Not fully implemented yet
The Crypto Layer is a comprehensive and flexible cryptographic library designed to provide a unified interface for various cryptographic operations and algorithms. It offers a wide range of functionalities, including encryption, decryption, signing, signature verification, and hashing, while supporting both symmetric and asymmetric cryptography.
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Encryption Algorithms: Supports a variety of encryption algorithms, including:
- Asymmetric Encryption: RSA, ECC (Elliptic Curve Cryptography) with various curve types (P-256, P-384, P-521, secp256k1, Brainpool curves, Curve25519, Curve448, FRP256v1)
- Symmetric Block Ciphers: AES (with multiple modes like GCM, CCM, ECB, CBC, CFB, OFB, CTR), Triple DES (two-key and three-key configurations), DES, RC2, Camellia
- Stream Ciphers: RC4, ChaCha20
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Hashing Algorithms: Supports a wide range of hashing algorithms, including:
- SHA-1, SHA-2 (SHA-224, SHA-256, SHA-384, SHA-512, SHA-512/224, SHA-512/256)
- SHA-3 (SHA3-224, SHA3-256, SHA3-384, SHA3-512)
- MD2, MD4, MD5, RIPEMD-160
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Key Management: Provides a unified interface for creating, loading, and managing cryptographic keys, supporting various key usages and algorithms.
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Cross-Platform Support: Designed to work seamlessly across multiple platforms, including Linux and Windows, with platform-specific implementations for key handling and security module integration.
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Security Module Integration: Integrates with Hardware Security Modules (HSMs) and Trusted Platform Modules (TPMs) for secure key storage and cryptographic operations, ensuring enhanced security and compliance with industry standards.
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Extensibility: The modular design of the Crypto Layer allows for easy extension and integration of additional cryptographic algorithms and security modules in the future.
The Crypto Layer provides a comprehensive set of interfaces and enums for working with cryptographic operations and algorithms. Here's a brief overview of the main components:
The encryption
module defines enums for various encryption algorithms, including:
AsymmetricEncryption
: Represents asymmetric encryption algorithms like RSA and ECC.BlockCiphers
: Represents symmetric block cipher algorithms like AES, Triple DES, DES, RC2, and Camellia.StreamCiphers
: Represents stream cipher algorithms like RC4 and ChaCha20.
The hashes
module defines the Hash
enum, which represents various hashing algorithms like SHA-1, SHA-2, SHA-3, MD2, MD4, MD5, and RIPEMD-160.
The key_handle
module provides the KeyHandle
trait, which defines a common interface for cryptographic key operations like signing, decryption, encryption, and signature verification. The GenericKeyHandle
enum represents a platform-agnostic key handle that can be used on both Linux and Windows platforms.
The module_provider
module defines the Provider
trait, which encapsulates operations related to cryptographic processing and key management. This trait is designed to be implemented by security modules, ensuring a unified approach to interacting with different types of security modules.
The factory
module provides the SecModules
struct, which serves as a namespace for managing and accessing security module instances. It includes methods for retrieving or creating instances of security modules based on their type (HSM or TPM).
The error
module defines the SecurityModuleError
enum, which represents various types of errors that can occur within a security module, including errors originating from HSMs, TPMs, or during cryptographic operations like signing, decryption, encryption, and signature verification.
Here are some usage examples based on the Windows TPM handler implementation:
use crypto_layer::factory::{SecModules, SecurityModule};
use crypto_layer::tpm::core::instance::TpmType;
let key_id = "my_key_id".to_string();
let tpm_provider = SecModules::get_instances(key_id, SecurityModule::Tpm(TpmType::default()))
.expect("Failed to create TPM provider");
use crypto_layer::common::error::SecurityModuleError;
match tpm_provider.lock().unwrap().initialize_module() {
Ok(()) => println!("TPM module initialized successfully"),
Err(e) => println!("Failed to initialize TPM module: {:?}", e),
}
use crypto_layer::common::crypto::algorithms::{
encryption::{AsymmetricEncryption, BlockCiphers},
hashes::Hash,
};
use crypto_layer::common::KeyUsage;
let key_algorithm = AsymmetricEncryption::Ecc(EccSchemeAlgorithm::EcDsa(EccCurves::P256));
let sym_algorithm = Some(BlockCiphers::Aes(SymmetricMode::Cbc, KeyBits::Bits256));
let hash = Some(Hash::Sha2(Sha2Bits::Sha256));
let key_usages = vec![KeyUsage::SignEncrypt, KeyUsage::Decrypt];
match tpm_provider.lock().unwrap().create_key(
"my_key_id",
key_algorithm,
sym_algorithm,
hash,
key_usages,
) {
Ok(()) => println!("Key created successfully"),
Err(e) => println!("Failed to create key: {:?}", e),
}
let data = b"Hello, world!";
match tpm_provider.lock().unwrap().sign_data(data) {
Ok(signature) => println!("Signature: {:?}", signature),
Err(e) => println!("Failed to sign data: {:?}", e),
}
let data = b"Hello, world!";
let signature = // ... obtained signature ...
match tpm_provider.lock().unwrap().verify_signature(data, &signature) {
Ok(valid) => {
if valid {
println!("Signature is valid");
} else {
println!("Signature is invalid");
}
}
Err(e) => println!("Failed to verify signature: {:?}", e),
}
These examples demonstrate how to use the Windows TPM handler implementation to perform various cryptographic operations using the Crypto Layer.
The Crypto Layer is distributed as a Rust crate and can be included in your project by adding the following line to your Cargo.toml
file:
[dependencies]
crypto-layer = "0.1.0"
Contributions to the Crypto Layer are welcome! If you find any issues or have suggestions for improvements, please open an issue or submit a pull request on the project's GitHub repository.
The Crypto Layer is released under the MIT License.