// Copyright 2024 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 gcm import ( "crypto/internal/fips140" "crypto/internal/fips140/aes" "crypto/internal/fips140/alias" "crypto/internal/fips140/drbg" "crypto/internal/fips140deps/byteorder" "math" ) // SealWithRandomNonce encrypts plaintext to out, and writes a random nonce to // nonce. nonce must be 12 bytes, and out must be 16 bytes longer than plaintext. // out and plaintext may overlap exactly or not at all. additionalData and out // must not overlap. // // This complies with FIPS 140-3 IG C.H Scenario 2. // // Note that this is NOT a [cipher.AEAD].Seal method. func SealWithRandomNonce(g *GCM, nonce, out, plaintext, additionalData []byte) { if uint64(len(plaintext)) > uint64((1<<32)-2)*gcmBlockSize { panic("crypto/cipher: message too large for GCM") } if len(nonce) != gcmStandardNonceSize { panic("crypto/cipher: incorrect nonce length given to GCMWithRandomNonce") } if len(out) != len(plaintext)+gcmTagSize { panic("crypto/cipher: incorrect output length given to GCMWithRandomNonce") } if alias.InexactOverlap(out, plaintext) { panic("crypto/cipher: invalid buffer overlap of output and input") } if alias.AnyOverlap(out, additionalData) { panic("crypto/cipher: invalid buffer overlap of output and additional data") } fips140.RecordApproved() drbg.Read(nonce) seal(out, g, nonce, plaintext, additionalData) } // NewGCMWithCounterNonce returns a new AEAD that works like GCM, but enforces // the construction of deterministic nonces. The nonce must be 96 bits, the // first 32 bits must be an encoding of the module name, and the last 64 bits // must be a counter. // // This complies with FIPS 140-3 IG C.H Scenario 3. func NewGCMWithCounterNonce(cipher *aes.Block) (*GCMWithCounterNonce, error) { g, err := newGCM(&GCM{}, cipher, gcmStandardNonceSize, gcmTagSize) if err != nil { return nil, err } return &GCMWithCounterNonce{g: *g}, nil } type GCMWithCounterNonce struct { g GCM ready bool fixedName uint32 start uint64 next uint64 } func (g *GCMWithCounterNonce) NonceSize() int { return gcmStandardNonceSize } func (g *GCMWithCounterNonce) Overhead() int { return gcmTagSize } func (g *GCMWithCounterNonce) Seal(dst, nonce, plaintext, data []byte) []byte { if len(nonce) != gcmStandardNonceSize { panic("crypto/cipher: incorrect nonce length given to GCM") } counter := byteorder.BEUint64(nonce[len(nonce)-8:]) if !g.ready { // The first invocation sets the fixed name encoding and start counter. g.ready = true g.start = counter g.fixedName = byteorder.BEUint32(nonce[:4]) } if g.fixedName != byteorder.BEUint32(nonce[:4]) { panic("crypto/cipher: incorrect module name given to GCMWithCounterNonce") } counter -= g.start // Ensure the counter is monotonically increasing. if counter == math.MaxUint64 { panic("crypto/cipher: counter wrapped") } if counter < g.next { panic("crypto/cipher: counter decreased") } g.next = counter + 1 fips140.RecordApproved() return g.g.sealAfterIndicator(dst, nonce, plaintext, data) } func (g *GCMWithCounterNonce) Open(dst, nonce, ciphertext, data []byte) ([]byte, error) { fips140.RecordApproved() return g.g.Open(dst, nonce, ciphertext, data) } // NewGCMForTLS12 returns a new AEAD that works like GCM, but enforces the // construction of nonces as specified in RFC 5288, Section 3 and RFC 9325, // Section 7.2.1. // // This complies with FIPS 140-3 IG C.H Scenario 1.a. func NewGCMForTLS12(cipher *aes.Block) (*GCMForTLS12, error) { g, err := newGCM(&GCM{}, cipher, gcmStandardNonceSize, gcmTagSize) if err != nil { return nil, err } return &GCMForTLS12{g: *g}, nil } type GCMForTLS12 struct { g GCM next uint64 } func (g *GCMForTLS12) NonceSize() int { return gcmStandardNonceSize } func (g *GCMForTLS12) Overhead() int { return gcmTagSize } func (g *GCMForTLS12) Seal(dst, nonce, plaintext, data []byte) []byte { if len(nonce) != gcmStandardNonceSize { panic("crypto/cipher: incorrect nonce length given to GCM") } counter := byteorder.BEUint64(nonce[len(nonce)-8:]) // Ensure the counter is monotonically increasing. if counter == math.MaxUint64 { panic("crypto/cipher: counter wrapped") } if counter < g.next { panic("crypto/cipher: counter decreased") } g.next = counter + 1 fips140.RecordApproved() return g.g.sealAfterIndicator(dst, nonce, plaintext, data) } func (g *GCMForTLS12) Open(dst, nonce, ciphertext, data []byte) ([]byte, error) { fips140.RecordApproved() return g.g.Open(dst, nonce, ciphertext, data) } // NewGCMForTLS13 returns a new AEAD that works like GCM, but enforces the // construction of nonces as specified in RFC 8446, Section 5.3. func NewGCMForTLS13(cipher *aes.Block) (*GCMForTLS13, error) { g, err := newGCM(&GCM{}, cipher, gcmStandardNonceSize, gcmTagSize) if err != nil { return nil, err } return &GCMForTLS13{g: *g}, nil } type GCMForTLS13 struct { g GCM ready bool mask uint64 next uint64 } func (g *GCMForTLS13) NonceSize() int { return gcmStandardNonceSize } func (g *GCMForTLS13) Overhead() int { return gcmTagSize } func (g *GCMForTLS13) Seal(dst, nonce, plaintext, data []byte) []byte { if len(nonce) != gcmStandardNonceSize { panic("crypto/cipher: incorrect nonce length given to GCM") } counter := byteorder.BEUint64(nonce[len(nonce)-8:]) if !g.ready { // In the first call, the counter is zero, so we learn the XOR mask. g.ready = true g.mask = counter } counter ^= g.mask // Ensure the counter is monotonically increasing. if counter == math.MaxUint64 { panic("crypto/cipher: counter wrapped") } if counter < g.next { panic("crypto/cipher: counter decreased") } g.next = counter + 1 fips140.RecordApproved() return g.g.sealAfterIndicator(dst, nonce, plaintext, data) } func (g *GCMForTLS13) Open(dst, nonce, ciphertext, data []byte) ([]byte, error) { fips140.RecordApproved() return g.g.Open(dst, nonce, ciphertext, data) } // NewGCMForSSH returns a new AEAD that works like GCM, but enforces the // construction of nonces as specified in RFC 5647. // // This complies with FIPS 140-3 IG C.H Scenario 1.d. func NewGCMForSSH(cipher *aes.Block) (*GCMForSSH, error) { g, err := newGCM(&GCM{}, cipher, gcmStandardNonceSize, gcmTagSize) if err != nil { return nil, err } return &GCMForSSH{g: *g}, nil } type GCMForSSH struct { g GCM ready bool start uint64 next uint64 } func (g *GCMForSSH) NonceSize() int { return gcmStandardNonceSize } func (g *GCMForSSH) Overhead() int { return gcmTagSize } func (g *GCMForSSH) Seal(dst, nonce, plaintext, data []byte) []byte { if len(nonce) != gcmStandardNonceSize { panic("crypto/cipher: incorrect nonce length given to GCM") } counter := byteorder.BEUint64(nonce[len(nonce)-8:]) if !g.ready { // In the first call we learn the start value. g.ready = true g.start = counter } counter -= g.start // Ensure the counter is monotonically increasing. if counter == math.MaxUint64 { panic("crypto/cipher: counter wrapped") } if counter < g.next { panic("crypto/cipher: counter decreased") } g.next = counter + 1 fips140.RecordApproved() return g.g.sealAfterIndicator(dst, nonce, plaintext, data) } func (g *GCMForSSH) Open(dst, nonce, ciphertext, data []byte) ([]byte, error) { fips140.RecordApproved() return g.g.Open(dst, nonce, ciphertext, data) }