Documentation ¶
Overview ¶
Package hash provides interfaces for hash functions.
Example (BinaryMarshaler) ¶
package main import ( "bytes" "crypto/sha256" "encoding" "fmt" "log" ) func main() { const ( input1 = "The tunneling gopher digs downwards, " input2 = "unaware of what he will find." ) first := sha256.New() first.Write([]byte(input1)) marshaler, ok := first.(encoding.BinaryMarshaler) if !ok { log.Fatal("first does not implement encoding.BinaryMarshaler") } state, err := marshaler.MarshalBinary() if err != nil { log.Fatal("unable to marshal hash:", err) } second := sha256.New() unmarshaler, ok := second.(encoding.BinaryUnmarshaler) if !ok { log.Fatal("second does not implement encoding.BinaryUnmarshaler") } if err := unmarshaler.UnmarshalBinary(state); err != nil { log.Fatal("unable to unmarshal hash:", err) } first.Write([]byte(input2)) second.Write([]byte(input2)) fmt.Printf("%x\n", first.Sum(nil)) fmt.Println(bytes.Equal(first.Sum(nil), second.Sum(nil))) }
Output: 57d51a066f3a39942649cd9a76c77e97ceab246756ff3888659e6aa5a07f4a52 true
Index ¶
Examples ¶
Constants ¶
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Variables ¶
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Functions ¶
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Types ¶
type Hash ¶
type Hash interface { // Write (via the embedded io.Writer interface) adds more data to the running hash. // It never returns an error. io.Writer // Sum appends the current hash to b and returns the resulting slice. // It does not change the underlying hash state. Sum(b []byte) []byte // Reset resets the Hash to its initial state. Reset() // Size returns the number of bytes Sum will return. Size() int // BlockSize returns the hash's underlying block size. // The Write method must be able to accept any amount // of data, but it may operate more efficiently if all writes // are a multiple of the block size. BlockSize() int }
Hash is the common interface implemented by all hash functions.
Hash implementations in the standard library (e.g. hash/crc32 and crypto/sha256) implement the encoding.BinaryMarshaler and encoding.BinaryUnmarshaler interfaces. Marshaling a hash implementation allows its internal state to be saved and used for additional processing later, without having to re-write the data previously written to the hash. The hash state may contain portions of the input in its original form, which users are expected to handle for any possible security implications.
Compatibility: Any future changes to hash or crypto packages will endeavor to maintain compatibility with state encoded using previous versions. That is, any released versions of the packages should be able to decode data written with any previously released version, subject to issues such as security fixes. See the Go compatibility document for background: https://golang.org/doc/go1compat
Directories ¶
Path | Synopsis |
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Package adler32 implements the Adler-32 checksum.
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Package adler32 implements the Adler-32 checksum. |
Package crc32 implements the 32-bit cyclic redundancy check, or CRC-32, checksum.
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Package crc32 implements the 32-bit cyclic redundancy check, or CRC-32, checksum. |
Package crc64 implements the 64-bit cyclic redundancy check, or CRC-64, checksum.
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Package crc64 implements the 64-bit cyclic redundancy check, or CRC-64, checksum. |
Package fnv implements FNV-1 and FNV-1a, non-cryptographic hash functions created by Glenn Fowler, Landon Curt Noll, and Phong Vo.
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Package fnv implements FNV-1 and FNV-1a, non-cryptographic hash functions created by Glenn Fowler, Landon Curt Noll, and Phong Vo. |
Package maphash provides hash functions on byte sequences.
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Package maphash provides hash functions on byte sequences. |