// Post memory manager (PMM) calls // // Copyright (C) 2009 Kevin O'Connor // // This file may be distributed under the terms of the GNU LGPLv3 license. #include "biosvar.h" // GET_BDA #include "config.h" // BUILD_BIOS_ADDR #include "list.h" // hlist_node #include "malloc.h" // _malloc #include "memmap.h" // struct e820entry #include "output.h" // dprintf #include "stacks.h" // wait_preempt #include "std/optionrom.h" // OPTION_ROM_ALIGN #include "string.h" // memset // Information on a reserved area. struct allocinfo_s { struct hlist_node node; void *data, *dataend, *allocend; }; // Information on a tracked memory allocation. struct allocdetail_s { struct allocinfo_s detailinfo; struct allocinfo_s datainfo; u32 handle; }; // The various memory zones. struct zone_s { struct hlist_head head; }; struct zone_s ZoneLow VARVERIFY32INIT, ZoneHigh VARVERIFY32INIT; struct zone_s ZoneFSeg VARVERIFY32INIT; struct zone_s ZoneTmpLow VARVERIFY32INIT, ZoneTmpHigh VARVERIFY32INIT; static struct zone_s *Zones[] VARVERIFY32INIT = { &ZoneTmpLow, &ZoneLow, &ZoneFSeg, &ZoneTmpHigh, &ZoneHigh }; /**************************************************************** * low-level memory reservations ****************************************************************/ // Find and reserve space from a given zone static void * allocSpace(struct zone_s *zone, u32 size, u32 align, struct allocinfo_s *fill) { struct allocinfo_s *info; hlist_for_each_entry(info, &zone->head, node) { void *dataend = info->dataend; void *allocend = info->allocend; void *newallocend = (void*)ALIGN_DOWN((u32)allocend - size, align); if (newallocend >= dataend && newallocend <= allocend) { // Found space - now reserve it. if (!fill) fill = newallocend; fill->data = newallocend; fill->dataend = newallocend + size; fill->allocend = allocend; info->allocend = newallocend; hlist_add_before(&fill->node, &info->node); return newallocend; } } return NULL; } // Release space allocated with allocSpace() static void freeSpace(struct allocinfo_s *info) { struct allocinfo_s *next = container_of_or_null( info->node.next, struct allocinfo_s, node); if (next && next->allocend == info->data) next->allocend = info->allocend; hlist_del(&info->node); } // Add new memory to a zone static void addSpace(struct zone_s *zone, void *start, void *end) { // Find position to add space struct allocinfo_s *info; struct hlist_node **pprev; hlist_for_each_entry_pprev(info, pprev, &zone->head, node) { if (info->data < start) break; } // Add space using temporary allocation info. struct allocdetail_s tempdetail; tempdetail.datainfo.data = tempdetail.datainfo.dataend = start; tempdetail.datainfo.allocend = end; hlist_add(&tempdetail.datainfo.node, pprev); // Allocate final allocation info. struct allocdetail_s *detail = allocSpace( &ZoneTmpHigh, sizeof(*detail), MALLOC_MIN_ALIGN, NULL); if (!detail) { detail = allocSpace(&ZoneTmpLow, sizeof(*detail) , MALLOC_MIN_ALIGN, NULL); if (!detail) { hlist_del(&tempdetail.datainfo.node); warn_noalloc(); return; } } // Replace temp alloc space with final alloc space pprev = tempdetail.datainfo.node.pprev; hlist_del(&tempdetail.datainfo.node); memcpy(&detail->datainfo, &tempdetail.datainfo, sizeof(detail->datainfo)); detail->handle = MALLOC_DEFAULT_HANDLE; hlist_add(&detail->datainfo.node, pprev); } // Search all zones for an allocation obtained from allocSpace() static struct allocinfo_s * findAlloc(void *data) { int i; for (i=0; ihead, node) { if (info->data == data) return info; } } return NULL; } // Return the last sentinal node of a zone static struct allocinfo_s * findLast(struct zone_s *zone) { struct allocinfo_s *info, *last = NULL; hlist_for_each_entry(info, &zone->head, node) { last = info; } return last; } /**************************************************************** * ebda movement ****************************************************************/ // Move ebda static int relocate_ebda(u32 newebda, u32 oldebda, u8 ebda_size) { u32 lowram = GET_BDA(mem_size_kb) * 1024; if (oldebda != lowram) // EBDA isn't at end of ram - give up. return -1; // Do copy memmove((void*)newebda, (void*)oldebda, ebda_size * 1024); // Update indexes dprintf(1, "ebda moved from %x to %x\n", oldebda, newebda); SET_BDA(mem_size_kb, newebda / 1024); SET_BDA(ebda_seg, FLATPTR_TO_SEG(newebda)); return 0; } // Support expanding the ZoneLow dynamically. static void * zonelow_expand(u32 size, u32 align, struct allocinfo_s *fill) { // Make sure to not move ebda while an optionrom is running. if (unlikely(wait_preempt())) { void *data = allocSpace(&ZoneLow, size, align, fill); if (data) return data; } struct allocinfo_s *info = findLast(&ZoneLow); if (!info) return NULL; u32 oldpos = (u32)info->allocend; u32 newpos = ALIGN_DOWN(oldpos - size, align); u32 bottom = (u32)info->dataend; if (newpos >= bottom && newpos <= oldpos) // Space already present. return allocSpace(&ZoneLow, size, align, fill); u16 ebda_seg = get_ebda_seg(); u32 ebda_pos = (u32)MAKE_FLATPTR(ebda_seg, 0); u8 ebda_size = GET_EBDA(ebda_seg, size); u32 ebda_end = ebda_pos + ebda_size * 1024; if (ebda_end != bottom) // Something else is after ebda - can't use any existing space. newpos = ALIGN_DOWN(ebda_end - size, align); u32 newbottom = ALIGN_DOWN(newpos, 1024); u32 newebda = ALIGN_DOWN(newbottom - ebda_size * 1024, 1024); if (newebda < BUILD_EBDA_MINIMUM) // Not enough space. return NULL; // Move ebda int ret = relocate_ebda(newebda, ebda_pos, ebda_size); if (ret) return NULL; // Update zone if (ebda_end == bottom) { info->data = (void*)newbottom; info->dataend = (void*)newbottom; } else addSpace(&ZoneLow, (void*)newbottom, (void*)ebda_end); return allocSpace(&ZoneLow, size, align, fill); } /**************************************************************** * tracked memory allocations ****************************************************************/ // Allocate memory from the given zone and track it as a PMM allocation void * __malloc _malloc(struct zone_s *zone, u32 handle, u32 size, u32 align) { ASSERT32FLAT(); if (!size) return NULL; // Find and reserve space for bookkeeping. struct allocdetail_s *detail = allocSpace( &ZoneTmpHigh, sizeof(*detail), MALLOC_MIN_ALIGN, NULL); if (!detail) { detail = allocSpace(&ZoneTmpLow, sizeof(*detail) , MALLOC_MIN_ALIGN, NULL); if (!detail) return NULL; } // Find and reserve space for main allocation void *data = allocSpace(zone, size, align, &detail->datainfo); if (!CONFIG_MALLOC_UPPERMEMORY && !data && zone == &ZoneLow) data = zonelow_expand(size, align, &detail->datainfo); if (!data) { freeSpace(&detail->detailinfo); return NULL; } dprintf(8, "_malloc zone=%p handle=%x size=%d align=%x ret=%p (detail=%p)\n" , zone, handle, size, align, data, detail); detail->handle = handle; return data; } // Free a data block allocated with _malloc int _free(void *data) { ASSERT32FLAT(); struct allocinfo_s *info = findAlloc(data); if (!info || data == (void*)info || data == info->dataend) return -1; struct allocdetail_s *detail = container_of( info, struct allocdetail_s, datainfo); dprintf(8, "_free %p (detail=%p)\n", data, detail); freeSpace(info); freeSpace(&detail->detailinfo); return 0; } // Find the amount of free space in a given zone. u32 malloc_getspace(struct zone_s *zone) { // XXX - doesn't account for ZoneLow being able to grow. // XXX - results not reliable when CONFIG_THREAD_OPTIONROMS u32 maxspace = 0; struct allocinfo_s *info; hlist_for_each_entry(info, &zone->head, node) { u32 space = info->allocend - info->dataend; if (space > maxspace) maxspace = space; } if (zone != &ZoneTmpHigh && zone != &ZoneTmpLow) return maxspace; // Account for space needed for PMM tracking. u32 reserve = ALIGN(sizeof(struct allocdetail_s), MALLOC_MIN_ALIGN); if (maxspace <= reserve) return 0; return maxspace - reserve; } // Find the data block allocated with _malloc with a given handle. void * malloc_find(u32 handle) { int i; for (i=0; ihead, node) { if (info->data != (void*)info) continue; struct allocdetail_s *detail = container_of( info, struct allocdetail_s, detailinfo); if (detail->handle == handle) return detail->datainfo.data; } } return NULL; } /**************************************************************** * 0xc0000-0xf0000 management ****************************************************************/ static u32 RomEnd = BUILD_ROM_START; static struct allocinfo_s *RomBase; #define OPROM_HEADER_RESERVE 16 // Return the maximum memory position option roms may use. u32 rom_get_max(void) { if (CONFIG_MALLOC_UPPERMEMORY) return ALIGN_DOWN((u32)RomBase->allocend - OPROM_HEADER_RESERVE , OPTION_ROM_ALIGN); extern u8 code32init_end[]; u32 end = (u32)code32init_end; return end > BUILD_BIOS_ADDR ? BUILD_BIOS_ADDR : end; } // Return the end of the last deployed option rom. u32 rom_get_last(void) { return RomEnd; } // Request space for an optionrom in 0xc0000-0xf0000 area. struct rom_header * rom_reserve(u32 size) { u32 newend = ALIGN(RomEnd + size, OPTION_ROM_ALIGN); if (newend > rom_get_max()) return NULL; if (CONFIG_MALLOC_UPPERMEMORY) { if (newend < (u32)zonelow_base) newend = (u32)zonelow_base; RomBase->data = RomBase->dataend = (void*)newend + OPROM_HEADER_RESERVE; } return (void*)RomEnd; } // Confirm space as in use by an optionrom. int rom_confirm(u32 size) { void *new = rom_reserve(size); if (!new) { warn_noalloc(); return -1; } RomEnd = ALIGN(RomEnd + size, OPTION_ROM_ALIGN); return 0; } /**************************************************************** * Setup ****************************************************************/ void malloc_preinit(void) { ASSERT32FLAT(); dprintf(3, "malloc preinit\n"); // Don't declare any memory between 0xa0000 and 0x100000 add_e820(BUILD_LOWRAM_END, BUILD_BIOS_ADDR-BUILD_LOWRAM_END, E820_HOLE); // Mark known areas as reserved. add_e820(BUILD_BIOS_ADDR, BUILD_BIOS_SIZE, E820_RESERVED); // Populate temp high ram u32 highram = 0; int i; for (i=e820_count-1; i>=0; i--) { struct e820entry *en = &e820_list[i]; u64 end = en->start + en->size; if (end < 1024*1024) break; if (en->type != E820_RAM || end > 0xffffffff) continue; u32 s = en->start, e = end; if (!highram) { u32 newe = ALIGN_DOWN(e - BUILD_MAX_HIGHTABLE, MALLOC_MIN_ALIGN); if (newe <= e && newe >= s) { highram = newe; e = newe; } } addSpace(&ZoneTmpHigh, (void*)s, (void*)e); } // Populate regions addSpace(&ZoneTmpLow, (void*)BUILD_STACK_ADDR, (void*)BUILD_EBDA_MINIMUM); if (highram) { addSpace(&ZoneHigh, (void*)highram , (void*)highram + BUILD_MAX_HIGHTABLE); add_e820(highram, BUILD_MAX_HIGHTABLE, E820_RESERVED); } } void csm_malloc_preinit(u32 low_pmm, u32 low_pmm_size, u32 hi_pmm, u32 hi_pmm_size) { ASSERT32FLAT(); if (hi_pmm_size > BUILD_MAX_HIGHTABLE) { void *hi_pmm_end = (void *)hi_pmm + hi_pmm_size; addSpace(&ZoneTmpHigh, (void *)hi_pmm, hi_pmm_end - BUILD_MAX_HIGHTABLE); addSpace(&ZoneHigh, hi_pmm_end - BUILD_MAX_HIGHTABLE, hi_pmm_end); } else { addSpace(&ZoneTmpHigh, (void *)hi_pmm, (void *)hi_pmm + hi_pmm_size); } addSpace(&ZoneTmpLow, (void *)low_pmm, (void *)low_pmm + low_pmm_size); } u32 LegacyRamSize VARFSEG; // Calculate the maximum ramsize (less than 4gig) from e820 map. static void calcRamSize(void) { u32 rs = 0; int i; for (i=e820_count-1; i>=0; i--) { struct e820entry *en = &e820_list[i]; u64 end = en->start + en->size; u32 type = en->type; if (end <= 0xffffffff && (type == E820_ACPI || type == E820_RAM)) { rs = end; break; } } LegacyRamSize = rs >= 1024*1024 ? rs : 1024*1024; } // Update pointers after code relocation. void malloc_init(void) { ASSERT32FLAT(); dprintf(3, "malloc init\n"); if (CONFIG_RELOCATE_INIT) { // Fixup malloc pointers after relocation int i; for (i=0; ihead.first) zone->head.first->pprev = &zone->head.first; } } // Initialize low-memory region extern u8 varlow_start[], varlow_end[], final_varlow_start[]; memmove(final_varlow_start, varlow_start, varlow_end - varlow_start); if (CONFIG_MALLOC_UPPERMEMORY) { addSpace(&ZoneLow, zonelow_base + OPROM_HEADER_RESERVE , final_varlow_start); RomBase = findLast(&ZoneLow); } else { addSpace(&ZoneLow, (void*)ALIGN_DOWN((u32)final_varlow_start, 1024) , final_varlow_start); } // Add space available in f-segment to ZoneFSeg extern u8 zonefseg_start[], zonefseg_end[]; memset(zonefseg_start, 0, zonefseg_end - zonefseg_start); addSpace(&ZoneFSeg, zonefseg_start, zonefseg_end); calcRamSize(); } void malloc_prepboot(void) { ASSERT32FLAT(); dprintf(3, "malloc finalize\n"); u32 base = rom_get_max(); memset((void*)RomEnd, 0, base-RomEnd); if (CONFIG_MALLOC_UPPERMEMORY) { // Place an optionrom signature around used low mem area. struct rom_header *dummyrom = (void*)base; dummyrom->signature = OPTION_ROM_SIGNATURE; int size = (BUILD_BIOS_ADDR - base) / 512; dummyrom->size = (size > 255) ? 255 : size; } // Reserve more low-mem if needed. u32 endlow = GET_BDA(mem_size_kb)*1024; add_e820(endlow, BUILD_LOWRAM_END-endlow, E820_RESERVED); // Clear unused f-seg ram. struct allocinfo_s *info = findLast(&ZoneFSeg); memset(info->dataend, 0, info->allocend - info->dataend); dprintf(1, "Space available for UMB: %x-%x, %x-%x\n" , RomEnd, base, (u32)info->dataend, (u32)info->allocend); // Give back unused high ram. info = findLast(&ZoneHigh); if (info) { u32 giveback = ALIGN_DOWN(info->allocend - info->dataend, PAGE_SIZE); add_e820((u32)info->dataend, giveback, E820_RAM); dprintf(1, "Returned %d bytes of ZoneHigh\n", giveback); } calcRamSize(); }