xsp-files
v4.2.1
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XSP file format for objects encrypted with NaCl (XSalsa+Poly).
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XSP format for NaCl-encrypted files (XSalsa+Poly).
XSP file format for objects encrypted with NaCl.
Get xsp-files
NPM Package
This library is registered on npmjs.org. To install it, do:
npm install xsp-files
Package comes with already compiled library code in dist/ folder. For testing, bring up a build environment and run npm test script(s).
Building
Once you get package, or this repo, do in the folder
npm ci
which will install dev-dependencies. Note that option ci
brings exact versions, mentioned in package-lock.json
, while option i
(install
) may get other versions, based on ranges in package.json
.
Building and testing is done via npm script. Do in the folder
npm run test
or
npm run build
and have fun with it.
XSP file format
Each NaCl's cipher must be read completely, before any plain text output. Such requirement makes reading big files awkward. Therefore, we need a file format, which satisfies the following requirements:
- file should be split into segments;
- it should be possible to randomly read segments;
- segment should have poly+cipher, allowing to check segment's integrity;
- it should be possible to randomly remove and add segments without re-encrypting the whole file;
- segments' nonces should never be reused, even when performing partial changes to a file, without complete file re-encryption;
- it should be possible to detect segment reshuffling;
- there should be cryptographic proof of a complete file size, for files with known size;
- there should be a stream-like setting, where segments can be encrypted and read without knowledge of a final length;
- when complete length of a stream is finally known, switching to known-length setting should be cheap.
We call this format XSP, to stand for XSalsa+Poly, to indicate that file layout is specifically tailored for storing NaCl's secret box's ciphers. XSP file has header, and zero or many segments with data.
Segments are NaCl's packs of Poly and XSalsa cipher.
+------+ +---------------+
| poly | | data cipher |
+------+ +---------------+
| <-- NaCl format --> |
Header is packed with its nonce into WN format (introduced in ecma-nacl):
+-------+ +------+ +---------------+
| nonce | | poly | | data cipher |
+-------+ +------+ +---------------+
| <---- WN format ----> |
Header data
Header provides information about segments, their nonces, and expected sizes. It contains the following:
|<- 1 byte ->| |<- 2 ->| |<- n*31 ->|
+------------+ +----------+ +------------+
| version | | seg size | | seg chains |
+------------+ +----------+ +------------+
- Version byte is a positive integer. Described in this section header layout corresponds to versions 1 and 2.
- Two big-endian bytes have a non-negative integer with segment content size in 256 byte units. Packed segment size is this plus 16 bytes (for Poly). Last segments in segment chains can be shorter.
- Info about
n=0,1,...
segment chains.
Data segments come in chains. Segments in the same chain have consecutive nonces. All segments should be the same size, except for the last segment in a chain.
Segment chain is described in header with following bytes:
|<- 4 bytes ->| |<- 3 bytes ->| |<- 24 bytes ->|
+----------------+ +---------------+ +---------------------+
| number of segs | | last seg size | | first segment nonce |
+----------------+ +---------------+ +---------------------+
|<- seg chain ->|
- First 4 bytes is a big-endian encoded non-negative integer number of segments in this chain.
- Following 3 bytes is a big-endian encoded non-negative integer with the last segment content length in this chain.
- Last 24 bytes is a nonce of the first segment in this chain. Nonces for all other segments are calculated by advancing this nonce. For example, advancing this nonce by one, we get nonce for the second segment in the chain, and so on. Nonce advancing function comes from ecma-nacl, treating 24-byte nonce as three 64-bit unsigned integers to which respective number is added.
In a situation when writer has to send file's header before knowing total file length, the last chain can be infinite. Number of segments in infinite chain is set to be 0xffffffff
, which is used as the maximum possible segment index. Last segment size in infinite chain is set to common segment size.
Let's note that since nonce for every chain is unique, it is possible to calculated differences between two versions, i.e. what segments of file have changed, and which stayed the same. Segments that stay same guarantee that respective section of file's content stay the same.
Current format versions (storing attributes)
Version 2 is used for content and related attributes' bytes, while version 1 stores no attributes.
Both versions have the same header layout to hide presence of attributes. Version 2 is encrypted like version 1, except that together with n content bytes, k bytes of attributes are encrypted in the following order:
|<- 4 bytes ->| |<- k bytes ->| |<- n bytes ->|
| num of attr bytes | | attributes | | content |
Attributes' length can be up to 4GB in length.
Note 1. Format versions 1 and 2 distinguish how content is assembled before encryption. Since packaging is the same, segment level API is the same for these versions. But high level encrypting sink and decrypting source provide APIs with and without attributes.
Note 2. We may think about attributes' and content as two sections. Some future format may have more than two sections in object, allowing to have content from different files in the same object without revealing such setup with a different header length. Implementation of such format will need only higher level encrypting sink and decrypting source.
Object versions
Every object may go through many versions, and it would be nice to have both object id and a version imprinted into package. Imagine that a client wants to get a particular object and version from a server. If server tries to give an incorrect version, it should be noticeable immediately. XSP employs the following approach to this.
Header is a with-nonce package. Nonce is some zeroth (initial) nonce for an object, advanced by version number. Zeroth nonce can be used as object's id. If you expect a particular id+version combination, you expect to use a particular nonce to open header.
There may be a scenario, in which two clients try to write same new version of an object. In this concurrent case, they may send headers that use same nonce. This opens a possibility for crypt-analysis of a header. But since header only has info about segments structure and segment nonces, such crypt-analysis won't jeopardize the content. When creating a new version, both clients will generate new random nonces for use in segments chains that constitute either whole, or a diff of a new version, ensuring that there is no segment nonce reuse.
API for XSP reading and writing
Let's import XSP-related functionality:
import * as xsp from 'xsp-files';
Opening segments
Reader is used for reading.
let reader = await xsp.makeSegmentsReader(
key, // this is object/file key
zerothHeaderNonce, // this is a zeroth nonce, used as id
version, // version that is expected to be read by this reader
fileHeader, // object header, checked for version in this call
cryptor); // is an async cryptor, used to decrypt segments and header
Reader provides a few informational functions, and a segment opening function. Reading XSP file starting from the very first segment may look as follows
// content length may be set, or, if it was unknown at time of header creation,
// content length will be undefined
const contentLength = reader.contentLength;
// This is an iterator from the first segment. To start from another segment, give an index
let segInfosIter = reader.segmentInfos();
// assume that this contains all encrypted segments
const allEncrBytes = ... // Uint8Array type
for (const segInfo of segInfosIter) {
// get encrypted bytes of a particular segment using segInfo
const encrBytes = allEncrBytes.subarray(
segInfo.packedOfs, segInfo.packedOfs + segInfo.packedLen);
// decrypt segment's content bytes
const content = await reader.openSeg(segInfo, encrBytes);
// do something with decrypted content of a segment ...
}
// reader should be destroyed, when no longer needed
reader.destroy();
A stream-like higher level API can be used for reading:
const src = (reader.formatVersion === 2) ?
await makeDecryptedByteSourceWithAttrs(segsByteSrc, segReader) :
makeDecryptedByteSource(segsByteSrc, segReader));
// can read bytes at current position
let bytes = await src.read(100);
// can change current position
const position = await src.getPosition();
await src.seek(position + 200);
// read to the end of the source
bytes = await src.read();
if (reader.formatVersion === 2) {
const attrSize = await src.getAttrsSize();
const attrBytes = await src.readAttrs();
}
Packing segments
Writer is used for encrypting (packing) segments. For writing all new segments from start to finish, we use option new
:
let writer = await makeSegmentsWriter(
key, // this is object/file key
zerothHeaderNonce, // this is a zeroth nonce, used as id
version, // version that will be packed by the writer
{ // option to create writer
type: 'new', // all new segments
segSize: segSizein256bs, // full seg size in 256bytes, e.g. 16 equals 4*4*256B, or 4KB size
formatWithSections: true // optional field, indicates format with attributes
},
randomBytes, // random numbers, used for segment nonces
cryptor); // is an async cryptor, used to encrypt segments and header
For writing an updated version, given an object source of a base version, baseSrc
, we use option update
to write only partial update of a file:
let writer = await makeSegmentsWriter(
key, zerothHeaderNonce, version,
{ // option to create writer
type: 'update', // making a diff, effectively updating existing base segments
base: baseSrc // base source is used to reencrypt base bytes located on
// boundaries of base and updated segments
},
randomBytes, cryptor);
We may use writer's information and packing functions directly, or we may use a sink with simpler api for streaming. For format without attributes (writer.formatVersion === 1
) we do:
const { sink, sub } = await xsp.makeEncryptingByteSink(writer);
For format with attributes (writer.formatVersion === 2
) we do for new object:
const { sink, sub } = await xsp.makeEncryptingByteSinkWithAttrs(writer);
and for writer with base:
const baseAttrsLen = await baseSrc.getAttrsSize();
const { sink, sub } = await xsp.makeEncryptingByteSinkWithAttrs(writer, baseAttrsLen);
Attributes should be written, or size set before content of the first segment is written:
await sink.writeAttrs(attrs);
// or
await byteSink.setAttrSectionSize(attrSize);
// with following call somewhere before write completion
await sink.writeAttrs(attrs);
Writing content eventually trickles down as events in subscription. Note that encryption doesn't start without subscription.
// we can put content into sink at a given offset, result shows in the events
await sink.write(ofs, content);
// sub is an event subscribing function that fits well with rxjs,
// and with an optional backpressure function can have
const enc$ = Observable.create(obs => sub(obs, backpressure)).share();
// there is a couple of encryption events:
// - event with encrypted header and layout information
const headerEvent$ = enc$.filter(ev => (ev.type === 'header'));
// - events with encrypted segment chunks
const segEvent$ = enc$.filter(ev => (ev.type === 'seg'));
// header event sets xsp object's geometry/layout, it can't change afterwards
headerEvent$
.flatMap(async headerEvent => {
// layout information can be used to adjust saving/sending strategy
foo( headerEvent.layout );
// header bytes here can be sent/saved, etc.
bar( headerEvent.header );
});
// segment events contain packed segments, and some info about location
segEvent$
.flatMap(async segEvent => {
fooBar(
segEvent.segInfo, // information about segment
segEvent.seg); // segment bytes
});
Cleanup
As with reader, writer should be destroyed after use:
writer.destroy();
License
This code is provided here under GNU Public License Version 3.
XSP object format is free for anyone to use, to implement, to do anything with them.