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reactos/drivers/filesystems/btrfs/scrub.c
Victor Perevertkin 194ea909fd
[BTRFS][UBTRFS][SHELLBTRFS] Upgrade to 1.7.2 
CORE-16679
2020-04-23 07:07:36 +03:00

3454 lines
143 KiB
C
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/* Copyright (c) Mark Harmstone 2017
*
* This file is part of WinBtrfs.
*
* WinBtrfs is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public Licence as published by
* the Free Software Foundation, either version 3 of the Licence, or
* (at your option) any later version.
*
* WinBtrfs 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 Lesser General Public Licence for more details.
*
* You should have received a copy of the GNU Lesser General Public Licence
* along with WinBtrfs. If not, see <http://www.gnu.org/licenses/>. */
#include "btrfs_drv.h"
#define SCRUB_UNIT 0x100000 // 1 MB
struct _scrub_context;
typedef struct {
struct _scrub_context* context;
PIRP Irp;
uint64_t start;
uint32_t length;
IO_STATUS_BLOCK iosb;
uint8_t* buf;
bool csum_error;
void* bad_csums;
} scrub_context_stripe;
typedef struct _scrub_context {
KEVENT Event;
scrub_context_stripe* stripes;
LONG stripes_left;
} scrub_context;
typedef struct {
ANSI_STRING name;
bool orig_subvol;
LIST_ENTRY list_entry;
} path_part;
static void log_file_checksum_error(device_extension* Vcb, uint64_t addr, uint64_t devid, uint64_t subvol, uint64_t inode, uint64_t offset) {
LIST_ENTRY *le, parts;
root* r = NULL;
KEY searchkey;
traverse_ptr tp;
uint64_t dir;
bool orig_subvol = true, not_in_tree = false;
ANSI_STRING fn;
scrub_error* err;
NTSTATUS Status;
ULONG utf16len;
le = Vcb->roots.Flink;
while (le != &Vcb->roots) {
root* r2 = CONTAINING_RECORD(le, root, list_entry);
if (r2->id == subvol) {
r = r2;
break;
}
le = le->Flink;
}
if (!r) {
ERR("could not find subvol %I64x\n", subvol);
return;
}
InitializeListHead(&parts);
dir = inode;
while (true) {
if (dir == r->root_item.objid) {
if (r == Vcb->root_fileref->fcb->subvol)
break;
searchkey.obj_id = r->id;
searchkey.obj_type = TYPE_ROOT_BACKREF;
searchkey.offset = 0xffffffffffffffff;
Status = find_item(Vcb, Vcb->root_root, &tp, &searchkey, false, NULL);
if (!NT_SUCCESS(Status)) {
ERR("find_item returned %08lx\n", Status);
goto end;
}
if (tp.item->key.obj_id == searchkey.obj_id && tp.item->key.obj_type == searchkey.obj_type) {
ROOT_REF* rr = (ROOT_REF*)tp.item->data;
path_part* pp;
if (tp.item->size < sizeof(ROOT_REF)) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset, tp.item->size, sizeof(ROOT_REF));
goto end;
}
if (tp.item->size < offsetof(ROOT_REF, name[0]) + rr->n) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset,
tp.item->size, offsetof(ROOT_REF, name[0]) + rr->n);
goto end;
}
pp = ExAllocatePoolWithTag(PagedPool, sizeof(path_part), ALLOC_TAG);
if (!pp) {
ERR("out of memory\n");
goto end;
}
pp->name.Buffer = rr->name;
pp->name.Length = pp->name.MaximumLength = rr->n;
pp->orig_subvol = false;
InsertTailList(&parts, &pp->list_entry);
r = NULL;
le = Vcb->roots.Flink;
while (le != &Vcb->roots) {
root* r2 = CONTAINING_RECORD(le, root, list_entry);
if (r2->id == tp.item->key.offset) {
r = r2;
break;
}
le = le->Flink;
}
if (!r) {
ERR("could not find subvol %I64x\n", tp.item->key.offset);
goto end;
}
dir = rr->dir;
orig_subvol = false;
} else {
not_in_tree = true;
break;
}
} else {
searchkey.obj_id = dir;
searchkey.obj_type = TYPE_INODE_EXTREF;
searchkey.offset = 0xffffffffffffffff;
Status = find_item(Vcb, r, &tp, &searchkey, false, NULL);
if (!NT_SUCCESS(Status)) {
ERR("find_item returned %08lx\n", Status);
goto end;
}
if (tp.item->key.obj_id == searchkey.obj_id && tp.item->key.obj_type == TYPE_INODE_REF) {
INODE_REF* ir = (INODE_REF*)tp.item->data;
path_part* pp;
if (tp.item->size < sizeof(INODE_REF)) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset, tp.item->size, sizeof(INODE_REF));
goto end;
}
if (tp.item->size < offsetof(INODE_REF, name[0]) + ir->n) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset,
tp.item->size, offsetof(INODE_REF, name[0]) + ir->n);
goto end;
}
pp = ExAllocatePoolWithTag(PagedPool, sizeof(path_part), ALLOC_TAG);
if (!pp) {
ERR("out of memory\n");
goto end;
}
pp->name.Buffer = ir->name;
pp->name.Length = pp->name.MaximumLength = ir->n;
pp->orig_subvol = orig_subvol;
InsertTailList(&parts, &pp->list_entry);
if (dir == tp.item->key.offset)
break;
dir = tp.item->key.offset;
} else if (tp.item->key.obj_id == searchkey.obj_id && tp.item->key.obj_type == TYPE_INODE_EXTREF) {
INODE_EXTREF* ier = (INODE_EXTREF*)tp.item->data;
path_part* pp;
if (tp.item->size < sizeof(INODE_EXTREF)) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset,
tp.item->size, sizeof(INODE_EXTREF));
goto end;
}
if (tp.item->size < offsetof(INODE_EXTREF, name[0]) + ier->n) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset,
tp.item->size, offsetof(INODE_EXTREF, name[0]) + ier->n);
goto end;
}
pp = ExAllocatePoolWithTag(PagedPool, sizeof(path_part), ALLOC_TAG);
if (!pp) {
ERR("out of memory\n");
goto end;
}
pp->name.Buffer = ier->name;
pp->name.Length = pp->name.MaximumLength = ier->n;
pp->orig_subvol = orig_subvol;
InsertTailList(&parts, &pp->list_entry);
if (dir == ier->dir)
break;
dir = ier->dir;
} else {
ERR("could not find INODE_REF for inode %I64x in subvol %I64x\n", dir, r->id);
goto end;
}
}
}
fn.MaximumLength = 0;
if (not_in_tree) {
le = parts.Blink;
while (le != &parts) {
path_part* pp = CONTAINING_RECORD(le, path_part, list_entry);
LIST_ENTRY* le2 = le->Blink;
if (pp->orig_subvol)
break;
RemoveTailList(&parts);
ExFreePool(pp);
le = le2;
}
}
le = parts.Flink;
while (le != &parts) {
path_part* pp = CONTAINING_RECORD(le, path_part, list_entry);
fn.MaximumLength += pp->name.Length + 1;
le = le->Flink;
}
fn.Buffer = ExAllocatePoolWithTag(PagedPool, fn.MaximumLength, ALLOC_TAG);
if (!fn.Buffer) {
ERR("out of memory\n");
goto end;
}
fn.Length = 0;
le = parts.Blink;
while (le != &parts) {
path_part* pp = CONTAINING_RECORD(le, path_part, list_entry);
fn.Buffer[fn.Length] = '\\';
fn.Length++;
RtlCopyMemory(&fn.Buffer[fn.Length], pp->name.Buffer, pp->name.Length);
fn.Length += pp->name.Length;
le = le->Blink;
}
if (not_in_tree)
ERR("subvol %I64x, %.*s, offset %I64x\n", subvol, fn.Length, fn.Buffer, offset);
else
ERR("%.*s, offset %I64x\n", fn.Length, fn.Buffer, offset);
Status = utf8_to_utf16(NULL, 0, &utf16len, fn.Buffer, fn.Length);
if (!NT_SUCCESS(Status)) {
ERR("utf8_to_utf16 1 returned %08lx\n", Status);
ExFreePool(fn.Buffer);
goto end;
}
err = ExAllocatePoolWithTag(PagedPool, offsetof(scrub_error, data.filename[0]) + utf16len, ALLOC_TAG);
if (!err) {
ERR("out of memory\n");
ExFreePool(fn.Buffer);
goto end;
}
err->address = addr;
err->device = devid;
err->recovered = false;
err->is_metadata = false;
err->parity = false;
err->data.subvol = not_in_tree ? subvol : 0;
err->data.offset = offset;
err->data.filename_length = (uint16_t)utf16len;
Status = utf8_to_utf16(err->data.filename, utf16len, &utf16len, fn.Buffer, fn.Length);
if (!NT_SUCCESS(Status)) {
ERR("utf8_to_utf16 2 returned %08lx\n", Status);
ExFreePool(fn.Buffer);
ExFreePool(err);
goto end;
}
ExAcquireResourceExclusiveLite(&Vcb->scrub.stats_lock, true);
Vcb->scrub.num_errors++;
InsertTailList(&Vcb->scrub.errors, &err->list_entry);
ExReleaseResourceLite(&Vcb->scrub.stats_lock);
ExFreePool(fn.Buffer);
end:
while (!IsListEmpty(&parts)) {
path_part* pp = CONTAINING_RECORD(RemoveHeadList(&parts), path_part, list_entry);
ExFreePool(pp);
}
}
static void log_file_checksum_error_shared(device_extension* Vcb, uint64_t treeaddr, uint64_t addr, uint64_t devid, uint64_t extent) {
tree_header* tree;
NTSTATUS Status;
leaf_node* ln;
ULONG i;
tree = ExAllocatePoolWithTag(PagedPool, Vcb->superblock.node_size, ALLOC_TAG);
if (!tree) {
ERR("out of memory\n");
return;
}
Status = read_data(Vcb, treeaddr, Vcb->superblock.node_size, NULL, true, (uint8_t*)tree, NULL, NULL, NULL, 0, false, NormalPagePriority);
if (!NT_SUCCESS(Status)) {
ERR("read_data returned %08lx\n", Status);
goto end;
}
if (tree->level != 0) {
ERR("tree level was %x, expected 0\n", tree->level);
goto end;
}
ln = (leaf_node*)&tree[1];
for (i = 0; i < tree->num_items; i++) {
if (ln[i].key.obj_type == TYPE_EXTENT_DATA && ln[i].size >= sizeof(EXTENT_DATA) - 1 + sizeof(EXTENT_DATA2)) {
EXTENT_DATA* ed = (EXTENT_DATA*)((uint8_t*)tree + sizeof(tree_header) + ln[i].offset);
EXTENT_DATA2* ed2 = (EXTENT_DATA2*)ed->data;
if (ed->type == EXTENT_TYPE_REGULAR && ed2->size != 0 && ed2->address == addr)
log_file_checksum_error(Vcb, addr, devid, tree->tree_id, ln[i].key.obj_id, ln[i].key.offset + addr - extent);
}
}
end:
ExFreePool(tree);
}
static void log_tree_checksum_error(device_extension* Vcb, uint64_t addr, uint64_t devid, uint64_t root, uint8_t level, KEY* firstitem) {
scrub_error* err;
err = ExAllocatePoolWithTag(PagedPool, sizeof(scrub_error), ALLOC_TAG);
if (!err) {
ERR("out of memory\n");
return;
}
err->address = addr;
err->device = devid;
err->recovered = false;
err->is_metadata = true;
err->parity = false;
err->metadata.root = root;
err->metadata.level = level;
if (firstitem) {
ERR("root %I64x, level %u, first item (%I64x,%x,%I64x)\n", root, level, firstitem->obj_id,
firstitem->obj_type, firstitem->offset);
err->metadata.firstitem = *firstitem;
} else {
ERR("root %I64x, level %u\n", root, level);
RtlZeroMemory(&err->metadata.firstitem, sizeof(KEY));
}
ExAcquireResourceExclusiveLite(&Vcb->scrub.stats_lock, true);
Vcb->scrub.num_errors++;
InsertTailList(&Vcb->scrub.errors, &err->list_entry);
ExReleaseResourceLite(&Vcb->scrub.stats_lock);
}
static void log_tree_checksum_error_shared(device_extension* Vcb, uint64_t offset, uint64_t address, uint64_t devid) {
tree_header* tree;
NTSTATUS Status;
internal_node* in;
ULONG i;
tree = ExAllocatePoolWithTag(PagedPool, Vcb->superblock.node_size, ALLOC_TAG);
if (!tree) {
ERR("out of memory\n");
return;
}
Status = read_data(Vcb, offset, Vcb->superblock.node_size, NULL, true, (uint8_t*)tree, NULL, NULL, NULL, 0, false, NormalPagePriority);
if (!NT_SUCCESS(Status)) {
ERR("read_data returned %08lx\n", Status);
goto end;
}
if (tree->level == 0) {
ERR("tree level was 0\n");
goto end;
}
in = (internal_node*)&tree[1];
for (i = 0; i < tree->num_items; i++) {
if (in[i].address == address) {
log_tree_checksum_error(Vcb, address, devid, tree->tree_id, tree->level - 1, &in[i].key);
break;
}
}
end:
ExFreePool(tree);
}
static void log_unrecoverable_error(device_extension* Vcb, uint64_t address, uint64_t devid) {
KEY searchkey;
traverse_ptr tp;
NTSTATUS Status;
EXTENT_ITEM* ei;
EXTENT_ITEM2* ei2 = NULL;
uint8_t* ptr;
ULONG len;
uint64_t rc;
// FIXME - still log even if rest of this function fails
searchkey.obj_id = address;
searchkey.obj_type = TYPE_METADATA_ITEM;
searchkey.offset = 0xffffffffffffffff;
Status = find_item(Vcb, Vcb->extent_root, &tp, &searchkey, false, NULL);
if (!NT_SUCCESS(Status)) {
ERR("find_item returned %08lx\n", Status);
return;
}
if ((tp.item->key.obj_type != TYPE_EXTENT_ITEM && tp.item->key.obj_type != TYPE_METADATA_ITEM) ||
tp.item->key.obj_id >= address + Vcb->superblock.sector_size ||
(tp.item->key.obj_type == TYPE_EXTENT_ITEM && tp.item->key.obj_id + tp.item->key.offset <= address) ||
(tp.item->key.obj_type == TYPE_METADATA_ITEM && tp.item->key.obj_id + Vcb->superblock.node_size <= address)
)
return;
if (tp.item->size < sizeof(EXTENT_ITEM)) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset, tp.item->size, sizeof(EXTENT_ITEM));
return;
}
ei = (EXTENT_ITEM*)tp.item->data;
ptr = (uint8_t*)&ei[1];
len = tp.item->size - sizeof(EXTENT_ITEM);
if (tp.item->key.obj_id == TYPE_EXTENT_ITEM && ei->flags & EXTENT_ITEM_TREE_BLOCK) {
if (tp.item->size < sizeof(EXTENT_ITEM) + sizeof(EXTENT_ITEM2)) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset,
tp.item->size, sizeof(EXTENT_ITEM) + sizeof(EXTENT_ITEM2));
return;
}
ei2 = (EXTENT_ITEM2*)ptr;
ptr += sizeof(EXTENT_ITEM2);
len -= sizeof(EXTENT_ITEM2);
}
rc = 0;
while (len > 0) {
uint8_t type = *ptr;
ptr++;
len--;
if (type == TYPE_TREE_BLOCK_REF) {
TREE_BLOCK_REF* tbr;
if (len < sizeof(TREE_BLOCK_REF)) {
ERR("TREE_BLOCK_REF takes up %Iu bytes, but only %lu remaining\n", sizeof(TREE_BLOCK_REF), len);
break;
}
tbr = (TREE_BLOCK_REF*)ptr;
log_tree_checksum_error(Vcb, address, devid, tbr->offset, ei2 ? ei2->level : (uint8_t)tp.item->key.offset, ei2 ? &ei2->firstitem : NULL);
rc++;
ptr += sizeof(TREE_BLOCK_REF);
len -= sizeof(TREE_BLOCK_REF);
} else if (type == TYPE_EXTENT_DATA_REF) {
EXTENT_DATA_REF* edr;
if (len < sizeof(EXTENT_DATA_REF)) {
ERR("EXTENT_DATA_REF takes up %Iu bytes, but only %lu remaining\n", sizeof(EXTENT_DATA_REF), len);
break;
}
edr = (EXTENT_DATA_REF*)ptr;
log_file_checksum_error(Vcb, address, devid, edr->root, edr->objid, edr->offset + address - tp.item->key.obj_id);
rc += edr->count;
ptr += sizeof(EXTENT_DATA_REF);
len -= sizeof(EXTENT_DATA_REF);
} else if (type == TYPE_SHARED_BLOCK_REF) {
SHARED_BLOCK_REF* sbr;
if (len < sizeof(SHARED_BLOCK_REF)) {
ERR("SHARED_BLOCK_REF takes up %Iu bytes, but only %lu remaining\n", sizeof(SHARED_BLOCK_REF), len);
break;
}
sbr = (SHARED_BLOCK_REF*)ptr;
log_tree_checksum_error_shared(Vcb, sbr->offset, address, devid);
rc++;
ptr += sizeof(SHARED_BLOCK_REF);
len -= sizeof(SHARED_BLOCK_REF);
} else if (type == TYPE_SHARED_DATA_REF) {
SHARED_DATA_REF* sdr;
if (len < sizeof(SHARED_DATA_REF)) {
ERR("SHARED_DATA_REF takes up %Iu bytes, but only %lu remaining\n", sizeof(SHARED_DATA_REF), len);
break;
}
sdr = (SHARED_DATA_REF*)ptr;
log_file_checksum_error_shared(Vcb, sdr->offset, address, devid, tp.item->key.obj_id);
rc += sdr->count;
ptr += sizeof(SHARED_DATA_REF);
len -= sizeof(SHARED_DATA_REF);
} else {
ERR("unknown extent type %x\n", type);
break;
}
}
if (rc < ei->refcount) {
do {
traverse_ptr next_tp;
if (find_next_item(Vcb, &tp, &next_tp, false, NULL))
tp = next_tp;
else
break;
if (tp.item->key.obj_id == address) {
if (tp.item->key.obj_type == TYPE_TREE_BLOCK_REF)
log_tree_checksum_error(Vcb, address, devid, tp.item->key.offset, ei2 ? ei2->level : (uint8_t)tp.item->key.offset, ei2 ? &ei2->firstitem : NULL);
else if (tp.item->key.obj_type == TYPE_EXTENT_DATA_REF) {
EXTENT_DATA_REF* edr;
if (tp.item->size < sizeof(EXTENT_DATA_REF)) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset,
tp.item->size, sizeof(EXTENT_DATA_REF));
break;
}
edr = (EXTENT_DATA_REF*)tp.item->data;
log_file_checksum_error(Vcb, address, devid, edr->root, edr->objid, edr->offset + address - tp.item->key.obj_id);
} else if (tp.item->key.obj_type == TYPE_SHARED_BLOCK_REF)
log_tree_checksum_error_shared(Vcb, tp.item->key.offset, address, devid);
else if (tp.item->key.obj_type == TYPE_SHARED_DATA_REF)
log_file_checksum_error_shared(Vcb, tp.item->key.offset, address, devid, tp.item->key.obj_id);
} else
break;
} while (true);
}
}
static void log_error(device_extension* Vcb, uint64_t addr, uint64_t devid, bool metadata, bool recoverable, bool parity) {
if (recoverable) {
scrub_error* err;
if (parity) {
ERR("recovering from parity error at %I64x on device %I64x\n", addr, devid);
} else {
if (metadata)
ERR("recovering from metadata checksum error at %I64x on device %I64x\n", addr, devid);
else
ERR("recovering from data checksum error at %I64x on device %I64x\n", addr, devid);
}
err = ExAllocatePoolWithTag(PagedPool, sizeof(scrub_error), ALLOC_TAG);
if (!err) {
ERR("out of memory\n");
return;
}
err->address = addr;
err->device = devid;
err->recovered = true;
err->is_metadata = metadata;
err->parity = parity;
if (metadata)
RtlZeroMemory(&err->metadata, sizeof(err->metadata));
else
RtlZeroMemory(&err->data, sizeof(err->data));
ExAcquireResourceExclusiveLite(&Vcb->scrub.stats_lock, true);
Vcb->scrub.num_errors++;
InsertTailList(&Vcb->scrub.errors, &err->list_entry);
ExReleaseResourceLite(&Vcb->scrub.stats_lock);
} else {
if (metadata)
ERR("unrecoverable metadata checksum error at %I64x\n", addr);
else
ERR("unrecoverable data checksum error at %I64x\n", addr);
log_unrecoverable_error(Vcb, addr, devid);
}
}
_Function_class_(IO_COMPLETION_ROUTINE)
static NTSTATUS __stdcall scrub_read_completion(PDEVICE_OBJECT DeviceObject, PIRP Irp, PVOID conptr) {
scrub_context_stripe* stripe = conptr;
scrub_context* context = (scrub_context*)stripe->context;
ULONG left = InterlockedDecrement(&context->stripes_left);
UNUSED(DeviceObject);
stripe->iosb = Irp->IoStatus;
if (left == 0)
KeSetEvent(&context->Event, 0, false);
return STATUS_MORE_PROCESSING_REQUIRED;
}
static NTSTATUS scrub_extent_dup(device_extension* Vcb, chunk* c, uint64_t offset, void* csum, scrub_context* context) {
NTSTATUS Status;
bool csum_error = false;
ULONG i;
CHUNK_ITEM_STRIPE* cis = (CHUNK_ITEM_STRIPE*)&c->chunk_item[1];
uint16_t present_devices = 0;
if (csum) {
ULONG good_stripe = 0xffffffff;
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (c->devices[i]->devobj) {
present_devices++;
// if first stripe is okay, we only need to check that the others are identical to it
if (good_stripe != 0xffffffff) {
if (RtlCompareMemory(context->stripes[i].buf, context->stripes[good_stripe].buf,
context->stripes[good_stripe].length) != context->stripes[i].length) {
context->stripes[i].csum_error = true;
csum_error = true;
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
} else {
Status = check_csum(Vcb, context->stripes[i].buf, context->stripes[i].length / Vcb->superblock.sector_size, csum);
if (Status == STATUS_CRC_ERROR) {
context->stripes[i].csum_error = true;
csum_error = true;
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
} else if (!NT_SUCCESS(Status)) {
ERR("check_csum returned %08lx\n", Status);
return Status;
} else
good_stripe = i;
}
}
}
} else {
ULONG good_stripe = 0xffffffff;
for (i = 0; i < c->chunk_item->num_stripes; i++) {
ULONG j;
if (c->devices[i]->devobj) {
// if first stripe is okay, we only need to check that the others are identical to it
if (good_stripe != 0xffffffff) {
if (RtlCompareMemory(context->stripes[i].buf, context->stripes[good_stripe].buf,
context->stripes[good_stripe].length) != context->stripes[i].length) {
context->stripes[i].csum_error = true;
csum_error = true;
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
} else {
for (j = 0; j < context->stripes[i].length / Vcb->superblock.node_size; j++) {
tree_header* th = (tree_header*)&context->stripes[i].buf[j * Vcb->superblock.node_size];
if (!check_tree_checksum(Vcb, th) || th->address != offset + UInt32x32To64(j, Vcb->superblock.node_size)) {
context->stripes[i].csum_error = true;
csum_error = true;
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
}
if (!context->stripes[i].csum_error)
good_stripe = i;
}
}
}
}
if (!csum_error)
return STATUS_SUCCESS;
// handle checksum error
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (context->stripes[i].csum_error) {
if (csum) {
context->stripes[i].bad_csums = ExAllocatePoolWithTag(PagedPool, context->stripes[i].length * Vcb->csum_size / Vcb->superblock.sector_size, ALLOC_TAG);
if (!context->stripes[i].bad_csums) {
ERR("out of memory\n");
return STATUS_INSUFFICIENT_RESOURCES;
}
do_calc_job(Vcb, context->stripes[i].buf, context->stripes[i].length / Vcb->superblock.sector_size, context->stripes[i].bad_csums);
} else {
ULONG j;
context->stripes[i].bad_csums = ExAllocatePoolWithTag(PagedPool, context->stripes[i].length * Vcb->csum_size / Vcb->superblock.node_size, ALLOC_TAG);
if (!context->stripes[i].bad_csums) {
ERR("out of memory\n");
return STATUS_INSUFFICIENT_RESOURCES;
}
for (j = 0; j < context->stripes[i].length / Vcb->superblock.node_size; j++) {
tree_header* th = (tree_header*)&context->stripes[i].buf[j * Vcb->superblock.node_size];
get_tree_checksum(Vcb, th, (uint8_t*)context->stripes[i].bad_csums + (Vcb->csum_size * j));
}
}
}
}
if (present_devices > 1) {
ULONG good_stripe = 0xffffffff;
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (c->devices[i]->devobj && !context->stripes[i].csum_error) {
good_stripe = i;
break;
}
}
if (good_stripe != 0xffffffff) {
// log
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (context->stripes[i].csum_error) {
ULONG j;
if (csum) {
for (j = 0; j < context->stripes[i].length / Vcb->superblock.sector_size; j++) {
if (RtlCompareMemory((uint8_t*)context->stripes[i].bad_csums + (j * Vcb->csum_size), (uint8_t*)csum + (j + Vcb->csum_size), Vcb->csum_size) != Vcb->csum_size) {
uint64_t addr = offset + UInt32x32To64(j, Vcb->superblock.sector_size);
log_error(Vcb, addr, c->devices[i]->devitem.dev_id, false, true, false);
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
}
} else {
for (j = 0; j < context->stripes[i].length / Vcb->superblock.node_size; j++) {
tree_header* th = (tree_header*)&context->stripes[i].buf[j * Vcb->superblock.node_size];
uint64_t addr = offset + UInt32x32To64(j, Vcb->superblock.node_size);
if (RtlCompareMemory((uint8_t*)context->stripes[i].bad_csums + (j * Vcb->csum_size), th, Vcb->csum_size) != Vcb->csum_size || th->address != addr) {
log_error(Vcb, addr, c->devices[i]->devitem.dev_id, true, true, false);
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
}
}
}
}
// write good data over bad
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (context->stripes[i].csum_error && !c->devices[i]->readonly) {
Status = write_data_phys(c->devices[i]->devobj, c->devices[i]->fileobj, cis[i].offset + offset - c->offset,
context->stripes[good_stripe].buf, context->stripes[i].length);
if (!NT_SUCCESS(Status)) {
ERR("write_data_phys returned %08lx\n", Status);
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_WRITE_ERRORS);
return Status;
}
}
}
return STATUS_SUCCESS;
}
// if csum errors on all stripes, check sector by sector
for (i = 0; i < c->chunk_item->num_stripes; i++) {
ULONG j;
if (c->devices[i]->devobj) {
if (csum) {
for (j = 0; j < context->stripes[i].length / Vcb->superblock.sector_size; j++) {
if (RtlCompareMemory((uint8_t*)context->stripes[i].bad_csums + (j * Vcb->csum_size), (uint8_t*)csum + (j * Vcb->csum_size), Vcb->csum_size) != Vcb->csum_size) {
ULONG k;
uint64_t addr = offset + UInt32x32To64(j, Vcb->superblock.sector_size);
bool recovered = false;
for (k = 0; k < c->chunk_item->num_stripes; k++) {
if (i != k && c->devices[k]->devobj &&
RtlCompareMemory((uint8_t*)context->stripes[k].bad_csums + (j * Vcb->csum_size),
(uint8_t*)csum + (j * Vcb->csum_size), Vcb->csum_size) == Vcb->csum_size) {
log_error(Vcb, addr, c->devices[i]->devitem.dev_id, false, true, false);
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
RtlCopyMemory(context->stripes[i].buf + (j * Vcb->superblock.sector_size),
context->stripes[k].buf + (j * Vcb->superblock.sector_size), Vcb->superblock.sector_size);
recovered = true;
break;
}
}
if (!recovered) {
log_error(Vcb, addr, c->devices[i]->devitem.dev_id, false, false, false);
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
}
}
} else {
for (j = 0; j < context->stripes[i].length / Vcb->superblock.node_size; j++) {
tree_header* th = (tree_header*)&context->stripes[i].buf[j * Vcb->superblock.node_size];
uint64_t addr = offset + UInt32x32To64(j, Vcb->superblock.node_size);
if (RtlCompareMemory((uint8_t*)context->stripes[i].bad_csums + (j * Vcb->csum_size), th, Vcb->csum_size) != Vcb->csum_size || th->address != addr) {
ULONG k;
bool recovered = false;
for (k = 0; k < c->chunk_item->num_stripes; k++) {
if (i != k && c->devices[k]->devobj) {
tree_header* th2 = (tree_header*)&context->stripes[k].buf[j * Vcb->superblock.node_size];
if (RtlCompareMemory((uint8_t*)context->stripes[k].bad_csums + (j * Vcb->csum_size), th2, Vcb->csum_size) == Vcb->csum_size && th2->address == addr) {
log_error(Vcb, addr, c->devices[i]->devitem.dev_id, true, true, false);
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
RtlCopyMemory(th, th2, Vcb->superblock.node_size);
recovered = true;
break;
}
}
}
if (!recovered) {
log_error(Vcb, addr, c->devices[i]->devitem.dev_id, true, false, false);
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
}
}
}
}
}
// write good data over bad
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (c->devices[i]->devobj && !c->devices[i]->readonly) {
Status = write_data_phys(c->devices[i]->devobj, c->devices[i]->fileobj, cis[i].offset + offset - c->offset,
context->stripes[i].buf, context->stripes[i].length);
if (!NT_SUCCESS(Status)) {
ERR("write_data_phys returned %08lx\n", Status);
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
return Status;
}
}
}
return STATUS_SUCCESS;
}
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (c->devices[i]->devobj) {
ULONG j;
if (csum) {
for (j = 0; j < context->stripes[i].length / Vcb->superblock.sector_size; j++) {
if (RtlCompareMemory((uint8_t*)context->stripes[i].bad_csums + (j * Vcb->csum_size), (uint8_t*)csum + (j + Vcb->csum_size), Vcb->csum_size) != Vcb->csum_size) {
uint64_t addr = offset + UInt32x32To64(j, Vcb->superblock.sector_size);
log_error(Vcb, addr, c->devices[i]->devitem.dev_id, false, false, false);
}
}
} else {
for (j = 0; j < context->stripes[i].length / Vcb->superblock.node_size; j++) {
tree_header* th = (tree_header*)&context->stripes[i].buf[j * Vcb->superblock.node_size];
uint64_t addr = offset + UInt32x32To64(j, Vcb->superblock.node_size);
if (RtlCompareMemory((uint8_t*)context->stripes[i].bad_csums + (j * Vcb->csum_size), th, Vcb->csum_size) != Vcb->csum_size || th->address != addr)
log_error(Vcb, addr, c->devices[i]->devitem.dev_id, true, false, false);
}
}
}
}
return STATUS_SUCCESS;
}
static NTSTATUS scrub_extent_raid0(device_extension* Vcb, chunk* c, uint64_t offset, uint32_t length, uint16_t startoffstripe, void* csum, scrub_context* context) {
ULONG j;
uint16_t stripe;
uint32_t pos, *stripeoff;
pos = 0;
stripeoff = ExAllocatePoolWithTag(NonPagedPool, sizeof(uint32_t) * c->chunk_item->num_stripes, ALLOC_TAG);
if (!stripeoff) {
ERR("out of memory\n");
return STATUS_INSUFFICIENT_RESOURCES;
}
RtlZeroMemory(stripeoff, sizeof(uint32_t) * c->chunk_item->num_stripes);
stripe = startoffstripe;
while (pos < length) {
uint32_t readlen;
if (pos == 0)
readlen = (uint32_t)min(context->stripes[stripe].length, c->chunk_item->stripe_length - (context->stripes[stripe].start % c->chunk_item->stripe_length));
else
readlen = min(length - pos, (uint32_t)c->chunk_item->stripe_length);
if (csum) {
for (j = 0; j < readlen; j += Vcb->superblock.sector_size) {
if (!check_sector_csum(Vcb, context->stripes[stripe].buf + stripeoff[stripe], (uint8_t*)csum + (pos * Vcb->csum_size / Vcb->superblock.sector_size))) {
uint64_t addr = offset + pos;
log_error(Vcb, addr, c->devices[stripe]->devitem.dev_id, false, false, false);
log_device_error(Vcb, c->devices[stripe], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
pos += Vcb->superblock.sector_size;
stripeoff[stripe] += Vcb->superblock.sector_size;
}
} else {
for (j = 0; j < readlen; j += Vcb->superblock.node_size) {
tree_header* th = (tree_header*)(context->stripes[stripe].buf + stripeoff[stripe]);
uint64_t addr = offset + pos;
if (!check_tree_checksum(Vcb, th) || th->address != addr) {
log_error(Vcb, addr, c->devices[stripe]->devitem.dev_id, true, false, false);
log_device_error(Vcb, c->devices[stripe], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
pos += Vcb->superblock.node_size;
stripeoff[stripe] += Vcb->superblock.node_size;
}
}
stripe = (stripe + 1) % c->chunk_item->num_stripes;
}
ExFreePool(stripeoff);
return STATUS_SUCCESS;
}
static NTSTATUS scrub_extent_raid10(device_extension* Vcb, chunk* c, uint64_t offset, uint32_t length, uint16_t startoffstripe, void* csum, scrub_context* context) {
ULONG j;
uint16_t stripe, sub_stripes = max(c->chunk_item->sub_stripes, 1);
uint32_t pos, *stripeoff;
bool csum_error = false;
NTSTATUS Status;
pos = 0;
stripeoff = ExAllocatePoolWithTag(NonPagedPool, sizeof(uint32_t) * c->chunk_item->num_stripes / sub_stripes, ALLOC_TAG);
if (!stripeoff) {
ERR("out of memory\n");
return STATUS_INSUFFICIENT_RESOURCES;
}
RtlZeroMemory(stripeoff, sizeof(uint32_t) * c->chunk_item->num_stripes / sub_stripes);
stripe = startoffstripe;
while (pos < length) {
uint32_t readlen;
if (pos == 0)
readlen = (uint32_t)min(context->stripes[stripe * sub_stripes].length,
c->chunk_item->stripe_length - (context->stripes[stripe * sub_stripes].start % c->chunk_item->stripe_length));
else
readlen = min(length - pos, (uint32_t)c->chunk_item->stripe_length);
if (csum) {
ULONG good_stripe = 0xffffffff;
uint16_t k;
for (k = 0; k < sub_stripes; k++) {
if (c->devices[(stripe * sub_stripes) + k]->devobj) {
// if first stripe is okay, we only need to check that the others are identical to it
if (good_stripe != 0xffffffff) {
if (RtlCompareMemory(context->stripes[(stripe * sub_stripes) + k].buf + stripeoff[stripe],
context->stripes[(stripe * sub_stripes) + good_stripe].buf + stripeoff[stripe],
readlen) != readlen) {
context->stripes[(stripe * sub_stripes) + k].csum_error = true;
csum_error = true;
log_device_error(Vcb, c->devices[(stripe * sub_stripes) + k], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
} else {
for (j = 0; j < readlen; j += Vcb->superblock.sector_size) {
if (!check_sector_csum(Vcb, context->stripes[(stripe * sub_stripes) + k].buf + stripeoff[stripe] + j,
(uint8_t*)csum + ((pos + j) * Vcb->csum_size / Vcb->superblock.sector_size))) {
csum_error = true;
context->stripes[(stripe * sub_stripes) + k].csum_error = true;
log_device_error(Vcb, c->devices[(stripe * sub_stripes) + k], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
break;
}
}
if (!context->stripes[(stripe * sub_stripes) + k].csum_error)
good_stripe = k;
}
}
}
pos += readlen;
stripeoff[stripe] += readlen;
} else {
ULONG good_stripe = 0xffffffff;
uint16_t k;
for (k = 0; k < sub_stripes; k++) {
if (c->devices[(stripe * sub_stripes) + k]->devobj) {
// if first stripe is okay, we only need to check that the others are identical to it
if (good_stripe != 0xffffffff) {
if (RtlCompareMemory(context->stripes[(stripe * sub_stripes) + k].buf + stripeoff[stripe],
context->stripes[(stripe * sub_stripes) + good_stripe].buf + stripeoff[stripe],
readlen) != readlen) {
context->stripes[(stripe * sub_stripes) + k].csum_error = true;
csum_error = true;
log_device_error(Vcb, c->devices[(stripe * sub_stripes) + k], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
} else {
for (j = 0; j < readlen; j += Vcb->superblock.node_size) {
tree_header* th = (tree_header*)(context->stripes[(stripe * sub_stripes) + k].buf + stripeoff[stripe] + j);
uint64_t addr = offset + pos + j;
if (!check_tree_checksum(Vcb, th) || th->address != addr) {
csum_error = true;
context->stripes[(stripe * sub_stripes) + k].csum_error = true;
log_device_error(Vcb, c->devices[(stripe * sub_stripes) + k], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
break;
}
}
if (!context->stripes[(stripe * sub_stripes) + k].csum_error)
good_stripe = k;
}
}
}
pos += readlen;
stripeoff[stripe] += readlen;
}
stripe = (stripe + 1) % (c->chunk_item->num_stripes / sub_stripes);
}
if (!csum_error) {
Status = STATUS_SUCCESS;
goto end;
}
for (j = 0; j < c->chunk_item->num_stripes; j += sub_stripes) {
ULONG goodstripe = 0xffffffff;
uint16_t k;
bool hasbadstripe = false;
if (context->stripes[j].length == 0)
continue;
for (k = 0; k < sub_stripes; k++) {
if (c->devices[j + k]->devobj) {
if (!context->stripes[j + k].csum_error)
goodstripe = k;
else
hasbadstripe = true;
}
}
if (hasbadstripe) {
if (goodstripe != 0xffffffff) {
for (k = 0; k < sub_stripes; k++) {
if (c->devices[j + k]->devobj && context->stripes[j + k].csum_error) {
uint32_t so = 0;
bool recovered = false;
pos = 0;
stripe = startoffstripe;
while (pos < length) {
uint32_t readlen;
if (pos == 0)
readlen = (uint32_t)min(context->stripes[stripe * sub_stripes].length,
c->chunk_item->stripe_length - (context->stripes[stripe * sub_stripes].start % c->chunk_item->stripe_length));
else
readlen = min(length - pos, (uint32_t)c->chunk_item->stripe_length);
if (stripe == j / sub_stripes) {
if (csum) {
ULONG l;
for (l = 0; l < readlen; l += Vcb->superblock.sector_size) {
if (RtlCompareMemory(context->stripes[j + k].buf + so,
context->stripes[j + goodstripe].buf + so,
Vcb->superblock.sector_size) != Vcb->superblock.sector_size) {
uint64_t addr = offset + pos;
log_error(Vcb, addr, c->devices[j + k]->devitem.dev_id, false, true, false);
recovered = true;
}
pos += Vcb->superblock.sector_size;
so += Vcb->superblock.sector_size;
}
} else {
ULONG l;
for (l = 0; l < readlen; l += Vcb->superblock.node_size) {
if (RtlCompareMemory(context->stripes[j + k].buf + so,
context->stripes[j + goodstripe].buf + so,
Vcb->superblock.node_size) != Vcb->superblock.node_size) {
uint64_t addr = offset + pos;
log_error(Vcb, addr, c->devices[j + k]->devitem.dev_id, true, true, false);
recovered = true;
}
pos += Vcb->superblock.node_size;
so += Vcb->superblock.node_size;
}
}
} else
pos += readlen;
stripe = (stripe + 1) % (c->chunk_item->num_stripes / sub_stripes);
}
if (recovered) {
// write good data over bad
if (!c->devices[j + k]->readonly) {
CHUNK_ITEM_STRIPE* cis = (CHUNK_ITEM_STRIPE*)&c->chunk_item[1];
Status = write_data_phys(c->devices[j + k]->devobj, c->devices[j + k]->fileobj, cis[j + k].offset + offset - c->offset,
context->stripes[j + goodstripe].buf, context->stripes[j + goodstripe].length);
if (!NT_SUCCESS(Status)) {
ERR("write_data_phys returned %08lx\n", Status);
log_device_error(Vcb, c->devices[j + k], BTRFS_DEV_STAT_WRITE_ERRORS);
goto end;
}
}
}
}
}
} else {
uint32_t so = 0;
bool recovered = false;
if (csum) {
for (k = 0; k < sub_stripes; k++) {
if (c->devices[j + k]->devobj) {
context->stripes[j + k].bad_csums = ExAllocatePoolWithTag(PagedPool, context->stripes[j + k].length * Vcb->csum_size / Vcb->superblock.sector_size,
ALLOC_TAG);
if (!context->stripes[j + k].bad_csums) {
ERR("out of memory\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
do_calc_job(Vcb, context->stripes[j + k].buf, context->stripes[j + k].length / Vcb->superblock.sector_size, context->stripes[j + k].bad_csums);
}
}
} else {
for (k = 0; k < sub_stripes; k++) {
if (c->devices[j + k]->devobj) {
ULONG l;
context->stripes[j + k].bad_csums = ExAllocatePoolWithTag(PagedPool, context->stripes[j + k].length * Vcb->csum_size / Vcb->superblock.node_size,
ALLOC_TAG);
if (!context->stripes[j + k].bad_csums) {
ERR("out of memory\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
for (l = 0; l < context->stripes[j + k].length / Vcb->superblock.node_size; l++) {
tree_header* th = (tree_header*)&context->stripes[j + k].buf[l * Vcb->superblock.node_size];
get_tree_checksum(Vcb, th, (uint8_t*)context->stripes[j + k].bad_csums + (Vcb->csum_size * l));
}
}
}
}
pos = 0;
stripe = startoffstripe;
while (pos < length) {
uint32_t readlen;
if (pos == 0)
readlen = (uint32_t)min(context->stripes[stripe * sub_stripes].length,
c->chunk_item->stripe_length - (context->stripes[stripe * sub_stripes].start % c->chunk_item->stripe_length));
else
readlen = min(length - pos, (uint32_t)c->chunk_item->stripe_length);
if (stripe == j / sub_stripes) {
ULONG l;
if (csum) {
for (l = 0; l < readlen; l += Vcb->superblock.sector_size) {
bool has_error = false;
goodstripe = 0xffffffff;
for (k = 0; k < sub_stripes; k++) {
if (c->devices[j + k]->devobj) {
if (RtlCompareMemory((uint8_t*)context->stripes[j + k].bad_csums + (so * Vcb->csum_size / Vcb->superblock.sector_size),
(uint8_t*)csum + (pos * Vcb->csum_size / Vcb->superblock.sector_size),
Vcb->csum_size) != Vcb->csum_size) {
has_error = true;
} else
goodstripe = k;
}
}
if (has_error) {
if (goodstripe != 0xffffffff) {
for (k = 0; k < sub_stripes; k++) {
if (c->devices[j + k]->devobj &&
RtlCompareMemory((uint8_t*)context->stripes[j + k].bad_csums + (so * Vcb->csum_size / Vcb->superblock.sector_size),
(uint8_t*)csum + (pos * Vcb->csum_size / Vcb->superblock.sector_size),
Vcb->csum_size) != Vcb->csum_size) {
uint64_t addr = offset + pos;
log_error(Vcb, addr, c->devices[j + k]->devitem.dev_id, false, true, false);
recovered = true;
RtlCopyMemory(context->stripes[j + k].buf + so, context->stripes[j + goodstripe].buf + so,
Vcb->superblock.sector_size);
}
}
} else {
uint64_t addr = offset + pos;
for (k = 0; k < sub_stripes; k++) {
if (c->devices[j + j]->devobj) {
log_error(Vcb, addr, c->devices[j + k]->devitem.dev_id, false, false, false);
log_device_error(Vcb, c->devices[j + k], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
}
}
}
pos += Vcb->superblock.sector_size;
so += Vcb->superblock.sector_size;
}
} else {
for (l = 0; l < readlen; l += Vcb->superblock.node_size) {
for (k = 0; k < sub_stripes; k++) {
if (c->devices[j + k]->devobj) {
tree_header* th = (tree_header*)&context->stripes[j + k].buf[so];
uint64_t addr = offset + pos;
if (RtlCompareMemory((uint8_t*)context->stripes[j + k].bad_csums + (so * Vcb->csum_size / Vcb->superblock.node_size), th, Vcb->csum_size) != Vcb->csum_size || th->address != addr) {
ULONG m;
recovered = false;
for (m = 0; m < sub_stripes; m++) {
if (m != k) {
tree_header* th2 = (tree_header*)&context->stripes[j + m].buf[so];
if (RtlCompareMemory((uint8_t*)context->stripes[j + m].bad_csums + (so * Vcb->csum_size / Vcb->superblock.node_size), th2, Vcb->csum_size) == Vcb->csum_size && th2->address == addr) {
log_error(Vcb, addr, c->devices[j + k]->devitem.dev_id, true, true, false);
RtlCopyMemory(th, th2, Vcb->superblock.node_size);
recovered = true;
break;
} else
log_device_error(Vcb, c->devices[j + m], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
}
if (!recovered)
log_error(Vcb, addr, c->devices[j + k]->devitem.dev_id, true, false, false);
}
}
}
pos += Vcb->superblock.node_size;
so += Vcb->superblock.node_size;
}
}
} else
pos += readlen;
stripe = (stripe + 1) % (c->chunk_item->num_stripes / sub_stripes);
}
if (recovered) {
// write good data over bad
for (k = 0; k < sub_stripes; k++) {
if (c->devices[j + k]->devobj && !c->devices[j + k]->readonly) {
CHUNK_ITEM_STRIPE* cis = (CHUNK_ITEM_STRIPE*)&c->chunk_item[1];
Status = write_data_phys(c->devices[j + k]->devobj, c->devices[j + k]->fileobj, cis[j + k].offset + offset - c->offset,
context->stripes[j + k].buf, context->stripes[j + k].length);
if (!NT_SUCCESS(Status)) {
ERR("write_data_phys returned %08lx\n", Status);
log_device_error(Vcb, c->devices[j + k], BTRFS_DEV_STAT_WRITE_ERRORS);
goto end;
}
}
}
}
}
}
}
Status = STATUS_SUCCESS;
end:
ExFreePool(stripeoff);
return Status;
}
static NTSTATUS scrub_extent(device_extension* Vcb, chunk* c, ULONG type, uint64_t offset, uint32_t size, void* csum) {
ULONG i;
scrub_context context;
CHUNK_ITEM_STRIPE* cis;
NTSTATUS Status;
uint16_t startoffstripe, num_missing, allowed_missing;
TRACE("(%p, %p, %lx, %I64x, %x, %p)\n", Vcb, c, type, offset, size, csum);
context.stripes = ExAllocatePoolWithTag(NonPagedPool, sizeof(scrub_context_stripe) * c->chunk_item->num_stripes, ALLOC_TAG);
if (!context.stripes) {
ERR("out of memory\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
RtlZeroMemory(context.stripes, sizeof(scrub_context_stripe) * c->chunk_item->num_stripes);
context.stripes_left = 0;
cis = (CHUNK_ITEM_STRIPE*)&c->chunk_item[1];
if (type == BLOCK_FLAG_RAID0) {
uint64_t startoff, endoff;
uint16_t endoffstripe;
get_raid0_offset(offset - c->offset, c->chunk_item->stripe_length, c->chunk_item->num_stripes, &startoff, &startoffstripe);
get_raid0_offset(offset + size - c->offset - 1, c->chunk_item->stripe_length, c->chunk_item->num_stripes, &endoff, &endoffstripe);
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (startoffstripe > i)
context.stripes[i].start = startoff - (startoff % c->chunk_item->stripe_length) + c->chunk_item->stripe_length;
else if (startoffstripe == i)
context.stripes[i].start = startoff;
else
context.stripes[i].start = startoff - (startoff % c->chunk_item->stripe_length);
if (endoffstripe > i)
context.stripes[i].length = (uint32_t)(endoff - (endoff % c->chunk_item->stripe_length) + c->chunk_item->stripe_length - context.stripes[i].start);
else if (endoffstripe == i)
context.stripes[i].length = (uint32_t)(endoff + 1 - context.stripes[i].start);
else
context.stripes[i].length = (uint32_t)(endoff - (endoff % c->chunk_item->stripe_length) - context.stripes[i].start);
}
allowed_missing = 0;
} else if (type == BLOCK_FLAG_RAID10) {
uint64_t startoff, endoff;
uint16_t endoffstripe, j, sub_stripes = max(c->chunk_item->sub_stripes, 1);
get_raid0_offset(offset - c->offset, c->chunk_item->stripe_length, c->chunk_item->num_stripes / sub_stripes, &startoff, &startoffstripe);
get_raid0_offset(offset + size - c->offset - 1, c->chunk_item->stripe_length, c->chunk_item->num_stripes / sub_stripes, &endoff, &endoffstripe);
if ((c->chunk_item->num_stripes % sub_stripes) != 0) {
ERR("chunk %I64x: num_stripes %x was not a multiple of sub_stripes %x!\n", c->offset, c->chunk_item->num_stripes, sub_stripes);
Status = STATUS_INTERNAL_ERROR;
goto end;
}
startoffstripe *= sub_stripes;
endoffstripe *= sub_stripes;
for (i = 0; i < c->chunk_item->num_stripes; i += sub_stripes) {
if (startoffstripe > i)
context.stripes[i].start = startoff - (startoff % c->chunk_item->stripe_length) + c->chunk_item->stripe_length;
else if (startoffstripe == i)
context.stripes[i].start = startoff;
else
context.stripes[i].start = startoff - (startoff % c->chunk_item->stripe_length);
if (endoffstripe > i)
context.stripes[i].length = (uint32_t)(endoff - (endoff % c->chunk_item->stripe_length) + c->chunk_item->stripe_length - context.stripes[i].start);
else if (endoffstripe == i)
context.stripes[i].length = (uint32_t)(endoff + 1 - context.stripes[i].start);
else
context.stripes[i].length = (uint32_t)(endoff - (endoff % c->chunk_item->stripe_length) - context.stripes[i].start);
for (j = 1; j < sub_stripes; j++) {
context.stripes[i+j].start = context.stripes[i].start;
context.stripes[i+j].length = context.stripes[i].length;
}
}
startoffstripe /= sub_stripes;
allowed_missing = 1;
} else
allowed_missing = c->chunk_item->num_stripes - 1;
num_missing = 0;
for (i = 0; i < c->chunk_item->num_stripes; i++) {
PIO_STACK_LOCATION IrpSp;
context.stripes[i].context = (struct _scrub_context*)&context;
if (type == BLOCK_FLAG_DUPLICATE) {
context.stripes[i].start = offset - c->offset;
context.stripes[i].length = size;
} else if (type != BLOCK_FLAG_RAID0 && type != BLOCK_FLAG_RAID10) {
ERR("unexpected chunk type %lx\n", type);
Status = STATUS_INTERNAL_ERROR;
goto end;
}
if (!c->devices[i]->devobj) {
num_missing++;
if (num_missing > allowed_missing) {
ERR("too many missing devices (at least %u, maximum allowed %u)\n", num_missing, allowed_missing);
Status = STATUS_INTERNAL_ERROR;
goto end;
}
} else if (context.stripes[i].length > 0) {
context.stripes[i].buf = ExAllocatePoolWithTag(NonPagedPool, context.stripes[i].length, ALLOC_TAG);
if (!context.stripes[i].buf) {
ERR("out of memory\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
context.stripes[i].Irp = IoAllocateIrp(c->devices[i]->devobj->StackSize, false);
if (!context.stripes[i].Irp) {
ERR("IoAllocateIrp failed\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
IrpSp = IoGetNextIrpStackLocation(context.stripes[i].Irp);
IrpSp->MajorFunction = IRP_MJ_READ;
IrpSp->FileObject = c->devices[i]->fileobj;
if (c->devices[i]->devobj->Flags & DO_BUFFERED_IO) {
context.stripes[i].Irp->AssociatedIrp.SystemBuffer = ExAllocatePoolWithTag(NonPagedPool, context.stripes[i].length, ALLOC_TAG);
if (!context.stripes[i].Irp->AssociatedIrp.SystemBuffer) {
ERR("out of memory\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
context.stripes[i].Irp->Flags |= IRP_BUFFERED_IO | IRP_DEALLOCATE_BUFFER | IRP_INPUT_OPERATION;
context.stripes[i].Irp->UserBuffer = context.stripes[i].buf;
} else if (c->devices[i]->devobj->Flags & DO_DIRECT_IO) {
context.stripes[i].Irp->MdlAddress = IoAllocateMdl(context.stripes[i].buf, context.stripes[i].length, false, false, NULL);
if (!context.stripes[i].Irp->MdlAddress) {
ERR("IoAllocateMdl failed\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
Status = STATUS_SUCCESS;
_SEH2_TRY {
MmProbeAndLockPages(context.stripes[i].Irp->MdlAddress, KernelMode, IoWriteAccess);
} _SEH2_EXCEPT (EXCEPTION_EXECUTE_HANDLER) {
Status = _SEH2_GetExceptionCode();
} _SEH2_END;
if (!NT_SUCCESS(Status)) {
ERR("MmProbeAndLockPages threw exception %08lx\n", Status);
IoFreeMdl(context.stripes[i].Irp->MdlAddress);
context.stripes[i].Irp->MdlAddress = NULL;
goto end;
}
} else
context.stripes[i].Irp->UserBuffer = context.stripes[i].buf;
IrpSp->Parameters.Read.Length = context.stripes[i].length;
IrpSp->Parameters.Read.ByteOffset.QuadPart = context.stripes[i].start + cis[i].offset;
context.stripes[i].Irp->UserIosb = &context.stripes[i].iosb;
IoSetCompletionRoutine(context.stripes[i].Irp, scrub_read_completion, &context.stripes[i], true, true, true);
context.stripes_left++;
Vcb->scrub.data_scrubbed += context.stripes[i].length;
}
}
if (context.stripes_left == 0) {
ERR("error - not reading any stripes\n");
Status = STATUS_INTERNAL_ERROR;
goto end;
}
KeInitializeEvent(&context.Event, NotificationEvent, false);
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (c->devices[i]->devobj && context.stripes[i].length > 0)
IoCallDriver(c->devices[i]->devobj, context.stripes[i].Irp);
}
KeWaitForSingleObject(&context.Event, Executive, KernelMode, false, NULL);
// return an error if any of the stripes returned an error
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (!NT_SUCCESS(context.stripes[i].iosb.Status)) {
Status = context.stripes[i].iosb.Status;
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_READ_ERRORS);
goto end;
}
}
if (type == BLOCK_FLAG_DUPLICATE) {
Status = scrub_extent_dup(Vcb, c, offset, csum, &context);
if (!NT_SUCCESS(Status)) {
ERR("scrub_extent_dup returned %08lx\n", Status);
goto end;
}
} else if (type == BLOCK_FLAG_RAID0) {
Status = scrub_extent_raid0(Vcb, c, offset, size, startoffstripe, csum, &context);
if (!NT_SUCCESS(Status)) {
ERR("scrub_extent_raid0 returned %08lx\n", Status);
goto end;
}
} else if (type == BLOCK_FLAG_RAID10) {
Status = scrub_extent_raid10(Vcb, c, offset, size, startoffstripe, csum, &context);
if (!NT_SUCCESS(Status)) {
ERR("scrub_extent_raid10 returned %08lx\n", Status);
goto end;
}
}
end:
if (context.stripes) {
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (context.stripes[i].Irp) {
if (c->devices[i]->devobj->Flags & DO_DIRECT_IO && context.stripes[i].Irp->MdlAddress) {
MmUnlockPages(context.stripes[i].Irp->MdlAddress);
IoFreeMdl(context.stripes[i].Irp->MdlAddress);
}
IoFreeIrp(context.stripes[i].Irp);
}
if (context.stripes[i].buf)
ExFreePool(context.stripes[i].buf);
if (context.stripes[i].bad_csums)
ExFreePool(context.stripes[i].bad_csums);
}
ExFreePool(context.stripes);
}
return Status;
}
static NTSTATUS scrub_data_extent(device_extension* Vcb, chunk* c, uint64_t offset, ULONG type, void* csum, RTL_BITMAP* bmp, ULONG bmplen) {
NTSTATUS Status;
ULONG runlength, index;
runlength = RtlFindFirstRunClear(bmp, &index);
while (runlength != 0) {
if (index >= bmplen)
break;
if (index + runlength >= bmplen) {
runlength = bmplen - index;
if (runlength == 0)
break;
}
do {
ULONG rl;
if (runlength * Vcb->superblock.sector_size > SCRUB_UNIT)
rl = SCRUB_UNIT / Vcb->superblock.sector_size;
else
rl = runlength;
Status = scrub_extent(Vcb, c, type, offset + UInt32x32To64(index, Vcb->superblock.sector_size),
rl * Vcb->superblock.sector_size, (uint8_t*)csum + (index * Vcb->csum_size));
if (!NT_SUCCESS(Status)) {
ERR("scrub_data_extent_dup returned %08lx\n", Status);
return Status;
}
runlength -= rl;
index += rl;
} while (runlength > 0);
runlength = RtlFindNextForwardRunClear(bmp, index, &index);
}
return STATUS_SUCCESS;
}
typedef struct {
uint8_t* buf;
PIRP Irp;
void* context;
IO_STATUS_BLOCK iosb;
uint64_t offset;
bool rewrite, missing;
RTL_BITMAP error;
ULONG* errorarr;
} scrub_context_raid56_stripe;
typedef struct {
scrub_context_raid56_stripe* stripes;
LONG stripes_left;
KEVENT Event;
RTL_BITMAP alloc;
RTL_BITMAP has_csum;
RTL_BITMAP is_tree;
void* csum;
uint8_t* parity_scratch;
uint8_t* parity_scratch2;
} scrub_context_raid56;
_Function_class_(IO_COMPLETION_ROUTINE)
static NTSTATUS __stdcall scrub_read_completion_raid56(PDEVICE_OBJECT DeviceObject, PIRP Irp, PVOID conptr) {
scrub_context_raid56_stripe* stripe = conptr;
scrub_context_raid56* context = (scrub_context_raid56*)stripe->context;
LONG left = InterlockedDecrement(&context->stripes_left);
UNUSED(DeviceObject);
stripe->iosb = Irp->IoStatus;
if (left == 0)
KeSetEvent(&context->Event, 0, false);
return STATUS_MORE_PROCESSING_REQUIRED;
}
static void scrub_raid5_stripe(device_extension* Vcb, chunk* c, scrub_context_raid56* context, uint64_t stripe_start, uint64_t bit_start,
uint64_t num, uint16_t missing_devices) {
ULONG sectors_per_stripe = (ULONG)(c->chunk_item->stripe_length / Vcb->superblock.sector_size), i, off;
uint16_t stripe, parity = (bit_start + num + c->chunk_item->num_stripes - 1) % c->chunk_item->num_stripes;
uint64_t stripeoff;
stripe = (parity + 1) % c->chunk_item->num_stripes;
off = (ULONG)(bit_start + num - stripe_start) * sectors_per_stripe * (c->chunk_item->num_stripes - 1);
stripeoff = num * sectors_per_stripe;
if (missing_devices == 0)
RtlCopyMemory(context->parity_scratch, &context->stripes[parity].buf[num * c->chunk_item->stripe_length], (ULONG)c->chunk_item->stripe_length);
while (stripe != parity) {
RtlClearAllBits(&context->stripes[stripe].error);
for (i = 0; i < sectors_per_stripe; i++) {
if (c->devices[stripe]->devobj && RtlCheckBit(&context->alloc, off)) {
if (RtlCheckBit(&context->is_tree, off)) {
tree_header* th = (tree_header*)&context->stripes[stripe].buf[stripeoff * Vcb->superblock.sector_size];
uint64_t addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 1) * c->chunk_item->stripe_length) + (off * Vcb->superblock.sector_size);
if (!check_tree_checksum(Vcb, th) || th->address != addr) {
RtlSetBits(&context->stripes[stripe].error, i, Vcb->superblock.node_size / Vcb->superblock.sector_size);
log_device_error(Vcb, c->devices[stripe], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
if (missing_devices > 0)
log_error(Vcb, addr, c->devices[stripe]->devitem.dev_id, true, false, false);
}
off += Vcb->superblock.node_size / Vcb->superblock.sector_size;
stripeoff += Vcb->superblock.node_size / Vcb->superblock.sector_size;
i += (Vcb->superblock.node_size / Vcb->superblock.sector_size) - 1;
continue;
} else if (RtlCheckBit(&context->has_csum, off)) {
if (!check_sector_csum(Vcb, context->stripes[stripe].buf + (stripeoff * Vcb->superblock.sector_size), (uint8_t*)context->csum + (Vcb->csum_size * off))) {
RtlSetBit(&context->stripes[stripe].error, i);
log_device_error(Vcb, c->devices[stripe], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
if (missing_devices > 0) {
uint64_t addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 1) * c->chunk_item->stripe_length) + (off * Vcb->superblock.sector_size);
log_error(Vcb, addr, c->devices[stripe]->devitem.dev_id, false, false, false);
}
}
}
}
off++;
stripeoff++;
}
if (missing_devices == 0)
do_xor(context->parity_scratch, &context->stripes[stripe].buf[num * c->chunk_item->stripe_length], (ULONG)c->chunk_item->stripe_length);
stripe = (stripe + 1) % c->chunk_item->num_stripes;
stripeoff = num * sectors_per_stripe;
}
// check parity
if (missing_devices == 0) {
RtlClearAllBits(&context->stripes[parity].error);
for (i = 0; i < sectors_per_stripe; i++) {
ULONG o, j;
o = i * Vcb->superblock.sector_size;
for (j = 0; j < Vcb->superblock.sector_size; j++) { // FIXME - use SSE
if (context->parity_scratch[o] != 0) {
RtlSetBit(&context->stripes[parity].error, i);
break;
}
o++;
}
}
}
// log and fix errors
if (missing_devices > 0)
return;
for (i = 0; i < sectors_per_stripe; i++) {
ULONG num_errors = 0, bad_off;
uint64_t bad_stripe;
bool alloc = false;
stripe = (parity + 1) % c->chunk_item->num_stripes;
off = (ULONG)((bit_start + num - stripe_start) * sectors_per_stripe * (c->chunk_item->num_stripes - 1)) + i;
while (stripe != parity) {
if (RtlCheckBit(&context->alloc, off)) {
alloc = true;
if (RtlCheckBit(&context->stripes[stripe].error, i)) {
bad_stripe = stripe;
bad_off = off;
num_errors++;
}
}
off += sectors_per_stripe;
stripe = (stripe + 1) % c->chunk_item->num_stripes;
}
if (!alloc)
continue;
if (num_errors == 0 && !RtlCheckBit(&context->stripes[parity].error, i)) // everything fine
continue;
if (num_errors == 0 && RtlCheckBit(&context->stripes[parity].error, i)) { // parity error
uint64_t addr;
do_xor(&context->stripes[parity].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch[i * Vcb->superblock.sector_size],
Vcb->superblock.sector_size);
bad_off = (ULONG)((bit_start + num - stripe_start) * sectors_per_stripe * (c->chunk_item->num_stripes - 1)) + i;
addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 1) * c->chunk_item->stripe_length) + (bad_off * Vcb->superblock.sector_size);
context->stripes[parity].rewrite = true;
log_error(Vcb, addr, c->devices[parity]->devitem.dev_id, false, true, true);
log_device_error(Vcb, c->devices[parity], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
} else if (num_errors == 1) {
uint64_t addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 1) * c->chunk_item->stripe_length) + (bad_off * Vcb->superblock.sector_size);
if (RtlCheckBit(&context->is_tree, bad_off)) {
tree_header* th;
do_xor(&context->parity_scratch[i * Vcb->superblock.sector_size],
&context->stripes[bad_stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.node_size);
th = (tree_header*)&context->parity_scratch[i * Vcb->superblock.sector_size];
if (check_tree_checksum(Vcb, th) && th->address == addr) {
RtlCopyMemory(&context->stripes[bad_stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch[i * Vcb->superblock.sector_size], Vcb->superblock.node_size);
context->stripes[bad_stripe].rewrite = true;
RtlClearBits(&context->stripes[bad_stripe].error, i + 1, (Vcb->superblock.node_size / Vcb->superblock.sector_size) - 1);
log_error(Vcb, addr, c->devices[bad_stripe]->devitem.dev_id, true, true, false);
} else
log_error(Vcb, addr, c->devices[bad_stripe]->devitem.dev_id, true, false, false);
} else {
uint8_t hash[MAX_HASH_SIZE];
do_xor(&context->parity_scratch[i * Vcb->superblock.sector_size],
&context->stripes[bad_stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.sector_size);
get_sector_csum(Vcb, &context->parity_scratch[i * Vcb->superblock.sector_size], hash);
if (RtlCompareMemory(hash, (uint8_t*)context->csum + (Vcb->csum_size * bad_off), Vcb->csum_size) == Vcb->csum_size) {
RtlCopyMemory(&context->stripes[bad_stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch[i * Vcb->superblock.sector_size], Vcb->superblock.sector_size);
context->stripes[bad_stripe].rewrite = true;
log_error(Vcb, addr, c->devices[bad_stripe]->devitem.dev_id, false, true, false);
} else
log_error(Vcb, addr, c->devices[bad_stripe]->devitem.dev_id, false, false, false);
}
} else {
stripe = (parity + 1) % c->chunk_item->num_stripes;
off = (ULONG)((bit_start + num - stripe_start) * sectors_per_stripe * (c->chunk_item->num_stripes - 1)) + i;
while (stripe != parity) {
if (RtlCheckBit(&context->alloc, off)) {
if (RtlCheckBit(&context->stripes[stripe].error, i)) {
uint64_t addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 1) * c->chunk_item->stripe_length) + (off * Vcb->superblock.sector_size);
log_error(Vcb, addr, c->devices[stripe]->devitem.dev_id, RtlCheckBit(&context->is_tree, off), false, false);
}
}
off += sectors_per_stripe;
stripe = (stripe + 1) % c->chunk_item->num_stripes;
}
}
}
}
static void scrub_raid6_stripe(device_extension* Vcb, chunk* c, scrub_context_raid56* context, uint64_t stripe_start, uint64_t bit_start,
uint64_t num, uint16_t missing_devices) {
ULONG sectors_per_stripe = (ULONG)(c->chunk_item->stripe_length / Vcb->superblock.sector_size), i, off;
uint16_t stripe, parity1 = (bit_start + num + c->chunk_item->num_stripes - 2) % c->chunk_item->num_stripes;
uint16_t parity2 = (parity1 + 1) % c->chunk_item->num_stripes;
uint64_t stripeoff;
stripe = (parity1 + 2) % c->chunk_item->num_stripes;
off = (ULONG)(bit_start + num - stripe_start) * sectors_per_stripe * (c->chunk_item->num_stripes - 2);
stripeoff = num * sectors_per_stripe;
if (c->devices[parity1]->devobj)
RtlCopyMemory(context->parity_scratch, &context->stripes[parity1].buf[num * c->chunk_item->stripe_length], (ULONG)c->chunk_item->stripe_length);
if (c->devices[parity2]->devobj)
RtlZeroMemory(context->parity_scratch2, (ULONG)c->chunk_item->stripe_length);
while (stripe != parity1) {
RtlClearAllBits(&context->stripes[stripe].error);
for (i = 0; i < sectors_per_stripe; i++) {
if (c->devices[stripe]->devobj && RtlCheckBit(&context->alloc, off)) {
if (RtlCheckBit(&context->is_tree, off)) {
tree_header* th = (tree_header*)&context->stripes[stripe].buf[stripeoff * Vcb->superblock.sector_size];
uint64_t addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 2) * c->chunk_item->stripe_length) + (off * Vcb->superblock.sector_size);
if (!check_tree_checksum(Vcb, th) || th->address != addr) {
RtlSetBits(&context->stripes[stripe].error, i, Vcb->superblock.node_size / Vcb->superblock.sector_size);
log_device_error(Vcb, c->devices[stripe], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
if (missing_devices == 2)
log_error(Vcb, addr, c->devices[stripe]->devitem.dev_id, true, false, false);
}
off += Vcb->superblock.node_size / Vcb->superblock.sector_size;
stripeoff += Vcb->superblock.node_size / Vcb->superblock.sector_size;
i += (Vcb->superblock.node_size / Vcb->superblock.sector_size) - 1;
continue;
} else if (RtlCheckBit(&context->has_csum, off)) {
uint8_t hash[MAX_HASH_SIZE];
get_sector_csum(Vcb, context->stripes[stripe].buf + (stripeoff * Vcb->superblock.sector_size), hash);
if (RtlCompareMemory(hash, (uint8_t*)context->csum + (Vcb->csum_size * off), Vcb->csum_size) != Vcb->csum_size) {
uint64_t addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 2) * c->chunk_item->stripe_length) + (off * Vcb->superblock.sector_size);
RtlSetBit(&context->stripes[stripe].error, i);
log_device_error(Vcb, c->devices[stripe], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
if (missing_devices == 2)
log_error(Vcb, addr, c->devices[stripe]->devitem.dev_id, false, false, false);
}
}
}
off++;
stripeoff++;
}
if (c->devices[parity1]->devobj)
do_xor(context->parity_scratch, &context->stripes[stripe].buf[num * c->chunk_item->stripe_length], (uint32_t)c->chunk_item->stripe_length);
stripe = (stripe + 1) % c->chunk_item->num_stripes;
stripeoff = num * sectors_per_stripe;
}
RtlClearAllBits(&context->stripes[parity1].error);
if (missing_devices == 0 || (missing_devices == 1 && !c->devices[parity2]->devobj)) {
// check parity 1
for (i = 0; i < sectors_per_stripe; i++) {
ULONG o, j;
o = i * Vcb->superblock.sector_size;
for (j = 0; j < Vcb->superblock.sector_size; j++) { // FIXME - use SSE
if (context->parity_scratch[o] != 0) {
RtlSetBit(&context->stripes[parity1].error, i);
break;
}
o++;
}
}
}
RtlClearAllBits(&context->stripes[parity2].error);
if (missing_devices == 0 || (missing_devices == 1 && !c->devices[parity1]->devobj)) {
// check parity 2
stripe = parity1 == 0 ? (c->chunk_item->num_stripes - 1) : (parity1 - 1);
while (stripe != parity2) {
galois_double(context->parity_scratch2, (uint32_t)c->chunk_item->stripe_length);
do_xor(context->parity_scratch2, &context->stripes[stripe].buf[num * c->chunk_item->stripe_length], (uint32_t)c->chunk_item->stripe_length);
stripe = stripe == 0 ? (c->chunk_item->num_stripes - 1) : (stripe - 1);
}
for (i = 0; i < sectors_per_stripe; i++) {
if (RtlCompareMemory(&context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch2[i * Vcb->superblock.sector_size], Vcb->superblock.sector_size) != Vcb->superblock.sector_size)
RtlSetBit(&context->stripes[parity2].error, i);
}
}
if (missing_devices == 2)
return;
// log and fix errors
for (i = 0; i < sectors_per_stripe; i++) {
ULONG num_errors = 0;
uint64_t bad_stripe1, bad_stripe2;
ULONG bad_off1, bad_off2;
bool alloc = false;
stripe = (parity1 + 2) % c->chunk_item->num_stripes;
off = (ULONG)((bit_start + num - stripe_start) * sectors_per_stripe * (c->chunk_item->num_stripes - 2)) + i;
while (stripe != parity1) {
if (RtlCheckBit(&context->alloc, off)) {
alloc = true;
if (!c->devices[stripe]->devobj || RtlCheckBit(&context->stripes[stripe].error, i)) {
if (num_errors == 0) {
bad_stripe1 = stripe;
bad_off1 = off;
} else if (num_errors == 1) {
bad_stripe2 = stripe;
bad_off2 = off;
}
num_errors++;
}
}
off += sectors_per_stripe;
stripe = (stripe + 1) % c->chunk_item->num_stripes;
}
if (!alloc)
continue;
if (num_errors == 0 && !RtlCheckBit(&context->stripes[parity1].error, i) && !RtlCheckBit(&context->stripes[parity2].error, i)) // everything fine
continue;
if (num_errors == 0) { // parity error
uint64_t addr;
if (RtlCheckBit(&context->stripes[parity1].error, i)) {
do_xor(&context->stripes[parity1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch[i * Vcb->superblock.sector_size],
Vcb->superblock.sector_size);
bad_off1 = (ULONG)((bit_start + num - stripe_start) * sectors_per_stripe * (c->chunk_item->num_stripes - 2)) + i;
addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 2) * c->chunk_item->stripe_length) + (bad_off1 * Vcb->superblock.sector_size);
context->stripes[parity1].rewrite = true;
log_error(Vcb, addr, c->devices[parity1]->devitem.dev_id, false, true, true);
log_device_error(Vcb, c->devices[parity1], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
if (RtlCheckBit(&context->stripes[parity2].error, i)) {
RtlCopyMemory(&context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch2[i * Vcb->superblock.sector_size],
Vcb->superblock.sector_size);
bad_off1 = (ULONG)((bit_start + num - stripe_start) * sectors_per_stripe * (c->chunk_item->num_stripes - 2)) + i;
addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 2) * c->chunk_item->stripe_length) + (bad_off1 * Vcb->superblock.sector_size);
context->stripes[parity2].rewrite = true;
log_error(Vcb, addr, c->devices[parity2]->devitem.dev_id, false, true, true);
log_device_error(Vcb, c->devices[parity2], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
} else if (num_errors == 1) {
uint32_t len;
uint16_t stripe_num, bad_stripe_num;
uint64_t addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 2) * c->chunk_item->stripe_length) + (bad_off1 * Vcb->superblock.sector_size);
uint8_t* scratch;
len = RtlCheckBit(&context->is_tree, bad_off1)? Vcb->superblock.node_size : Vcb->superblock.sector_size;
scratch = ExAllocatePoolWithTag(PagedPool, len, ALLOC_TAG);
if (!scratch) {
ERR("out of memory\n");
return;
}
RtlZeroMemory(scratch, len);
do_xor(&context->parity_scratch[i * Vcb->superblock.sector_size],
&context->stripes[bad_stripe1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], len);
stripe = parity1 == 0 ? (c->chunk_item->num_stripes - 1) : (parity1 - 1);
if (c->devices[parity2]->devobj) {
stripe_num = c->chunk_item->num_stripes - 3;
while (stripe != parity2) {
galois_double(scratch, len);
if (stripe != bad_stripe1)
do_xor(scratch, &context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], len);
else
bad_stripe_num = stripe_num;
stripe = stripe == 0 ? (c->chunk_item->num_stripes - 1) : (stripe - 1);
stripe_num--;
}
do_xor(scratch, &context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], len);
if (bad_stripe_num != 0)
galois_divpower(scratch, (uint8_t)bad_stripe_num, len);
}
if (RtlCheckBit(&context->is_tree, bad_off1)) {
uint8_t hash1[MAX_HASH_SIZE];
uint8_t hash2[MAX_HASH_SIZE];
tree_header *th1 = NULL, *th2 = NULL;
if (c->devices[parity1]->devobj) {
th1 = (tree_header*)&context->parity_scratch[i * Vcb->superblock.sector_size];
get_tree_checksum(Vcb, th1, hash1);
}
if (c->devices[parity2]->devobj) {
th2 = (tree_header*)scratch;
get_tree_checksum(Vcb, th2, hash2);
}
if ((c->devices[parity1]->devobj && RtlCompareMemory(hash1, th1, Vcb->csum_size) == Vcb->csum_size && th1->address == addr) ||
(c->devices[parity2]->devobj && RtlCompareMemory(hash2, th2, Vcb->csum_size) == Vcb->csum_size && th2->address == addr)) {
if (!c->devices[parity1]->devobj || RtlCompareMemory(hash1, th1, Vcb->csum_size) != Vcb->csum_size || th1->address != addr) {
RtlCopyMemory(&context->stripes[bad_stripe1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
scratch, Vcb->superblock.node_size);
if (c->devices[parity1]->devobj) {
// fix parity 1
stripe = (parity1 + 2) % c->chunk_item->num_stripes;
RtlCopyMemory(&context->stripes[parity1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.node_size);
stripe = (stripe + 1) % c->chunk_item->num_stripes;
while (stripe != parity1) {
do_xor(&context->stripes[parity1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.node_size);
stripe = (stripe + 1) % c->chunk_item->num_stripes;
}
context->stripes[parity1].rewrite = true;
log_error(Vcb, addr, c->devices[parity1]->devitem.dev_id, false, true, true);
log_device_error(Vcb, c->devices[parity1], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
} else {
RtlCopyMemory(&context->stripes[bad_stripe1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch[i * Vcb->superblock.sector_size], Vcb->superblock.node_size);
if (!c->devices[parity2]->devobj || RtlCompareMemory(hash2, th2, Vcb->csum_size) != Vcb->csum_size || th2->address != addr) {
// fix parity 2
stripe = parity1 == 0 ? (c->chunk_item->num_stripes - 1) : (parity1 - 1);
if (c->devices[parity2]->devobj) {
RtlCopyMemory(&context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.node_size);
stripe = stripe == 0 ? (c->chunk_item->num_stripes - 1) : (stripe - 1);
while (stripe != parity2) {
galois_double(&context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], Vcb->superblock.node_size);
do_xor(&context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.node_size);
stripe = stripe == 0 ? (c->chunk_item->num_stripes - 1) : (stripe - 1);
}
context->stripes[parity2].rewrite = true;
log_error(Vcb, addr, c->devices[parity2]->devitem.dev_id, false, true, true);
log_device_error(Vcb, c->devices[parity2], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
}
}
context->stripes[bad_stripe1].rewrite = true;
RtlClearBits(&context->stripes[bad_stripe1].error, i + 1, (Vcb->superblock.node_size / Vcb->superblock.sector_size) - 1);
log_error(Vcb, addr, c->devices[bad_stripe1]->devitem.dev_id, true, true, false);
} else
log_error(Vcb, addr, c->devices[bad_stripe1]->devitem.dev_id, true, false, false);
} else {
uint8_t hash1[MAX_HASH_SIZE];
uint8_t hash2[MAX_HASH_SIZE];
if (c->devices[parity1]->devobj)
get_sector_csum(Vcb, &context->parity_scratch[i * Vcb->superblock.sector_size], hash1);
if (c->devices[parity2]->devobj)
get_sector_csum(Vcb, scratch, hash2);
if ((c->devices[parity1]->devobj && RtlCompareMemory(hash1, (uint8_t*)context->csum + (bad_off1 * Vcb->csum_size), Vcb->csum_size) == Vcb->csum_size) ||
(c->devices[parity2]->devobj && RtlCompareMemory(hash2, (uint8_t*)context->csum + (bad_off1 * Vcb->csum_size), Vcb->csum_size) == Vcb->csum_size)) {
if (c->devices[parity2]->devobj && RtlCompareMemory(hash2, (uint8_t*)context->csum + (bad_off1 * Vcb->csum_size), Vcb->csum_size) == Vcb->csum_size) {
RtlCopyMemory(&context->stripes[bad_stripe1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
scratch, Vcb->superblock.sector_size);
if (c->devices[parity1]->devobj && RtlCompareMemory(hash1, (uint8_t*)context->csum + (bad_off1 * Vcb->csum_size), Vcb->csum_size) != Vcb->csum_size) {
// fix parity 1
stripe = (parity1 + 2) % c->chunk_item->num_stripes;
RtlCopyMemory(&context->stripes[parity1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.sector_size);
stripe = (stripe + 1) % c->chunk_item->num_stripes;
while (stripe != parity1) {
do_xor(&context->stripes[parity1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.sector_size);
stripe = (stripe + 1) % c->chunk_item->num_stripes;
}
context->stripes[parity1].rewrite = true;
log_error(Vcb, addr, c->devices[parity1]->devitem.dev_id, false, true, true);
log_device_error(Vcb, c->devices[parity1], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
} else {
RtlCopyMemory(&context->stripes[bad_stripe1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch[i * Vcb->superblock.sector_size], Vcb->superblock.sector_size);
if (c->devices[parity2]->devobj && RtlCompareMemory(hash2, (uint8_t*)context->csum + (bad_off1 * Vcb->csum_size), Vcb->csum_size) != Vcb->csum_size) {
// fix parity 2
stripe = parity1 == 0 ? (c->chunk_item->num_stripes - 1) : (parity1 - 1);
RtlCopyMemory(&context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.sector_size);
stripe = stripe == 0 ? (c->chunk_item->num_stripes - 1) : (stripe - 1);
while (stripe != parity2) {
galois_double(&context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], Vcb->superblock.sector_size);
do_xor(&context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
Vcb->superblock.sector_size);
stripe = stripe == 0 ? (c->chunk_item->num_stripes - 1) : (stripe - 1);
}
context->stripes[parity2].rewrite = true;
log_error(Vcb, addr, c->devices[parity2]->devitem.dev_id, false, true, true);
log_device_error(Vcb, c->devices[parity2], BTRFS_DEV_STAT_CORRUPTION_ERRORS);
}
}
context->stripes[bad_stripe1].rewrite = true;
log_error(Vcb, addr, c->devices[bad_stripe1]->devitem.dev_id, false, true, false);
} else
log_error(Vcb, addr, c->devices[bad_stripe1]->devitem.dev_id, false, false, false);
}
ExFreePool(scratch);
} else if (num_errors == 2 && missing_devices == 0) {
uint16_t x, y, k;
uint64_t addr;
uint32_t len = (RtlCheckBit(&context->is_tree, bad_off1) || RtlCheckBit(&context->is_tree, bad_off2)) ? Vcb->superblock.node_size : Vcb->superblock.sector_size;
uint8_t gyx, gx, denom, a, b, *p, *q, *pxy, *qxy;
uint32_t j;
stripe = parity1 == 0 ? (c->chunk_item->num_stripes - 1) : (parity1 - 1);
// put qxy in parity_scratch
// put pxy in parity_scratch2
k = c->chunk_item->num_stripes - 3;
if (stripe == bad_stripe1 || stripe == bad_stripe2) {
RtlZeroMemory(&context->parity_scratch[i * Vcb->superblock.sector_size], len);
RtlZeroMemory(&context->parity_scratch2[i * Vcb->superblock.sector_size], len);
if (stripe == bad_stripe1)
x = k;
else
y = k;
} else {
RtlCopyMemory(&context->parity_scratch[i * Vcb->superblock.sector_size],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], len);
RtlCopyMemory(&context->parity_scratch2[i * Vcb->superblock.sector_size],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], len);
}
stripe = stripe == 0 ? (c->chunk_item->num_stripes - 1) : (stripe - 1);
k--;
do {
galois_double(&context->parity_scratch[i * Vcb->superblock.sector_size], len);
if (stripe != bad_stripe1 && stripe != bad_stripe2) {
do_xor(&context->parity_scratch[i * Vcb->superblock.sector_size],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], len);
do_xor(&context->parity_scratch2[i * Vcb->superblock.sector_size],
&context->stripes[stripe].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], len);
} else if (stripe == bad_stripe1)
x = k;
else if (stripe == bad_stripe2)
y = k;
stripe = stripe == 0 ? (c->chunk_item->num_stripes - 1) : (stripe - 1);
k--;
} while (stripe != parity2);
gyx = gpow2(y > x ? (y-x) : (255-x+y));
gx = gpow2(255-x);
denom = gdiv(1, gyx ^ 1);
a = gmul(gyx, denom);
b = gmul(gx, denom);
p = &context->stripes[parity1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)];
q = &context->stripes[parity2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)];
pxy = &context->parity_scratch2[i * Vcb->superblock.sector_size];
qxy = &context->parity_scratch[i * Vcb->superblock.sector_size];
for (j = 0; j < len; j++) {
*qxy = gmul(a, *p ^ *pxy) ^ gmul(b, *q ^ *qxy);
p++;
q++;
pxy++;
qxy++;
}
do_xor(&context->parity_scratch2[i * Vcb->superblock.sector_size], &context->parity_scratch[i * Vcb->superblock.sector_size], len);
do_xor(&context->parity_scratch2[i * Vcb->superblock.sector_size], &context->stripes[parity1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)], len);
addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 2) * c->chunk_item->stripe_length) + (bad_off1 * Vcb->superblock.sector_size);
if (RtlCheckBit(&context->is_tree, bad_off1)) {
tree_header* th = (tree_header*)&context->parity_scratch[i * Vcb->superblock.sector_size];
if (check_tree_checksum(Vcb, th) && th->address == addr) {
RtlCopyMemory(&context->stripes[bad_stripe1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch[i * Vcb->superblock.sector_size], Vcb->superblock.node_size);
context->stripes[bad_stripe1].rewrite = true;
RtlClearBits(&context->stripes[bad_stripe1].error, i + 1, (Vcb->superblock.node_size / Vcb->superblock.sector_size) - 1);
log_error(Vcb, addr, c->devices[bad_stripe1]->devitem.dev_id, true, true, false);
} else
log_error(Vcb, addr, c->devices[bad_stripe1]->devitem.dev_id, true, false, false);
} else {
if (check_sector_csum(Vcb, &context->parity_scratch[i * Vcb->superblock.sector_size], (uint8_t*)context->csum + (Vcb->csum_size * bad_off1))) {
RtlCopyMemory(&context->stripes[bad_stripe1].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch[i * Vcb->superblock.sector_size], Vcb->superblock.sector_size);
context->stripes[bad_stripe1].rewrite = true;
log_error(Vcb, addr, c->devices[bad_stripe1]->devitem.dev_id, false, true, false);
} else
log_error(Vcb, addr, c->devices[bad_stripe1]->devitem.dev_id, false, false, false);
}
addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 2) * c->chunk_item->stripe_length) + (bad_off2 * Vcb->superblock.sector_size);
if (RtlCheckBit(&context->is_tree, bad_off2)) {
tree_header* th = (tree_header*)&context->parity_scratch2[i * Vcb->superblock.sector_size];
if (check_tree_checksum(Vcb, th) && th->address == addr) {
RtlCopyMemory(&context->stripes[bad_stripe2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch2[i * Vcb->superblock.sector_size], Vcb->superblock.node_size);
context->stripes[bad_stripe2].rewrite = true;
RtlClearBits(&context->stripes[bad_stripe2].error, i + 1, (Vcb->superblock.node_size / Vcb->superblock.sector_size) - 1);
log_error(Vcb, addr, c->devices[bad_stripe2]->devitem.dev_id, true, true, false);
} else
log_error(Vcb, addr, c->devices[bad_stripe2]->devitem.dev_id, true, false, false);
} else {
if (check_sector_csum(Vcb, &context->parity_scratch2[i * Vcb->superblock.sector_size], (uint8_t*)context->csum + (Vcb->csum_size * bad_off2))) {
RtlCopyMemory(&context->stripes[bad_stripe2].buf[(num * c->chunk_item->stripe_length) + (i * Vcb->superblock.sector_size)],
&context->parity_scratch2[i * Vcb->superblock.sector_size], Vcb->superblock.sector_size);
context->stripes[bad_stripe2].rewrite = true;
log_error(Vcb, addr, c->devices[bad_stripe2]->devitem.dev_id, false, true, false);
} else
log_error(Vcb, addr, c->devices[bad_stripe2]->devitem.dev_id, false, false, false);
}
} else {
stripe = (parity2 + 1) % c->chunk_item->num_stripes;
off = (ULONG)((bit_start + num - stripe_start) * sectors_per_stripe * (c->chunk_item->num_stripes - 2)) + i;
while (stripe != parity1) {
if (c->devices[stripe]->devobj && RtlCheckBit(&context->alloc, off)) {
if (RtlCheckBit(&context->stripes[stripe].error, i)) {
uint64_t addr = c->offset + (stripe_start * (c->chunk_item->num_stripes - 2) * c->chunk_item->stripe_length) + (off * Vcb->superblock.sector_size);
log_error(Vcb, addr, c->devices[stripe]->devitem.dev_id, RtlCheckBit(&context->is_tree, off), false, false);
}
}
off += sectors_per_stripe;
stripe = (stripe + 1) % c->chunk_item->num_stripes;
}
}
}
}
static NTSTATUS scrub_chunk_raid56_stripe_run(device_extension* Vcb, chunk* c, uint64_t stripe_start, uint64_t stripe_end) {
NTSTATUS Status;
KEY searchkey;
traverse_ptr tp;
bool b;
uint64_t run_start, run_end, full_stripe_len, stripe;
uint32_t max_read, num_sectors;
ULONG arrlen, *allocarr, *csumarr = NULL, *treearr, num_parity_stripes = c->chunk_item->type & BLOCK_FLAG_RAID6 ? 2 : 1;
scrub_context_raid56 context;
uint16_t i;
CHUNK_ITEM_STRIPE* cis = (CHUNK_ITEM_STRIPE*)&c->chunk_item[1];
TRACE("(%p, %p, %I64x, %I64x)\n", Vcb, c, stripe_start, stripe_end);
full_stripe_len = (c->chunk_item->num_stripes - num_parity_stripes) * c->chunk_item->stripe_length;
run_start = c->offset + (stripe_start * full_stripe_len);
run_end = c->offset + ((stripe_end + 1) * full_stripe_len);
searchkey.obj_id = run_start;
searchkey.obj_type = TYPE_METADATA_ITEM;
searchkey.offset = 0xffffffffffffffff;
Status = find_item(Vcb, Vcb->extent_root, &tp, &searchkey, false, NULL);
if (!NT_SUCCESS(Status)) {
ERR("find_item returned %08lx\n", Status);
return Status;
}
num_sectors = (uint32_t)((stripe_end - stripe_start + 1) * full_stripe_len / Vcb->superblock.sector_size);
arrlen = (ULONG)sector_align((num_sectors / 8) + 1, sizeof(ULONG));
allocarr = ExAllocatePoolWithTag(PagedPool, arrlen, ALLOC_TAG);
if (!allocarr) {
ERR("out of memory\n");
return STATUS_INSUFFICIENT_RESOURCES;
}
treearr = ExAllocatePoolWithTag(PagedPool, arrlen, ALLOC_TAG);
if (!treearr) {
ERR("out of memory\n");
ExFreePool(allocarr);
return STATUS_INSUFFICIENT_RESOURCES;
}
RtlInitializeBitMap(&context.alloc, allocarr, num_sectors);
RtlClearAllBits(&context.alloc);
RtlInitializeBitMap(&context.is_tree, treearr, num_sectors);
RtlClearAllBits(&context.is_tree);
context.parity_scratch = ExAllocatePoolWithTag(PagedPool, (ULONG)c->chunk_item->stripe_length, ALLOC_TAG);
if (!context.parity_scratch) {
ERR("out of memory\n");
ExFreePool(allocarr);
ExFreePool(treearr);
return STATUS_INSUFFICIENT_RESOURCES;
}
if (c->chunk_item->type & BLOCK_FLAG_DATA) {
csumarr = ExAllocatePoolWithTag(PagedPool, arrlen, ALLOC_TAG);
if (!csumarr) {
ERR("out of memory\n");
ExFreePool(allocarr);
ExFreePool(treearr);
ExFreePool(context.parity_scratch);
return STATUS_INSUFFICIENT_RESOURCES;
}
RtlInitializeBitMap(&context.has_csum, csumarr, num_sectors);
RtlClearAllBits(&context.has_csum);
context.csum = ExAllocatePoolWithTag(PagedPool, num_sectors * Vcb->csum_size, ALLOC_TAG);
if (!context.csum) {
ERR("out of memory\n");
ExFreePool(allocarr);
ExFreePool(treearr);
ExFreePool(context.parity_scratch);
ExFreePool(csumarr);
return STATUS_INSUFFICIENT_RESOURCES;
}
}
if (c->chunk_item->type & BLOCK_FLAG_RAID6) {
context.parity_scratch2 = ExAllocatePoolWithTag(PagedPool, (ULONG)c->chunk_item->stripe_length, ALLOC_TAG);
if (!context.parity_scratch2) {
ERR("out of memory\n");
ExFreePool(allocarr);
ExFreePool(treearr);
ExFreePool(context.parity_scratch);
if (c->chunk_item->type & BLOCK_FLAG_DATA) {
ExFreePool(csumarr);
ExFreePool(context.csum);
}
return STATUS_INSUFFICIENT_RESOURCES;
}
}
do {
traverse_ptr next_tp;
if (tp.item->key.obj_id >= run_end)
break;
if (tp.item->key.obj_type == TYPE_EXTENT_ITEM || tp.item->key.obj_type == TYPE_METADATA_ITEM) {
uint64_t size = tp.item->key.obj_type == TYPE_METADATA_ITEM ? Vcb->superblock.node_size : tp.item->key.offset;
if (tp.item->key.obj_id + size > run_start) {
uint64_t extent_start = max(run_start, tp.item->key.obj_id);
uint64_t extent_end = min(tp.item->key.obj_id + size, run_end);
bool extent_is_tree = false;
RtlSetBits(&context.alloc, (ULONG)((extent_start - run_start) / Vcb->superblock.sector_size), (ULONG)((extent_end - extent_start) / Vcb->superblock.sector_size));
if (tp.item->key.obj_type == TYPE_METADATA_ITEM)
extent_is_tree = true;
else {
EXTENT_ITEM* ei = (EXTENT_ITEM*)tp.item->data;
if (tp.item->size < sizeof(EXTENT_ITEM)) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset, tp.item->size, sizeof(EXTENT_ITEM));
Status = STATUS_INTERNAL_ERROR;
goto end;
}
if (ei->flags & EXTENT_ITEM_TREE_BLOCK)
extent_is_tree = true;
}
if (extent_is_tree)
RtlSetBits(&context.is_tree, (ULONG)((extent_start - run_start) / Vcb->superblock.sector_size), (ULONG)((extent_end - extent_start) / Vcb->superblock.sector_size));
else if (c->chunk_item->type & BLOCK_FLAG_DATA) {
traverse_ptr tp2;
bool b2;
searchkey.obj_id = EXTENT_CSUM_ID;
searchkey.obj_type = TYPE_EXTENT_CSUM;
searchkey.offset = extent_start;
Status = find_item(Vcb, Vcb->checksum_root, &tp2, &searchkey, false, NULL);
if (!NT_SUCCESS(Status) && Status != STATUS_NOT_FOUND) {
ERR("find_item returned %08lx\n", Status);
goto end;
}
do {
traverse_ptr next_tp2;
if (tp2.item->key.offset >= extent_end)
break;
if (tp2.item->key.offset >= extent_start) {
uint64_t csum_start = max(extent_start, tp2.item->key.offset);
uint64_t csum_end = min(extent_end, tp2.item->key.offset + (tp2.item->size * Vcb->superblock.sector_size / Vcb->csum_size));
RtlSetBits(&context.has_csum, (ULONG)((csum_start - run_start) / Vcb->superblock.sector_size), (ULONG)((csum_end - csum_start) / Vcb->superblock.sector_size));
RtlCopyMemory((uint8_t*)context.csum + ((csum_start - run_start) * Vcb->csum_size / Vcb->superblock.sector_size),
tp2.item->data + ((csum_start - tp2.item->key.offset) * Vcb->csum_size / Vcb->superblock.sector_size),
(ULONG)((csum_end - csum_start) * Vcb->csum_size / Vcb->superblock.sector_size));
}
b2 = find_next_item(Vcb, &tp2, &next_tp2, false, NULL);
if (b2)
tp2 = next_tp2;
} while (b2);
}
}
}
b = find_next_item(Vcb, &tp, &next_tp, false, NULL);
if (b)
tp = next_tp;
} while (b);
context.stripes = ExAllocatePoolWithTag(PagedPool, sizeof(scrub_context_raid56_stripe) * c->chunk_item->num_stripes, ALLOC_TAG);
if (!context.stripes) {
ERR("out of memory\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
max_read = (uint32_t)min(1048576 / c->chunk_item->stripe_length, stripe_end - stripe_start + 1); // only process 1 MB of data at a time
for (i = 0; i < c->chunk_item->num_stripes; i++) {
context.stripes[i].buf = ExAllocatePoolWithTag(PagedPool, (ULONG)(max_read * c->chunk_item->stripe_length), ALLOC_TAG);
if (!context.stripes[i].buf) {
uint64_t j;
ERR("out of memory\n");
for (j = 0; j < i; j++) {
ExFreePool(context.stripes[j].buf);
}
ExFreePool(context.stripes);
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
context.stripes[i].errorarr = ExAllocatePoolWithTag(PagedPool, (ULONG)sector_align(((c->chunk_item->stripe_length / Vcb->superblock.sector_size) / 8) + 1, sizeof(ULONG)), ALLOC_TAG);
if (!context.stripes[i].errorarr) {
uint64_t j;
ERR("out of memory\n");
ExFreePool(context.stripes[i].buf);
for (j = 0; j < i; j++) {
ExFreePool(context.stripes[j].buf);
}
ExFreePool(context.stripes);
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
RtlInitializeBitMap(&context.stripes[i].error, context.stripes[i].errorarr, (ULONG)(c->chunk_item->stripe_length / Vcb->superblock.sector_size));
context.stripes[i].context = &context;
context.stripes[i].rewrite = false;
}
stripe = stripe_start;
Status = STATUS_SUCCESS;
chunk_lock_range(Vcb, c, run_start, run_end - run_start);
do {
ULONG read_stripes;
uint16_t missing_devices = 0;
bool need_wait = false;
if (max_read < stripe_end + 1 - stripe)
read_stripes = max_read;
else
read_stripes = (ULONG)(stripe_end + 1 - stripe);
context.stripes_left = c->chunk_item->num_stripes;
// read megabyte by megabyte
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (c->devices[i]->devobj) {
PIO_STACK_LOCATION IrpSp;
context.stripes[i].Irp = IoAllocateIrp(c->devices[i]->devobj->StackSize, false);
if (!context.stripes[i].Irp) {
ERR("IoAllocateIrp failed\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end3;
}
context.stripes[i].Irp->MdlAddress = NULL;
IrpSp = IoGetNextIrpStackLocation(context.stripes[i].Irp);
IrpSp->MajorFunction = IRP_MJ_READ;
IrpSp->FileObject = c->devices[i]->fileobj;
if (c->devices[i]->devobj->Flags & DO_BUFFERED_IO) {
context.stripes[i].Irp->AssociatedIrp.SystemBuffer = ExAllocatePoolWithTag(NonPagedPool, (ULONG)(read_stripes * c->chunk_item->stripe_length), ALLOC_TAG);
if (!context.stripes[i].Irp->AssociatedIrp.SystemBuffer) {
ERR("out of memory\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end3;
}
context.stripes[i].Irp->Flags |= IRP_BUFFERED_IO | IRP_DEALLOCATE_BUFFER | IRP_INPUT_OPERATION;
context.stripes[i].Irp->UserBuffer = context.stripes[i].buf;
} else if (c->devices[i]->devobj->Flags & DO_DIRECT_IO) {
context.stripes[i].Irp->MdlAddress = IoAllocateMdl(context.stripes[i].buf, (ULONG)(read_stripes * c->chunk_item->stripe_length), false, false, NULL);
if (!context.stripes[i].Irp->MdlAddress) {
ERR("IoAllocateMdl failed\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end3;
}
Status = STATUS_SUCCESS;
_SEH2_TRY {
MmProbeAndLockPages(context.stripes[i].Irp->MdlAddress, KernelMode, IoWriteAccess);
} _SEH2_EXCEPT (EXCEPTION_EXECUTE_HANDLER) {
Status = _SEH2_GetExceptionCode();
} _SEH2_END;
if (!NT_SUCCESS(Status)) {
ERR("MmProbeAndLockPages threw exception %08lx\n", Status);
IoFreeMdl(context.stripes[i].Irp->MdlAddress);
goto end3;
}
} else
context.stripes[i].Irp->UserBuffer = context.stripes[i].buf;
context.stripes[i].offset = stripe * c->chunk_item->stripe_length;
IrpSp->Parameters.Read.Length = (ULONG)(read_stripes * c->chunk_item->stripe_length);
IrpSp->Parameters.Read.ByteOffset.QuadPart = cis[i].offset + context.stripes[i].offset;
context.stripes[i].Irp->UserIosb = &context.stripes[i].iosb;
context.stripes[i].missing = false;
IoSetCompletionRoutine(context.stripes[i].Irp, scrub_read_completion_raid56, &context.stripes[i], true, true, true);
Vcb->scrub.data_scrubbed += read_stripes * c->chunk_item->stripe_length;
need_wait = true;
} else {
context.stripes[i].Irp = NULL;
context.stripes[i].missing = true;
missing_devices++;
InterlockedDecrement(&context.stripes_left);
}
}
if (c->chunk_item->type & BLOCK_FLAG_RAID5 && missing_devices > 1) {
ERR("too many missing devices (%u, maximum 1)\n", missing_devices);
Status = STATUS_UNEXPECTED_IO_ERROR;
goto end3;
} else if (c->chunk_item->type & BLOCK_FLAG_RAID6 && missing_devices > 2) {
ERR("too many missing devices (%u, maximum 2)\n", missing_devices);
Status = STATUS_UNEXPECTED_IO_ERROR;
goto end3;
}
if (need_wait) {
KeInitializeEvent(&context.Event, NotificationEvent, false);
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (c->devices[i]->devobj)
IoCallDriver(c->devices[i]->devobj, context.stripes[i].Irp);
}
KeWaitForSingleObject(&context.Event, Executive, KernelMode, false, NULL);
}
// return an error if any of the stripes returned an error
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (!context.stripes[i].missing && !NT_SUCCESS(context.stripes[i].iosb.Status)) {
Status = context.stripes[i].iosb.Status;
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_READ_ERRORS);
goto end3;
}
}
if (c->chunk_item->type & BLOCK_FLAG_RAID6) {
for (i = 0; i < read_stripes; i++) {
scrub_raid6_stripe(Vcb, c, &context, stripe_start, stripe, i, missing_devices);
}
} else {
for (i = 0; i < read_stripes; i++) {
scrub_raid5_stripe(Vcb, c, &context, stripe_start, stripe, i, missing_devices);
}
}
stripe += read_stripes;
end3:
for (i = 0; i < c->chunk_item->num_stripes; i++) {
if (context.stripes[i].Irp) {
if (c->devices[i]->devobj->Flags & DO_DIRECT_IO && context.stripes[i].Irp->MdlAddress) {
MmUnlockPages(context.stripes[i].Irp->MdlAddress);
IoFreeMdl(context.stripes[i].Irp->MdlAddress);
}
IoFreeIrp(context.stripes[i].Irp);
context.stripes[i].Irp = NULL;
if (context.stripes[i].rewrite) {
Status = write_data_phys(c->devices[i]->devobj, c->devices[i]->fileobj, cis[i].offset + context.stripes[i].offset,
context.stripes[i].buf, (uint32_t)(read_stripes * c->chunk_item->stripe_length));
if (!NT_SUCCESS(Status)) {
ERR("write_data_phys returned %08lx\n", Status);
log_device_error(Vcb, c->devices[i], BTRFS_DEV_STAT_WRITE_ERRORS);
goto end2;
}
}
}
}
if (!NT_SUCCESS(Status))
break;
} while (stripe < stripe_end);
end2:
chunk_unlock_range(Vcb, c, run_start, run_end - run_start);
for (i = 0; i < c->chunk_item->num_stripes; i++) {
ExFreePool(context.stripes[i].buf);
ExFreePool(context.stripes[i].errorarr);
}
ExFreePool(context.stripes);
end:
ExFreePool(treearr);
ExFreePool(allocarr);
ExFreePool(context.parity_scratch);
if (c->chunk_item->type & BLOCK_FLAG_RAID6)
ExFreePool(context.parity_scratch2);
if (c->chunk_item->type & BLOCK_FLAG_DATA) {
ExFreePool(csumarr);
ExFreePool(context.csum);
}
return Status;
}
static NTSTATUS scrub_chunk_raid56(device_extension* Vcb, chunk* c, uint64_t* offset, bool* changed) {
NTSTATUS Status;
KEY searchkey;
traverse_ptr tp;
bool b;
uint64_t full_stripe_len, stripe, stripe_start, stripe_end, total_data = 0;
ULONG num_extents = 0, num_parity_stripes = c->chunk_item->type & BLOCK_FLAG_RAID6 ? 2 : 1;
full_stripe_len = (c->chunk_item->num_stripes - num_parity_stripes) * c->chunk_item->stripe_length;
stripe = (*offset - c->offset) / full_stripe_len;
*offset = c->offset + (stripe * full_stripe_len);
searchkey.obj_id = *offset;
searchkey.obj_type = TYPE_METADATA_ITEM;
searchkey.offset = 0xffffffffffffffff;
Status = find_item(Vcb, Vcb->extent_root, &tp, &searchkey, false, NULL);
if (!NT_SUCCESS(Status)) {
ERR("find_item returned %08lx\n", Status);
return Status;
}
*changed = false;
do {
traverse_ptr next_tp;
if (tp.item->key.obj_id >= c->offset + c->chunk_item->size)
break;
if (tp.item->key.obj_id >= *offset && (tp.item->key.obj_type == TYPE_EXTENT_ITEM || tp.item->key.obj_type == TYPE_METADATA_ITEM)) {
uint64_t size = tp.item->key.obj_type == TYPE_METADATA_ITEM ? Vcb->superblock.node_size : tp.item->key.offset;
TRACE("%I64x\n", tp.item->key.obj_id);
if (size < Vcb->superblock.sector_size) {
ERR("extent %I64x has size less than sector_size (%I64x < %x)\n", tp.item->key.obj_id, size, Vcb->superblock.sector_size);
return STATUS_INTERNAL_ERROR;
}
stripe = (tp.item->key.obj_id - c->offset) / full_stripe_len;
if (*changed) {
if (stripe > stripe_end + 1) {
Status = scrub_chunk_raid56_stripe_run(Vcb, c, stripe_start, stripe_end);
if (!NT_SUCCESS(Status)) {
ERR("scrub_chunk_raid56_stripe_run returned %08lx\n", Status);
return Status;
}
stripe_start = stripe;
}
} else
stripe_start = stripe;
stripe_end = (tp.item->key.obj_id + size - 1 - c->offset) / full_stripe_len;
*changed = true;
total_data += size;
num_extents++;
// only do so much at a time
if (num_extents >= 64 || total_data >= 0x8000000) // 128 MB
break;
}
b = find_next_item(Vcb, &tp, &next_tp, false, NULL);
if (b)
tp = next_tp;
} while (b);
if (*changed) {
Status = scrub_chunk_raid56_stripe_run(Vcb, c, stripe_start, stripe_end);
if (!NT_SUCCESS(Status)) {
ERR("scrub_chunk_raid56_stripe_run returned %08lx\n", Status);
return Status;
}
*offset = c->offset + ((stripe_end + 1) * full_stripe_len);
}
return STATUS_SUCCESS;
}
static NTSTATUS scrub_chunk(device_extension* Vcb, chunk* c, uint64_t* offset, bool* changed) {
NTSTATUS Status;
KEY searchkey;
traverse_ptr tp;
bool b = false, tree_run = false;
ULONG type, num_extents = 0;
uint64_t total_data = 0, tree_run_start, tree_run_end;
TRACE("chunk %I64x\n", c->offset);
ExAcquireResourceSharedLite(&Vcb->tree_lock, true);
if (c->chunk_item->type & BLOCK_FLAG_DUPLICATE)
type = BLOCK_FLAG_DUPLICATE;
else if (c->chunk_item->type & BLOCK_FLAG_RAID0)
type = BLOCK_FLAG_RAID0;
else if (c->chunk_item->type & BLOCK_FLAG_RAID1)
type = BLOCK_FLAG_DUPLICATE;
else if (c->chunk_item->type & BLOCK_FLAG_RAID10)
type = BLOCK_FLAG_RAID10;
else if (c->chunk_item->type & BLOCK_FLAG_RAID5) {
Status = scrub_chunk_raid56(Vcb, c, offset, changed);
goto end;
} else if (c->chunk_item->type & BLOCK_FLAG_RAID6) {
Status = scrub_chunk_raid56(Vcb, c, offset, changed);
goto end;
} else if (c->chunk_item->type & BLOCK_FLAG_RAID1C3)
type = BLOCK_FLAG_DUPLICATE;
else if (c->chunk_item->type & BLOCK_FLAG_RAID1C4)
type = BLOCK_FLAG_DUPLICATE;
else // SINGLE
type = BLOCK_FLAG_DUPLICATE;
searchkey.obj_id = *offset;
searchkey.obj_type = TYPE_METADATA_ITEM;
searchkey.offset = 0xffffffffffffffff;
Status = find_item(Vcb, Vcb->extent_root, &tp, &searchkey, false, NULL);
if (!NT_SUCCESS(Status)) {
ERR("error - find_item returned %08lx\n", Status);
goto end;
}
do {
traverse_ptr next_tp;
if (tp.item->key.obj_id >= c->offset + c->chunk_item->size)
break;
if (tp.item->key.obj_id >= *offset && (tp.item->key.obj_type == TYPE_EXTENT_ITEM || tp.item->key.obj_type == TYPE_METADATA_ITEM)) {
uint64_t size = tp.item->key.obj_type == TYPE_METADATA_ITEM ? Vcb->superblock.node_size : tp.item->key.offset;
bool is_tree;
void* csum = NULL;
RTL_BITMAP bmp;
ULONG* bmparr = NULL, bmplen;
TRACE("%I64x\n", tp.item->key.obj_id);
is_tree = false;
if (tp.item->key.obj_type == TYPE_METADATA_ITEM)
is_tree = true;
else {
EXTENT_ITEM* ei = (EXTENT_ITEM*)tp.item->data;
if (tp.item->size < sizeof(EXTENT_ITEM)) {
ERR("(%I64x,%x,%I64x) was %u bytes, expected at least %Iu\n", tp.item->key.obj_id, tp.item->key.obj_type, tp.item->key.offset, tp.item->size, sizeof(EXTENT_ITEM));
Status = STATUS_INTERNAL_ERROR;
goto end;
}
if (ei->flags & EXTENT_ITEM_TREE_BLOCK)
is_tree = true;
}
if (size < Vcb->superblock.sector_size) {
ERR("extent %I64x has size less than sector_size (%I64x < %x)\n", tp.item->key.obj_id, size, Vcb->superblock.sector_size);
Status = STATUS_INTERNAL_ERROR;
goto end;
}
// load csum
if (!is_tree) {
traverse_ptr tp2;
csum = ExAllocatePoolWithTag(PagedPool, (ULONG)(Vcb->csum_size * size / Vcb->superblock.sector_size), ALLOC_TAG);
if (!csum) {
ERR("out of memory\n");
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
bmplen = (ULONG)(size / Vcb->superblock.sector_size);
bmparr = ExAllocatePoolWithTag(PagedPool, (ULONG)(sector_align((bmplen >> 3) + 1, sizeof(ULONG))), ALLOC_TAG);
if (!bmparr) {
ERR("out of memory\n");
ExFreePool(csum);
Status = STATUS_INSUFFICIENT_RESOURCES;
goto end;
}
RtlInitializeBitMap(&bmp, bmparr, bmplen);
RtlSetAllBits(&bmp); // 1 = no csum, 0 = csum
searchkey.obj_id = EXTENT_CSUM_ID;
searchkey.obj_type = TYPE_EXTENT_CSUM;
searchkey.offset = tp.item->key.obj_id;
Status = find_item(Vcb, Vcb->checksum_root, &tp2, &searchkey, false, NULL);
if (!NT_SUCCESS(Status) && Status != STATUS_NOT_FOUND) {
ERR("find_item returned %08lx\n", Status);
ExFreePool(csum);
ExFreePool(bmparr);
goto end;
}
if (Status != STATUS_NOT_FOUND) {
do {
traverse_ptr next_tp2;
if (tp2.item->key.obj_type == TYPE_EXTENT_CSUM) {
if (tp2.item->key.offset >= tp.item->key.obj_id + size)
break;
else if (tp2.item->size >= Vcb->csum_size && tp2.item->key.offset + (tp2.item->size * Vcb->superblock.sector_size / Vcb->csum_size) >= tp.item->key.obj_id) {
uint64_t cs = max(tp.item->key.obj_id, tp2.item->key.offset);
uint64_t ce = min(tp.item->key.obj_id + size, tp2.item->key.offset + (tp2.item->size * Vcb->superblock.sector_size / Vcb->csum_size));
RtlCopyMemory((uint8_t*)csum + ((cs - tp.item->key.obj_id) * Vcb->csum_size / Vcb->superblock.sector_size),
tp2.item->data + ((cs - tp2.item->key.offset) * Vcb->csum_size / Vcb->superblock.sector_size),
(ULONG)((ce - cs) * Vcb->csum_size / Vcb->superblock.sector_size));
RtlClearBits(&bmp, (ULONG)((cs - tp.item->key.obj_id) / Vcb->superblock.sector_size), (ULONG)((ce - cs) / Vcb->superblock.sector_size));
if (ce == tp.item->key.obj_id + size)
break;
}
}
if (find_next_item(Vcb, &tp2, &next_tp2, false, NULL))
tp2 = next_tp2;
else
break;
} while (true);
}
}
if (tree_run) {
if (!is_tree || tp.item->key.obj_id > tree_run_end) {
Status = scrub_extent(Vcb, c, type, tree_run_start, (uint32_t)(tree_run_end - tree_run_start), NULL);
if (!NT_SUCCESS(Status)) {
ERR("scrub_extent returned %08lx\n", Status);
goto end;
}
if (!is_tree)
tree_run = false;
else {
tree_run_start = tp.item->key.obj_id;
tree_run_end = tp.item->key.obj_id + Vcb->superblock.node_size;
}
} else
tree_run_end = tp.item->key.obj_id + Vcb->superblock.node_size;
} else if (is_tree) {
tree_run = true;
tree_run_start = tp.item->key.obj_id;
tree_run_end = tp.item->key.obj_id + Vcb->superblock.node_size;
}
if (!is_tree) {
Status = scrub_data_extent(Vcb, c, tp.item->key.obj_id, type, csum, &bmp, bmplen);
if (!NT_SUCCESS(Status)) {
ERR("scrub_data_extent returned %08lx\n", Status);
ExFreePool(csum);
ExFreePool(bmparr);
goto end;
}
ExFreePool(csum);
ExFreePool(bmparr);
}
*offset = tp.item->key.obj_id + size;
*changed = true;
total_data += size;
num_extents++;
// only do so much at a time
if (num_extents >= 64 || total_data >= 0x8000000) // 128 MB
break;
}
b = find_next_item(Vcb, &tp, &next_tp, false, NULL);
if (b)
tp = next_tp;
} while (b);
if (tree_run) {
Status = scrub_extent(Vcb, c, type, tree_run_start, (uint32_t)(tree_run_end - tree_run_start), NULL);
if (!NT_SUCCESS(Status)) {
ERR("scrub_extent returned %08lx\n", Status);
goto end;
}
}
Status = STATUS_SUCCESS;
end:
ExReleaseResourceLite(&Vcb->tree_lock);
return Status;
}
_Function_class_(KSTART_ROUTINE)
static void __stdcall scrub_thread(void* context) {
device_extension* Vcb = context;
LIST_ENTRY chunks, *le;
NTSTATUS Status;
LARGE_INTEGER time;
KeInitializeEvent(&Vcb->scrub.finished, NotificationEvent, false);
InitializeListHead(&chunks);
ExAcquireResourceExclusiveLite(&Vcb->tree_lock, true);
if (Vcb->need_write && !Vcb->readonly)
Status = do_write(Vcb, NULL);
else
Status = STATUS_SUCCESS;
free_trees(Vcb);
if (!NT_SUCCESS(Status)) {
ExReleaseResourceLite(&Vcb->tree_lock);
ERR("do_write returned %08lx\n", Status);
Vcb->scrub.error = Status;
goto end;
}
ExConvertExclusiveToSharedLite(&Vcb->tree_lock);
ExAcquireResourceExclusiveLite(&Vcb->scrub.stats_lock, true);
KeQuerySystemTime(&Vcb->scrub.start_time);
Vcb->scrub.finish_time.QuadPart = 0;
Vcb->scrub.resume_time.QuadPart = Vcb->scrub.start_time.QuadPart;
Vcb->scrub.duration.QuadPart = 0;
Vcb->scrub.total_chunks = 0;
Vcb->scrub.chunks_left = 0;
Vcb->scrub.data_scrubbed = 0;
Vcb->scrub.num_errors = 0;
while (!IsListEmpty(&Vcb->scrub.errors)) {
scrub_error* err = CONTAINING_RECORD(RemoveHeadList(&Vcb->scrub.errors), scrub_error, list_entry);
ExFreePool(err);
}
ExAcquireResourceSharedLite(&Vcb->chunk_lock, true);
le = Vcb->chunks.Flink;
while (le != &Vcb->chunks) {
chunk* c = CONTAINING_RECORD(le, chunk, list_entry);
acquire_chunk_lock(c, Vcb);
if (!c->readonly) {
InsertTailList(&chunks, &c->list_entry_balance);
Vcb->scrub.total_chunks++;
Vcb->scrub.chunks_left++;
}
release_chunk_lock(c, Vcb);
le = le->Flink;
}
ExReleaseResourceLite(&Vcb->chunk_lock);
ExReleaseResource(&Vcb->scrub.stats_lock);
ExReleaseResourceLite(&Vcb->tree_lock);
while (!IsListEmpty(&chunks)) {
chunk* c = CONTAINING_RECORD(RemoveHeadList(&chunks), chunk, list_entry_balance);
uint64_t offset = c->offset;
bool changed;
c->reloc = true;
KeWaitForSingleObject(&Vcb->scrub.event, Executive, KernelMode, false, NULL);
if (!Vcb->scrub.stopping) {
do {
changed = false;
Status = scrub_chunk(Vcb, c, &offset, &changed);
if (!NT_SUCCESS(Status)) {
ERR("scrub_chunk returned %08lx\n", Status);
Vcb->scrub.stopping = true;
Vcb->scrub.error = Status;
break;
}
if (offset == c->offset + c->chunk_item->size || Vcb->scrub.stopping)
break;
KeWaitForSingleObject(&Vcb->scrub.event, Executive, KernelMode, false, NULL);
} while (changed);
}
ExAcquireResourceExclusiveLite(&Vcb->scrub.stats_lock, true);
if (!Vcb->scrub.stopping)
Vcb->scrub.chunks_left--;
if (IsListEmpty(&chunks))
KeQuerySystemTime(&Vcb->scrub.finish_time);
ExReleaseResource(&Vcb->scrub.stats_lock);
c->reloc = false;
c->list_entry_balance.Flink = NULL;
}
KeQuerySystemTime(&time);
Vcb->scrub.duration.QuadPart += time.QuadPart - Vcb->scrub.resume_time.QuadPart;
end:
ZwClose(Vcb->scrub.thread);
Vcb->scrub.thread = NULL;
KeSetEvent(&Vcb->scrub.finished, 0, false);
}
NTSTATUS start_scrub(device_extension* Vcb, KPROCESSOR_MODE processor_mode) {
NTSTATUS Status;
OBJECT_ATTRIBUTES oa;
if (!SeSinglePrivilegeCheck(RtlConvertLongToLuid(SE_MANAGE_VOLUME_PRIVILEGE), processor_mode))
return STATUS_PRIVILEGE_NOT_HELD;
if (Vcb->locked) {
WARN("cannot start scrub while locked\n");
return STATUS_DEVICE_NOT_READY;
}
if (Vcb->balance.thread) {
WARN("cannot start scrub while balance running\n");
return STATUS_DEVICE_NOT_READY;
}
if (Vcb->scrub.thread) {
WARN("scrub already running\n");
return STATUS_DEVICE_NOT_READY;
}
if (Vcb->readonly)
return STATUS_MEDIA_WRITE_PROTECTED;
Vcb->scrub.stopping = false;
Vcb->scrub.paused = false;
Vcb->scrub.error = STATUS_SUCCESS;
KeInitializeEvent(&Vcb->scrub.event, NotificationEvent, !Vcb->scrub.paused);
InitializeObjectAttributes(&oa, NULL, OBJ_KERNEL_HANDLE, NULL, NULL);
Status = PsCreateSystemThread(&Vcb->scrub.thread, 0, &oa, NULL, NULL, scrub_thread, Vcb);
if (!NT_SUCCESS(Status)) {
ERR("PsCreateSystemThread returned %08lx\n", Status);
return Status;
}
return STATUS_SUCCESS;
}
NTSTATUS query_scrub(device_extension* Vcb, KPROCESSOR_MODE processor_mode, void* data, ULONG length) {
btrfs_query_scrub* bqs = (btrfs_query_scrub*)data;
ULONG len;
NTSTATUS Status;
LIST_ENTRY* le;
btrfs_scrub_error* bse = NULL;
if (!SeSinglePrivilegeCheck(RtlConvertLongToLuid(SE_MANAGE_VOLUME_PRIVILEGE), processor_mode))
return STATUS_PRIVILEGE_NOT_HELD;
if (length < offsetof(btrfs_query_scrub, errors))
return STATUS_BUFFER_TOO_SMALL;
ExAcquireResourceSharedLite(&Vcb->scrub.stats_lock, true);
if (Vcb->scrub.thread && Vcb->scrub.chunks_left > 0)
bqs->status = Vcb->scrub.paused ? BTRFS_SCRUB_PAUSED : BTRFS_SCRUB_RUNNING;
else
bqs->status = BTRFS_SCRUB_STOPPED;
bqs->start_time.QuadPart = Vcb->scrub.start_time.QuadPart;
bqs->finish_time.QuadPart = Vcb->scrub.finish_time.QuadPart;
bqs->chunks_left = Vcb->scrub.chunks_left;
bqs->total_chunks = Vcb->scrub.total_chunks;
bqs->data_scrubbed = Vcb->scrub.data_scrubbed;
bqs->duration = Vcb->scrub.duration.QuadPart;
if (bqs->status == BTRFS_SCRUB_RUNNING) {
LARGE_INTEGER time;
KeQuerySystemTime(&time);
bqs->duration += time.QuadPart - Vcb->scrub.resume_time.QuadPart;
}
bqs->error = Vcb->scrub.error;
bqs->num_errors = Vcb->scrub.num_errors;
len = length - offsetof(btrfs_query_scrub, errors);
le = Vcb->scrub.errors.Flink;
while (le != &Vcb->scrub.errors) {
scrub_error* err = CONTAINING_RECORD(le, scrub_error, list_entry);
ULONG errlen;
if (err->is_metadata)
errlen = offsetof(btrfs_scrub_error, metadata.firstitem) + sizeof(KEY);
else
errlen = offsetof(btrfs_scrub_error, data.filename) + err->data.filename_length;
if (len < errlen) {
Status = STATUS_BUFFER_OVERFLOW;
goto end;
}
if (!bse)
bse = &bqs->errors;
else {
ULONG lastlen;
if (bse->is_metadata)
lastlen = offsetof(btrfs_scrub_error, metadata.firstitem) + sizeof(KEY);
else
lastlen = offsetof(btrfs_scrub_error, data.filename) + bse->data.filename_length;
bse->next_entry = lastlen;
bse = (btrfs_scrub_error*)(((uint8_t*)bse) + lastlen);
}
bse->next_entry = 0;
bse->address = err->address;
bse->device = err->device;
bse->recovered = err->recovered;
bse->is_metadata = err->is_metadata;
bse->parity = err->parity;
if (err->is_metadata) {
bse->metadata.root = err->metadata.root;
bse->metadata.level = err->metadata.level;
bse->metadata.firstitem = err->metadata.firstitem;
} else {
bse->data.subvol = err->data.subvol;
bse->data.offset = err->data.offset;
bse->data.filename_length = err->data.filename_length;
RtlCopyMemory(bse->data.filename, err->data.filename, err->data.filename_length);
}
len -= errlen;
le = le->Flink;
}
Status = STATUS_SUCCESS;
end:
ExReleaseResourceLite(&Vcb->scrub.stats_lock);
return Status;
}
NTSTATUS pause_scrub(device_extension* Vcb, KPROCESSOR_MODE processor_mode) {
LARGE_INTEGER time;
if (!SeSinglePrivilegeCheck(RtlConvertLongToLuid(SE_MANAGE_VOLUME_PRIVILEGE), processor_mode))
return STATUS_PRIVILEGE_NOT_HELD;
if (!Vcb->scrub.thread)
return STATUS_DEVICE_NOT_READY;
if (Vcb->scrub.paused)
return STATUS_DEVICE_NOT_READY;
Vcb->scrub.paused = true;
KeClearEvent(&Vcb->scrub.event);
KeQuerySystemTime(&time);
Vcb->scrub.duration.QuadPart += time.QuadPart - Vcb->scrub.resume_time.QuadPart;
return STATUS_SUCCESS;
}
NTSTATUS resume_scrub(device_extension* Vcb, KPROCESSOR_MODE processor_mode) {
if (!SeSinglePrivilegeCheck(RtlConvertLongToLuid(SE_MANAGE_VOLUME_PRIVILEGE), processor_mode))
return STATUS_PRIVILEGE_NOT_HELD;
if (!Vcb->scrub.thread)
return STATUS_DEVICE_NOT_READY;
if (!Vcb->scrub.paused)
return STATUS_DEVICE_NOT_READY;
Vcb->scrub.paused = false;
KeSetEvent(&Vcb->scrub.event, 0, false);
KeQuerySystemTime(&Vcb->scrub.resume_time);
return STATUS_SUCCESS;
}
NTSTATUS stop_scrub(device_extension* Vcb, KPROCESSOR_MODE processor_mode) {
if (!SeSinglePrivilegeCheck(RtlConvertLongToLuid(SE_MANAGE_VOLUME_PRIVILEGE), processor_mode))
return STATUS_PRIVILEGE_NOT_HELD;
if (!Vcb->scrub.thread)
return STATUS_DEVICE_NOT_READY;
Vcb->scrub.paused = false;
Vcb->scrub.stopping = true;
KeSetEvent(&Vcb->scrub.event, 0, false);
return STATUS_SUCCESS;
}
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