gotosocial/vendor/golang.org/x/crypto/blake2b/blake2x.go

// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.

package blake2b

import (
	"encoding/binary"
	"errors"
	"io"
)

// XOF defines the interface to hash functions that
// support arbitrary-length output.
type XOF interface {
	// Write absorbs more data into the hash's state. It panics if called
	// after Read.
	io.Writer

	// Read reads more output from the hash. It returns io.EOF if the limit
	// has been reached.
	io.Reader

	// Clone returns a copy of the XOF in its current state.
	Clone() XOF

	// Reset resets the XOF to its initial state.
	Reset()
}

// OutputLengthUnknown can be used as the size argument to NewXOF to indicate
// the length of the output is not known in advance.
const OutputLengthUnknown = 0

// magicUnknownOutputLength is a magic value for the output size that indicates
// an unknown number of output bytes.
const magicUnknownOutputLength = (1 << 32) - 1

// maxOutputLength is the absolute maximum number of bytes to produce when the
// number of output bytes is unknown.
const maxOutputLength = (1 << 32) * 64

// NewXOF creates a new variable-output-length hash. The hash either produce a
// known number of bytes (1 <= size < 2**32-1), or an unknown number of bytes
// (size == OutputLengthUnknown). In the latter case, an absolute limit of
// 256GiB applies.
//
// A non-nil key turns the hash into a MAC. The key must between
// zero and 32 bytes long.
func NewXOF(size uint32, key []byte) (XOF, error) {
	if len(key) > Size {
		return nil, errKeySize
	}
	if size == magicUnknownOutputLength {
		// 2^32-1 indicates an unknown number of bytes and thus isn't a
		// valid length.
		return nil, errors.New("blake2b: XOF length too large")
	}
	if size == OutputLengthUnknown {
		size = magicUnknownOutputLength
	}
	x := &xof{
		d: digest{
			size:   Size,
			keyLen: len(key),
		},
		length: size,
	}
	copy(x.d.key[:], key)
	x.Reset()
	return x, nil
}

type xof struct {
	d                digest
	length           uint32
	remaining        uint64
	cfg, root, block [Size]byte
	offset           int
	nodeOffset       uint32
	readMode         bool
}

func (x *xof) Write(p []byte) (n int, err error) {
	if x.readMode {
		panic("blake2b: write to XOF after read")
	}
	return x.d.Write(p)
}

func (x *xof) Clone() XOF {
	clone := *x
	return &clone
}

func (x *xof) Reset() {
	x.cfg[0] = byte(Size)
	binary.LittleEndian.PutUint32(x.cfg[4:], uint32(Size)) // leaf length
	binary.LittleEndian.PutUint32(x.cfg[12:], x.length)    // XOF length
	x.cfg[17] = byte(Size)                                 // inner hash size

	x.d.Reset()
	x.d.h[1] ^= uint64(x.length) << 32

	x.remaining = uint64(x.length)
	if x.remaining == magicUnknownOutputLength {
		x.remaining = maxOutputLength
	}
	x.offset, x.nodeOffset = 0, 0
	x.readMode = false
}

func (x *xof) Read(p []byte) (n int, err error) {
	if !x.readMode {
		x.d.finalize(&x.root)
		x.readMode = true
	}

	if x.remaining == 0 {
		return 0, io.EOF
	}

	n = len(p)
	if uint64(n) > x.remaining {
		n = int(x.remaining)
		p = p[:n]
	}

	if x.offset > 0 {
		blockRemaining := Size - x.offset
		if n < blockRemaining {
			x.offset += copy(p, x.block[x.offset:])
			x.remaining -= uint64(n)
			return
		}
		copy(p, x.block[x.offset:])
		p = p[blockRemaining:]
		x.offset = 0
		x.remaining -= uint64(blockRemaining)
	}

	for len(p) >= Size {
		binary.LittleEndian.PutUint32(x.cfg[8:], x.nodeOffset)
		x.nodeOffset++

		x.d.initConfig(&x.cfg)
		x.d.Write(x.root[:])
		x.d.finalize(&x.block)

		copy(p, x.block[:])
		p = p[Size:]
		x.remaining -= uint64(Size)
	}

	if todo := len(p); todo > 0 {
		if x.remaining < uint64(Size) {
			x.cfg[0] = byte(x.remaining)
		}
		binary.LittleEndian.PutUint32(x.cfg[8:], x.nodeOffset)
		x.nodeOffset++

		x.d.initConfig(&x.cfg)
		x.d.Write(x.root[:])
		x.d.finalize(&x.block)

		x.offset = copy(p, x.block[:todo])
		x.remaining -= uint64(todo)
	}
	return
}

func (d *digest) initConfig(cfg *[Size]byte) {
	d.offset, d.c[0], d.c[1] = 0, 0, 0
	for i := range d.h {
		d.h[i] = iv[i] ^ binary.LittleEndian.Uint64(cfg[i*8:])
	}
}
Grand test fixup (#138) * start fixing up tests * fix up tests + automate with drone * fiddle with linting * messing about with drone.yml * some more fiddling * hmmm * add cache * add vendor directory * verbose * ci updates * update some little things * update sig 2021-08-12 21:03:24 +02:00			`// Copyright 2017 The Go Authors. All rights reserved.`
			`// Use of this source code is governed by a BSD-style`
			`// license that can be found in the LICENSE file.`

			`package blake2b`

			`import (`
			`"encoding/binary"`
			`"errors"`
			`"io"`
			`)`

			`// XOF defines the interface to hash functions that`
			`// support arbitrary-length output.`
			`type XOF interface {`
			`// Write absorbs more data into the hash's state. It panics if called`
			`// after Read.`
			`io.Writer`

			`// Read reads more output from the hash. It returns io.EOF if the limit`
			`// has been reached.`
			`io.Reader`

			`// Clone returns a copy of the XOF in its current state.`
			`Clone() XOF`

			`// Reset resets the XOF to its initial state.`
			`Reset()`
			`}`

			`// OutputLengthUnknown can be used as the size argument to NewXOF to indicate`
			`// the length of the output is not known in advance.`
			`const OutputLengthUnknown = 0`

			`// magicUnknownOutputLength is a magic value for the output size that indicates`
			`// an unknown number of output bytes.`
			`const magicUnknownOutputLength = (1 << 32) - 1`

			`// maxOutputLength is the absolute maximum number of bytes to produce when the`
			`// number of output bytes is unknown.`
			`const maxOutputLength = (1 << 32) * 64`

			`// NewXOF creates a new variable-output-length hash. The hash either produce a`
			`// known number of bytes (1 <= size < 2**32-1), or an unknown number of bytes`
			`// (size == OutputLengthUnknown). In the latter case, an absolute limit of`
			`// 256GiB applies.`
			`//`
			`// A non-nil key turns the hash into a MAC. The key must between`
			`// zero and 32 bytes long.`
			`func NewXOF(size uint32, key []byte) (XOF, error) {`
			`if len(key) > Size {`
			`return nil, errKeySize`
			`}`
			`if size == magicUnknownOutputLength {`
			`// 2^32-1 indicates an unknown number of bytes and thus isn't a`
			`// valid length.`
			`return nil, errors.New("blake2b: XOF length too large")`
			`}`
			`if size == OutputLengthUnknown {`
			`size = magicUnknownOutputLength`
			`}`
			`x := &xof{`
			`d: digest{`
			`size: Size,`
			`keyLen: len(key),`
			`},`
			`length: size,`
			`}`
			`copy(x.d.key[:], key)`
			`x.Reset()`
			`return x, nil`
			`}`

			`type xof struct {`
			`d digest`
			`length uint32`
			`remaining uint64`
			`cfg, root, block [Size]byte`
			`offset int`
			`nodeOffset uint32`
			`readMode bool`
			`}`

			`func (x *xof) Write(p []byte) (n int, err error) {`
			`if x.readMode {`
			`panic("blake2b: write to XOF after read")`
			`}`
			`return x.d.Write(p)`
			`}`

			`func (x *xof) Clone() XOF {`
			`clone := *x`
			`return &clone`
			`}`

			`func (x *xof) Reset() {`
			`x.cfg[0] = byte(Size)`
			`binary.LittleEndian.PutUint32(x.cfg[4:], uint32(Size)) // leaf length`
			`binary.LittleEndian.PutUint32(x.cfg[12:], x.length) // XOF length`
			`x.cfg[17] = byte(Size) // inner hash size`

			`x.d.Reset()`
			`x.d.h[1] ^= uint64(x.length) << 32`

			`x.remaining = uint64(x.length)`
			`if x.remaining == magicUnknownOutputLength {`
			`x.remaining = maxOutputLength`
			`}`
			`x.offset, x.nodeOffset = 0, 0`
			`x.readMode = false`
			`}`

			`func (x *xof) Read(p []byte) (n int, err error) {`
			`if !x.readMode {`
			`x.d.finalize(&x.root)`
			`x.readMode = true`
			`}`

			`if x.remaining == 0 {`
			`return 0, io.EOF`
			`}`

			`n = len(p)`
			`if uint64(n) > x.remaining {`
			`n = int(x.remaining)`
			`p = p[:n]`
			`}`

			`if x.offset > 0 {`
			`blockRemaining := Size - x.offset`
			`if n < blockRemaining {`
			`x.offset += copy(p, x.block[x.offset:])`
			`x.remaining -= uint64(n)`
			`return`
			`}`
			`copy(p, x.block[x.offset:])`
			`p = p[blockRemaining:]`
			`x.offset = 0`
			`x.remaining -= uint64(blockRemaining)`
			`}`

			`for len(p) >= Size {`
			`binary.LittleEndian.PutUint32(x.cfg[8:], x.nodeOffset)`
			`x.nodeOffset++`

			`x.d.initConfig(&x.cfg)`
			`x.d.Write(x.root[:])`
			`x.d.finalize(&x.block)`

			`copy(p, x.block[:])`
			`p = p[Size:]`
			`x.remaining -= uint64(Size)`
			`}`

			`if todo := len(p); todo > 0 {`
			`if x.remaining < uint64(Size) {`
			`x.cfg[0] = byte(x.remaining)`
			`}`
			`binary.LittleEndian.PutUint32(x.cfg[8:], x.nodeOffset)`
			`x.nodeOffset++`

			`x.d.initConfig(&x.cfg)`
			`x.d.Write(x.root[:])`
			`x.d.finalize(&x.block)`

			`x.offset = copy(p, x.block[:todo])`
			`x.remaining -= uint64(todo)`
			`}`
			`return`
			`}`

			`func (d digest) initConfig(cfg [Size]byte) {`
			`d.offset, d.c[0], d.c[1] = 0, 0, 0`
			`for i := range d.h {`
			`d.h[i] = iv[i] ^ binary.LittleEndian.Uint64(cfg[i*8:])`
			`}`
			`}`