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pe.c
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pe.c
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// SPDX-License-Identifier: BSD-2-Clause-Patent
/*
* pe.c - helper functions for pe binaries.
* Copyright Peter Jones <pjones@redhat.com>
*/
#include "shim.h"
#include <openssl/err.h>
#include <openssl/bn.h>
#include <openssl/dh.h>
#include <openssl/ocsp.h>
#include <openssl/pkcs12.h>
#include <openssl/rand.h>
#include <openssl/crypto.h>
#include <openssl/ssl.h>
#include <openssl/x509.h>
#include <openssl/x509v3.h>
#include <openssl/rsa.h>
#include <openssl/dso.h>
#include <Library/BaseCryptLib.h>
#define check_size_line(data, datasize_in, hashbase, hashsize, l) ({ \
if ((unsigned long)hashbase > \
(unsigned long)data + datasize_in) { \
efi_status = EFI_INVALID_PARAMETER; \
perror(L"shim.c:%d Invalid hash base 0x%016x\n", l, \
hashbase); \
goto done; \
} \
if ((unsigned long)hashbase + hashsize > \
(unsigned long)data + datasize_in) { \
efi_status = EFI_INVALID_PARAMETER; \
perror(L"shim.c:%d Invalid hash size 0x%016x\n", l, \
hashsize); \
goto done; \
} \
})
#define check_size(d, ds, h, hs) check_size_line(d, ds, h, hs, __LINE__)
/*
* Calculate the SHA1 and SHA256 hashes of a binary
*/
EFI_STATUS
generate_hash(char *data, unsigned int datasize,
PE_COFF_LOADER_IMAGE_CONTEXT *context, UINT8 *sha256hash,
UINT8 *sha1hash)
{
unsigned int sha256ctxsize, sha1ctxsize;
void *sha256ctx = NULL, *sha1ctx = NULL;
char *hashbase;
unsigned int hashsize;
unsigned int SumOfBytesHashed, SumOfSectionBytes;
unsigned int index, pos;
EFI_IMAGE_SECTION_HEADER *Section;
EFI_IMAGE_SECTION_HEADER *SectionHeader = NULL;
EFI_STATUS efi_status = EFI_SUCCESS;
EFI_IMAGE_DOS_HEADER *DosHdr = (void *)data;
unsigned int PEHdr_offset = 0;
if (datasize <= sizeof (*DosHdr) ||
DosHdr->e_magic != EFI_IMAGE_DOS_SIGNATURE) {
perror(L"Invalid signature\n");
return EFI_INVALID_PARAMETER;
}
PEHdr_offset = DosHdr->e_lfanew;
sha256ctxsize = Sha256GetContextSize();
sha256ctx = AllocatePool(sha256ctxsize);
sha1ctxsize = Sha1GetContextSize();
sha1ctx = AllocatePool(sha1ctxsize);
if (!sha256ctx || !sha1ctx) {
perror(L"Unable to allocate memory for hash context\n");
return EFI_OUT_OF_RESOURCES;
}
if (!Sha256Init(sha256ctx) || !Sha1Init(sha1ctx)) {
perror(L"Unable to initialise hash\n");
efi_status = EFI_OUT_OF_RESOURCES;
goto done;
}
/* Hash start to checksum */
hashbase = data;
hashsize = (char *)&context->PEHdr->Pe32.OptionalHeader.CheckSum -
hashbase;
check_size(data, datasize, hashbase, hashsize);
if (!(Sha256Update(sha256ctx, hashbase, hashsize)) ||
!(Sha1Update(sha1ctx, hashbase, hashsize))) {
perror(L"Unable to generate hash\n");
efi_status = EFI_OUT_OF_RESOURCES;
goto done;
}
/* Hash post-checksum to start of certificate table */
hashbase = (char *)&context->PEHdr->Pe32.OptionalHeader.CheckSum +
sizeof (int);
hashsize = (char *)context->SecDir - hashbase;
check_size(data, datasize, hashbase, hashsize);
if (!(Sha256Update(sha256ctx, hashbase, hashsize)) ||
!(Sha1Update(sha1ctx, hashbase, hashsize))) {
perror(L"Unable to generate hash\n");
efi_status = EFI_OUT_OF_RESOURCES;
goto done;
}
/* Hash end of certificate table to end of image header */
EFI_IMAGE_DATA_DIRECTORY *dd = context->SecDir + 1;
hashbase = (char *)dd;
hashsize = context->SizeOfHeaders - (unsigned long)((char *)dd - data);
if (hashsize > datasize) {
perror(L"Data Directory size %d is invalid\n", hashsize);
efi_status = EFI_INVALID_PARAMETER;
goto done;
}
check_size(data, datasize, hashbase, hashsize);
if (!(Sha256Update(sha256ctx, hashbase, hashsize)) ||
!(Sha1Update(sha1ctx, hashbase, hashsize))) {
perror(L"Unable to generate hash\n");
efi_status = EFI_OUT_OF_RESOURCES;
goto done;
}
/* Sort sections */
SumOfBytesHashed = context->SizeOfHeaders;
/*
* XXX Do we need this here, or is it already done in all cases?
*/
if (context->NumberOfSections == 0 ||
context->FirstSection == NULL) {
uint16_t opthdrsz;
uint64_t addr;
uint16_t nsections;
EFI_IMAGE_SECTION_HEADER *section0, *sectionN;
nsections = context->PEHdr->Pe32.FileHeader.NumberOfSections;
opthdrsz = context->PEHdr->Pe32.FileHeader.SizeOfOptionalHeader;
/* Validate section0 is within image */
addr = PEHdr_offset + sizeof(UINT32)
+ sizeof(EFI_IMAGE_FILE_HEADER)
+ opthdrsz;
section0 = ImageAddress(data, datasize, addr);
if (!section0) {
perror(L"Malformed file header.\n");
perror(L"Image address for Section Header 0 is 0x%016llx\n",
addr);
perror(L"File size is 0x%016llx\n", datasize);
efi_status = EFI_INVALID_PARAMETER;
goto done;
}
/* Validate sectionN is within image */
addr += (uint64_t)(intptr_t)§ion0[nsections-1] -
(uint64_t)(intptr_t)section0;
sectionN = ImageAddress(data, datasize, addr);
if (!sectionN) {
perror(L"Malformed file header.\n");
perror(L"Image address for Section Header %d is 0x%016llx\n",
nsections - 1, addr);
perror(L"File size is 0x%016llx\n", datasize);
efi_status = EFI_INVALID_PARAMETER;
goto done;
}
context->NumberOfSections = nsections;
context->FirstSection = section0;
}
/*
* Allocate a new section table so we can sort them without
* modifying the image.
*/
SectionHeader = AllocateZeroPool (sizeof (EFI_IMAGE_SECTION_HEADER)
* context->NumberOfSections);
if (SectionHeader == NULL) {
perror(L"Unable to allocate section header\n");
efi_status = EFI_OUT_OF_RESOURCES;
goto done;
}
/*
* Validate section locations and sizes, and sort the table into
* our newly allocated header table
*/
SumOfSectionBytes = 0;
Section = context->FirstSection;
for (index = 0; index < context->NumberOfSections; index++) {
EFI_IMAGE_SECTION_HEADER *SectionPtr;
char *base;
size_t size;
efi_status = get_section_vma(index, data, datasize, context,
&base, &size, &SectionPtr);
if (efi_status == EFI_NOT_FOUND)
break;
if (EFI_ERROR(efi_status)) {
perror(L"Malformed section header\n");
goto done;
}
/* Validate section size is within image. */
if (SectionPtr->SizeOfRawData >
datasize - SumOfBytesHashed - SumOfSectionBytes) {
perror(L"Malformed section %d size\n", index);
efi_status = EFI_INVALID_PARAMETER;
goto done;
}
SumOfSectionBytes += SectionPtr->SizeOfRawData;
pos = index;
while ((pos > 0) && (Section->PointerToRawData < SectionHeader[pos - 1].PointerToRawData)) {
CopyMem (&SectionHeader[pos], &SectionHeader[pos - 1], sizeof (EFI_IMAGE_SECTION_HEADER));
pos--;
}
CopyMem (&SectionHeader[pos], Section, sizeof (EFI_IMAGE_SECTION_HEADER));
Section += 1;
}
/* Hash the sections */
for (index = 0; index < context->NumberOfSections; index++) {
Section = &SectionHeader[index];
if (Section->SizeOfRawData == 0) {
continue;
}
hashbase = ImageAddress(data, datasize,
Section->PointerToRawData);
if (!hashbase) {
perror(L"Malformed section header\n");
efi_status = EFI_INVALID_PARAMETER;
goto done;
}
/* Verify hashsize within image. */
if (Section->SizeOfRawData >
datasize - Section->PointerToRawData) {
perror(L"Malformed section raw size %d\n", index);
efi_status = EFI_INVALID_PARAMETER;
goto done;
}
hashsize = (unsigned int) Section->SizeOfRawData;
check_size(data, datasize, hashbase, hashsize);
if (!(Sha256Update(sha256ctx, hashbase, hashsize)) ||
!(Sha1Update(sha1ctx, hashbase, hashsize))) {
perror(L"Unable to generate hash\n");
efi_status = EFI_OUT_OF_RESOURCES;
goto done;
}
SumOfBytesHashed += Section->SizeOfRawData;
}
/* Hash all remaining data up to SecDir if SecDir->Size is not 0 */
if (datasize > SumOfBytesHashed && context->SecDir->Size) {
hashbase = data + SumOfBytesHashed;
hashsize = datasize - context->SecDir->Size - SumOfBytesHashed;
if ((datasize - SumOfBytesHashed < context->SecDir->Size) ||
(SumOfBytesHashed + hashsize != context->SecDir->VirtualAddress)) {
perror(L"Malformed binary after Attribute Certificate Table\n");
console_print(L"datasize: %u SumOfBytesHashed: %u SecDir->Size: %lu\n",
datasize, SumOfBytesHashed, context->SecDir->Size);
console_print(L"hashsize: %u SecDir->VirtualAddress: 0x%08lx\n",
hashsize, context->SecDir->VirtualAddress);
efi_status = EFI_INVALID_PARAMETER;
goto done;
}
check_size(data, datasize, hashbase, hashsize);
if (!(Sha256Update(sha256ctx, hashbase, hashsize)) ||
!(Sha1Update(sha1ctx, hashbase, hashsize))) {
perror(L"Unable to generate hash\n");
efi_status = EFI_OUT_OF_RESOURCES;
goto done;
}
#if 1
}
#else // we have to migrate to doing this later :/
SumOfBytesHashed += hashsize;
}
/* Hash all remaining data */
if (datasize > SumOfBytesHashed) {
hashbase = data + SumOfBytesHashed;
hashsize = datasize - SumOfBytesHashed;
check_size(data, datasize, hashbase, hashsize);
if (!(Sha256Update(sha256ctx, hashbase, hashsize)) ||
!(Sha1Update(sha1ctx, hashbase, hashsize))) {
perror(L"Unable to generate hash\n");
efi_status = EFI_OUT_OF_RESOURCES;
goto done;
}
SumOfBytesHashed += hashsize;
}
#endif
if (!(Sha256Final(sha256ctx, sha256hash)) ||
!(Sha1Final(sha1ctx, sha1hash))) {
perror(L"Unable to finalise hash\n");
efi_status = EFI_OUT_OF_RESOURCES;
goto done;
}
dprint(L"sha1 authenticode hash:\n");
dhexdumpat(sha1hash, SHA1_DIGEST_SIZE, 0);
dprint(L"sha256 authenticode hash:\n");
dhexdumpat(sha256hash, SHA256_DIGEST_SIZE, 0);
done:
if (SectionHeader)
FreePool(SectionHeader);
if (sha1ctx)
FreePool(sha1ctx);
if (sha256ctx)
FreePool(sha256ctx);
return efi_status;
}
EFI_STATUS
verify_sbat_section(char *SBATBase, size_t SBATSize)
{
unsigned int i;
EFI_STATUS efi_status;
size_t n;
struct sbat_section_entry **entries = NULL;
char *sbat_data;
size_t sbat_size;
if (list_empty(&sbat_var))
return EFI_SUCCESS;
if (SBATBase == NULL || SBATSize == 0) {
dprint(L"No .sbat section data\n");
/*
* SBAT is mandatory for binaries loaded by shim, but optional
* for binaries loaded outside of shim but verified via the
* protocol.
*/
return in_protocol ? EFI_SUCCESS : EFI_SECURITY_VIOLATION;
}
if (checked_add(SBATSize, 1, &sbat_size)) {
dprint(L"SBATSize + 1 would overflow\n");
return EFI_SECURITY_VIOLATION;
}
sbat_data = AllocatePool(sbat_size);
if (!sbat_data) {
console_print(L"Failed to allocate .sbat section buffer\n");
return EFI_OUT_OF_RESOURCES;
}
CopyMem(sbat_data, SBATBase, SBATSize);
sbat_data[SBATSize] = '\0';
efi_status = parse_sbat_section(sbat_data, sbat_size, &n, &entries);
if (EFI_ERROR(efi_status)) {
perror(L"Could not parse .sbat section data: %r\n", efi_status);
goto err;
}
dprint(L"SBAT section data\n");
for (i = 0; i < n; i++) {
dprint(L"%a, %a, %a, %a, %a, %a\n",
entries[i]->component_name,
entries[i]->component_generation,
entries[i]->vendor_name,
entries[i]->vendor_package_name,
entries[i]->vendor_version,
entries[i]->vendor_url);
}
efi_status = verify_sbat(n, entries);
cleanup_sbat_section_entries(n, entries);
err:
FreePool(sbat_data);
return efi_status;
}
static inline uint64_t
shim_mem_attrs_to_uefi_mem_attrs (uint64_t attrs)
{
uint64_t ret = EFI_MEMORY_RP |
EFI_MEMORY_RO |
EFI_MEMORY_XP;
if (attrs & MEM_ATTR_R)
ret &= ~EFI_MEMORY_RP;
if (attrs & MEM_ATTR_W)
ret &= ~EFI_MEMORY_RO;
if (attrs & MEM_ATTR_X)
ret &= ~EFI_MEMORY_XP;
return ret;
}
static inline uint64_t
uefi_mem_attrs_to_shim_mem_attrs (uint64_t attrs)
{
uint64_t ret = MEM_ATTR_R |
MEM_ATTR_W |
MEM_ATTR_X;
if (attrs & EFI_MEMORY_RP)
ret &= ~MEM_ATTR_R;
if (attrs & EFI_MEMORY_RO)
ret &= ~MEM_ATTR_W;
if (attrs & EFI_MEMORY_XP)
ret &= ~MEM_ATTR_X;
return ret;
}
static EFI_STATUS
get_mem_attrs (uintptr_t addr, size_t size, uint64_t *attrs)
{
EFI_MEMORY_ATTRIBUTE_PROTOCOL *proto = NULL;
EFI_PHYSICAL_ADDRESS physaddr = addr;
EFI_STATUS efi_status;
efi_status = LibLocateProtocol(&EFI_MEMORY_ATTRIBUTE_PROTOCOL_GUID,
(VOID **)&proto);
if (EFI_ERROR(efi_status) || !proto)
return efi_status;
if (!IS_PAGE_ALIGNED(physaddr) || !IS_PAGE_ALIGNED(size) || size == 0 || attrs == NULL) {
dprint(L"%a called on 0x%llx-0x%llx and attrs 0x%llx\n",
__func__, (unsigned long long)physaddr,
(unsigned long long)(physaddr+size-1),
attrs);
return EFI_SUCCESS;
}
efi_status = proto->GetMemoryAttributes(proto, physaddr, size, attrs);
*attrs = uefi_mem_attrs_to_shim_mem_attrs (*attrs);
return efi_status;
}
static EFI_STATUS
update_mem_attrs(uintptr_t addr, uint64_t size,
uint64_t set_attrs, uint64_t clear_attrs)
{
EFI_MEMORY_ATTRIBUTE_PROTOCOL *proto = NULL;
EFI_PHYSICAL_ADDRESS physaddr = addr;
EFI_STATUS efi_status, ret;
uint64_t before = 0, after = 0, uefi_set_attrs, uefi_clear_attrs;
efi_status = LibLocateProtocol(&EFI_MEMORY_ATTRIBUTE_PROTOCOL_GUID,
(VOID **)&proto);
if (EFI_ERROR(efi_status) || !proto)
return efi_status;
efi_status = get_mem_attrs (addr, size, &before);
if (EFI_ERROR(efi_status))
dprint(L"get_mem_attrs(0x%llx, 0x%llx, 0x%llx) -> 0x%lx\n",
(unsigned long long)addr, (unsigned long long)size,
&before, efi_status);
if (!IS_PAGE_ALIGNED(physaddr) || !IS_PAGE_ALIGNED(size) || size == 0) {
dprint(L"%a called on 0x%llx-0x%llx (size 0x%llx) +%a%a%a -%a%a%a\n",
__func__, (unsigned long long)physaddr,
(unsigned long long)(physaddr + size - 1),
(unsigned long long)size,
(set_attrs & MEM_ATTR_R) ? "r" : "",
(set_attrs & MEM_ATTR_W) ? "w" : "",
(set_attrs & MEM_ATTR_X) ? "x" : "",
(clear_attrs & MEM_ATTR_R) ? "r" : "",
(clear_attrs & MEM_ATTR_W) ? "w" : "",
(clear_attrs & MEM_ATTR_X) ? "x" : "");
return 0;
}
uefi_set_attrs = shim_mem_attrs_to_uefi_mem_attrs (set_attrs);
dprint("translating set_attrs from 0x%lx to 0x%lx\n", set_attrs, uefi_set_attrs);
uefi_clear_attrs = shim_mem_attrs_to_uefi_mem_attrs (clear_attrs);
dprint("translating clear_attrs from 0x%lx to 0x%lx\n", clear_attrs, uefi_clear_attrs);
efi_status = EFI_SUCCESS;
if (uefi_set_attrs) {
efi_status = proto->SetMemoryAttributes(proto, physaddr, size, uefi_set_attrs);
if (EFI_ERROR(efi_status)) {
dprint(L"Failed to set memory attrs:0x%0x physaddr:0x%llx size:0x%0lx status:%r\n",
uefi_set_attrs, physaddr, size, efi_status);
}
}
if (!EFI_ERROR(efi_status) && uefi_clear_attrs) {
efi_status = proto->ClearMemoryAttributes(proto, physaddr, size, uefi_clear_attrs);
if (EFI_ERROR(efi_status)) {
dprint(L"Failed to clear memory attrs:0x%0x physaddr:0x%llx size:0x%0lx status:%r\n",
uefi_clear_attrs, physaddr, size, efi_status);
}
}
ret = efi_status;
efi_status = get_mem_attrs (addr, size, &after);
if (EFI_ERROR(efi_status))
dprint(L"get_mem_attrs(0x%llx, %llu, 0x%llx) -> 0x%lx\n",
(unsigned long long)addr, (unsigned long long)size,
&after, efi_status);
dprint(L"set +%a%a%a -%a%a%a on 0x%llx-0x%llx before:%c%c%c after:%c%c%c\n",
(set_attrs & MEM_ATTR_R) ? "r" : "",
(set_attrs & MEM_ATTR_W) ? "w" : "",
(set_attrs & MEM_ATTR_X) ? "x" : "",
(clear_attrs & MEM_ATTR_R) ? "r" : "",
(clear_attrs & MEM_ATTR_W) ? "w" : "",
(clear_attrs & MEM_ATTR_X) ? "x" : "",
(unsigned long long)addr, (unsigned long long)(addr + size - 1),
(before & MEM_ATTR_R) ? 'r' : '-',
(before & MEM_ATTR_W) ? 'w' : '-',
(before & MEM_ATTR_X) ? 'x' : '-',
(after & MEM_ATTR_R) ? 'r' : '-',
(after & MEM_ATTR_W) ? 'w' : '-',
(after & MEM_ATTR_X) ? 'x' : '-');
return ret;
}
EFI_STATUS verify_image(void *data, unsigned int datasize,
EFI_LOADED_IMAGE *li,
PE_COFF_LOADER_IMAGE_CONTEXT *context)
{
EFI_STATUS efi_status;
UINT8 sha1hash[SHA1_DIGEST_SIZE];
UINT8 sha256hash[SHA256_DIGEST_SIZE];
/*
* The binary header contains relevant context and section pointers
*/
efi_status = read_header(data, datasize, context);
if (EFI_ERROR(efi_status)) {
perror(L"Failed to read header: %r\n", efi_status);
return efi_status;
}
/*
* Perform the image verification before we start copying data around
* in order to load it.
*/
if (secure_mode()) {
efi_status = verify_buffer(data, datasize,
context, sha256hash, sha1hash);
if (EFI_ERROR(efi_status)) {
if (verbose)
console_print(L"Verification failed: %r\n", efi_status);
else
console_error(L"Verification failed", efi_status);
return efi_status;
} else if (verbose)
console_print(L"Verification succeeded\n");
}
/*
* Calculate the hash for the TPM measurement.
* XXX: We're computing these twice in secure boot mode when the
* buffers already contain the previously computed hashes. Also,
* this is only useful for the TPM1.2 case. We should try to fix
* this in a follow-up.
*/
efi_status = generate_hash(data, datasize, context, sha256hash,
sha1hash);
if (EFI_ERROR(efi_status))
return efi_status;
/* Measure the binary into the TPM */
#ifdef REQUIRE_TPM
efi_status =
#endif
tpm_log_pe((EFI_PHYSICAL_ADDRESS)(UINTN)data, datasize,
(EFI_PHYSICAL_ADDRESS)(UINTN)context->ImageAddress,
li->FilePath, sha1hash, 4);
#ifdef REQUIRE_TPM
if (efi_status != EFI_SUCCESS) {
return efi_status;
}
#endif
return EFI_SUCCESS;
}
/*
* Once the image has been loaded it needs to be validated and relocated
*/
EFI_STATUS
handle_image (void *data, unsigned int datasize,
EFI_LOADED_IMAGE *li,
EFI_IMAGE_ENTRY_POINT *entry_point,
EFI_PHYSICAL_ADDRESS *alloc_address,
UINTN *alloc_pages)
{
EFI_STATUS efi_status;
char *buffer;
int i;
EFI_IMAGE_SECTION_HEADER *Section;
char *base, *end;
UINT32 size;
PE_COFF_LOADER_IMAGE_CONTEXT context;
unsigned int alignment, alloc_size;
int found_entry_point = 0;
UINT8 sha1hash[SHA1_DIGEST_SIZE];
UINT8 sha256hash[SHA256_DIGEST_SIZE];
/*
* The binary header contains relevant context and section pointers
*/
efi_status = read_header(data, datasize, &context);
if (EFI_ERROR(efi_status)) {
perror(L"Failed to read header: %r\n", efi_status);
return efi_status;
}
/*
* Perform the image verification before we start copying data around
* in order to load it.
*/
if (secure_mode ()) {
efi_status = verify_buffer(data, datasize, &context, sha256hash,
sha1hash);
if (EFI_ERROR(efi_status)) {
if (verbose)
console_print(L"Verification failed: %r\n", efi_status);
else
console_error(L"Verification failed", efi_status);
return efi_status;
} else {
if (verbose)
console_print(L"Verification succeeded\n");
}
}
/*
* Calculate the hash for the TPM measurement.
* XXX: We're computing these twice in secure boot mode when the
* buffers already contain the previously computed hashes. Also,
* this is only useful for the TPM1.2 case. We should try to fix
* this in a follow-up.
*/
efi_status = generate_hash(data, datasize, &context, sha256hash,
sha1hash);
if (EFI_ERROR(efi_status))
return efi_status;
/* Measure the binary into the TPM */
#ifdef REQUIRE_TPM
efi_status =
#endif
tpm_log_pe((EFI_PHYSICAL_ADDRESS)(UINTN)data, datasize,
(EFI_PHYSICAL_ADDRESS)(UINTN)context.ImageAddress,
li->FilePath, sha1hash, 4);
#ifdef REQUIRE_TPM
if (efi_status != EFI_SUCCESS) {
return efi_status;
}
#endif
/* The spec says, uselessly, of SectionAlignment:
* =====
* The alignment (in bytes) of sections when they are loaded into
* memory. It must be greater than or equal to FileAlignment. The
* default is the page size for the architecture.
* =====
* Which doesn't tell you whose responsibility it is to enforce the
* "default", or when. It implies that the value in the field must
* be > FileAlignment (also poorly defined), but it appears visual
* studio will happily write 512 for FileAlignment (its default) and
* 0 for SectionAlignment, intending to imply PAGE_SIZE.
*
* We only support one page size, so if it's zero, nerf it to 4096.
*/
alignment = context.SectionAlignment;
if (!alignment)
alignment = 4096;
alloc_size = ALIGN_VALUE(context.ImageSize + context.SectionAlignment,
PAGE_SIZE);
*alloc_pages = alloc_size / PAGE_SIZE;
efi_status = BS->AllocatePages(AllocateAnyPages, EfiLoaderCode,
*alloc_pages, alloc_address);
if (EFI_ERROR(efi_status)) {
perror(L"Failed to allocate image buffer\n");
return EFI_OUT_OF_RESOURCES;
}
buffer = (void *)ALIGN_VALUE((unsigned long)*alloc_address, alignment);
dprint(L"Loading 0x%llx bytes at 0x%llx\n",
(unsigned long long)context.ImageSize,
(unsigned long long)(uintptr_t)buffer);
update_mem_attrs((uintptr_t)buffer, alloc_size, MEM_ATTR_R|MEM_ATTR_W,
MEM_ATTR_X);
CopyMem(buffer, data, context.SizeOfHeaders);
/* Flush the instruction cache for the region holding the image */
cache_invalidate(buffer, buffer + context.ImageSize);
*entry_point = ImageAddress(buffer, context.ImageSize, context.EntryPoint);
if (!*entry_point) {
perror(L"Entry point is invalid\n");
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
char *RelocBase, *RelocBaseEnd;
/*
* These are relative virtual addresses, so we have to check them
* against the image size, not the data size.
*/
RelocBase = ImageAddress(buffer, context.ImageSize,
context.RelocDir->VirtualAddress);
/*
* RelocBaseEnd here is the address of the last byte of the table
*/
RelocBaseEnd = ImageAddress(buffer, context.ImageSize,
context.RelocDir->VirtualAddress +
context.RelocDir->Size - 1);
EFI_IMAGE_SECTION_HEADER *RelocSection = NULL;
/*
* Copy the executable's sections to their desired offsets
*/
Section = context.FirstSection;
for (i = 0; i < context.NumberOfSections; i++, Section++) {
/* Don't try to copy discardable sections with zero size */
if ((Section->Characteristics & EFI_IMAGE_SCN_MEM_DISCARDABLE) &&
!Section->Misc.VirtualSize)
continue;
/*
* Skip sections that aren't marked readable.
*/
if (!(Section->Characteristics & EFI_IMAGE_SCN_MEM_READ))
continue;
if (!(Section->Characteristics & EFI_IMAGE_SCN_MEM_DISCARDABLE) &&
(Section->Characteristics & EFI_IMAGE_SCN_MEM_WRITE) &&
(Section->Characteristics & EFI_IMAGE_SCN_MEM_EXECUTE) &&
(mok_policy & MOK_POLICY_REQUIRE_NX)) {
perror(L"Section %d is writable and executable\n", i);
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
base = ImageAddress (buffer, context.ImageSize,
Section->VirtualAddress);
end = ImageAddress (buffer, context.ImageSize,
Section->VirtualAddress
+ Section->Misc.VirtualSize - 1);
if (end < base) {
perror(L"Section %d has negative size\n", i);
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
if (Section->VirtualAddress <= context.EntryPoint &&
(Section->VirtualAddress + Section->Misc.VirtualSize - 1)
> context.EntryPoint)
found_entry_point++;
/* We do want to process .reloc, but it's often marked
* discardable, so we don't want to memcpy it. */
if (CompareMem(Section->Name, ".reloc\0\0", 8) == 0) {
if (RelocSection) {
perror(L"Image has multiple relocation sections\n");
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
/* If it has nonzero sizes, and our bounds check
* made sense, and the VA and size match RelocDir's
* versions, then we believe in this section table. */
if (Section->SizeOfRawData &&
Section->Misc.VirtualSize &&
base && end &&
RelocBase == base &&
RelocBaseEnd <= end) {
RelocSection = Section;
} else {
perror(L"Relocation section is invalid \n");
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
}
if (Section->Characteristics & EFI_IMAGE_SCN_MEM_DISCARDABLE) {
continue;
}
if (!base) {
perror(L"Section %d has invalid base address\n", i);
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
if (!end) {
perror(L"Section %d has zero size\n", i);
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
if (!(Section->Characteristics & EFI_IMAGE_SCN_CNT_UNINITIALIZED_DATA) &&
(Section->VirtualAddress < context.SizeOfHeaders ||
Section->PointerToRawData < context.SizeOfHeaders)) {
perror(L"Section %d is inside image headers\n", i);
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
if (Section->Characteristics & EFI_IMAGE_SCN_CNT_UNINITIALIZED_DATA) {
ZeroMem(base, Section->Misc.VirtualSize);
} else {
if (Section->PointerToRawData < context.SizeOfHeaders) {
perror(L"Section %d is inside image headers\n", i);
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
size = Section->Misc.VirtualSize;
if (size > Section->SizeOfRawData)
size = Section->SizeOfRawData;
if (size > 0)
CopyMem(base, data + Section->PointerToRawData, size);
if (size < Section->Misc.VirtualSize)
ZeroMem(base + size, Section->Misc.VirtualSize - size);
}
}
if (context.NumberOfRvaAndSizes <= EFI_IMAGE_DIRECTORY_ENTRY_BASERELOC) {
perror(L"Image has no relocation entry\n");
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
if (context.RelocDir->Size && RelocSection) {
/*
* Run the relocation fixups
*/
efi_status = relocate_coff(&context, RelocSection, data,
buffer);
if (EFI_ERROR(efi_status)) {
perror(L"Relocation failed: %r\n", efi_status);
BS->FreePages(*alloc_address, *alloc_pages);
return efi_status;
}
}
/*
* Now set the page permissions appropriately.
*/
Section = context.FirstSection;
for (i = 0; i < context.NumberOfSections; i++, Section++) {
uint64_t set_attrs = MEM_ATTR_R;
uint64_t clear_attrs = MEM_ATTR_W|MEM_ATTR_X;
uintptr_t addr;
uint64_t length;
/*
* Skip discardable sections with zero size
*/
if ((Section->Characteristics & EFI_IMAGE_SCN_MEM_DISCARDABLE) &&
!Section->Misc.VirtualSize)
continue;
/*
* Skip sections that aren't marked readable.
*/
if (!(Section->Characteristics & EFI_IMAGE_SCN_MEM_READ))
continue;
base = ImageAddress (buffer, context.ImageSize,
Section->VirtualAddress);
end = ImageAddress (buffer, context.ImageSize,
Section->VirtualAddress
+ Section->Misc.VirtualSize - 1);
addr = (uintptr_t)base;
// Align the length up to PAGE_SIZE. This is required because
// platforms generally set memory attributes at page
// granularity, but the section length (unlike the section
// address) is not required to be aligned.
length = ALIGN_VALUE((uintptr_t)end - (uintptr_t)base + 1, PAGE_SIZE);
if (Section->Characteristics & EFI_IMAGE_SCN_MEM_WRITE) {
set_attrs |= MEM_ATTR_W;
clear_attrs &= ~MEM_ATTR_W;
}
if (Section->Characteristics & EFI_IMAGE_SCN_MEM_EXECUTE) {
set_attrs |= MEM_ATTR_X;
clear_attrs &= ~MEM_ATTR_X;
}
update_mem_attrs(addr, length, set_attrs, clear_attrs);
}
/*
* grub needs to know its location and size in memory, so fix up
* the loaded image protocol values
*/
li->ImageBase = buffer;
li->ImageSize = context.ImageSize;
/* Pass the load options to the second stage loader */
li->LoadOptions = load_options;
li->LoadOptionsSize = load_options_size;
if (!found_entry_point) {
perror(L"Entry point is not within sections\n");
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
if (found_entry_point > 1) {
perror(L"%d sections contain entry point\n", found_entry_point);
BS->FreePages(*alloc_address, *alloc_pages);
return EFI_UNSUPPORTED;
}
return EFI_SUCCESS;
}
// vim:fenc=utf-8:tw=75:noet