windel Bouwman |
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date | Sun, 13 Jan 2013 10:42:03 +0100 |
parents | 24ce177e01e8 |
children |
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#include "kernel.h" // ================= Placement malloc: // Assume here that nothing gets ever kfree'd. This makes it simple! uint64_t placement_address = (uint64_t)&kernel_end; // ================= Other malloc // TODO: move this to user space? #define HEAP_MAGIC 0xc0ffee #define HEAP_INUSE 1 #define HEAP_FREE 0 /* malloc and free divide the chunks of memory present at the heap of the kernel into smaller parts. The heap is located at: 0x */ static heap_t* kernel_heap = 0; void expand_heap(heap_t *heap, uint64_t newsize); /* Allocates 'size' bytes and returns the pointer if succesfull. Before the kernel is initialized, placement malloc is used. Kernelpanic in case of failure.. */ static void* kmalloc_int(uint64_t size, uint64_t aligned) { // Check if there exists a kernel heap. If not, use placement malloc for now. if (kernel_heap == 0) { // Before that the heap is initialized, use placement malloc if (aligned == 1) { // Align placement address if ( (placement_address | 0xFFF) != 0 ) { placement_address &= ~(0xFFF); placement_address += 0x1000; } } uint64_t tmp = placement_address; placement_address += size; return (void*)tmp; } else { // We have a kernel heap, search the heap for a block of suitable size. // Start at the beginning of our heap and search a free block: heap_header_t *current = kernel_heap->first_block; while (current->magic == HEAP_MAGIC) { if ((current->state == HEAP_FREE) && (current->size >= size)) { // We found a hole with suitable size. Determine if split is of any use. // Insert a heap header if required: if (current->size > size + sizeof(heap_t) + 1) { // Calculate location of the inserted header: heap_header_t *newheader = (heap_header_t*) (((uint64_t)current)+size+sizeof(heap_header_t)); // Set the new header fields: newheader->size = current->size - size - sizeof(heap_header_t); newheader->state = HEAP_FREE; newheader->magic = HEAP_MAGIC; // Set the size of this block current->size = size; } else { // We allocate this whole block // Mark block as used: current->state = HEAP_INUSE; } // Calculate the size of the block: char *address = ((char*)current)+sizeof(heap_header_t); return address; } // Goto next heap block: current = (heap_header_t*)(((uint64_t) current) + current->size + sizeof(heap_header_t)); } // We did not find a block large enough. Expand the heap and try again. expand_heap(kernel_heap, 0x10000000); return kmalloc_int(size, aligned); } } // Convenient wrappers: void* kmalloc(uint64_t size) { return kmalloc_int(size, 0); } void* kmalloc_a(uint64_t size) { return kmalloc_int(size, 1); } void kfree(void* ptr) { printf("Free address %x\n", ptr); if (kernel_heap == 0) { return; } else { // TODO } // TODO: free blocks: } heap_t* create_heap(uint64_t location, uint64_t size) { // Make sure that the new heap location is mapped into the address space: uint64_t i = 0; while (i < size) { alloc_frame( get_page(location + i, kernel_map)); i += 0x1000; } // create new heap structure: heap_t* h = (heap_t*)kmalloc(sizeof(heap_t)); // Create one big hole: h->first_block = (heap_header_t*)location; // Place header at beginning of heap h->first_block->magic = HEAP_MAGIC; h->first_block->state = HEAP_FREE; h->first_block->size = size - sizeof(heap_header_t); return h; } // Make the total heap bigger: void expand_heap(heap_t *heap, uint64_t newsize) { uint64_t oldsize = heap->end_address - heap->start_address; if (newsize < oldsize) { panic("Cannot expand heap to a smaller size\n"); } uint64_t i = oldsize; while (i < newsize) { alloc_frame( get_page(heap->start_address + i, kernel_map)); i += 0x1000; } }