Command Line Interface ======================================== .. highlight:: sh Outline ------------ The ``botan`` program is a command line tool for using a broad variety of functions of the Botan library in the shell. All commands follow the syntax ``botan ``. If ``botan`` is run with an unknown command, or without any command, or with the ``--help`` option, all available commands will be printed. If a particular command is run with the ``--help`` option (like ``botan --help``) some information about the usage of the command is printed. Starting in version 2.9, commands that take a passphrase (such as ``gen_bcrypt`` or ``pkcs8``) will also accept the literal ``-`` to mean ask for the passphrase on the terminal. If supported by the operating system, echo will be disabled while reading the passphrase. Hash Function ---------------- ``hash --algo=SHA-256 --buf-size=4096 --no-fsname files`` Compute the *algo* digest over the data in any number of *files*. If no files are listed on the command line, the input source defaults to standard input. Unless the ``--no-fsname`` option is given, the filename is printed alongside the hash, in the style of tools such as ``sha256sum``. Password Hash ---------------- ``gen_bcrypt --work-factor=12 password`` Calculate the bcrypt password digest of *password*. *work-factor* is an integer between 4 and 18. A higher *work-factor* value results in a more expensive hash calculation. ``check_bcrypt password hash`` Checks if the bcrypt hash of the passed *password* equals the passed *hash* value. HMAC ---------------- ``hmac --hash=SHA-256 --buf-size=4096 --no-fsname key files`` Compute the HMAC tag with the cryptographic hash function *hash* using the key in file *key* over the data in *files*. *files* defaults to STDIN. Unless the ``--no-fsname`` option is given, the filename is printed alongside the HMAC value. Public Key Cryptography ------------------------------------- ``keygen --algo=RSA --params= --passphrase= --pbe= --pbe-millis=300 --der-out`` Generate a PKCS #8 *algo* private key. If *der-out* is passed, the pair is BER encoded. Otherwise, PEM encoding is used. To protect the PKCS #8 formatted key, it is recommended to encrypt it with a provided *passphrase*. *pbe* is the name of the desired encryption algorithm, which uses *pbe-millis* milliseconds to derive the encryption key from the passed *passphrase*. Algorithm specific parameters, as the desired bit length of an RSA key, can be passed with *params*. - For RSA *params* specifies the bit length of the RSA modulus. It defaults to 3072. - For DH *params* specifies the DH parameters. It defaults to modp/ietf/2048. - For DSA *params* specifies the DSA parameters. It defaults to dsa/botan/2048. - For EC algorithms *params* specifies the elliptic curve. It defaults to secp256r1. The default *pbe* algorithm is "PBES2(AES-256/CBC,SHA-256)". With PBES2 scheme, you can select any CBC or GCM mode cipher which has an OID defined (such as 3DES, Camellia, SM4, Twofish or Serpent). However most other implementations support only AES or 3DES in CBC mode. You can also choose Scrypt instead of PBKDF2, by using "Scrypt" instead of the name of a hash function, for example "PBES2(AES-256/CBC,Scrypt)". Scrypt is also supported by some other implementations including OpenSSL. ``pkcs8 --pass-in= --pub-out --der-out --pass-out= --pbe= --pbe-millis=300 key`` Open a PKCS #8 formatted key at *key*. If *key* is encrypted, the passphrase must be passed as *pass-in*. It is possible to (re)encrypt the read key with the passphrase passed as *pass-out*. The parameters *pbe-millis* and *pbe* work similarly to ``keygen``. ``sign --der-format --passphrase= --hash=SHA-256 --emsa= key file`` Sign the data in *file* using the PKCS #8 private key *key*. If *key* is encrypted, the used passphrase must be passed as *pass-in*. *emsa* specifies the signature scheme and *hash* the cryptographic hash function used in the scheme. - For RSA signatures EMSA4 (RSA-PSS) is the default scheme. - For ECDSA and DSA *emsa* defaults to EMSA1 (signing the hash directly) For ECDSA and DSA, the option ``--der-format`` outputs the signature as an ASN.1 encoded blob. Some other tools (including ``openssl``) default to this format. The signature is formatted for your screen using base64. ``verify --der-format --hash=SHA-256 --emsa= pubkey file signature`` Verify the authenticity of the data in *file* with the provided signature *signature* and the public key *pubkey*. Similarly to the signing process, *emsa* specifies the signature scheme and *hash* the cryptographic hash function used in the scheme. ``gen_dl_group --pbits=1024 --qbits=0 --seed= --type=subgroup`` Generate ANSI X9.42 encoded Diffie-Hellman group parameters. - If *type=subgroup* is passed, the size of the prime subgroup q is sampled as a prime of *qbits* length and p is *pbits* long. If *qbits* is not passed, its length is estimated from *pbits* as described in RFC 3766. - If *type=strong* is passed, p is sampled as a safe prime with length *pbits* and the prime subgroup has size q with *pbits*-1 length. - If *type=dsa* is used, p and q are generated by the algorithm specified in FIPS 186-4. If the ``--seed`` parameter is used, it allows to select the seed value, instead of one being randomly generated. If the seed does not in fact generate a valid DSA group, the command will fail. ``dl_group_info --pem name`` Print raw Diffie-Hellman parameters (p,g) of the standardized DH group *name*. If *pem* is set, the X9.42 encoded group is printed. ``ec_group_info --pem name`` Print raw elliptic curve domain parameters of the standardized curve *name*. If *pem* is set, the encoded domain is printed. ``pk_encrypt --aead=AES-256/GCM rsa_pubkey datafile`` Encrypts ``datafile`` using the specified AEAD algorithm, under a key protected by the specified RSA public key. ``pk_decrypt rsa_privkey datafile`` Decrypts a file encrypted with ``pk_encrypt``. If the key is encrypted using a password, it will be prompted for on the terminal. X.509 ---------------------------------------------- ``gen_pkcs10 key CN --country= --organization= --email= --key-pass= --hash=SHA-256 --emsa=`` Generate a PKCS #10 certificate signing request (CSR) using the passed PKCS #8 private key *key*. If the private key is encrypted, the decryption passphrase *key-pass* has to be passed.*emsa* specifies the padding scheme to be used when calculating the signature. - For RSA keys EMSA4 (RSA-PSS) is the default scheme. - For ECDSA, DSA, ECGDSA, ECKCDSA and GOST-34.10 keys *emsa* defaults to EMSA1. ``gen_self_signed key CN --country= --dns= --organization= --email= --key-pass= --ca --hash=SHA-256 --emsa=`` Generate a self signed X.509 certificate using the PKCS #8 private key *key*. If the private key is encrypted, the decryption passphrase *key-pass* has to be passed. If *ca* is passed, the certificate is marked for certificate authority (CA) usage. *emsa* specifies the padding scheme to be used when calculating the signature. - For RSA keys EMSA4 (RSA-PSS) is the default scheme. - For ECDSA, DSA, ECGDSA, ECKCDSA and GOST-34.10 keys *emsa* defaults to EMSA1. ``sign_cert --ca-key-pass= --hash=SHA-256 --duration=365 --emsa= ca_cert ca_key pkcs10_req`` Create a CA signed X.509 certificate from the information contained in the PKCS #10 CSR *pkcs10_req*. The CA certificate is passed as *ca_cert* and the respective PKCS #8 private key as *ca_key*. If the private key is encrypted, the decryption passphrase *ca-key-pass* has to be passed. The created certificate has a validity period of *duration* days. *emsa* specifies the padding scheme to be used when calculating the signature. *emsa* defaults to the padding scheme used in the CA certificate. ``ocsp_check subject issuer`` Verify an X.509 certificate against the issuers OCSP responder. Pass the certificate to validate as *subject* and the CA certificate as *issuer*. ``cert_info --fingerprint --ber file`` Parse X.509 PEM certificate and display data fields. If ``--fingerprint`` is used, the certificate's fingerprint is also printed. ``cert_verify subject *ca_certs`` Verify if the provided X.509 certificate *subject* can be successfully validated. The list of trusted CA certificates is passed with *ca_certs*, which is a list of one or more certificates. TLS Server/Client ----------------------- ``tls_ciphers --policy=default --version=tls1.2`` Prints the list of ciphersuites that will be offered under a particular policy/version. The policy can be any of the the strings "default", "suiteb_128", "suiteb_192", "strict", or "all" to denote built-in policies, or it can name a file from which a policy description will be read. ``tls_client host --port=443 --print-certs --policy= --tls1.0 --tls1.1 --tls1.2 --session-db= --session-db-pass= --next-protocols= --type=tcp`` Implements a testing TLS client, which connects to *host* via TCP or UDP on port *port*. The TLS version can be set with the flags *tls1.0*, *tls1.1* and *tls1.2* of which the lowest specified version is automatically chosen. If none of the TLS version flags is set, the latest supported version is chosen. The client honors the TLS policy defined in the *policy* file and prints all certificates in the chain, if *print-certs* is passed. *next-protocols* is a comma separated list and specifies the protocols to advertise with Application-Layer Protocol Negotiation (ALPN). ``tls_server cert key --port=443 --type=tcp --policy=`` Implements a testing TLS server, which allows TLS clients to connect and which echos any data that is sent to it. Binds to either TCP or UDP on port *port*. The server uses the certificate *cert* and the respective PKCS #8 private key *key*. The server honors the TLS policy defined in the *policy* file. ``tls_http_server cert key --port=443 --policy= --session-db --session-db-pass=`` Only available if Boost.Asio support was enabled. Provides a simple HTTP server which replies to all requests with an informational text output. The server honors the TLS policy defined in the *policy* file. ``tls_proxy listen_port target_host target_port server_cert server_key`` Only available if Boost.Asio support was enabled. Listens on a port and forwards all connects to a target server specified at ``target_host`` and ``target_port``. Number Theory ----------------------- ``is_prime --prob=56 n`` Test if the integer *n* is composite or prime with a Miller-Rabin primality test with *(prob+2)/2* iterations. ``factor n`` Factor the integer *n* using a combination of trial division by small primes, and Pollard's Rho algorithm. It can in reasonable time factor integers up to 110 bits or so. ``gen_prime --count=1 bits`` Samples *count* primes with a length of *bits* bits. PSK Database -------------------- The PSK database commands are only available if sqlite3 support was compiled in. ``psk_set db db_key name psk`` Using the PSK database named db and encrypting under the (hex) key ``db_key``, save the provided psk (also hex) under ``name``:: $ botan psk_set psk.db deadba55 bunny f00fee ``psk_get db db_key name`` Get back a value saved with ``psk_set``:: $ botan psk_get psk.db deadba55 bunny f00fee ``psk_list db db_key`` List all values saved to the database under the given key:: $ botan psk_list psk.db deadba55 bunny Secret Sharing ------------------ Split a file into several shares. ``tss_split M N data_file --id= --share-prefix=share --share-suffix=tss --hash=SHA-256`` Split a file into ``N`` pieces any ``M`` of which suffices to recover the original input. The ID allows specifying a unique key ID which may be up to 16 bytes long, this ensures that shares can be uniquely matched. If not specified a random 16 byte value is used. A checksum can be appended to the data to help verify correct recovery, this can be disabled using ``--hash=None``. ``tss_recover *shares`` Recover some data split by ``tss_split``. If insufficient number of shares are provided an error is printed. Data Encoding/Decoding ------------------------ ``base64_dec file`` Encode *file* to Base64. ``base64_enc file`` Decode Base64 encoded *file*. ``hex_dec file`` Encode *file* to Hex. ``hex_enc file`` Decode Hex encoded *file*. Miscellaneous Commands ------------------------------------- ``version --full`` Print the version number. If option ``--full`` is provided, additional details are printed. ``config info_type`` Prints build information, useful for applications which want to build against the library. The ``info_type`` argument can be any of ``prefix``, ``cflags``, ``ldflags``, or ``libs``. This is similar to information provided by the ``pkg-config`` tool. ``cpuid`` List available processor flags (AES-NI, SIMD extensions, ...). ``asn1print --pem file`` Decode and print *file* with ASN.1 Basic Encoding Rules (BER). If flag ``--pem`` is used, or the filename ends in ``.pem``, then PEM encoding is assumed. Otherwise the input is assumed to be binary DER/BER. ``http_get url`` Retrieve resource from the passed http *url*. ``speed --msec=500 --provider= --buf-size=1024 algos`` Measures the speed of the passed *algos*. If no *algos* are passed all available speed tests are executed. *msec* (in milliseconds) sets the period of measurement for each algorithm. The *buf-size* option allows testing the same algorithm on one or more input sizes, for example ``speed --buf-size=136,1500 AES-128/GCM`` tests the performance of GCM for small and large packet sizes. ``rng --system --rdrand bytes`` Sample *bytes* random bytes from the specified random number generator. If *system* is set, the system RNG is used. If *system* is unset and *rdrand* is set, the hardware RDRAND instruction is used if available. If both are unset, HMAC_DRBG is used. ``cc_encrypt CC passphrase --tweak=`` Encrypt the passed valid credit card number *CC* using FPE encryption and the passphrase *passphrase*. The key is derived from the passphrase using PBKDF2 with SHA256. Due to the nature of FPE, the ciphertext is also a credit card number with a valid checksum. *tweak* is public and parameterizes the encryption function. ``cc_decrypt CC passphrase --tweak=`` Decrypt the passed valid ciphertext *CC* using FPE decryption with the passphrase *passphrase* and the tweak *tweak*.