/* * Copyright (c) 2010-2014 Richard Braun. * * This program 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. * * This program 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 this program. If not, see . */ #include #include #include #include #include #include #include #include #include "biosmem.h" #include "x15/elf.h" #include "x15/multiboot.h" /* Mach glue. */ #define __bootdata /* nothing */ #define __boot /* nothing */ #define __init /* nothing */ #define boot_memmove memmove #define boot_memset(P,C,S) memset((char *) phystokv(P), C, S) #define boot_strlen(P) strlen((char *) phystokv(P)) #define boot_panic panic #define printk printf #define BOOT_VTOP(addr) _kvtophys(addr) /* XXX */ extern char _boot; extern char _end; /* * Maximum number of entries in the BIOS memory map. * * Because of adjustments of overlapping ranges, the memory map can grow * to twice this size. */ #define BIOSMEM_MAX_MAP_SIZE 128 /* * Memory range types. */ #define BIOSMEM_TYPE_AVAILABLE 1 #define BIOSMEM_TYPE_RESERVED 2 #define BIOSMEM_TYPE_ACPI 3 #define BIOSMEM_TYPE_NVS 4 #define BIOSMEM_TYPE_UNUSABLE 5 #define BIOSMEM_TYPE_DISABLED 6 /* * Memory map entry. */ struct biosmem_map_entry { uint64_t base_addr; uint64_t length; unsigned int type; }; /* * Contiguous block of physical memory. * * Tha "available" range records what has been passed to the VM system as * available inside the segment. */ struct biosmem_segment { phys_addr_t start; phys_addr_t end; phys_addr_t avail_start; phys_addr_t avail_end; }; /* * Memory map built from the information passed by the boot loader. * * If the boot loader didn't pass a valid memory map, a simple map is built * based on the mem_lower and mem_upper multiboot fields. */ static struct biosmem_map_entry biosmem_map[BIOSMEM_MAX_MAP_SIZE * 2] __bootdata; static unsigned int biosmem_map_size __bootdata; /* * Physical segment boundaries. */ static struct biosmem_segment biosmem_segments[VM_PAGE_MAX_SEGS] __bootdata; /* * Boundaries of the simple bootstrap heap. * * This heap is located above BIOS memory. */ static uint32_t biosmem_heap_start __bootdata; static uint32_t biosmem_heap_cur __bootdata; static uint32_t biosmem_heap_end __bootdata; static char biosmem_panic_toobig_msg[] __bootdata = "biosmem: too many memory map entries"; static char biosmem_panic_setup_msg[] __bootdata = "biosmem: unable to set up the early memory allocator"; static char biosmem_panic_noseg_msg[] __bootdata = "biosmem: unable to find any memory segment"; static char biosmem_panic_inval_msg[] __bootdata = "biosmem: attempt to allocate 0 page"; static char biosmem_panic_nomem_msg[] __bootdata = "biosmem: unable to allocate memory"; static void __boot biosmem_map_build(const struct multiboot_raw_info *mbi) { struct multiboot_raw_mmap_entry *mb_entry, *mb_end; struct biosmem_map_entry *start, *entry, *end; unsigned long addr; addr = phystokv(mbi->mmap_addr); mb_entry = (struct multiboot_raw_mmap_entry *)addr; mb_end = (struct multiboot_raw_mmap_entry *)(addr + mbi->mmap_length); start = biosmem_map; entry = start; end = entry + BIOSMEM_MAX_MAP_SIZE; while ((mb_entry < mb_end) && (entry < end)) { entry->base_addr = mb_entry->base_addr; entry->length = mb_entry->length; entry->type = mb_entry->type; mb_entry = (void *)mb_entry + sizeof(mb_entry->size) + mb_entry->size; entry++; } biosmem_map_size = entry - start; } static void __boot biosmem_map_build_simple(const struct multiboot_raw_info *mbi) { struct biosmem_map_entry *entry; entry = biosmem_map; entry->base_addr = 0; entry->length = mbi->mem_lower << 10; entry->type = BIOSMEM_TYPE_AVAILABLE; entry++; entry->base_addr = BIOSMEM_END; entry->length = mbi->mem_upper << 10; entry->type = BIOSMEM_TYPE_AVAILABLE; biosmem_map_size = 2; } static int __boot biosmem_map_entry_is_invalid(const struct biosmem_map_entry *entry) { return (entry->base_addr + entry->length) <= entry->base_addr; } static void __boot biosmem_map_filter(void) { struct biosmem_map_entry *entry; unsigned int i; i = 0; while (i < biosmem_map_size) { entry = &biosmem_map[i]; if (biosmem_map_entry_is_invalid(entry)) { biosmem_map_size--; boot_memmove(entry, entry + 1, (biosmem_map_size - i) * sizeof(*entry)); continue; } i++; } } static void __boot biosmem_map_sort(void) { struct biosmem_map_entry tmp; unsigned int i, j; /* * Simple insertion sort. */ for (i = 1; i < biosmem_map_size; i++) { tmp = biosmem_map[i]; for (j = i - 1; j < i; j--) { if (biosmem_map[j].base_addr < tmp.base_addr) break; biosmem_map[j + 1] = biosmem_map[j]; } biosmem_map[j + 1] = tmp; } } static void __boot biosmem_map_adjust(void) { struct biosmem_map_entry tmp, *a, *b, *first, *second; uint64_t a_end, b_end, last_end; unsigned int i, j, last_type; biosmem_map_filter(); /* * Resolve overlapping areas, giving priority to most restrictive * (i.e. numerically higher) types. */ for (i = 0; i < biosmem_map_size; i++) { a = &biosmem_map[i]; a_end = a->base_addr + a->length; j = i + 1; while (j < biosmem_map_size) { b = &biosmem_map[j]; b_end = b->base_addr + b->length; if ((a->base_addr >= b_end) || (a_end <= b->base_addr)) { j++; continue; } if (a->base_addr < b->base_addr) { first = a; second = b; } else { first = b; second = a; } if (a_end > b_end) { last_end = a_end; last_type = a->type; } else { last_end = b_end; last_type = b->type; } tmp.base_addr = second->base_addr; tmp.length = MIN(a_end, b_end) - tmp.base_addr; tmp.type = MAX(a->type, b->type); first->length = tmp.base_addr - first->base_addr; second->base_addr += tmp.length; second->length = last_end - second->base_addr; second->type = last_type; /* * Filter out invalid entries. */ if (biosmem_map_entry_is_invalid(a) && biosmem_map_entry_is_invalid(b)) { *a = tmp; biosmem_map_size--; memmove(b, b + 1, (biosmem_map_size - j) * sizeof(*b)); continue; } else if (biosmem_map_entry_is_invalid(a)) { *a = tmp; j++; continue; } else if (biosmem_map_entry_is_invalid(b)) { *b = tmp; j++; continue; } if (tmp.type == a->type) first = a; else if (tmp.type == b->type) first = b; else { /* * If the overlapping area can't be merged with one of its * neighbors, it must be added as a new entry. */ if (biosmem_map_size >= ARRAY_SIZE(biosmem_map)) boot_panic(biosmem_panic_toobig_msg); biosmem_map[biosmem_map_size] = tmp; biosmem_map_size++; j++; continue; } if (first->base_addr > tmp.base_addr) first->base_addr = tmp.base_addr; first->length += tmp.length; j++; } } biosmem_map_sort(); } static int __boot biosmem_map_find_avail(phys_addr_t *phys_start, phys_addr_t *phys_end) { const struct biosmem_map_entry *entry, *map_end; phys_addr_t seg_start, seg_end; uint64_t start, end; seg_start = (phys_addr_t)-1; seg_end = (phys_addr_t)-1; map_end = biosmem_map + biosmem_map_size; for (entry = biosmem_map; entry < map_end; entry++) { if (entry->type != BIOSMEM_TYPE_AVAILABLE) continue; start = vm_page_round(entry->base_addr); if (start >= *phys_end) break; end = vm_page_trunc(entry->base_addr + entry->length); if ((start < end) && (start < *phys_end) && (end > *phys_start)) { if (seg_start == (phys_addr_t)-1) seg_start = start; seg_end = end; } } if ((seg_start == (phys_addr_t)-1) || (seg_end == (phys_addr_t)-1)) return -1; if (seg_start > *phys_start) *phys_start = seg_start; if (seg_end < *phys_end) *phys_end = seg_end; return 0; } static void __boot biosmem_set_segment(unsigned int seg_index, phys_addr_t start, phys_addr_t end) { biosmem_segments[seg_index].start = start; biosmem_segments[seg_index].end = end; } static phys_addr_t __boot biosmem_segment_end(unsigned int seg_index) { return biosmem_segments[seg_index].end; } static phys_addr_t __boot biosmem_segment_size(unsigned int seg_index) { return biosmem_segments[seg_index].end - biosmem_segments[seg_index].start; } static void __boot biosmem_save_cmdline_sizes(struct multiboot_raw_info *mbi) { struct multiboot_raw_module *mod; uint32_t i; if (mbi->flags & MULTIBOOT_LOADER_CMDLINE) mbi->unused0 = boot_strlen((unsigned long)mbi->cmdline) + 1; if (mbi->flags & MULTIBOOT_LOADER_MODULES) { unsigned long addr; addr = phystokv(mbi->mods_addr); for (i = 0; i < mbi->mods_count; i++) { mod = (struct multiboot_raw_module *)addr + i; mod->reserved = boot_strlen((unsigned long)mod->string) + 1; } } } static void __boot biosmem_find_boot_data_update(uint32_t min, uint32_t *start, uint32_t *end, uint32_t data_start, uint32_t data_end) { assert (data_start < data_end); if ((min <= data_start) && (data_start < *start)) { *start = data_start; *end = data_end; } } /* * Find the first boot data in the given range, and return their containing * area (start address is returned directly, end address is returned in end). * The following are considered boot data : * - the kernel * - the kernel command line * - the module table * - the modules * - the modules command lines * - the ELF section header table * - the ELF .shstrtab, .symtab and .strtab sections * * If no boot data was found, 0 is returned, and the end address isn't set. */ static uint32_t __boot biosmem_find_boot_data(const struct multiboot_raw_info *mbi, uint32_t min, uint32_t max, uint32_t *endp) { struct multiboot_raw_module *mod; struct elf_shdr *shdr; uint32_t i, start, end = end; unsigned long tmp; start = max; biosmem_find_boot_data_update(min, &start, &end, BOOT_VTOP((unsigned long)&_boot), BOOT_VTOP((unsigned long)&_end)); if ((mbi->flags & MULTIBOOT_LOADER_CMDLINE) && (mbi->cmdline != 0)) biosmem_find_boot_data_update(min, &start, &end, mbi->cmdline, mbi->cmdline + mbi->unused0); if (mbi->flags & MULTIBOOT_LOADER_MODULES) { i = mbi->mods_count * sizeof(struct multiboot_raw_module); biosmem_find_boot_data_update(min, &start, &end, mbi->mods_addr, mbi->mods_addr + i); tmp = phystokv(mbi->mods_addr); for (i = 0; i < mbi->mods_count; i++) { mod = (struct multiboot_raw_module *)tmp + i; biosmem_find_boot_data_update(min, &start, &end, mod->mod_start, mod->mod_end); if (mod->string != 0) biosmem_find_boot_data_update(min, &start, &end, mod->string, mod->string + mod->reserved); } } if (mbi->flags & MULTIBOOT_LOADER_SHDR) { tmp = mbi->shdr_num * mbi->shdr_size; biosmem_find_boot_data_update(min, &start, &end, mbi->shdr_addr, mbi->shdr_addr + tmp); tmp = phystokv(mbi->shdr_addr); for (i = 0; i < mbi->shdr_num; i++) { shdr = (struct elf_shdr *)(tmp + (i * mbi->shdr_size)); if ((shdr->type != ELF_SHT_SYMTAB) && (shdr->type != ELF_SHT_STRTAB)) continue; biosmem_find_boot_data_update(min, &start, &end, shdr->addr, shdr->addr + shdr->size); } } if (start == max) return 0; *endp = end; return start; } static void __boot biosmem_setup_allocator(struct multiboot_raw_info *mbi) { uint32_t heap_start, heap_end, max_heap_start, max_heap_end; uint32_t mem_end, next; /* * Find some memory for the heap. Look for the largest unused area in * upper memory, carefully avoiding all boot data. */ mem_end = vm_page_trunc((mbi->mem_upper + 1024) << 10); #ifndef __LP64__ if (mem_end > VM_PAGE_DIRECTMAP_LIMIT) mem_end = VM_PAGE_DIRECTMAP_LIMIT; #endif /* __LP64__ */ max_heap_start = 0; max_heap_end = 0; next = BIOSMEM_END; do { heap_start = next; heap_end = biosmem_find_boot_data(mbi, heap_start, mem_end, &next); if (heap_end == 0) { heap_end = mem_end; next = 0; } if ((heap_end - heap_start) > (max_heap_end - max_heap_start)) { max_heap_start = heap_start; max_heap_end = heap_end; } } while (next != 0); max_heap_start = vm_page_round(max_heap_start); max_heap_end = vm_page_trunc(max_heap_end); if (max_heap_start >= max_heap_end) boot_panic(biosmem_panic_setup_msg); biosmem_heap_start = max_heap_start; biosmem_heap_end = max_heap_end; biosmem_heap_cur = biosmem_heap_end; /* Mach pmap glue. */ extern vm_offset_t phys_last_addr; phys_last_addr = (vm_offset_t) max_heap_end; } void __boot biosmem_bootstrap(struct multiboot_raw_info *mbi) { phys_addr_t phys_start, phys_end; int error; if (mbi->flags & MULTIBOOT_LOADER_MMAP) biosmem_map_build(mbi); else biosmem_map_build_simple(mbi); biosmem_map_adjust(); phys_start = BIOSMEM_BASE; phys_end = VM_PAGE_DMA_LIMIT; error = biosmem_map_find_avail(&phys_start, &phys_end); if (error) boot_panic(biosmem_panic_noseg_msg); biosmem_set_segment(VM_PAGE_SEG_DMA, phys_start, phys_end); phys_start = VM_PAGE_DMA_LIMIT; #ifdef VM_PAGE_DMA32_LIMIT phys_end = VM_PAGE_DMA32_LIMIT; error = biosmem_map_find_avail(&phys_start, &phys_end); if (error) goto out; biosmem_set_segment(VM_PAGE_SEG_DMA32, phys_start, phys_end); phys_start = VM_PAGE_DMA32_LIMIT; #endif /* VM_PAGE_DMA32_LIMIT */ phys_end = VM_PAGE_DIRECTMAP_LIMIT; error = biosmem_map_find_avail(&phys_start, &phys_end); if (error) goto out; biosmem_set_segment(VM_PAGE_SEG_DIRECTMAP, phys_start, phys_end); phys_start = VM_PAGE_DIRECTMAP_LIMIT; phys_end = VM_PAGE_HIGHMEM_LIMIT; error = biosmem_map_find_avail(&phys_start, &phys_end); if (error) goto out; biosmem_set_segment(VM_PAGE_SEG_HIGHMEM, phys_start, phys_end); out: /* * The kernel and modules command lines will be memory mapped later * during initialization. Their respective sizes must be saved. */ biosmem_save_cmdline_sizes(mbi); biosmem_setup_allocator(mbi); } void * __boot biosmem_bootalloc(unsigned int nr_pages) { unsigned long addr, size; size = vm_page_ptoa(nr_pages); if (size == 0) boot_panic(biosmem_panic_inval_msg); /* Top-down allocation to avoid unnecessarily filling DMA segments */ addr = biosmem_heap_cur - size; if ((addr < biosmem_heap_start) || (addr > biosmem_heap_cur)) boot_panic(biosmem_panic_nomem_msg); biosmem_heap_cur = addr; return boot_memset(addr, 0, size); } phys_addr_t __boot biosmem_directmap_size(void) { if (biosmem_segment_size(VM_PAGE_SEG_DIRECTMAP) != 0) return biosmem_segment_end(VM_PAGE_SEG_DIRECTMAP); else if (biosmem_segment_size(VM_PAGE_SEG_DMA32) != 0) return biosmem_segment_end(VM_PAGE_SEG_DMA32); else return biosmem_segment_end(VM_PAGE_SEG_DMA); } static const char * __init biosmem_type_desc(unsigned int type) { switch (type) { case BIOSMEM_TYPE_AVAILABLE: return "available"; case BIOSMEM_TYPE_RESERVED: return "reserved"; case BIOSMEM_TYPE_ACPI: return "ACPI"; case BIOSMEM_TYPE_NVS: return "ACPI NVS"; case BIOSMEM_TYPE_UNUSABLE: return "unusable"; default: return "unknown (reserved)"; } } static void __init biosmem_map_show(void) { const struct biosmem_map_entry *entry, *end; printk("biosmem: physical memory map:\n"); for (entry = biosmem_map, end = entry + biosmem_map_size; entry < end; entry++) printk("biosmem: %018llx:%018llx, %s\n", entry->base_addr, entry->base_addr + entry->length, biosmem_type_desc(entry->type)); printk("biosmem: heap: %x-%x\n", biosmem_heap_start, biosmem_heap_end); } static void __init biosmem_load_segment(struct biosmem_segment *seg, uint64_t max_phys_end, phys_addr_t phys_start, phys_addr_t phys_end, phys_addr_t avail_start, phys_addr_t avail_end) { unsigned int seg_index; seg_index = seg - biosmem_segments; if (phys_end > max_phys_end) { if (max_phys_end <= phys_start) { printk("biosmem: warning: segment %s physically unreachable, " "not loaded\n", vm_page_seg_name(seg_index)); return; } printk("biosmem: warning: segment %s truncated to %#llx\n", vm_page_seg_name(seg_index), max_phys_end); phys_end = max_phys_end; } if ((avail_start < phys_start) || (avail_start > phys_end)) avail_start = phys_start; if ((avail_end < phys_start) || (avail_end > phys_end)) avail_end = phys_end; seg->avail_start = avail_start; seg->avail_end = avail_end; vm_page_load(seg_index, phys_start, phys_end, avail_start, avail_end); } void __init biosmem_setup(void) { uint64_t max_phys_end; struct biosmem_segment *seg; struct cpu *cpu; unsigned int i; biosmem_map_show(); #if notyet cpu = cpu_current(); max_phys_end = (cpu->phys_addr_width == 0) ? (uint64_t)-1 : (uint64_t)1 << cpu->phys_addr_width; #else max_phys_end = (uint64_t)1 << 32; (void) cpu; #endif for (i = 0; i < ARRAY_SIZE(biosmem_segments); i++) { if (biosmem_segment_size(i) == 0) break; seg = &biosmem_segments[i]; biosmem_load_segment(seg, max_phys_end, seg->start, seg->end, biosmem_heap_start, biosmem_heap_cur == seg->start ? seg->end: biosmem_heap_cur); } } static void __init biosmem_free_usable_range(phys_addr_t start, phys_addr_t end) { struct vm_page *page; printk("biosmem: release to vm_page: %llx-%llx (%lluk)\n", (unsigned long long)start, (unsigned long long)end, (unsigned long long)((end - start) >> 10)); while (start < end) { page = vm_page_lookup_pa(start); assert(page != NULL); vm_page_manage(page); start += PAGE_SIZE; } } static void __init biosmem_free_usable_update_start(phys_addr_t *start, phys_addr_t res_start, phys_addr_t res_end) { if ((*start >= res_start) && (*start < res_end)) *start = res_end; } static phys_addr_t __init biosmem_free_usable_start(phys_addr_t start) { const struct biosmem_segment *seg; unsigned int i; biosmem_free_usable_update_start(&start, (unsigned long)&_boot, BOOT_VTOP((unsigned long)&_end)); biosmem_free_usable_update_start(&start, biosmem_heap_start, biosmem_heap_end); for (i = 0; i < ARRAY_SIZE(biosmem_segments); i++) { seg = &biosmem_segments[i]; biosmem_free_usable_update_start(&start, seg->avail_start, seg->avail_end); } return start; } static int __init biosmem_free_usable_reserved(phys_addr_t addr) { const struct biosmem_segment *seg; unsigned int i; if ((addr >= (unsigned long)&_boot) && (addr < BOOT_VTOP((unsigned long)&_end))) return 1; if ((addr >= biosmem_heap_start) && (addr < biosmem_heap_end)) return 1; for (i = 0; i < ARRAY_SIZE(biosmem_segments); i++) { seg = &biosmem_segments[i]; if ((addr >= seg->avail_start) && (addr < seg->avail_end)) return 1; } return 0; } static phys_addr_t __init biosmem_free_usable_end(phys_addr_t start, phys_addr_t entry_end) { while (start < entry_end) { if (biosmem_free_usable_reserved(start)) break; start += PAGE_SIZE; } return start; } static void __init biosmem_free_usable_entry(phys_addr_t start, phys_addr_t end) { phys_addr_t entry_end; entry_end = end; for (;;) { start = biosmem_free_usable_start(start); if (start >= entry_end) return; end = biosmem_free_usable_end(start, entry_end); biosmem_free_usable_range(start, end); start = end; } } void __init biosmem_free_usable(void) { struct biosmem_map_entry *entry; uint64_t start, end; unsigned int i; for (i = 0; i < biosmem_map_size; i++) { entry = &biosmem_map[i]; if (entry->type != BIOSMEM_TYPE_AVAILABLE) continue; start = vm_page_round(entry->base_addr); if (start >= VM_PAGE_HIGHMEM_LIMIT) break; end = vm_page_trunc(entry->base_addr + entry->length); if (start < BIOSMEM_BASE) start = BIOSMEM_BASE; biosmem_free_usable_entry(start, end); } }