stand/efiboot/efimemory.c

1.5.2.1  martin /*	$NetBSD: efimemory.c,v 1.5.2.1 2020/04/13 08:03:54 martin Exp $	*/
    1.1  nonaka
    1.1  nonaka /*-
    1.1  nonaka  * Copyright (c) 2016 Kimihiro Nonaka <nonaka (at) netbsd.org>
    1.1  nonaka  * All rights reserved.
    1.1  nonaka  *
    1.1  nonaka  * Redistribution and use in source and binary forms, with or without
    1.1  nonaka  * modification, are permitted provided that the following conditions
    1.1  nonaka  * are met:
    1.1  nonaka  * 1. Redistributions of source code must retain the above copyright
    1.1  nonaka  *    notice, this list of conditions and the following disclaimer.
    1.1  nonaka  * 2. Redistributions in binary form must reproduce the above copyright
    1.1  nonaka  *    notice, this list of conditions and the following disclaimer in the
    1.1  nonaka  *    documentation and/or other materials provided with the distribution.
    1.1  nonaka  *
    1.1  nonaka  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
    1.1  nonaka  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
    1.1  nonaka  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
    1.1  nonaka  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
    1.1  nonaka  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
    1.1  nonaka  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
    1.1  nonaka  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
    1.1  nonaka  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
    1.1  nonaka  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
    1.1  nonaka  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
    1.1  nonaka  * SUCH DAMAGE.
    1.1  nonaka  */
    1.1  nonaka
    1.1  nonaka #include "efiboot.h"
    1.1  nonaka
    1.1  nonaka #include <bootinfo.h>
    1.1  nonaka
1.5.2.1  martin static const char *efi_memory_type[] = {
1.5.2.1  martin 	[EfiReservedMemoryType]		= "Reserved Memory Type",
1.5.2.1  martin 	[EfiLoaderCode]			= "Loader Code",
1.5.2.1  martin 	[EfiLoaderData]			= "Loader Data",
1.5.2.1  martin 	[EfiBootServicesCode]		= "Boot Services Code",
1.5.2.1  martin 	[EfiBootServicesData]		= "Boot Services Data",
1.5.2.1  martin 	[EfiRuntimeServicesCode]	= "Runtime Services Code",
1.5.2.1  martin 	[EfiRuntimeServicesData]	= "Runtime Services Data",
1.5.2.1  martin 	[EfiConventionalMemory]		= "Conventional Memory",
1.5.2.1  martin 	[EfiUnusableMemory]		= "Unusable Memory",
1.5.2.1  martin 	[EfiACPIReclaimMemory]		= "ACPI Reclaim Memory",
1.5.2.1  martin 	[EfiACPIMemoryNVS]		= "ACPI Memory NVS",
1.5.2.1  martin 	[EfiMemoryMappedIO]		= "MMIO",
1.5.2.1  martin 	[EfiMemoryMappedIOPortSpace]	= "MMIO (Port Space)",
1.5.2.1  martin 	[EfiPalCode]			= "Pal Code",
1.5.2.1  martin 	[EfiPersistentMemory]		= "Persistent Memory",
    1.1  nonaka };
    1.1  nonaka
1.5.2.1  martin #ifndef KERN_LOADSPACE_SIZE
1.5.2.1  martin #define KERN_LOADSPACE_SIZE	(128 * 1024 * 1024)	/* 128MiB */
1.5.2.1  martin #endif
    1.1  nonaka
    1.1  nonaka static int
    1.1  nonaka getmemtype(EFI_MEMORY_DESCRIPTOR *md)
    1.1  nonaka {
    1.1  nonaka
    1.1  nonaka 	switch (md->Type) {
    1.1  nonaka 	case EfiLoaderCode:
    1.1  nonaka 	case EfiLoaderData:
    1.1  nonaka 	case EfiBootServicesCode:
    1.1  nonaka 	case EfiBootServicesData:
    1.1  nonaka 	case EfiConventionalMemory:
    1.1  nonaka 		return (md->Attribute & EFI_MEMORY_WB) ?
    1.1  nonaka 		    BIM_Memory : BIM_Reserved;
    1.1  nonaka
    1.1  nonaka 	case EfiACPIReclaimMemory:
    1.1  nonaka 		return BIM_ACPI;
    1.1  nonaka
    1.1  nonaka 	case EfiACPIMemoryNVS:
    1.1  nonaka 		return BIM_NVS;
    1.1  nonaka
    1.4  nonaka 	case EfiPersistentMemory:
    1.4  nonaka 		return BIM_PMEM;
    1.4  nonaka
    1.1  nonaka 	case EfiReservedMemoryType:
    1.1  nonaka 	case EfiRuntimeServicesCode:
    1.1  nonaka 	case EfiRuntimeServicesData:
    1.1  nonaka 	case EfiUnusableMemory:
    1.1  nonaka 	case EfiMemoryMappedIO:
    1.1  nonaka 	case EfiMemoryMappedIOPortSpace:
    1.1  nonaka 	case EfiPalCode:
    1.1  nonaka 	case EfiMaxMemoryType:
    1.4  nonaka 	default:
    1.1  nonaka 		return BIM_Reserved;
    1.1  nonaka 	}
    1.1  nonaka }
    1.1  nonaka
    1.3  nonaka EFI_MEMORY_DESCRIPTOR *
    1.3  nonaka efi_memory_get_map(UINTN *NoEntries, UINTN *MapKey, UINTN *DescriptorSize,
    1.3  nonaka     UINT32 *DescriptorVersion, bool sorted)
    1.1  nonaka {
1.5.2.1  martin 	EFI_MEMORY_DESCRIPTOR *desc, *md, *next, *target, *tmp;
    1.1  nonaka 	UINTN i, j;
    1.1  nonaka
    1.1  nonaka 	*NoEntries = 0;
    1.1  nonaka 	desc = LibMemoryMap(NoEntries, MapKey, DescriptorSize,
    1.1  nonaka 	    DescriptorVersion);
    1.1  nonaka 	if (desc == NULL)
    1.5  nonaka 		panic("efi_memory_get_map failed");
    1.1  nonaka
    1.1  nonaka 	if (!sorted)
    1.1  nonaka 		return desc;
    1.1  nonaka
1.5.2.1  martin 	tmp = alloc(*DescriptorSize);
1.5.2.1  martin 	if (tmp == NULL)
1.5.2.1  martin 		return desc;
1.5.2.1  martin
    1.1  nonaka 	for (i = 0, md = desc; i < *NoEntries - 1; i++, md = next) {
    1.1  nonaka 		target = next = NextMemoryDescriptor(md, *DescriptorSize);
    1.1  nonaka 		for (j = i + 1; j < *NoEntries; j++) {
    1.1  nonaka 			if (md->PhysicalStart > target->PhysicalStart) {
1.5.2.1  martin 				CopyMem(tmp, md, *DescriptorSize);
1.5.2.1  martin 				CopyMem(md, target, *DescriptorSize);
1.5.2.1  martin 				CopyMem(target, tmp, *DescriptorSize);
    1.1  nonaka 			}
    1.1  nonaka 			target = NextMemoryDescriptor(target, *DescriptorSize);
    1.1  nonaka 		}
    1.1  nonaka 	}
1.5.2.1  martin 	dealloc(tmp, *DescriptorSize);
1.5.2.1  martin
    1.1  nonaka 	return desc;
    1.1  nonaka }
    1.1  nonaka
1.5.2.1  martin EFI_MEMORY_DESCRIPTOR *
1.5.2.1  martin efi_memory_compact_map(EFI_MEMORY_DESCRIPTOR *desc, UINTN *NoEntries,
1.5.2.1  martin     UINTN DescriptorSize)
1.5.2.1  martin {
1.5.2.1  martin 	EFI_MEMORY_DESCRIPTOR *md, *next, *target, *tmp;
1.5.2.1  martin 	UINTN i, j;
1.5.2.1  martin 	UINT32 type;
1.5.2.1  martin 	bool first = true, do_compact;
1.5.2.1  martin
1.5.2.1  martin 	for (i = 0, md = target = desc; i < *NoEntries; i++, md = next) {
1.5.2.1  martin 		type = md->Type;
1.5.2.1  martin 		switch (type) {
1.5.2.1  martin 		case EfiLoaderCode:
1.5.2.1  martin 		case EfiLoaderData:
1.5.2.1  martin 		case EfiBootServicesCode:
1.5.2.1  martin 		case EfiBootServicesData:
1.5.2.1  martin 		case EfiConventionalMemory:
1.5.2.1  martin 			if ((md->Attribute & EFI_MEMORY_WB) != 0)
1.5.2.1  martin 				type = EfiConventionalMemory;
1.5.2.1  martin 			if (md->Attribute == target->Attribute) {
1.5.2.1  martin 				do_compact = true;
1.5.2.1  martin 				break;
1.5.2.1  martin 			}
1.5.2.1  martin 			/* FALLTHROUGH */
1.5.2.1  martin 		case EfiACPIReclaimMemory:
1.5.2.1  martin 		case EfiACPIMemoryNVS:
1.5.2.1  martin 		case EfiPersistentMemory:
1.5.2.1  martin 		case EfiReservedMemoryType:
1.5.2.1  martin 		case EfiRuntimeServicesCode:
1.5.2.1  martin 		case EfiRuntimeServicesData:
1.5.2.1  martin 		case EfiUnusableMemory:
1.5.2.1  martin 		case EfiMemoryMappedIO:
1.5.2.1  martin 		case EfiMemoryMappedIOPortSpace:
1.5.2.1  martin 		case EfiPalCode:
1.5.2.1  martin 		default:
1.5.2.1  martin 			do_compact = false;
1.5.2.1  martin 			break;
1.5.2.1  martin 		}
1.5.2.1  martin
1.5.2.1  martin 		if (first) {
1.5.2.1  martin 			first = false;
1.5.2.1  martin 		} else if (do_compact &&
1.5.2.1  martin 		    type == target->Type &&
1.5.2.1  martin 		    md->Attribute == target->Attribute &&
1.5.2.1  martin 		    md->PhysicalStart == target->PhysicalStart + target->NumberOfPages * EFI_PAGE_SIZE) {
1.5.2.1  martin 			/* continuous region */
1.5.2.1  martin 			target->NumberOfPages += md->NumberOfPages;
1.5.2.1  martin
1.5.2.1  martin 			tmp = md;
1.5.2.1  martin 			for (j = i + 1; j < *NoEntries; j++) {
1.5.2.1  martin 				next = NextMemoryDescriptor(md, DescriptorSize);
1.5.2.1  martin 				CopyMem(md, next, DescriptorSize);
1.5.2.1  martin 				md = next;
1.5.2.1  martin 			}
1.5.2.1  martin 			next = tmp;
1.5.2.1  martin
1.5.2.1  martin 			i--;
1.5.2.1  martin 			(*NoEntries)--;
1.5.2.1  martin 			continue;
1.5.2.1  martin 		} else {
1.5.2.1  martin 			target = md;
1.5.2.1  martin 		}
1.5.2.1  martin
1.5.2.1  martin 		target->Type = type;
1.5.2.1  martin 		next = NextMemoryDescriptor(md, DescriptorSize);
1.5.2.1  martin 	}
1.5.2.1  martin
1.5.2.1  martin 	return desc;
1.5.2.1  martin }
1.5.2.1  martin
1.5.2.1  martin int
1.5.2.1  martin efi_memory_get_memmap(struct bi_memmap_entry **memmapp, size_t *num)
1.5.2.1  martin {
1.5.2.1  martin 	EFI_STATUS status;
1.5.2.1  martin 	EFI_MEMORY_DESCRIPTOR *mdtop, *md, *next;
1.5.2.1  martin 	UINTN i, NoEntries, MapKey, DescriptorSize;
1.5.2.1  martin 	UINT32 DescriptorVersion;
1.5.2.1  martin 	UINTN cols, rows;
1.5.2.1  martin 	struct bi_memmap_entry *memmap;
1.5.2.1  martin
1.5.2.1  martin 	status = uefi_call_wrapper(ST->ConOut->QueryMode, 4, ST->ConOut,
1.5.2.1  martin 	    ST->ConOut->Mode->Mode, &cols, &rows);
1.5.2.1  martin 	if (EFI_ERROR(status) || rows <= 2)
1.5.2.1  martin 		return -1;
1.5.2.1  martin
1.5.2.1  martin 	mdtop = efi_memory_get_map(&NoEntries, &MapKey, &DescriptorSize,
1.5.2.1  martin 	    &DescriptorVersion, true);
1.5.2.1  martin 	efi_memory_compact_map(mdtop, &NoEntries, DescriptorSize);
1.5.2.1  martin
1.5.2.1  martin 	memmap = alloc(sizeof(*memmap) * NoEntries);
1.5.2.1  martin
1.5.2.1  martin 	for (i = 0, md = mdtop; i < NoEntries; i++, md = next) {
1.5.2.1  martin 		memmap[i].addr = md->PhysicalStart;
1.5.2.1  martin 		memmap[i].size = md->NumberOfPages * EFI_PAGE_SIZE;
1.5.2.1  martin 		memmap[i].type = getmemtype(md);
1.5.2.1  martin
1.5.2.1  martin 		next = NextMemoryDescriptor(md, DescriptorSize);
1.5.2.1  martin 	}
1.5.2.1  martin
1.5.2.1  martin 	*memmapp = memmap;
1.5.2.1  martin 	*num = NoEntries;
1.5.2.1  martin 	return 0;
1.5.2.1  martin }
1.5.2.1  martin
    1.1  nonaka /*
    1.1  nonaka  * get memory size below 1MB
    1.1  nonaka  */
    1.1  nonaka int
    1.1  nonaka getbasemem(void)
    1.1  nonaka {
    1.1  nonaka 	EFI_MEMORY_DESCRIPTOR *mdtop, *md, *next;
    1.1  nonaka 	UINTN i, NoEntries, MapKey, DescriptorSize, MappingSize;
    1.1  nonaka 	UINT32 DescriptorVersion;
    1.1  nonaka 	EFI_PHYSICAL_ADDRESS basemem = 0, epa;
    1.1  nonaka
    1.3  nonaka 	mdtop = efi_memory_get_map(&NoEntries, &MapKey, &DescriptorSize,
    1.1  nonaka 	    &DescriptorVersion, true);
    1.1  nonaka
    1.1  nonaka 	for (i = 0, md = mdtop; i < NoEntries; i++, md = next) {
    1.1  nonaka 		next = NextMemoryDescriptor(md, DescriptorSize);
    1.1  nonaka 		if (getmemtype(md) != BIM_Memory)
    1.1  nonaka 			continue;
    1.1  nonaka 		if (md->PhysicalStart >= 1 * 1024 * 1024)
    1.1  nonaka 			continue;
    1.1  nonaka 		if (basemem != md->PhysicalStart)
    1.1  nonaka 			continue;
    1.1  nonaka
    1.1  nonaka 		MappingSize = md->NumberOfPages * EFI_PAGE_SIZE;
    1.1  nonaka 		epa = md->PhysicalStart + MappingSize;
    1.1  nonaka 		if (epa == 0 || epa > 1 * 1024 * 1024)
    1.1  nonaka 			epa = 1 * 1024 * 1024;
    1.1  nonaka 		basemem = epa;
    1.1  nonaka 	}
    1.1  nonaka
    1.1  nonaka 	FreePool(mdtop);
    1.1  nonaka
    1.1  nonaka 	return basemem / 1024;	/* KiB */
    1.1  nonaka }
    1.1  nonaka
    1.1  nonaka /*
    1.1  nonaka  * get memory size above 1MB below 4GB
    1.1  nonaka  */
    1.1  nonaka int
    1.1  nonaka getextmemx(void)
    1.1  nonaka {
    1.1  nonaka 	EFI_MEMORY_DESCRIPTOR *mdtop, *md, *next;
    1.1  nonaka 	UINTN i, NoEntries, MapKey, DescriptorSize, MappingSize;
    1.1  nonaka 	UINT32 DescriptorVersion;
    1.1  nonaka 	EFI_PHYSICAL_ADDRESS extmem16m = 0;	/* 0-16MB */
    1.1  nonaka 	EFI_PHYSICAL_ADDRESS extmem4g = 0;	/* 16MB-4GB */
    1.1  nonaka 	EFI_PHYSICAL_ADDRESS pa, epa;
    1.1  nonaka 	bool first16m = true, first4g = true;
    1.1  nonaka 	int extmem;
    1.1  nonaka
    1.3  nonaka 	mdtop = efi_memory_get_map(&NoEntries, &MapKey, &DescriptorSize,
    1.1  nonaka 	    &DescriptorVersion, true);
    1.1  nonaka
    1.1  nonaka 	for (i = 0, md = mdtop; i < NoEntries; i++, md = next) {
    1.1  nonaka 		next = NextMemoryDescriptor(md, DescriptorSize);
    1.1  nonaka 		if (getmemtype(md) == BIM_Reserved)
    1.1  nonaka 			continue;
    1.1  nonaka 		if (md->PhysicalStart >= 4 * 1024 * 1024 * 1024ULL)
    1.1  nonaka 			continue;
    1.1  nonaka
    1.1  nonaka 		MappingSize = md->NumberOfPages * EFI_PAGE_SIZE;
    1.1  nonaka 		epa = md->PhysicalStart + MappingSize;
    1.1  nonaka 		if (epa == 0 || epa > 4 * 1024 * 1024 * 1024LL)
    1.1  nonaka 			epa = 4 * 1024 * 1024 * 1024LL;
    1.1  nonaka
    1.1  nonaka 		if (epa <= 1 * 1024 * 1024)
    1.1  nonaka 			continue;
    1.1  nonaka
    1.1  nonaka 		pa = md->PhysicalStart;
    1.1  nonaka 		if (pa < 16 * 1024 * 1024) {
    1.1  nonaka 			if (first16m || extmem16m == pa) {
    1.1  nonaka 				first16m = false;
    1.1  nonaka 				if (epa >= 16 * 1024 * 1024) {
    1.1  nonaka 					extmem16m = 16 * 1024 * 1024;
    1.1  nonaka 					pa = 16 * 1024 * 1024;
    1.1  nonaka 				} else
    1.1  nonaka 					extmem16m = epa;
    1.1  nonaka 			}
    1.1  nonaka 		}
    1.1  nonaka 		if (pa >= 16 * 1024 * 1024) {
    1.1  nonaka 			if (first4g || extmem4g == pa) {
    1.1  nonaka 				first4g = false;
    1.1  nonaka 				extmem4g = epa;
    1.1  nonaka 			}
    1.1  nonaka 		}
    1.1  nonaka 	}
    1.1  nonaka
    1.1  nonaka 	FreePool(mdtop);
    1.1  nonaka
    1.1  nonaka 	if (extmem16m > 1 * 1024 * 1024)
    1.1  nonaka 		extmem16m -= 1 * 1024 * 1024;	/* below 1MB */
    1.1  nonaka
    1.1  nonaka 	extmem = extmem16m / 1024;
    1.1  nonaka 	if (extmem == 15 * 1024)
    1.1  nonaka 		extmem += extmem4g / 1024;
    1.1  nonaka 	return extmem;
    1.1  nonaka }
    1.1  nonaka
    1.1  nonaka void
    1.1  nonaka efi_memory_probe(void)
    1.1  nonaka {
    1.1  nonaka 	EFI_MEMORY_DESCRIPTOR *mdtop, *md, *next;
1.5.2.1  martin 	EFI_STATUS status;
1.5.2.1  martin 	EFI_PHYSICAL_ADDRESS bouncebuf;
    1.1  nonaka 	UINTN i, n, NoEntries, MapKey, DescriptorSize, MappingSize;
    1.1  nonaka 	UINT32 DescriptorVersion;
    1.1  nonaka 	int memtype;
    1.1  nonaka
1.5.2.1  martin 	bouncebuf = EFI_ALLOCATE_MAX_ADDRESS;
1.5.2.1  martin 	status = uefi_call_wrapper(BS->AllocatePages, 4, AllocateMaxAddress,
1.5.2.1  martin 	    EfiLoaderData, EFI_SIZE_TO_PAGES(KERN_LOADSPACE_SIZE), &bouncebuf);
1.5.2.1  martin 	if (EFI_ERROR(status))
1.5.2.1  martin 		panic("couldn't allocate kernel space.");
1.5.2.1  martin 	efi_loadaddr = bouncebuf;
1.5.2.1  martin
    1.3  nonaka 	mdtop = efi_memory_get_map(&NoEntries, &MapKey, &DescriptorSize,
    1.1  nonaka 	    &DescriptorVersion, false);
    1.5  nonaka 	printf(" mem[");
    1.1  nonaka 	for (i = 0, n = 0, md = mdtop; i < NoEntries; i++, md = next) {
    1.1  nonaka 		next = NextMemoryDescriptor(md, DescriptorSize);
    1.1  nonaka
    1.1  nonaka 		memtype = getmemtype(md);
    1.1  nonaka 		if (memtype != BIM_Memory)
    1.1  nonaka 			continue;
    1.1  nonaka
    1.1  nonaka 		MappingSize = md->NumberOfPages * EFI_PAGE_SIZE;
    1.1  nonaka 		if (MappingSize < 12 * 1024)	/* XXX Why? from OpenBSD */
    1.1  nonaka 			continue;
    1.1  nonaka
    1.1  nonaka 		if (n++ > 0)
    1.5  nonaka 			printf(" ");
    1.5  nonaka 		printf("0x%" PRIxMAX "-0x%" PRIxMAX, (uintmax_t)md->PhysicalStart,
    1.5  nonaka 		    (uintmax_t)(md->PhysicalStart + MappingSize - 1));
    1.1  nonaka 	}
    1.5  nonaka 	printf("]\n");
    1.1  nonaka
    1.1  nonaka 	FreePool(mdtop);
    1.1  nonaka }
    1.1  nonaka
    1.1  nonaka void
1.5.2.1  martin efi_memory_show_map(bool sorted, bool compact)
    1.1  nonaka {
    1.1  nonaka 	EFI_STATUS status;
    1.1  nonaka 	EFI_MEMORY_DESCRIPTOR *mdtop, *md, *next;
    1.1  nonaka 	UINTN i, NoEntries, MapKey, DescriptorSize;
    1.1  nonaka 	UINT32 DescriptorVersion;
1.5.2.1  martin 	char efimemstr[32];
1.5.2.1  martin 	UINTN cols, rows, row;
    1.1  nonaka
    1.1  nonaka 	status = uefi_call_wrapper(ST->ConOut->QueryMode, 4, ST->ConOut,
    1.1  nonaka 	    ST->ConOut->Mode->Mode, &cols, &rows);
    1.1  nonaka 	if (EFI_ERROR(status) || rows <= 2)
    1.1  nonaka 		rows = 0;
    1.1  nonaka 	else
    1.1  nonaka 		rows -= 2;
    1.1  nonaka
    1.3  nonaka 	mdtop = efi_memory_get_map(&NoEntries, &MapKey, &DescriptorSize,
    1.1  nonaka 	    &DescriptorVersion, sorted);
1.5.2.1  martin 	if (compact)
1.5.2.1  martin 		efi_memory_compact_map(mdtop, &NoEntries, DescriptorSize);
1.5.2.1  martin
1.5.2.1  martin 	printf("%-22s  %-16s  %-16s  %-16s\n", "Type", "Start", "End", "Attributes");
1.5.2.1  martin 	printf("----------------------  ----------------  ----------------  ----------------\n");
1.5.2.1  martin 	row = 2;
    1.1  nonaka
    1.1  nonaka 	for (i = 0, md = mdtop; i < NoEntries; i++, md = next) {
    1.1  nonaka 		next = NextMemoryDescriptor(md, DescriptorSize);
    1.1  nonaka
1.5.2.1  martin 		if (md->Type >= __arraycount(efi_memory_type))
    1.1  nonaka 			snprintf(efimemstr, sizeof(efimemstr), "unknown (%d)",
    1.1  nonaka 			    md->Type);
1.5.2.1  martin 		printf("%-22s  %016" PRIxMAX "  %016" PRIxMAX "  %016" PRIxMAX "\n",
1.5.2.1  martin 		    md->Type >= __arraycount(efi_memory_type) ?
1.5.2.1  martin 		      efimemstr : efi_memory_type[md->Type],
    1.1  nonaka 		    (uintmax_t)md->PhysicalStart,
    1.1  nonaka 		    (uintmax_t)md->PhysicalStart +
    1.1  nonaka 		      md->NumberOfPages * EFI_PAGE_SIZE - 1,
1.5.2.1  martin 		    (uintmax_t)md->Attribute);
    1.1  nonaka
    1.2     roy 		if (++row >= rows) {
    1.1  nonaka 			row = 0;
    1.5  nonaka 			printf("Press Any Key to continue :");
    1.1  nonaka 			(void) awaitkey(-1, 0);
    1.5  nonaka 			printf("\n");
    1.1  nonaka 		}
    1.1  nonaka 	}
    1.1  nonaka
    1.1  nonaka 	FreePool(mdtop);
    1.1  nonaka }
    1.1  nonaka
    1.1  nonaka void
    1.1  nonaka vpbcopy(const void *va, void *pa, size_t n)
    1.1  nonaka {
    1.1  nonaka 	memmove(pa, va, n);
    1.1  nonaka }
    1.1  nonaka
    1.1  nonaka void
    1.1  nonaka pvbcopy(const void *pa, void *va, size_t n)
    1.1  nonaka {
    1.1  nonaka 	memmove(va, pa, n);
    1.1  nonaka }
    1.1  nonaka
    1.1  nonaka void
    1.1  nonaka pbzero(void *pa, size_t n)
    1.1  nonaka {
    1.1  nonaka 	memset(pa, 0, n);
    1.1  nonaka }
    1.1  nonaka
    1.1  nonaka physaddr_t
    1.1  nonaka vtophys(void *va)
    1.1  nonaka {
    1.1  nonaka 	return (physaddr_t)va;
    1.1  nonaka }