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forgejo/modules/auth/password/hash/hash.go
zeripath ef11d41639
Make CI use a dummy password hasher for all tests (#22983)
During the recent hash algorithm change it became clear that the choice
of password hash algorithm plays a role in the time taken for CI to run.

Therefore as attempt to improve CI we should consider using a dummy
hashing algorithm instead of a real hashing algorithm.

This PR creates a dummy algorithm which is then set as the default
hashing algorithm during tests that use the fixtures. This hopefully
will cause a reduction in the time it takes for CI to run.

---------

Signed-off-by: Andrew Thornton <art27@cantab.net>
Co-authored-by: Lunny Xiao <xiaolunwen@gmail.com>
2023-02-20 13:20:30 +08:00

190 lines
6.3 KiB
Go

// Copyright 2023 The Gitea Authors. All rights reserved.
// SPDX-License-Identifier: MIT
package hash
import (
"crypto/subtle"
"encoding/hex"
"fmt"
"strings"
"sync/atomic"
"code.gitea.io/gitea/modules/log"
)
// This package takes care of hashing passwords, verifying passwords, defining
// available password algorithms, defining recommended password algorithms and
// choosing the default password algorithm.
// PasswordSaltHasher will hash a provided password with the provided saltBytes
type PasswordSaltHasher interface {
HashWithSaltBytes(password string, saltBytes []byte) string
}
// PasswordHasher will hash a provided password with the salt
type PasswordHasher interface {
Hash(password, salt string) (string, error)
}
// PasswordVerifier will ensure that a providedPassword matches the hashPassword when hashed with the salt
type PasswordVerifier interface {
VerifyPassword(providedPassword, hashedPassword, salt string) bool
}
// PasswordHashAlgorithms are named PasswordSaltHashers with a default verifier and hash function
type PasswordHashAlgorithm struct {
PasswordSaltHasher
Specification string // The specification that is used to create the internal PasswordSaltHasher
}
// Hash the provided password with the salt and return the hash
func (algorithm *PasswordHashAlgorithm) Hash(password, salt string) (string, error) {
var saltBytes []byte
// There are two formats for the salt value:
// * The new format is a (32+)-byte hex-encoded string
// * The old format was a 10-byte binary format
// We have to tolerate both here.
if len(salt) == 10 {
saltBytes = []byte(salt)
} else {
var err error
saltBytes, err = hex.DecodeString(salt)
if err != nil {
return "", err
}
}
return algorithm.HashWithSaltBytes(password, saltBytes), nil
}
// Verify the provided password matches the hashPassword when hashed with the salt
func (algorithm *PasswordHashAlgorithm) VerifyPassword(providedPassword, hashedPassword, salt string) bool {
// Some PasswordSaltHashers have their own specialised compare function that takes into
// account the stored parameters within the hash. e.g. bcrypt
if verifier, ok := algorithm.PasswordSaltHasher.(PasswordVerifier); ok {
return verifier.VerifyPassword(providedPassword, hashedPassword, salt)
}
// Compute the hash of the password.
providedPasswordHash, err := algorithm.Hash(providedPassword, salt)
if err != nil {
log.Error("passwordhash: %v.Hash(): %v", algorithm.Specification, err)
return false
}
// Compare it against the hashed password in constant-time.
return subtle.ConstantTimeCompare([]byte(hashedPassword), []byte(providedPasswordHash)) == 1
}
var (
lastNonDefaultAlgorithm atomic.Value
availableHasherFactories = map[string]func(string) PasswordSaltHasher{}
)
// MustRegister registers a PasswordSaltHasher with the availableHasherFactories
// Caution: This is not thread safe.
func MustRegister[T PasswordSaltHasher](name string, newFn func(config string) T) {
if err := Register(name, newFn); err != nil {
panic(err)
}
}
// Register registers a PasswordSaltHasher with the availableHasherFactories
// Caution: This is not thread safe.
func Register[T PasswordSaltHasher](name string, newFn func(config string) T) error {
if _, has := availableHasherFactories[name]; has {
return fmt.Errorf("duplicate registration of password salt hasher: %s", name)
}
availableHasherFactories[name] = func(config string) PasswordSaltHasher {
n := newFn(config)
return n
}
return nil
}
// In early versions of gitea the password hash algorithm field of a user could be
// empty. At that point the default was `pbkdf2` without configuration values
//
// Please note this is not the same as the DefaultAlgorithm which is used
// to determine what an empty PASSWORD_HASH_ALGO setting in the app.ini means.
// These are not the same even if they have the same apparent value and they mean different things.
//
// DO NOT COALESCE THESE VALUES
const defaultEmptyHashAlgorithmSpecification = "pbkdf2"
// Parse will convert the provided algorithm specification in to a PasswordHashAlgorithm
// If the provided specification matches the DefaultHashAlgorithm Specification it will be
// used.
// In addition the last non-default hasher will be cached to help reduce the load from
// parsing specifications.
//
// NOTE: No de-aliasing is done in this function, thus any specification which does not
// contain a configuration will use the default values for that hasher. These are not
// necessarily the same values as those obtained by dealiasing. This allows for
// seamless backwards compatibility with the original configuration.
//
// To further labour this point, running `Parse("pbkdf2")` does not obtain the
// same algorithm as setting `PASSWORD_HASH_ALGO=pbkdf2` in app.ini, nor is it intended to.
// A user that has `password_hash_algo='pbkdf2'` in the db means get the original, unconfigured algorithm
// Users will be migrated automatically as they log-in to have the complete specification stored
// in their `password_hash_algo` fields by other code.
func Parse(algorithmSpec string) *PasswordHashAlgorithm {
if algorithmSpec == "" {
algorithmSpec = defaultEmptyHashAlgorithmSpecification
}
if DefaultHashAlgorithm != nil && algorithmSpec == DefaultHashAlgorithm.Specification {
return DefaultHashAlgorithm
}
ptr := lastNonDefaultAlgorithm.Load()
if ptr != nil {
hashAlgorithm, ok := ptr.(*PasswordHashAlgorithm)
if ok && hashAlgorithm.Specification == algorithmSpec {
return hashAlgorithm
}
}
// Now convert the provided specification in to a hasherType +/- some configuration parameters
vals := strings.SplitN(algorithmSpec, "$", 2)
var hasherType string
var config string
if len(vals) == 0 {
// This should not happen as algorithmSpec should not be empty
// due to it being assigned to defaultEmptyHashAlgorithmSpecification above
// but we should be absolutely cautious here
return nil
}
hasherType = vals[0]
if len(vals) > 1 {
config = vals[1]
}
newFn, has := availableHasherFactories[hasherType]
if !has {
// unknown hasher type
return nil
}
ph := newFn(config)
if ph == nil {
// The provided configuration is likely invalid - it will have been logged already
// but we cannot hash safely
return nil
}
hashAlgorithm := &PasswordHashAlgorithm{
PasswordSaltHasher: ph,
Specification: algorithmSpec,
}
lastNonDefaultAlgorithm.Store(hashAlgorithm)
return hashAlgorithm
}