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cb4e087fda
std.crypto: add support for ML-KEM
356 lines
12 KiB
Zig
356 lines
12 KiB
Zig
//! Cryptography.
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const root = @import("root");
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/// Authenticated Encryption with Associated Data
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pub const aead = struct {
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pub const aegis = struct {
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pub const Aegis128L = @import("crypto/aegis.zig").Aegis128L;
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pub const Aegis128L_256 = @import("crypto/aegis.zig").Aegis128L_256;
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pub const Aegis256 = @import("crypto/aegis.zig").Aegis256;
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pub const Aegis256_256 = @import("crypto/aegis.zig").Aegis256_256;
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};
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pub const aes_gcm = struct {
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pub const Aes128Gcm = @import("crypto/aes_gcm.zig").Aes128Gcm;
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pub const Aes256Gcm = @import("crypto/aes_gcm.zig").Aes256Gcm;
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};
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pub const aes_ocb = struct {
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pub const Aes128Ocb = @import("crypto/aes_ocb.zig").Aes128Ocb;
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pub const Aes256Ocb = @import("crypto/aes_ocb.zig").Aes256Ocb;
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};
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pub const chacha_poly = struct {
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pub const ChaCha20Poly1305 = @import("crypto/chacha20.zig").ChaCha20Poly1305;
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pub const ChaCha12Poly1305 = @import("crypto/chacha20.zig").ChaCha12Poly1305;
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pub const ChaCha8Poly1305 = @import("crypto/chacha20.zig").ChaCha8Poly1305;
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pub const XChaCha20Poly1305 = @import("crypto/chacha20.zig").XChaCha20Poly1305;
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pub const XChaCha12Poly1305 = @import("crypto/chacha20.zig").XChaCha12Poly1305;
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pub const XChaCha8Poly1305 = @import("crypto/chacha20.zig").XChaCha8Poly1305;
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};
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pub const isap = @import("crypto/isap.zig");
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pub const salsa_poly = struct {
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pub const XSalsa20Poly1305 = @import("crypto/salsa20.zig").XSalsa20Poly1305;
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};
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};
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/// Authentication (MAC) functions.
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pub const auth = struct {
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pub const hmac = @import("crypto/hmac.zig");
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pub const siphash = @import("crypto/siphash.zig");
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pub const aegis = struct {
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pub const Aegis128LMac = @import("crypto/aegis.zig").Aegis128LMac;
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pub const Aegis128LMac_128 = @import("crypto/aegis.zig").Aegis128LMac_128;
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pub const Aegis256Mac = @import("crypto/aegis.zig").Aegis256Mac;
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pub const Aegis256Mac_128 = @import("crypto/aegis.zig").Aegis256Mac_128;
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};
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pub const cmac = @import("crypto/cmac.zig");
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};
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/// Core functions, that should rarely be used directly by applications.
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pub const core = struct {
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pub const aes = @import("crypto/aes.zig");
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pub const keccak = @import("crypto/keccak_p.zig");
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pub const Ascon = @import("crypto/ascon.zig").State;
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/// Modes are generic compositions to construct encryption/decryption functions from block ciphers and permutations.
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///
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/// These modes are designed to be building blocks for higher-level constructions, and should generally not be used directly by applications, as they may not provide the expected properties and security guarantees.
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///
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/// Most applications may want to use AEADs instead.
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pub const modes = @import("crypto/modes.zig");
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};
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/// Diffie-Hellman key exchange functions.
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pub const dh = struct {
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pub const X25519 = @import("crypto/25519/x25519.zig").X25519;
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};
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/// Key Encapsulation Mechanisms.
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pub const kem = struct {
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pub const kyber_d00 = @import("crypto/ml_kem.zig").kyber_d00;
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pub const ml_kem_01 = @import("crypto/ml_kem.zig").ml_kem_01;
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};
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/// Elliptic-curve arithmetic.
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pub const ecc = struct {
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pub const Curve25519 = @import("crypto/25519/curve25519.zig").Curve25519;
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pub const Edwards25519 = @import("crypto/25519/edwards25519.zig").Edwards25519;
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pub const P256 = @import("crypto/pcurves/p256.zig").P256;
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pub const P384 = @import("crypto/pcurves/p384.zig").P384;
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pub const Ristretto255 = @import("crypto/25519/ristretto255.zig").Ristretto255;
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pub const Secp256k1 = @import("crypto/pcurves/secp256k1.zig").Secp256k1;
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};
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/// Hash functions.
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pub const hash = struct {
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pub const blake2 = @import("crypto/blake2.zig");
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pub const Blake3 = @import("crypto/blake3.zig").Blake3;
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pub const Md5 = @import("crypto/md5.zig").Md5;
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pub const Sha1 = @import("crypto/sha1.zig").Sha1;
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pub const sha2 = @import("crypto/sha2.zig");
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pub const sha3 = @import("crypto/sha3.zig");
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pub const composition = @import("crypto/hash_composition.zig");
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};
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/// Key derivation functions.
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pub const kdf = struct {
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pub const hkdf = @import("crypto/hkdf.zig");
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};
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/// MAC functions requiring single-use secret keys.
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pub const onetimeauth = struct {
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pub const Ghash = @import("crypto/ghash_polyval.zig").Ghash;
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pub const Polyval = @import("crypto/ghash_polyval.zig").Polyval;
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pub const Poly1305 = @import("crypto/poly1305.zig").Poly1305;
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};
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/// A password hashing function derives a uniform key from low-entropy input material such as passwords.
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/// It is intentionally slow or expensive.
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///
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/// With the standard definition of a key derivation function, if a key space is small, an exhaustive search may be practical.
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/// Password hashing functions make exhaustive searches way slower or way more expensive, even when implemented on GPUs and ASICs, by using different, optionally combined strategies:
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///
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/// - Requiring a lot of computation cycles to complete
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/// - Requiring a lot of memory to complete
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/// - Requiring multiple CPU cores to complete
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/// - Requiring cache-local data to complete in reasonable time
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/// - Requiring large static tables
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/// - Avoiding precomputations and time/memory tradeoffs
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/// - Requiring multi-party computations
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/// - Combining the input material with random per-entry data (salts), application-specific contexts and keys
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///
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/// Password hashing functions must be used whenever sensitive data has to be directly derived from a password.
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pub const pwhash = struct {
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pub const Encoding = enum {
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phc,
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crypt,
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};
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pub const Error = HasherError || error{AllocatorRequired};
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pub const HasherError = KdfError || phc_format.Error;
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pub const KdfError = errors.Error || std.mem.Allocator.Error || std.Thread.SpawnError;
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pub const argon2 = @import("crypto/argon2.zig");
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pub const bcrypt = @import("crypto/bcrypt.zig");
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pub const scrypt = @import("crypto/scrypt.zig");
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pub const pbkdf2 = @import("crypto/pbkdf2.zig").pbkdf2;
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pub const phc_format = @import("crypto/phc_encoding.zig");
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};
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/// Digital signature functions.
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pub const sign = struct {
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pub const Ed25519 = @import("crypto/25519/ed25519.zig").Ed25519;
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pub const ecdsa = @import("crypto/ecdsa.zig");
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};
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/// Stream ciphers. These do not provide any kind of authentication.
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/// Most applications should be using AEAD constructions instead of stream ciphers directly.
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pub const stream = struct {
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pub const chacha = struct {
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pub const ChaCha20IETF = @import("crypto/chacha20.zig").ChaCha20IETF;
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pub const ChaCha12IETF = @import("crypto/chacha20.zig").ChaCha12IETF;
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pub const ChaCha8IETF = @import("crypto/chacha20.zig").ChaCha8IETF;
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pub const ChaCha20With64BitNonce = @import("crypto/chacha20.zig").ChaCha20With64BitNonce;
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pub const ChaCha12With64BitNonce = @import("crypto/chacha20.zig").ChaCha12With64BitNonce;
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pub const ChaCha8With64BitNonce = @import("crypto/chacha20.zig").ChaCha8With64BitNonce;
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pub const XChaCha20IETF = @import("crypto/chacha20.zig").XChaCha20IETF;
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pub const XChaCha12IETF = @import("crypto/chacha20.zig").XChaCha12IETF;
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pub const XChaCha8IETF = @import("crypto/chacha20.zig").XChaCha8IETF;
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};
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pub const salsa = struct {
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pub const Salsa = @import("crypto/salsa20.zig").Salsa;
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pub const XSalsa = @import("crypto/salsa20.zig").XSalsa;
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pub const Salsa20 = @import("crypto/salsa20.zig").Salsa20;
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pub const XSalsa20 = @import("crypto/salsa20.zig").XSalsa20;
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};
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};
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pub const nacl = struct {
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const salsa20 = @import("crypto/salsa20.zig");
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pub const Box = salsa20.Box;
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pub const SecretBox = salsa20.SecretBox;
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pub const SealedBox = salsa20.SealedBox;
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};
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pub const utils = @import("crypto/utils.zig");
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/// Finite-field arithmetic.
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pub const ff = @import("crypto/ff.zig");
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/// This is a thread-local, cryptographically secure pseudo random number generator.
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pub const random = @import("crypto/tlcsprng.zig").interface;
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const std = @import("std.zig");
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pub const errors = @import("crypto/errors.zig");
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pub const tls = @import("crypto/tls.zig");
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pub const Certificate = @import("crypto/Certificate.zig");
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/// Side-channels mitigations.
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pub const SideChannelsMitigations = enum {
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/// No additional side-channel mitigations are applied.
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/// This is the fastest mode.
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none,
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/// The `basic` mode protects against most practical attacks, provided that the
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/// application or implements proper defenses against brute-force attacks.
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/// It offers a good balance between performance and security.
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basic,
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/// The `medium` mode offers increased resilience against side-channel attacks,
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/// making most attacks unpractical even on shared/low latency environements.
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/// This is the default mode.
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medium,
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/// The `full` mode offers the highest level of protection against side-channel attacks.
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/// Note that this doesn't cover all possible attacks (especially power analysis or
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/// thread-local attacks such as cachebleed), and that the performance impact is significant.
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full,
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};
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pub const default_side_channels_mitigations = .medium;
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test {
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_ = aead.aegis.Aegis128L;
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_ = aead.aegis.Aegis256;
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_ = aead.aes_gcm.Aes128Gcm;
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_ = aead.aes_gcm.Aes256Gcm;
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_ = aead.aes_ocb.Aes128Ocb;
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_ = aead.aes_ocb.Aes256Ocb;
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_ = aead.chacha_poly.ChaCha20Poly1305;
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_ = aead.chacha_poly.ChaCha12Poly1305;
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_ = aead.chacha_poly.ChaCha8Poly1305;
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_ = aead.chacha_poly.XChaCha20Poly1305;
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_ = aead.chacha_poly.XChaCha12Poly1305;
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_ = aead.chacha_poly.XChaCha8Poly1305;
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_ = aead.isap;
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_ = aead.salsa_poly.XSalsa20Poly1305;
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_ = auth.hmac;
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_ = auth.cmac;
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_ = auth.siphash;
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_ = core.aes;
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_ = core.Ascon;
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_ = core.modes;
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_ = dh.X25519;
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_ = kem.kyber_d00;
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_ = ecc.Curve25519;
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_ = ecc.Edwards25519;
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_ = ecc.P256;
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_ = ecc.P384;
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_ = ecc.Ristretto255;
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_ = ecc.Secp256k1;
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_ = hash.blake2;
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_ = hash.Blake3;
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_ = hash.Md5;
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_ = hash.Sha1;
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_ = hash.sha2;
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_ = hash.sha3;
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_ = hash.composition;
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_ = kdf.hkdf;
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_ = onetimeauth.Ghash;
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_ = onetimeauth.Poly1305;
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_ = pwhash.Encoding;
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_ = pwhash.Error;
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_ = pwhash.HasherError;
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_ = pwhash.KdfError;
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_ = pwhash.argon2;
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_ = pwhash.bcrypt;
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_ = pwhash.scrypt;
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_ = pwhash.pbkdf2;
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_ = pwhash.phc_format;
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_ = sign.Ed25519;
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_ = sign.ecdsa;
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_ = stream.chacha.ChaCha20IETF;
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_ = stream.chacha.ChaCha12IETF;
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_ = stream.chacha.ChaCha8IETF;
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_ = stream.chacha.ChaCha20With64BitNonce;
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_ = stream.chacha.ChaCha12With64BitNonce;
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_ = stream.chacha.ChaCha8With64BitNonce;
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_ = stream.chacha.XChaCha20IETF;
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_ = stream.chacha.XChaCha12IETF;
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_ = stream.chacha.XChaCha8IETF;
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_ = stream.salsa.Salsa20;
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_ = stream.salsa.XSalsa20;
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_ = nacl.Box;
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_ = nacl.SecretBox;
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_ = nacl.SealedBox;
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_ = utils;
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_ = ff;
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_ = random;
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_ = errors;
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_ = tls;
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_ = Certificate;
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}
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test "CSPRNG" {
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const a = random.int(u64);
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const b = random.int(u64);
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const c = random.int(u64);
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try std.testing.expect(a ^ b ^ c != 0);
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}
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test "issue #4532: no index out of bounds" {
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const types = [_]type{
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hash.Md5,
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hash.Sha1,
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hash.sha2.Sha224,
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hash.sha2.Sha256,
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hash.sha2.Sha384,
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hash.sha2.Sha512,
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hash.sha3.Sha3_224,
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hash.sha3.Sha3_256,
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hash.sha3.Sha3_384,
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hash.sha3.Sha3_512,
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hash.blake2.Blake2s128,
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hash.blake2.Blake2s224,
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hash.blake2.Blake2s256,
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hash.blake2.Blake2b128,
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hash.blake2.Blake2b256,
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hash.blake2.Blake2b384,
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hash.blake2.Blake2b512,
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};
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inline for (types) |Hasher| {
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var block = [_]u8{'#'} ** Hasher.block_length;
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var out1: [Hasher.digest_length]u8 = undefined;
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var out2: [Hasher.digest_length]u8 = undefined;
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const h0 = Hasher.init(.{});
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var h = h0;
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h.update(block[0..]);
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h.final(&out1);
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h = h0;
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h.update(block[0..1]);
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h.update(block[1..]);
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h.final(&out2);
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try std.testing.expectEqual(out1, out2);
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}
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}
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