// Copyright 2009 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 crc32 implements the 32-bit cyclic redundancy check, or CRC-32, // checksum. See http://en.wikipedia.org/wiki/Cyclic_redundancy_check for // information. // // Polynomials are represented in LSB-first form also known as reversed representation. // // See http://en.wikipedia.org/wiki/Mathematics_of_cyclic_redundancy_checks#Reversed_representations_and_reciprocal_polynomials // for information. package crc32 import ( "errors" "hash" "sync" ) // The size of a CRC-32 checksum in bytes. const Size = 4 // Predefined polynomials. const ( // IEEE is by far and away the most common CRC-32 polynomial. // Used by ethernet (IEEE 802.3), v.42, fddi, gzip, zip, png, ... IEEE = 0xedb88320 // Castagnoli's polynomial, used in iSCSI. // Has better error detection characteristics than IEEE. // http://dx.doi.org/10.1109/26.231911 Castagnoli = 0x82f63b78 // Koopman's polynomial. // Also has better error detection characteristics than IEEE. // http://dx.doi.org/10.1109/DSN.2002.1028931 Koopman = 0xeb31d82e ) // Table is a 256-word table representing the polynomial for efficient processing. type Table [256]uint32 // This file makes use of functions implemented in architecture-specific files. // The interface that they implement is as follows: // // // archAvailableIEEE reports whether an architecture-specific CRC32-IEEE // // algorithm is available. // archAvailableIEEE() bool // // // archInitIEEE initializes the architecture-specific CRC3-IEEE algorithm. // // It can only be called if archAvailableIEEE() returns true. // archInitIEEE() // // // archUpdateIEEE updates the given CRC32-IEEE. It can only be called if // // archInitIEEE() was previously called. // archUpdateIEEE(crc uint32, p []byte) uint32 // // // archAvailableCastagnoli reports whether an architecture-specific // // CRC32-C algorithm is available. // archAvailableCastagnoli() bool // // // archInitCastagnoli initializes the architecture-specific CRC32-C // // algorithm. It can only be called if archAvailableCastagnoli() returns // // true. // archInitCastagnoli() // // // archUpdateCastagnoli updates the given CRC32-C. It can only be called // // if archInitCastagnoli() was previously called. // archUpdateCastagnoli(crc uint32, p []byte) uint32 // castagnoliTable points to a lazily initialized Table for the Castagnoli // polynomial. MakeTable will always return this value when asked to make a // Castagnoli table so we can compare against it to find when the caller is // using this polynomial. var castagnoliTable *Table var castagnoliTable8 *slicing8Table var castagnoliArchImpl bool var updateCastagnoli func(crc uint32, p []byte) uint32 var castagnoliOnce sync.Once func castagnoliInit() { castagnoliTable = simpleMakeTable(Castagnoli) castagnoliArchImpl = archAvailableCastagnoli() if castagnoliArchImpl { archInitCastagnoli() updateCastagnoli = archUpdateCastagnoli } else { // Initialize the slicing-by-8 table. castagnoliTable8 = slicingMakeTable(Castagnoli) updateCastagnoli = func(crc uint32, p []byte) uint32 { return slicingUpdate(crc, castagnoliTable8, p) } } } // IEEETable is the table for the IEEE polynomial. var IEEETable = simpleMakeTable(IEEE) // ieeeTable8 is the slicing8Table for IEEE var ieeeTable8 *slicing8Table var ieeeArchImpl bool var updateIEEE func(crc uint32, p []byte) uint32 var ieeeOnce sync.Once func ieeeInit() { ieeeArchImpl = archAvailableIEEE() if ieeeArchImpl { archInitIEEE() updateIEEE = archUpdateIEEE } else { // Initialize the slicing-by-8 table. ieeeTable8 = slicingMakeTable(IEEE) updateIEEE = func(crc uint32, p []byte) uint32 { return slicingUpdate(crc, ieeeTable8, p) } } } // MakeTable returns a Table constructed from the specified polynomial. // The contents of this Table must not be modified. func MakeTable(poly uint32) *Table { switch poly { case IEEE: ieeeOnce.Do(ieeeInit) return IEEETable case Castagnoli: castagnoliOnce.Do(castagnoliInit) return castagnoliTable } return simpleMakeTable(poly) } // digest represents the partial evaluation of a checksum. type digest struct { crc uint32 tab *Table } // New creates a new hash.Hash32 computing the CRC-32 checksum using the // polynomial represented by the Table. Its Sum method will lay the // value out in big-endian byte order. The returned Hash32 also // implements encoding.BinaryMarshaler and encoding.BinaryUnmarshaler to // marshal and unmarshal the internal state of the hash. func New(tab *Table) hash.Hash32 { if tab == IEEETable { ieeeOnce.Do(ieeeInit) } return &digest{0, tab} } // NewIEEE creates a new hash.Hash32 computing the CRC-32 checksum using // the IEEE polynomial. Its Sum method will lay the value out in // big-endian byte order. The returned Hash32 also implements // encoding.BinaryMarshaler and encoding.BinaryUnmarshaler to marshal // and unmarshal the internal state of the hash. func NewIEEE() hash.Hash32 { return New(IEEETable) } func (d *digest) Size() int { return Size } func (d *digest) BlockSize() int { return 1 } func (d *digest) Reset() { d.crc = 0 } const ( magic = "crc\x01" marshaledSize = len(magic) + 4 + 4 ) func (d *digest) MarshalBinary() ([]byte, error) { b := make([]byte, 0, marshaledSize) b = append(b, magic...) b = appendUint32(b, tableSum(d.tab)) b = appendUint32(b, d.crc) return b, nil } func (d *digest) UnmarshalBinary(b []byte) error { if len(b) < len(magic) || string(b[:len(magic)]) != magic { return errors.New("hash/crc32: invalid hash state identifier") } if len(b) != marshaledSize { return errors.New("hash/crc32: invalid hash state size") } if tableSum(d.tab) != readUint32(b[4:]) { return errors.New("hash/crc32: tables do not match") } d.crc = readUint32(b[8:]) return nil } func appendUint32(b []byte, x uint32) []byte { a := [4]byte{ byte(x >> 24), byte(x >> 16), byte(x >> 8), byte(x), } return append(b, a[:]...) } func readUint32(b []byte) uint32 { _ = b[3] return uint32(b[3]) | uint32(b[2])<<8 | uint32(b[1])<<16 | uint32(b[0])<<24 } // Update returns the result of adding the bytes in p to the crc. func Update(crc uint32, tab *Table, p []byte) uint32 { switch tab { case castagnoliTable: return updateCastagnoli(crc, p) case IEEETable: // Unfortunately, because IEEETable is exported, IEEE may be used without a // call to MakeTable. We have to make sure it gets initialized in that case. ieeeOnce.Do(ieeeInit) return updateIEEE(crc, p) default: return simpleUpdate(crc, tab, p) } } func (d *digest) Write(p []byte) (n int, err error) { switch d.tab { case castagnoliTable: d.crc = updateCastagnoli(d.crc, p) case IEEETable: // We only create digest objects through New() which takes care of // initialization in this case. d.crc = updateIEEE(d.crc, p) default: d.crc = simpleUpdate(d.crc, d.tab, p) } return len(p), nil } func (d *digest) Sum32() uint32 { return d.crc } func (d *digest) Sum(in []byte) []byte { s := d.Sum32() return append(in, byte(s>>24), byte(s>>16), byte(s>>8), byte(s)) } // Checksum returns the CRC-32 checksum of data // using the polynomial represented by the Table. func Checksum(data []byte, tab *Table) uint32 { return Update(0, tab, data) } // ChecksumIEEE returns the CRC-32 checksum of data // using the IEEE polynomial. func ChecksumIEEE(data []byte) uint32 { ieeeOnce.Do(ieeeInit) return updateIEEE(0, data) } // tableSum returns the IEEE checksum of table t. func tableSum(t *Table) uint32 { var a [1024]byte b := a[:0] if t != nil { for _, x := range t { b = appendUint32(b, x) } } return ChecksumIEEE(b) }