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-rw-r--r--pkg/merkletree/merkletree.go500
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diff --git a/pkg/merkletree/merkletree.go b/pkg/merkletree/merkletree.go
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--- a/pkg/merkletree/merkletree.go
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@@ -1,500 +0,0 @@
-// Copyright 2020 The gVisor Authors.
-//
-// Licensed under the Apache License, Version 2.0 (the "License");
-// you may not use this file except in compliance with the License.
-// You may obtain a copy of the License at
-//
-// http://www.apache.org/licenses/LICENSE-2.0
-//
-// Unless required by applicable law or agreed to in writing, software
-// distributed under the License is distributed on an "AS IS" BASIS,
-// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
-// See the License for the specific language governing permissions and
-// limitations under the License.
-
-// Package merkletree implements Merkle tree generating and verification.
-package merkletree
-
-import (
- "bytes"
- "crypto/sha256"
- "crypto/sha512"
- "fmt"
- "io"
-
- "gvisor.dev/gvisor/pkg/abi/linux"
- "gvisor.dev/gvisor/pkg/usermem"
-)
-
-const (
- // sha256DigestSize specifies the digest size of a SHA256 hash.
- sha256DigestSize = 32
- // sha512DigestSize specifies the digest size of a SHA512 hash.
- sha512DigestSize = 64
-)
-
-// DigestSize returns the size (in bytes) of a digest.
-// TODO(b/156980949): Allow config SHA384.
-func DigestSize(hashAlgorithm int) int {
- switch hashAlgorithm {
- case linux.FS_VERITY_HASH_ALG_SHA256:
- return sha256DigestSize
- case linux.FS_VERITY_HASH_ALG_SHA512:
- return sha512DigestSize
- default:
- return -1
- }
-}
-
-// Layout defines the scale of a Merkle tree.
-type Layout struct {
- // blockSize is the size of a data block to be hashed.
- blockSize int64
- // digestSize is the size of a generated hash.
- digestSize int64
- // levelOffset contains the offset of the beginning of each level in
- // bytes. The number of levels in the tree is the length of the slice.
- // The leaf nodes (level 0) contain hashes of blocks of the input data.
- // Each level N contains hashes of the blocks in level N-1. The highest
- // level is the root hash.
- levelOffset []int64
-}
-
-// InitLayout initializes and returns a new Layout object describing the structure
-// of a tree. dataSize specifies the size of input data in bytes.
-func InitLayout(dataSize int64, hashAlgorithms int, dataAndTreeInSameFile bool) (Layout, error) {
- layout := Layout{
- blockSize: usermem.PageSize,
- }
-
- // TODO(b/156980949): Allow config SHA384.
- switch hashAlgorithms {
- case linux.FS_VERITY_HASH_ALG_SHA256:
- layout.digestSize = sha256DigestSize
- case linux.FS_VERITY_HASH_ALG_SHA512:
- layout.digestSize = sha512DigestSize
- default:
- return Layout{}, fmt.Errorf("unexpected hash algorithms")
- }
-
- // treeStart is the offset (in bytes) of the first level of the tree in
- // the file. If data and tree are in different files, treeStart should
- // be zero. If data is in the same file as the tree, treeStart points
- // to the block after the last data block (which may be zero-padded).
- var treeStart int64
- if dataAndTreeInSameFile {
- treeStart = dataSize
- if dataSize%layout.blockSize != 0 {
- treeStart += layout.blockSize - dataSize%layout.blockSize
- }
- }
-
- numBlocks := (dataSize + layout.blockSize - 1) / layout.blockSize
- level := 0
- offset := int64(0)
-
- // Calculate the number of levels in the Merkle tree and the beginning
- // offset of each level. Level 0 consists of the leaf nodes that
- // contain the hashes of the data blocks, while level numLevels - 1 is
- // the root.
- for numBlocks > 1 {
- layout.levelOffset = append(layout.levelOffset, treeStart+offset*layout.blockSize)
- // Round numBlocks up to fill up a block.
- numBlocks += (layout.hashesPerBlock() - numBlocks%layout.hashesPerBlock()) % layout.hashesPerBlock()
- offset += numBlocks / layout.hashesPerBlock()
- numBlocks = numBlocks / layout.hashesPerBlock()
- level++
- }
- layout.levelOffset = append(layout.levelOffset, treeStart+offset*layout.blockSize)
-
- return layout, nil
-}
-
-// hashesPerBlock() returns the number of digests in each block. For example,
-// if blockSize is 4096 bytes, and digestSize is 32 bytes, there will be 128
-// hashesPerBlock. Therefore 128 hashes in one level will be combined in one
-// hash in the level above.
-func (layout Layout) hashesPerBlock() int64 {
- return layout.blockSize / layout.digestSize
-}
-
-// numLevels returns the total number of levels in the Merkle tree.
-func (layout Layout) numLevels() int {
- return len(layout.levelOffset)
-}
-
-// rootLevel returns the level of the root hash.
-func (layout Layout) rootLevel() int {
- return layout.numLevels() - 1
-}
-
-// digestOffset finds the offset of a digest from the beginning of the tree.
-// The target digest is at level of the tree, with index from the beginning of
-// the current level.
-func (layout Layout) digestOffset(level int, index int64) int64 {
- return layout.levelOffset[level] + index*layout.digestSize
-}
-
-// blockOffset finds the offset of a block from the beginning of the tree. The
-// target block is at level of the tree, with index from the beginning of the
-// current level.
-func (layout Layout) blockOffset(level int, index int64) int64 {
- return layout.levelOffset[level] + index*layout.blockSize
-}
-
-// VerityDescriptor is a struct that is serialized and hashed to get a file's
-// root hash, which contains the root hash of the raw content and the file's
-// meatadata.
-type VerityDescriptor struct {
- Name string
- FileSize int64
- Mode uint32
- UID uint32
- GID uint32
- RootHash []byte
-}
-
-func (d *VerityDescriptor) String() string {
- return fmt.Sprintf("Name: %s, Size: %d, Mode: %d, UID: %d, GID: %d, RootHash: %v", d.Name, d.FileSize, d.Mode, d.UID, d.GID, d.RootHash)
-}
-
-// verify generates a hash from d, and compares it with expected.
-func (d *VerityDescriptor) verify(expected []byte, hashAlgorithms int) error {
- h, err := hashData([]byte(d.String()), hashAlgorithms)
- if err != nil {
- return err
- }
- if !bytes.Equal(h[:], expected) {
- return fmt.Errorf("unexpected root hash")
- }
- return nil
-
-}
-
-// hashData hashes data and returns the result hash based on the hash
-// algorithms.
-func hashData(data []byte, hashAlgorithms int) ([]byte, error) {
- var digest []byte
- switch hashAlgorithms {
- case linux.FS_VERITY_HASH_ALG_SHA256:
- digestArray := sha256.Sum256(data)
- digest = digestArray[:]
- case linux.FS_VERITY_HASH_ALG_SHA512:
- digestArray := sha512.Sum512(data)
- digest = digestArray[:]
- default:
- return nil, fmt.Errorf("unexpected hash algorithms")
- }
- return digest, nil
-}
-
-// GenerateParams contains the parameters used to generate a Merkle tree.
-type GenerateParams struct {
- // File is a reader of the file to be hashed.
- File io.ReaderAt
- // Size is the size of the file.
- Size int64
- // Name is the name of the target file.
- Name string
- // Mode is the mode of the target file.
- Mode uint32
- // UID is the user ID of the target file.
- UID uint32
- // GID is the group ID of the target file.
- GID uint32
- // HashAlgorithms is the algorithms used to hash data.
- HashAlgorithms int
- // TreeReader is a reader for the Merkle tree.
- TreeReader io.ReaderAt
- // TreeWriter is a writer for the Merkle tree.
- TreeWriter io.Writer
- // DataAndTreeInSameFile is true if data and Merkle tree are in the same
- // file, or false if Merkle tree is a separate file from data.
- DataAndTreeInSameFile bool
-}
-
-// Generate constructs a Merkle tree for the contents of params.File. The
-// output is written to params.TreeWriter.
-//
-// Generate returns a hash of a VerityDescriptor, which contains the file
-// metadata and the hash from file content.
-func Generate(params *GenerateParams) ([]byte, error) {
- layout, err := InitLayout(params.Size, params.HashAlgorithms, params.DataAndTreeInSameFile)
- if err != nil {
- return nil, err
- }
-
- numBlocks := (params.Size + layout.blockSize - 1) / layout.blockSize
-
- // If the data is in the same file as the tree, zero pad the last data
- // block.
- bytesInLastBlock := params.Size % layout.blockSize
- if params.DataAndTreeInSameFile && bytesInLastBlock != 0 {
- zeroBuf := make([]byte, layout.blockSize-bytesInLastBlock)
- if _, err := params.TreeWriter.Write(zeroBuf); err != nil {
- return nil, err
- }
- }
-
- var root []byte
- for level := 0; level < layout.numLevels(); level++ {
- for i := int64(0); i < numBlocks; i++ {
- buf := make([]byte, layout.blockSize)
- var (
- n int
- err error
- )
- if level == 0 {
- // Read data block from the target file since level 0 includes hashes
- // of blocks in the input data.
- n, err = params.File.ReadAt(buf, i*layout.blockSize)
- } else {
- // Read data block from the tree file since levels higher than 0 are
- // hashing the lower level hashes.
- n, err = params.TreeReader.ReadAt(buf, layout.blockOffset(level-1, i))
- }
-
- // err is populated as long as the bytes read is smaller than the buffer
- // size. This could be the case if we are reading the last block, and
- // break in that case. If this is the last block, the end of the block
- // will be zero-padded.
- if n == 0 && err == io.EOF {
- break
- } else if err != nil && err != io.EOF {
- return nil, err
- }
- // Hash the bytes in buf.
- digest, err := hashData(buf, params.HashAlgorithms)
- if err != nil {
- return nil, err
- }
-
- if level == layout.rootLevel() {
- root = digest
- }
-
- // Write the generated hash to the end of the tree file.
- if _, err = params.TreeWriter.Write(digest[:]); err != nil {
- return nil, err
- }
- }
- // If the generated digests do not round up to a block, zero-padding the
- // remaining of the last block. But no need to do so for root.
- if level != layout.rootLevel() && numBlocks%layout.hashesPerBlock() != 0 {
- zeroBuf := make([]byte, layout.blockSize-(numBlocks%layout.hashesPerBlock())*layout.digestSize)
- if _, err := params.TreeWriter.Write(zeroBuf[:]); err != nil {
- return nil, err
- }
- }
- numBlocks = (numBlocks + layout.hashesPerBlock() - 1) / layout.hashesPerBlock()
- }
- descriptor := VerityDescriptor{
- Name: params.Name,
- FileSize: params.Size,
- Mode: params.Mode,
- UID: params.UID,
- GID: params.GID,
- RootHash: root,
- }
- return hashData([]byte(descriptor.String()), params.HashAlgorithms)
-}
-
-// VerifyParams contains the params used to verify a portion of a file against
-// a Merkle tree.
-type VerifyParams struct {
- // Out will be filled with verified data.
- Out io.Writer
- // File is a handler on the file to be verified.
- File io.ReaderAt
- // tree is a handler on the Merkle tree used to verify file.
- Tree io.ReaderAt
- // Size is the size of the file.
- Size int64
- // Name is the name of the target file.
- Name string
- // Mode is the mode of the target file.
- Mode uint32
- // UID is the user ID of the target file.
- UID uint32
- // GID is the group ID of the target file.
- GID uint32
- // HashAlgorithms is the algorithms used to hash data.
- HashAlgorithms int
- // ReadOffset is the offset of the data range to be verified.
- ReadOffset int64
- // ReadSize is the size of the data range to be verified.
- ReadSize int64
- // Expected is a trusted hash for the file. It is compared with the
- // calculated root hash to verify the content.
- Expected []byte
- // DataAndTreeInSameFile is true if data and Merkle tree are in the same
- // file, or false if Merkle tree is a separate file from data.
- DataAndTreeInSameFile bool
-}
-
-// verifyMetadata verifies the metadata by hashing a descriptor that contains
-// the metadata and compare the generated hash with expected.
-//
-// For verifyMetadata, params.data is not needed. It only accesses params.tree
-// for the raw root hash.
-func verifyMetadata(params *VerifyParams, layout *Layout) error {
- root := make([]byte, layout.digestSize)
- if _, err := params.Tree.ReadAt(root, layout.blockOffset(layout.rootLevel(), 0 /* index */)); err != nil {
- return fmt.Errorf("failed to read root hash: %w", err)
- }
- descriptor := VerityDescriptor{
- Name: params.Name,
- FileSize: params.Size,
- Mode: params.Mode,
- UID: params.UID,
- GID: params.GID,
- RootHash: root,
- }
- return descriptor.verify(params.Expected, params.HashAlgorithms)
-}
-
-// Verify verifies the content read from data with offset. The content is
-// verified against tree. If content spans across multiple blocks, each block is
-// verified. Verification fails if the hash of the data does not match the tree
-// at any level, or if the final root hash does not match expected.
-// Once the data is verified, it will be written using params.Out.
-//
-// Verify checks for both target file content and metadata. If readSize is 0,
-// only metadata is checked.
-func Verify(params *VerifyParams) (int64, error) {
- if params.ReadSize < 0 {
- return 0, fmt.Errorf("unexpected read size: %d", params.ReadSize)
- }
- layout, err := InitLayout(int64(params.Size), params.HashAlgorithms, params.DataAndTreeInSameFile)
- if err != nil {
- return 0, err
- }
- if params.ReadSize == 0 {
- return 0, verifyMetadata(params, &layout)
- }
-
- // Calculate the index of blocks that includes the target range in input
- // data.
- firstDataBlock := params.ReadOffset / layout.blockSize
- lastDataBlock := (params.ReadOffset + params.ReadSize - 1) / layout.blockSize
-
- buf := make([]byte, layout.blockSize)
- var readErr error
- total := int64(0)
- for i := firstDataBlock; i <= lastDataBlock; i++ {
- // Read a block that includes all or part of target range in
- // input data.
- bytesRead, err := params.File.ReadAt(buf, i*layout.blockSize)
- readErr = err
- // If at the end of input data and all previous blocks are
- // verified, return the verified input data and EOF.
- if readErr == io.EOF && bytesRead == 0 {
- break
- }
- if readErr != nil && readErr != io.EOF {
- return 0, fmt.Errorf("read from data failed: %w", err)
- }
- // If this is the end of file, zero the remaining bytes in buf,
- // otherwise they are still from the previous block.
- // TODO(b/162908070): Investigate possible issues with zero
- // padding the data.
- if bytesRead < len(buf) {
- for j := bytesRead; j < len(buf); j++ {
- buf[j] = 0
- }
- }
- descriptor := VerityDescriptor{
- Name: params.Name,
- FileSize: params.Size,
- Mode: params.Mode,
- UID: params.UID,
- GID: params.GID,
- }
- if err := verifyBlock(params.Tree, &descriptor, &layout, buf, i, params.HashAlgorithms, params.Expected); err != nil {
- return 0, err
- }
-
- // startOff is the beginning of the read range within the
- // current data block. Note that for all blocks other than the
- // first, startOff should be 0.
- startOff := int64(0)
- if i == firstDataBlock {
- startOff = params.ReadOffset % layout.blockSize
- }
- // endOff is the end of the read range within the current data
- // block. Note that for all blocks other than the last, endOff
- // should be the block size.
- endOff := layout.blockSize
- if i == lastDataBlock {
- endOff = (params.ReadOffset+params.ReadSize-1)%layout.blockSize + 1
- }
- // If the provided size exceeds the end of input data, we should
- // only copy the parts in buf that's part of input data.
- if startOff > int64(bytesRead) {
- startOff = int64(bytesRead)
- }
- if endOff > int64(bytesRead) {
- endOff = int64(bytesRead)
- }
- n, err := params.Out.Write(buf[startOff:endOff])
- if err != nil {
- return total, err
- }
- total += int64(n)
-
- }
- return total, readErr
-}
-
-// verifyBlock verifies a block against tree. index is the number of block in
-// original data. The block is verified through each level of the tree. It
-// fails if the calculated hash from block is different from any level of
-// hashes stored in tree. And the final root hash is compared with
-// expected.
-func verifyBlock(tree io.ReaderAt, descriptor *VerityDescriptor, layout *Layout, dataBlock []byte, blockIndex int64, hashAlgorithms int, expected []byte) error {
- if len(dataBlock) != int(layout.blockSize) {
- return fmt.Errorf("incorrect block size")
- }
-
- expectedDigest := make([]byte, layout.digestSize)
- treeBlock := make([]byte, layout.blockSize)
- var digest []byte
- for level := 0; level < layout.numLevels(); level++ {
- // Calculate hash.
- if level == 0 {
- h, err := hashData(dataBlock, hashAlgorithms)
- if err != nil {
- return err
- }
- digest = h
- } else {
- // Read a block in previous level that contains the
- // hash we just generated, and generate a next level
- // hash from it.
- if _, err := tree.ReadAt(treeBlock, layout.blockOffset(level-1, blockIndex)); err != nil {
- return err
- }
- h, err := hashData(treeBlock, hashAlgorithms)
- if err != nil {
- return err
- }
- digest = h
- }
-
- // Read the digest for the current block and store in
- // expectedDigest.
- if _, err := tree.ReadAt(expectedDigest, layout.digestOffset(level, blockIndex)); err != nil {
- return err
- }
-
- if !bytes.Equal(digest, expectedDigest) {
- return fmt.Errorf("verification failed")
- }
- blockIndex = blockIndex / layout.hashesPerBlock()
- }
-
- // Verification for the tree succeeded. Now hash the descriptor with
- // the root hash and compare it with expected.
- descriptor.RootHash = digest
- return descriptor.verify(expected, hashAlgorithms)
-}