/* mm.c - functions for memory manager */ /* * GRUB -- GRand Unified Bootloader * Copyright (C) 2002,2005,2007,2008,2009 Free Software Foundation, Inc. * * GRUB is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * GRUB is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GRUB. If not, see . */ /* The design of this memory manager. This is a simple implementation of malloc with a few extensions. These are the extensions: - memalign is implemented efficiently. - multiple regions may be used as free space. They may not be contiguous. Regions are managed by a singly linked list, and the meta information is stored in the beginning of each region. Space after the meta information is used to allocate memory. The memory space is used as cells instead of bytes for simplicity. This is important for some CPUs which may not access multiple bytes at a time when the first byte is not aligned at a certain boundary (typically, 4-byte or 8-byte). The size of each cell is equal to the size of struct grub_mm_header, so the header of each allocated/free block fits into one cell precisely. One cell is 16 bytes on 32-bit platforms and 32 bytes on 64-bit platforms. There are two types of blocks: allocated blocks and free blocks. In allocated blocks, the header of each block has only its size. Note that this size is based on cells but not on bytes. The header is located right before the returned pointer, that is, the header resides at the previous cell. Free blocks constitutes a ring, using a singly linked list. The first free block is pointed to by the meta information of a region. The allocator attempts to pick up the second block instead of the first one. This is a typical optimization against defragmentation, and makes the implementation a bit easier. For safety, both allocated blocks and free ones are marked by magic numbers. Whenever anything unexpected is detected, GRUB aborts the operation. */ #include #include #include #include #include #include #include #include #ifdef MM_DEBUG # undef grub_malloc # undef grub_zalloc # undef grub_realloc # undef grub_free # undef grub_memalign #endif grub_mm_region_t grub_mm_base; /* Get a header from the pointer PTR, and set *P and *R to a pointer to the header and a pointer to its region, respectively. PTR must be allocated. */ static void get_header_from_pointer (void *ptr, grub_mm_header_t *p, grub_mm_region_t *r) { if ((grub_addr_t) ptr & (GRUB_MM_ALIGN - 1)) grub_fatal ("unaligned pointer %p", ptr); for (*r = grub_mm_base; *r; *r = (*r)->next) if ((grub_addr_t) ptr > (grub_addr_t) ((*r) + 1) && (grub_addr_t) ptr <= (grub_addr_t) ((*r) + 1) + (*r)->size) break; if (! *r) grub_fatal ("out of range pointer %p", ptr); *p = (grub_mm_header_t) ptr - 1; if ((*p)->magic != GRUB_MM_ALLOC_MAGIC) grub_fatal ("alloc magic is broken at %p", *p); } /* Initialize a region starting from ADDR and whose size is SIZE, to use it as free space. */ void grub_mm_init_region (void *addr, grub_size_t size) { grub_mm_header_t h; grub_mm_region_t r, *p, q; #if 0 grub_printf ("Using memory for heap: start=%p, end=%p\n", addr, addr + (unsigned int) size); #endif /* Allocate a region from the head. */ r = (grub_mm_region_t) ALIGN_UP ((grub_addr_t) addr, GRUB_MM_ALIGN); size -= (char *) r - (char *) addr + sizeof (*r); /* If this region is too small, ignore it. */ if (size < GRUB_MM_ALIGN) return; h = (grub_mm_header_t) (r + 1); h->next = h; h->magic = GRUB_MM_FREE_MAGIC; h->size = (size >> GRUB_MM_ALIGN_LOG2); r->first = h; r->pre_size = (grub_addr_t) r - (grub_addr_t) addr; r->size = (h->size << GRUB_MM_ALIGN_LOG2); /* Find where to insert this region. Put a smaller one before bigger ones, to prevent fragmentation. */ for (p = &grub_mm_base, q = *p; q; p = &(q->next), q = *p) if (q->size > r->size) break; *p = r; r->next = q; } /* Allocate the number of units N with the alignment ALIGN from the ring buffer starting from *FIRST. ALIGN must be a power of two. Both N and ALIGN are in units of GRUB_MM_ALIGN. Return a non-NULL if successful, otherwise return NULL. */ static void * grub_real_malloc (grub_mm_header_t *first, grub_size_t n, grub_size_t align) { grub_mm_header_t p, q; /* When everything is allocated side effect is that *first will have alloc magic marked, meaning that there is no room in this region. */ if ((*first)->magic == GRUB_MM_ALLOC_MAGIC) return 0; /* Try to search free slot for allocation in this memory region. */ for (q = *first, p = q->next; ; q = p, p = p->next) { grub_off_t extra; extra = ((grub_addr_t) (p + 1) >> GRUB_MM_ALIGN_LOG2) % align; if (extra) extra = align - extra; if (! p) grub_fatal ("null in the ring"); if (p->magic != GRUB_MM_FREE_MAGIC) grub_fatal ("free magic is broken at %p: 0x%x", p, p->magic); if (p->size >= n + extra) { extra += (p->size - extra - n) & (~(align - 1)); if (extra == 0 && p->size == n) { /* There is no special alignment requirement and memory block is complete match. 1. Just mark memory block as allocated and remove it from free list. Result: +---------------+ previous block's next | alloc, size=n | | +---------------+ v */ q->next = p->next; } else if (align == 1 || p->size == n + extra) { /* There might be alignment requirement, when taking it into account memory block fits in. 1. Allocate new area at end of memory block. 2. Reduce size of available blocks from original node. 3. Mark new area as allocated and "remove" it from free list. Result: +---------------+ | free, size-=n | next --+ +---------------+ | | alloc, size=n | | +---------------+ v */ p->size -= n; p += p->size; } else if (extra == 0) { grub_mm_header_t r; r = p + extra + n; r->magic = GRUB_MM_FREE_MAGIC; r->size = p->size - extra - n; r->next = p->next; q->next = r; if (q == p) { q = r; r->next = r; } } else { /* There is alignment requirement and there is room in memory block. Split memory block to three pieces. 1. Create new memory block right after section being allocated. Mark it as free. 2. Add new memory block to free chain. 3. Mark current memory block having only extra blocks. 4. Advance to aligned block and mark that as allocated and "remove" it from free list. Result: +------------------------------+ | free, size=extra | next --+ +------------------------------+ | | alloc, size=n | | +------------------------------+ | | free, size=orig.size-extra-n | <------+, next --+ +------------------------------+ v */ grub_mm_header_t r; r = p + extra + n; r->magic = GRUB_MM_FREE_MAGIC; r->size = p->size - extra - n; r->next = p; p->size = extra; q->next = r; p += extra; } p->magic = GRUB_MM_ALLOC_MAGIC; p->size = n; /* Mark find as a start marker for next allocation to fasten it. This will have side effect of fragmenting memory as small pieces before this will be un-used. */ *first = q; return p + 1; } /* Search was completed without result. */ if (p == *first) break; } return 0; } /* Allocate SIZE bytes with the alignment ALIGN and return the pointer. */ void * grub_memalign (grub_size_t align, grub_size_t size) { grub_mm_region_t r; grub_size_t n = ((size + GRUB_MM_ALIGN - 1) >> GRUB_MM_ALIGN_LOG2) + 1; int count = 0; if (!grub_mm_base) goto fail; align = (align >> GRUB_MM_ALIGN_LOG2); if (align == 0) align = 1; again: for (r = grub_mm_base; r; r = r->next) { void *p; p = grub_real_malloc (&(r->first), n, align); if (p) return p; } /* If failed, increase free memory somehow. */ switch (count) { case 0: /* Invalidate disk caches. */ grub_disk_cache_invalidate_all (); count++; goto again; case 1: /* Unload unneeded modules. */ grub_dl_unload_unneeded (); count++; goto again; default: break; } fail: grub_error (GRUB_ERR_OUT_OF_MEMORY, "out of memory"); return 0; } /* Allocate SIZE bytes and return the pointer. */ void * grub_malloc (grub_size_t size) { return grub_memalign (0, size); } /* Allocate SIZE bytes, clear them and return the pointer. */ void * grub_zalloc (grub_size_t size) { void *ret; ret = grub_memalign (0, size); if (ret) grub_memset (ret, 0, size); return ret; } /* Deallocate the pointer PTR. */ void grub_free (void *ptr) { grub_mm_header_t p; grub_mm_region_t r; if (! ptr) return; get_header_from_pointer (ptr, &p, &r); if (r->first->magic == GRUB_MM_ALLOC_MAGIC) { p->magic = GRUB_MM_FREE_MAGIC; r->first = p->next = p; } else { grub_mm_header_t q; #if 0 q = r->first; do { grub_printf ("%s:%d: q=%p, q->size=0x%x, q->magic=0x%x\n", GRUB_FILE, __LINE__, q, q->size, q->magic); q = q->next; } while (q != r->first); #endif for (q = r->first; q >= p || q->next <= p; q = q->next) { if (q->magic != GRUB_MM_FREE_MAGIC) grub_fatal ("free magic is broken at %p: 0x%x", q, q->magic); if (q >= q->next && (q < p || q->next > p)) break; } p->magic = GRUB_MM_FREE_MAGIC; p->next = q->next; q->next = p; if (p + p->size == p->next) { if (p->next == q) q = p; p->next->magic = 0; p->size += p->next->size; p->next = p->next->next; } if (q + q->size == p) { p->magic = 0; q->size += p->size; q->next = p->next; } r->first = q; } } /* Reallocate SIZE bytes and return the pointer. The contents will be the same as that of PTR. */ void * grub_realloc (void *ptr, grub_size_t size) { grub_mm_header_t p; grub_mm_region_t r; void *q; grub_size_t n; if (! ptr) return grub_malloc (size); if (! size) { grub_free (ptr); return 0; } /* FIXME: Not optimal. */ n = ((size + GRUB_MM_ALIGN - 1) >> GRUB_MM_ALIGN_LOG2) + 1; get_header_from_pointer (ptr, &p, &r); if (p->size >= n) return ptr; q = grub_malloc (size); if (! q) return q; grub_memcpy (q, ptr, size); grub_free (ptr); return q; } #ifdef MM_DEBUG int grub_mm_debug = 0; void grub_mm_dump_free (void) { grub_mm_region_t r; for (r = grub_mm_base; r; r = r->next) { grub_mm_header_t p; /* Follow the free list. */ p = r->first; do { if (p->magic != GRUB_MM_FREE_MAGIC) grub_fatal ("free magic is broken at %p: 0x%x", p, p->magic); grub_printf ("F:%p:%u:%p\n", p, (unsigned int) p->size << GRUB_MM_ALIGN_LOG2, p->next); p = p->next; } while (p != r->first); } grub_printf ("\n"); } void grub_mm_dump (unsigned lineno) { grub_mm_region_t r; grub_printf ("called at line %u\n", lineno); for (r = grub_mm_base; r; r = r->next) { grub_mm_header_t p; for (p = (grub_mm_header_t) ALIGN_UP ((grub_addr_t) (r + 1), GRUB_MM_ALIGN); (grub_addr_t) p < (grub_addr_t) (r+1) + r->size; p++) { switch (p->magic) { case GRUB_MM_FREE_MAGIC: grub_printf ("F:%p:%u:%p\n", p, (unsigned int) p->size << GRUB_MM_ALIGN_LOG2, p->next); break; case GRUB_MM_ALLOC_MAGIC: grub_printf ("A:%p:%u\n", p, (unsigned int) p->size << GRUB_MM_ALIGN_LOG2); break; } } } grub_printf ("\n"); } void * grub_debug_malloc (const char *file, int line, grub_size_t size) { void *ptr; if (grub_mm_debug) grub_printf ("%s:%d: malloc (0x%zx) = ", file, line, size); ptr = grub_malloc (size); if (grub_mm_debug) grub_printf ("%p\n", ptr); return ptr; } void * grub_debug_zalloc (const char *file, int line, grub_size_t size) { void *ptr; if (grub_mm_debug) grub_printf ("%s:%d: zalloc (0x%zx) = ", file, line, size); ptr = grub_zalloc (size); if (grub_mm_debug) grub_printf ("%p\n", ptr); return ptr; } void grub_debug_free (const char *file, int line, void *ptr) { if (grub_mm_debug) grub_printf ("%s:%d: free (%p)\n", file, line, ptr); grub_free (ptr); } void * grub_debug_realloc (const char *file, int line, void *ptr, grub_size_t size) { if (grub_mm_debug) grub_printf ("%s:%d: realloc (%p, 0x%zx) = ", file, line, ptr, size); ptr = grub_realloc (ptr, size); if (grub_mm_debug) grub_printf ("%p\n", ptr); return ptr; } void * grub_debug_memalign (const char *file, int line, grub_size_t align, grub_size_t size) { void *ptr; if (grub_mm_debug) grub_printf ("%s:%d: memalign (0x%zx, 0x%zx) = ", file, line, align, size); ptr = grub_memalign (align, size); if (grub_mm_debug) grub_printf ("%p\n", ptr); return ptr; } #endif /* MM_DEBUG */