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|
#pragma once
#define PICOJSON_USE_INT64
#include "picojson/picojson.h"
#include "base.h"
#include <set>
#include <chrono>
#include <unordered_map>
#include <memory>
#include <openssl/evp.h>
#include <openssl/hmac.h>
#include <openssl/pem.h>
#include <openssl/ec.h>
#include <openssl/err.h>
//If openssl version less than 1.1
#if OPENSSL_VERSION_NUMBER < 269484032
#define OPENSSL10
#endif
#ifndef JWT_CLAIM_EXPLICIT
#define JWT_CLAIM_EXPLICIT 1
#endif
namespace jwt {
using date = std::chrono::system_clock::time_point;
struct signature_verification_exception : public std::runtime_error {
signature_verification_exception()
: std::runtime_error("signature verification failed")
{}
explicit signature_verification_exception(const std::string& msg)
: std::runtime_error(msg)
{}
explicit signature_verification_exception(const char* msg)
: std::runtime_error(msg)
{}
};
struct signature_generation_exception : public std::runtime_error {
signature_generation_exception()
: std::runtime_error("signature generation failed")
{}
explicit signature_generation_exception(const std::string& msg)
: std::runtime_error(msg)
{}
explicit signature_generation_exception(const char* msg)
: std::runtime_error(msg)
{}
};
struct rsa_exception : public std::runtime_error {
explicit rsa_exception(const std::string& msg)
: std::runtime_error(msg)
{}
explicit rsa_exception(const char* msg)
: std::runtime_error(msg)
{}
};
struct ecdsa_exception : public std::runtime_error {
explicit ecdsa_exception(const std::string& msg)
: std::runtime_error(msg)
{}
explicit ecdsa_exception(const char* msg)
: std::runtime_error(msg)
{}
};
struct token_verification_exception : public std::runtime_error {
token_verification_exception()
: std::runtime_error("token verification failed")
{}
explicit token_verification_exception(const std::string& msg)
: std::runtime_error("token verification failed: " + msg)
{}
};
namespace helper {
inline
std::string extract_pubkey_from_cert(const std::string& certstr, const std::string& pw = "") {
// TODO: Cannot find the exact version this change happended
#if OPENSSL_VERSION_NUMBER <= 0x1000114fL
std::unique_ptr<BIO, decltype(&BIO_free_all)> certbio(BIO_new_mem_buf(const_cast<char*>(certstr.data()), certstr.size()), BIO_free_all);
#else
std::unique_ptr<BIO, decltype(&BIO_free_all)> certbio(BIO_new_mem_buf(certstr.data(), certstr.size()), BIO_free_all);
#endif
std::unique_ptr<BIO, decltype(&BIO_free_all)> keybio(BIO_new(BIO_s_mem()), BIO_free_all);
std::unique_ptr<X509, decltype(&X509_free)> cert(PEM_read_bio_X509(certbio.get(), nullptr, nullptr, const_cast<char*>(pw.c_str())), X509_free);
if (!cert) throw rsa_exception("Error loading cert into memory");
std::unique_ptr<EVP_PKEY, decltype(&EVP_PKEY_free)> key(X509_get_pubkey(cert.get()), EVP_PKEY_free);
if(!key) throw rsa_exception("Error getting public key from certificate");
if(!PEM_write_bio_PUBKEY(keybio.get(), key.get())) throw rsa_exception("Error writing public key data in PEM format");
char* ptr = nullptr;
auto len = BIO_get_mem_data(keybio.get(), &ptr);
if(len <= 0 || ptr == nullptr) throw rsa_exception("Failed to convert pubkey to pem");
std::string res(ptr, len);
return res;
}
inline
std::shared_ptr<EVP_PKEY> load_public_key_from_string(const std::string& key, const std::string& password = "") {
std::unique_ptr<BIO, decltype(&BIO_free_all)> pubkey_bio(BIO_new(BIO_s_mem()), BIO_free_all);
if(key.substr(0, 27) == "-----BEGIN CERTIFICATE-----") {
auto epkey = helper::extract_pubkey_from_cert(key, password);
if ((size_t)BIO_write(pubkey_bio.get(), epkey.data(), epkey.size()) != epkey.size())
throw rsa_exception("failed to load public key: bio_write failed");
} else {
if ((size_t)BIO_write(pubkey_bio.get(), key.data(), key.size()) != key.size())
throw rsa_exception("failed to load public key: bio_write failed");
}
std::shared_ptr<EVP_PKEY> pkey(PEM_read_bio_PUBKEY(pubkey_bio.get(), nullptr, nullptr, (void*)password.c_str()), EVP_PKEY_free);
if (!pkey)
throw rsa_exception("failed to load public key: PEM_read_bio_PUBKEY failed:" + std::string(ERR_error_string(ERR_get_error(), NULL)));
return pkey;
}
inline
std::shared_ptr<EVP_PKEY> load_private_key_from_string(const std::string& key, const std::string& password = "") {
std::unique_ptr<BIO, decltype(&BIO_free_all)> privkey_bio(BIO_new(BIO_s_mem()), BIO_free_all);
if ((size_t)BIO_write(privkey_bio.get(), key.data(), key.size()) != key.size())
throw rsa_exception("failed to load private key: bio_write failed");
std::shared_ptr<EVP_PKEY> pkey(PEM_read_bio_PrivateKey(privkey_bio.get(), nullptr, nullptr, const_cast<char*>(password.c_str())), EVP_PKEY_free);
if (!pkey)
throw rsa_exception("failed to load private key: PEM_read_bio_PrivateKey failed");
return pkey;
}
}
namespace algorithm {
/**
* "none" algorithm.
*
* Returns and empty signature and checks if the given signature is empty.
*/
struct none {
/// Return an empty string
std::string sign(const std::string&) const {
return "";
}
/// Check if the given signature is empty. JWT's with "none" algorithm should not contain a signature.
void verify(const std::string&, const std::string& signature) const {
if (!signature.empty())
throw signature_verification_exception();
}
/// Get algorithm name
std::string name() const {
return "none";
}
};
/**
* Base class for HMAC family of algorithms
*/
struct hmacsha {
/**
* Construct new hmac algorithm
* \param key Key to use for HMAC
* \param md Pointer to hash function
* \param name Name of the algorithm
*/
hmacsha(std::string key, const EVP_MD*(*md)(), const std::string& name)
: secret(std::move(key)), md(md), alg_name(name)
{}
/**
* Sign jwt data
* \param data The data to sign
* \return HMAC signature for the given data
* \throws signature_generation_exception
*/
std::string sign(const std::string& data) const {
std::string res;
res.resize(EVP_MAX_MD_SIZE);
unsigned int len = res.size();
if (HMAC(md(), secret.data(), secret.size(), (const unsigned char*)data.data(), data.size(), (unsigned char*)res.data(), &len) == nullptr)
throw signature_generation_exception();
res.resize(len);
return res;
}
/**
* Check if signature is valid
* \param data The data to check signature against
* \param signature Signature provided by the jwt
* \throws signature_verification_exception If the provided signature does not match
*/
void verify(const std::string& data, const std::string& signature) const {
try {
auto res = sign(data);
bool matched = true;
for (size_t i = 0; i < std::min<size_t>(res.size(), signature.size()); i++)
if (res[i] != signature[i])
matched = false;
if (res.size() != signature.size())
matched = false;
if (!matched)
throw signature_verification_exception();
}
catch (const signature_generation_exception&) {
throw signature_verification_exception();
}
}
/**
* Returns the algorithm name provided to the constructor
* \return Algorithmname
*/
std::string name() const {
return alg_name;
}
private:
/// HMAC secrect
const std::string secret;
/// HMAC hash generator
const EVP_MD*(*md)();
/// Algorithmname
const std::string alg_name;
};
/**
* Base class for RSA family of algorithms
*/
struct rsa {
/**
* Construct new rsa algorithm
* \param public_key RSA public key in PEM format
* \param private_key RSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
* \param md Pointer to hash function
* \param name Name of the algorithm
*/
rsa(const std::string& public_key, const std::string& private_key, const std::string& public_key_password, const std::string& private_key_password, const EVP_MD*(*md)(), const std::string& name)
: md(md), alg_name(name)
{
if (!private_key.empty()) {
pkey = helper::load_private_key_from_string(private_key, private_key_password);
} else if(!public_key.empty()) {
pkey = helper::load_public_key_from_string(public_key, public_key_password);
} else
throw rsa_exception("at least one of public or private key need to be present");
}
/**
* Sign jwt data
* \param data The data to sign
* \return RSA signature for the given data
* \throws signature_generation_exception
*/
std::string sign(const std::string& data) const {
#ifdef OPENSSL10
std::unique_ptr<EVP_MD_CTX, decltype(&EVP_MD_CTX_destroy)> ctx(EVP_MD_CTX_create(), EVP_MD_CTX_destroy);
#else
std::unique_ptr<EVP_MD_CTX, decltype(&EVP_MD_CTX_free)> ctx(EVP_MD_CTX_create(), EVP_MD_CTX_free);
#endif
if (!ctx)
throw signature_generation_exception("failed to create signature: could not create context");
if (!EVP_SignInit(ctx.get(), md()))
throw signature_generation_exception("failed to create signature: SignInit failed");
std::string res;
res.resize(EVP_PKEY_size(pkey.get()));
unsigned int len = 0;
if (!EVP_SignUpdate(ctx.get(), data.data(), data.size()))
throw signature_generation_exception();
if (!EVP_SignFinal(ctx.get(), (unsigned char*)res.data(), &len, pkey.get()))
throw signature_generation_exception();
res.resize(len);
return res;
}
/**
* Check if signature is valid
* \param data The data to check signature against
* \param signature Signature provided by the jwt
* \throws signature_verification_exception If the provided signature does not match
*/
void verify(const std::string& data, const std::string& signature) const {
#ifdef OPENSSL10
std::unique_ptr<EVP_MD_CTX, decltype(&EVP_MD_CTX_destroy)> ctx(EVP_MD_CTX_create(), EVP_MD_CTX_destroy);
#else
std::unique_ptr<EVP_MD_CTX, decltype(&EVP_MD_CTX_free)> ctx(EVP_MD_CTX_create(), EVP_MD_CTX_free);
#endif
if (!ctx)
throw signature_verification_exception("failed to verify signature: could not create context");
if (!EVP_VerifyInit(ctx.get(), md()))
throw signature_verification_exception("failed to verify signature: VerifyInit failed");
if (!EVP_VerifyUpdate(ctx.get(), data.data(), data.size()))
throw signature_verification_exception("failed to verify signature: VerifyUpdate failed");
auto res = EVP_VerifyFinal(ctx.get(), (const unsigned char*)signature.data(), signature.size(), pkey.get());
if (res != 1)
throw signature_verification_exception("evp verify final failed: " + std::to_string(res) + " " + ERR_error_string(ERR_get_error(), NULL));
}
/**
* Returns the algorithm name provided to the constructor
* \return Algorithmname
*/
std::string name() const {
return alg_name;
}
private:
/// OpenSSL structure containing converted keys
std::shared_ptr<EVP_PKEY> pkey;
/// Hash generator
const EVP_MD*(*md)();
/// Algorithmname
const std::string alg_name;
};
/**
* Base class for ECDSA family of algorithms
*/
struct ecdsa {
/**
* Construct new ecdsa algorithm
* \param public_key ECDSA public key in PEM format
* \param private_key ECDSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
* \param md Pointer to hash function
* \param name Name of the algorithm
*/
ecdsa(const std::string& public_key, const std::string& private_key, const std::string& public_key_password, const std::string& private_key_password, const EVP_MD*(*md)(), const std::string& name, size_t siglen)
: md(md), alg_name(name), signature_length(siglen)
{
if (!public_key.empty()) {
std::unique_ptr<BIO, decltype(&BIO_free_all)> pubkey_bio(BIO_new(BIO_s_mem()), BIO_free_all);
if(public_key.substr(0, 27) == "-----BEGIN CERTIFICATE-----") {
auto epkey = helper::extract_pubkey_from_cert(public_key, public_key_password);
if ((size_t)BIO_write(pubkey_bio.get(), epkey.data(), epkey.size()) != epkey.size())
throw ecdsa_exception("failed to load public key: bio_write failed");
} else {
if ((size_t)BIO_write(pubkey_bio.get(), public_key.data(), public_key.size()) != public_key.size())
throw ecdsa_exception("failed to load public key: bio_write failed");
}
pkey.reset(PEM_read_bio_EC_PUBKEY(pubkey_bio.get(), nullptr, nullptr, (void*)public_key_password.c_str()), EC_KEY_free);
if (!pkey)
throw ecdsa_exception("failed to load public key: PEM_read_bio_EC_PUBKEY failed:" + std::string(ERR_error_string(ERR_get_error(), NULL)));
size_t keysize = EC_GROUP_get_degree(EC_KEY_get0_group(pkey.get()));
if(keysize != signature_length*4 && (signature_length != 132 || keysize != 521))
throw ecdsa_exception("invalid key size");
}
if (!private_key.empty()) {
std::unique_ptr<BIO, decltype(&BIO_free_all)> privkey_bio(BIO_new(BIO_s_mem()), BIO_free_all);
if ((size_t)BIO_write(privkey_bio.get(), private_key.data(), private_key.size()) != private_key.size())
throw rsa_exception("failed to load private key: bio_write failed");
pkey.reset(PEM_read_bio_ECPrivateKey(privkey_bio.get(), nullptr, nullptr, const_cast<char*>(private_key_password.c_str())), EC_KEY_free);
if (!pkey)
throw rsa_exception("failed to load private key: PEM_read_bio_ECPrivateKey failed");
size_t keysize = EC_GROUP_get_degree(EC_KEY_get0_group(pkey.get()));
if(keysize != signature_length*4 && (signature_length != 132 || keysize != 521))
throw ecdsa_exception("invalid key size");
}
if(!pkey)
throw rsa_exception("at least one of public or private key need to be present");
if(EC_KEY_check_key(pkey.get()) == 0)
throw ecdsa_exception("failed to load key: key is invalid");
}
/**
* Sign jwt data
* \param data The data to sign
* \return ECDSA signature for the given data
* \throws signature_generation_exception
*/
std::string sign(const std::string& data) const {
const std::string hash = generate_hash(data);
std::unique_ptr<ECDSA_SIG, decltype(&ECDSA_SIG_free)>
sig(ECDSA_do_sign((const unsigned char*)hash.data(), hash.size(), pkey.get()), ECDSA_SIG_free);
if(!sig)
throw signature_generation_exception();
#ifdef OPENSSL10
auto rr = bn2raw(sig->r);
auto rs = bn2raw(sig->s);
#else
const BIGNUM *r;
const BIGNUM *s;
ECDSA_SIG_get0(sig.get(), &r, &s);
auto rr = bn2raw(r);
auto rs = bn2raw(s);
#endif
if(rr.size() > signature_length/2 || rs.size() > signature_length/2)
throw std::logic_error("bignum size exceeded expected length");
while(rr.size() != signature_length/2) rr = '\0' + rr;
while(rs.size() != signature_length/2) rs = '\0' + rs;
return rr + rs;
}
/**
* Check if signature is valid
* \param data The data to check signature against
* \param signature Signature provided by the jwt
* \throws signature_verification_exception If the provided signature does not match
*/
void verify(const std::string& data, const std::string& signature) const {
const std::string hash = generate_hash(data);
auto r = raw2bn(signature.substr(0, signature.size() / 2));
auto s = raw2bn(signature.substr(signature.size() / 2));
#ifdef OPENSSL10
ECDSA_SIG sig;
sig.r = r.get();
sig.s = s.get();
if(ECDSA_do_verify((const unsigned char*)hash.data(), hash.size(), &sig, pkey.get()) != 1)
throw signature_verification_exception("Invalid signature");
#else
std::unique_ptr<ECDSA_SIG, decltype(&ECDSA_SIG_free)> sig(ECDSA_SIG_new(), ECDSA_SIG_free);
ECDSA_SIG_set0(sig.get(), r.release(), s.release());
if(ECDSA_do_verify((const unsigned char*)hash.data(), hash.size(), sig.get(), pkey.get()) != 1)
throw signature_verification_exception("Invalid signature");
#endif
}
/**
* Returns the algorithm name provided to the constructor
* \return Algorithmname
*/
std::string name() const {
return alg_name;
}
private:
/**
* Convert a OpenSSL BIGNUM to a std::string
* \param bn BIGNUM to convert
* \return bignum as string
*/
#ifdef OPENSSL10
static std::string bn2raw(BIGNUM* bn)
#else
static std::string bn2raw(const BIGNUM* bn)
#endif
{
std::string res;
res.resize(BN_num_bytes(bn));
BN_bn2bin(bn, (unsigned char*)res.data());
return res;
}
/**
* Convert an std::string to a OpenSSL BIGNUM
* \param raw String to convert
* \return BIGNUM representation
*/
static std::unique_ptr<BIGNUM, decltype(&BN_free)> raw2bn(const std::string& raw) {
return std::unique_ptr<BIGNUM, decltype(&BN_free)>(BN_bin2bn((const unsigned char*)raw.data(), raw.size(), nullptr), BN_free);
}
/**
* Hash the provided data using the hash function specified in constructor
* \param data Data to hash
* \return Hash of data
*/
std::string generate_hash(const std::string& data) const {
#ifdef OPENSSL10
std::unique_ptr<EVP_MD_CTX, decltype(&EVP_MD_CTX_destroy)> ctx(EVP_MD_CTX_create(), &EVP_MD_CTX_destroy);
#else
std::unique_ptr<EVP_MD_CTX, decltype(&EVP_MD_CTX_free)> ctx(EVP_MD_CTX_new(), EVP_MD_CTX_free);
#endif
if(EVP_DigestInit(ctx.get(), md()) == 0)
throw signature_generation_exception("EVP_DigestInit failed");
if(EVP_DigestUpdate(ctx.get(), data.data(), data.size()) == 0)
throw signature_generation_exception("EVP_DigestUpdate failed");
unsigned int len = 0;
std::string res;
res.resize(EVP_MD_CTX_size(ctx.get()));
if(EVP_DigestFinal(ctx.get(), (unsigned char*)res.data(), &len) == 0)
throw signature_generation_exception("EVP_DigestFinal failed");
res.resize(len);
return res;
}
/// OpenSSL struct containing keys
std::shared_ptr<EC_KEY> pkey;
/// Hash generator function
const EVP_MD*(*md)();
/// Algorithmname
const std::string alg_name;
/// Length of the resulting signature
const size_t signature_length;
};
/**
* Base class for PSS-RSA family of algorithms
*/
struct pss {
/**
* Construct new pss algorithm
* \param public_key RSA public key in PEM format
* \param private_key RSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
* \param md Pointer to hash function
* \param name Name of the algorithm
*/
pss(const std::string& public_key, const std::string& private_key, const std::string& public_key_password, const std::string& private_key_password, const EVP_MD*(*md)(), const std::string& name)
: md(md), alg_name(name)
{
if (!private_key.empty()) {
pkey = helper::load_private_key_from_string(private_key, private_key_password);
} else if(!public_key.empty()) {
pkey = helper::load_public_key_from_string(public_key, public_key_password);
} else
throw rsa_exception("at least one of public or private key need to be present");
}
/**
* Sign jwt data
* \param data The data to sign
* \return ECDSA signature for the given data
* \throws signature_generation_exception
*/
std::string sign(const std::string& data) const {
auto hash = this->generate_hash(data);
std::unique_ptr<RSA, decltype(&RSA_free)> key(EVP_PKEY_get1_RSA(pkey.get()), RSA_free);
const int size = RSA_size(key.get());
std::string padded(size, 0x00);
if (!RSA_padding_add_PKCS1_PSS_mgf1(key.get(), (unsigned char*)padded.data(), (const unsigned char*)hash.data(), md(), md(), -1))
throw signature_generation_exception("failed to create signature: RSA_padding_add_PKCS1_PSS_mgf1 failed");
std::string res(size, 0x00);
if (RSA_private_encrypt(size, (const unsigned char*)padded.data(), (unsigned char*)res.data(), key.get(), RSA_NO_PADDING) < 0)
throw signature_generation_exception("failed to create signature: RSA_private_encrypt failed");
return res;
}
/**
* Check if signature is valid
* \param data The data to check signature against
* \param signature Signature provided by the jwt
* \throws signature_verification_exception If the provided signature does not match
*/
void verify(const std::string& data, const std::string& signature) const {
auto hash = this->generate_hash(data);
std::unique_ptr<RSA, decltype(&RSA_free)> key(EVP_PKEY_get1_RSA(pkey.get()), RSA_free);
const int size = RSA_size(key.get());
std::string sig(size, 0x00);
if(!RSA_public_decrypt(signature.size(), (const unsigned char*)signature.data(), (unsigned char*)sig.data(), key.get(), RSA_NO_PADDING))
throw signature_verification_exception("Invalid signature");
if(!RSA_verify_PKCS1_PSS_mgf1(key.get(), (const unsigned char*)hash.data(), md(), md(), (const unsigned char*)sig.data(), -1))
throw signature_verification_exception("Invalid signature");
}
/**
* Returns the algorithm name provided to the constructor
* \return Algorithmname
*/
std::string name() const {
return alg_name;
}
private:
/**
* Hash the provided data using the hash function specified in constructor
* \param data Data to hash
* \return Hash of data
*/
std::string generate_hash(const std::string& data) const {
#ifdef OPENSSL10
std::unique_ptr<EVP_MD_CTX, decltype(&EVP_MD_CTX_destroy)> ctx(EVP_MD_CTX_create(), &EVP_MD_CTX_destroy);
#else
std::unique_ptr<EVP_MD_CTX, decltype(&EVP_MD_CTX_free)> ctx(EVP_MD_CTX_new(), EVP_MD_CTX_free);
#endif
if(EVP_DigestInit(ctx.get(), md()) == 0)
throw signature_generation_exception("EVP_DigestInit failed");
if(EVP_DigestUpdate(ctx.get(), data.data(), data.size()) == 0)
throw signature_generation_exception("EVP_DigestUpdate failed");
unsigned int len = 0;
std::string res;
res.resize(EVP_MD_CTX_size(ctx.get()));
if(EVP_DigestFinal(ctx.get(), (unsigned char*)res.data(), &len) == 0)
throw signature_generation_exception("EVP_DigestFinal failed");
res.resize(len);
return res;
}
/// OpenSSL structure containing keys
std::shared_ptr<EVP_PKEY> pkey;
/// Hash generator function
const EVP_MD*(*md)();
/// Algorithmname
const std::string alg_name;
};
/**
* HS256 algorithm
*/
struct hs256 : public hmacsha {
/**
* Construct new instance of algorithm
* \param key HMAC signing key
*/
explicit hs256(std::string key)
: hmacsha(std::move(key), EVP_sha256, "HS256")
{}
};
/**
* HS384 algorithm
*/
struct hs384 : public hmacsha {
/**
* Construct new instance of algorithm
* \param key HMAC signing key
*/
explicit hs384(std::string key)
: hmacsha(std::move(key), EVP_sha384, "HS384")
{}
};
/**
* HS512 algorithm
*/
struct hs512 : public hmacsha {
/**
* Construct new instance of algorithm
* \param key HMAC signing key
*/
explicit hs512(std::string key)
: hmacsha(std::move(key), EVP_sha512, "HS512")
{}
};
/**
* RS256 algorithm
*/
struct rs256 : public rsa {
/**
* Construct new instance of algorithm
* \param public_key RSA public key in PEM format
* \param private_key RSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
*/
explicit rs256(const std::string& public_key, const std::string& private_key = "", const std::string& public_key_password = "", const std::string& private_key_password = "")
: rsa(public_key, private_key, public_key_password, private_key_password, EVP_sha256, "RS256")
{}
};
/**
* RS384 algorithm
*/
struct rs384 : public rsa {
/**
* Construct new instance of algorithm
* \param public_key RSA public key in PEM format
* \param private_key RSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
*/
explicit rs384(const std::string& public_key, const std::string& private_key = "", const std::string& public_key_password = "", const std::string& private_key_password = "")
: rsa(public_key, private_key, public_key_password, private_key_password, EVP_sha384, "RS384")
{}
};
/**
* RS512 algorithm
*/
struct rs512 : public rsa {
/**
* Construct new instance of algorithm
* \param public_key RSA public key in PEM format
* \param private_key RSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
*/
explicit rs512(const std::string& public_key, const std::string& private_key = "", const std::string& public_key_password = "", const std::string& private_key_password = "")
: rsa(public_key, private_key, public_key_password, private_key_password, EVP_sha512, "RS512")
{}
};
/**
* ES256 algorithm
*/
struct es256 : public ecdsa {
/**
* Construct new instance of algorithm
* \param public_key ECDSA public key in PEM format
* \param private_key ECDSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
*/
explicit es256(const std::string& public_key, const std::string& private_key = "", const std::string& public_key_password = "", const std::string& private_key_password = "")
: ecdsa(public_key, private_key, public_key_password, private_key_password, EVP_sha256, "ES256", 64)
{}
};
/**
* ES384 algorithm
*/
struct es384 : public ecdsa {
/**
* Construct new instance of algorithm
* \param public_key ECDSA public key in PEM format
* \param private_key ECDSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
*/
explicit es384(const std::string& public_key, const std::string& private_key = "", const std::string& public_key_password = "", const std::string& private_key_password = "")
: ecdsa(public_key, private_key, public_key_password, private_key_password, EVP_sha384, "ES384", 96)
{}
};
/**
* ES512 algorithm
*/
struct es512 : public ecdsa {
/**
* Construct new instance of algorithm
* \param public_key ECDSA public key in PEM format
* \param private_key ECDSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
*/
explicit es512(const std::string& public_key, const std::string& private_key = "", const std::string& public_key_password = "", const std::string& private_key_password = "")
: ecdsa(public_key, private_key, public_key_password, private_key_password, EVP_sha512, "ES512", 132)
{}
};
/**
* PS256 algorithm
*/
struct ps256 : public pss {
/**
* Construct new instance of algorithm
* \param public_key RSA public key in PEM format
* \param private_key RSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
*/
explicit ps256(const std::string& public_key, const std::string& private_key = "", const std::string& public_key_password = "", const std::string& private_key_password = "")
: pss(public_key, private_key, public_key_password, private_key_password, EVP_sha256, "PS256")
{}
};
/**
* PS384 algorithm
*/
struct ps384 : public pss {
/**
* Construct new instance of algorithm
* \param public_key RSA public key in PEM format
* \param private_key RSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
*/
explicit ps384(const std::string& public_key, const std::string& private_key = "", const std::string& public_key_password = "", const std::string& private_key_password = "")
: pss(public_key, private_key, public_key_password, private_key_password, EVP_sha384, "PS384")
{}
};
/**
* PS512 algorithm
*/
struct ps512 : public pss {
/**
* Construct new instance of algorithm
* \param public_key RSA public key in PEM format
* \param private_key RSA private key or empty string if not available. If empty, signing will always fail.
* \param public_key_password Password to decrypt public key pem.
* \param privat_key_password Password to decrypt private key pem.
*/
explicit ps512(const std::string& public_key, const std::string& private_key = "", const std::string& public_key_password = "", const std::string& private_key_password = "")
: pss(public_key, private_key, public_key_password, private_key_password, EVP_sha512, "PS512")
{}
};
}
/**
* Convenience wrapper for JSON value
*/
class claim {
picojson::value val;
public:
enum class type {
null,
boolean,
number,
string,
array,
object,
int64
};
claim()
: val()
{}
#if JWT_CLAIM_EXPLICIT
explicit claim(std::string s)
: val(std::move(s))
{}
explicit claim(const date& s)
: val(int64_t(std::chrono::system_clock::to_time_t(s)))
{}
explicit claim(const std::set<std::string>& s)
: val(picojson::array(s.cbegin(), s.cend()))
{}
explicit claim(const picojson::value& val)
: val(val)
{}
#else
claim(std::string s)
: val(std::move(s))
{}
claim(const date& s)
: val(int64_t(std::chrono::system_clock::to_time_t(s)))
{}
claim(const std::set<std::string>& s)
: val(picojson::array(s.cbegin(), s.cend()))
{}
claim(const picojson::value& val)
: val(val)
{}
#endif
template<typename Iterator>
claim(Iterator start, Iterator end)
: val(picojson::array())
{
auto& arr = val.get<picojson::array>();
for(; start != end; start++) {
arr.push_back(picojson::value(*start));
}
}
/**
* Get wrapped json object
* \return Wrapped json object
*/
picojson::value to_json() const {
return val;
}
/**
* Get type of contained object
* \return Type
* \throws std::logic_error An internal error occured
*/
type get_type() const {
if (val.is<picojson::null>()) return type::null;
else if (val.is<bool>()) return type::boolean;
else if (val.is<int64_t>()) return type::int64;
else if (val.is<double>()) return type::number;
else if (val.is<std::string>()) return type::string;
else if (val.is<picojson::array>()) return type::array;
else if (val.is<picojson::object>()) return type::object;
else throw std::logic_error("internal error");
}
/**
* Get the contained object as a string
* \return content as string
* \throws std::bad_cast Content was not a string
*/
const std::string& as_string() const {
if (!val.is<std::string>())
throw std::bad_cast();
return val.get<std::string>();
}
/**
* Get the contained object as a date
* \return content as date
* \throws std::bad_cast Content was not a date
*/
date as_date() const {
return std::chrono::system_clock::from_time_t(as_int());
}
/**
* Get the contained object as an array
* \return content as array
* \throws std::bad_cast Content was not an array
*/
const picojson::array& as_array() const {
if (!val.is<picojson::array>())
throw std::bad_cast();
return val.get<picojson::array>();
}
/**
* Get the contained object as a set of strings
* \return content as set of strings
* \throws std::bad_cast Content was not a set
*/
const std::set<std::string> as_set() const {
std::set<std::string> res;
for(auto& e : as_array()) {
if(!e.is<std::string>())
throw std::bad_cast();
res.insert(e.get<std::string>());
}
return res;
}
/**
* Get the contained object as an integer
* \return content as int
* \throws std::bad_cast Content was not an int
*/
int64_t as_int() const {
if (!val.is<int64_t>())
throw std::bad_cast();
return val.get<int64_t>();
}
/**
* Get the contained object as a bool
* \return content as bool
* \throws std::bad_cast Content was not a bool
*/
bool as_bool() const {
if (!val.is<bool>())
throw std::bad_cast();
return val.get<bool>();
}
/**
* Get the contained object as a number
* \return content as double
* \throws std::bad_cast Content was not a number
*/
double as_number() const {
if (!val.is<double>())
throw std::bad_cast();
return val.get<double>();
}
/**
* Get the contained object as an object
* \return content as object
* \throws std::bad_cast Content was not an object
*/
const picojson::object& as_object() const {
if (!val.is<picojson::object>())
throw std::bad_cast();
return val.get<picojson::object>();
}
};
/**
* Base class that represents a token payload.
* Contains Convenience accessors for common claims.
*/
class payload {
protected:
std::unordered_map<std::string, claim> payload_claims;
public:
/**
* Check if issuer is present ("iss")
* \return true if present, false otherwise
*/
bool has_issuer() const noexcept { return has_payload_claim("iss"); }
/**
* Check if subject is present ("sub")
* \return true if present, false otherwise
*/
bool has_subject() const noexcept { return has_payload_claim("sub"); }
/**
* Check if audience is present ("aud")
* \return true if present, false otherwise
*/
bool has_audience() const noexcept { return has_payload_claim("aud"); }
/**
* Check if expires is present ("exp")
* \return true if present, false otherwise
*/
bool has_expires_at() const noexcept { return has_payload_claim("exp"); }
/**
* Check if not before is present ("nbf")
* \return true if present, false otherwise
*/
bool has_not_before() const noexcept { return has_payload_claim("nbf"); }
/**
* Check if issued at is present ("iat")
* \return true if present, false otherwise
*/
bool has_issued_at() const noexcept { return has_payload_claim("iat"); }
/**
* Check if token id is present ("jti")
* \return true if present, false otherwise
*/
bool has_id() const noexcept { return has_payload_claim("jti"); }
/**
* Get issuer claim
* \return issuer as string
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a string (Should not happen in a valid token)
*/
const std::string& get_issuer() const { return get_payload_claim("iss").as_string(); }
/**
* Get subject claim
* \return subject as string
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a string (Should not happen in a valid token)
*/
const std::string& get_subject() const { return get_payload_claim("sub").as_string(); }
/**
* Get audience claim
* \return audience as a set of strings
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a set (Should not happen in a valid token)
*/
std::set<std::string> get_audience() const {
auto aud = get_payload_claim("aud");
if(aud.get_type() == jwt::claim::type::string) return { aud.as_string()};
else return aud.as_set();
}
/**
* Get expires claim
* \return expires as a date in utc
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a date (Should not happen in a valid token)
*/
const date get_expires_at() const { return get_payload_claim("exp").as_date(); }
/**
* Get not valid before claim
* \return nbf date in utc
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a date (Should not happen in a valid token)
*/
const date get_not_before() const { return get_payload_claim("nbf").as_date(); }
/**
* Get issued at claim
* \return issued at as date in utc
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a date (Should not happen in a valid token)
*/
const date get_issued_at() const { return get_payload_claim("iat").as_date(); }
/**
* Get id claim
* \return id as string
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a string (Should not happen in a valid token)
*/
const std::string& get_id() const { return get_payload_claim("jti").as_string(); }
/**
* Check if a payload claim is present
* \return true if claim was present, false otherwise
*/
bool has_payload_claim(const std::string& name) const noexcept { return payload_claims.count(name) != 0; }
/**
* Get payload claim
* \return Requested claim
* \throws std::runtime_error If claim was not present
*/
const claim& get_payload_claim(const std::string& name) const {
if (!has_payload_claim(name))
throw std::runtime_error("claim not found");
return payload_claims.at(name);
}
/**
* Get all payload claims
* \return map of claims
*/
std::unordered_map<std::string, claim> get_payload_claims() const { return payload_claims; }
};
/**
* Base class that represents a token header.
* Contains Convenience accessors for common claims.
*/
class header {
protected:
std::unordered_map<std::string, claim> header_claims;
public:
/**
* Check if algortihm is present ("alg")
* \return true if present, false otherwise
*/
bool has_algorithm() const noexcept { return has_header_claim("alg"); }
/**
* Check if type is present ("typ")
* \return true if present, false otherwise
*/
bool has_type() const noexcept { return has_header_claim("typ"); }
/**
* Check if content type is present ("cty")
* \return true if present, false otherwise
*/
bool has_content_type() const noexcept { return has_header_claim("cty"); }
/**
* Check if key id is present ("kid")
* \return true if present, false otherwise
*/
bool has_key_id() const noexcept { return has_header_claim("kid"); }
/**
* Get algorithm claim
* \return algorithm as string
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a string (Should not happen in a valid token)
*/
const std::string& get_algorithm() const { return get_header_claim("alg").as_string(); }
/**
* Get type claim
* \return type as a string
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a string (Should not happen in a valid token)
*/
const std::string& get_type() const { return get_header_claim("typ").as_string(); }
/**
* Get content type claim
* \return content type as string
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a string (Should not happen in a valid token)
*/
const std::string& get_content_type() const { return get_header_claim("cty").as_string(); }
/**
* Get key id claim
* \return key id as string
* \throws std::runtime_error If claim was not present
* \throws std::bad_cast Claim was present but not a string (Should not happen in a valid token)
*/
const std::string& get_key_id() const { return get_header_claim("kid").as_string(); }
/**
* Check if a header claim is present
* \return true if claim was present, false otherwise
*/
bool has_header_claim(const std::string& name) const noexcept { return header_claims.count(name) != 0; }
/**
* Get header claim
* \return Requested claim
* \throws std::runtime_error If claim was not present
*/
const claim& get_header_claim(const std::string& name) const {
if (!has_header_claim(name))
throw std::runtime_error("claim not found");
return header_claims.at(name);
}
/**
* Get all header claims
* \return map of claims
*/
std::unordered_map<std::string, claim> get_header_claims() const { return header_claims; }
};
/**
* Class containing all information about a decoded token
*/
class decoded_jwt : public header, public payload {
protected:
/// Unmodifed token, as passed to constructor
const std::string token;
/// Header part decoded from base64
std::string header;
/// Unmodified header part in base64
std::string header_base64;
/// Payload part decoded from base64
std::string payload;
/// Unmodified payload part in base64
std::string payload_base64;
/// Signature part decoded from base64
std::string signature;
/// Unmodified signature part in base64
std::string signature_base64;
public:
/**
* Constructor
* Parses a given token
* \param token The token to parse
* \throws std::invalid_argument Token is not in correct format
* \throws std::runtime_error Base64 decoding failed or invalid json
*/
explicit decoded_jwt(const std::string& token)
: token(token)
{
auto hdr_end = token.find('.');
if (hdr_end == std::string::npos)
throw std::invalid_argument("invalid token supplied");
auto payload_end = token.find('.', hdr_end + 1);
if (payload_end == std::string::npos)
throw std::invalid_argument("invalid token supplied");
header = header_base64 = token.substr(0, hdr_end);
payload = payload_base64 = token.substr(hdr_end + 1, payload_end - hdr_end - 1);
signature = signature_base64 = token.substr(payload_end + 1);
// Fix padding: JWT requires padding to get removed
auto fix_padding = [](std::string& str) {
switch (str.size() % 4) {
case 1:
str += alphabet::base64url::fill();
#ifdef __has_cpp_attribute
#if __has_cpp_attribute(fallthrough)
[[fallthrough]];
#endif
#endif
case 2:
str += alphabet::base64url::fill();
#ifdef __has_cpp_attribute
#if __has_cpp_attribute(fallthrough)
[[fallthrough]];
#endif
#endif
case 3:
str += alphabet::base64url::fill();
#ifdef __has_cpp_attribute
#if __has_cpp_attribute(fallthrough)
[[fallthrough]];
#endif
#endif
default:
break;
}
};
fix_padding(header);
fix_padding(payload);
fix_padding(signature);
header = base::decode<alphabet::base64url>(header);
payload = base::decode<alphabet::base64url>(payload);
signature = base::decode<alphabet::base64url>(signature);
auto parse_claims = [](const std::string& str) {
std::unordered_map<std::string, claim> res;
picojson::value val;
if (!picojson::parse(val, str).empty())
throw std::runtime_error("Invalid json");
for (auto& e : val.get<picojson::object>()) { res.insert({ e.first, claim(e.second) }); }
return res;
};
header_claims = parse_claims(header);
payload_claims = parse_claims(payload);
}
/**
* Get token string, as passed to constructor
* \return token as passed to constructor
*/
const std::string& get_token() const noexcept { return token; }
/**
* Get header part as json string
* \return header part after base64 decoding
*/
const std::string& get_header() const noexcept { return header; }
/**
* Get payload part as json string
* \return payload part after base64 decoding
*/
const std::string& get_payload() const noexcept { return payload; }
/**
* Get signature part as json string
* \return signature part after base64 decoding
*/
const std::string& get_signature() const noexcept { return signature; }
/**
* Get header part as base64 string
* \return header part before base64 decoding
*/
const std::string& get_header_base64() const noexcept { return header_base64; }
/**
* Get payload part as base64 string
* \return payload part before base64 decoding
*/
const std::string& get_payload_base64() const noexcept { return payload_base64; }
/**
* Get signature part as base64 string
* \return signature part before base64 decoding
*/
const std::string& get_signature_base64() const noexcept { return signature_base64; }
};
/**
* Builder class to build and sign a new token
* Use jwt::create() to get an instance of this class.
*/
class builder {
std::unordered_map<std::string, claim> header_claims;
std::unordered_map<std::string, claim> payload_claims;
builder() {}
friend builder create();
public:
/**
* Set a header claim.
* \param id Name of the claim
* \param c Claim to add
* \return *this to allow for method chaining
*/
builder& set_header_claim(const std::string& id, claim c) { header_claims[id] = std::move(c); return *this; }
/**
* Set a payload claim.
* \param id Name of the claim
* \param c Claim to add
* \return *this to allow for method chaining
*/
builder& set_payload_claim(const std::string& id, claim c) { payload_claims[id] = std::move(c); return *this; }
/**
* Set algorithm claim
* You normally don't need to do this, as the algorithm is automatically set if you don't change it.
* \param str Name of algorithm
* \return *this to allow for method chaining
*/
builder& set_algorithm(const std::string& str) { return set_header_claim("alg", claim(str)); }
/**
* Set type claim
* \param str Type to set
* \return *this to allow for method chaining
*/
builder& set_type(const std::string& str) { return set_header_claim("typ", claim(str)); }
/**
* Set content type claim
* \param str Type to set
* \return *this to allow for method chaining
*/
builder& set_content_type(const std::string& str) { return set_header_claim("cty", claim(str)); }
/**
* Set key id claim
* \param str Key id to set
* \return *this to allow for method chaining
*/
builder& set_key_id(const std::string& str) { return set_header_claim("kid", claim(str)); }
/**
* Set issuer claim
* \param str Issuer to set
* \return *this to allow for method chaining
*/
builder& set_issuer(const std::string& str) { return set_payload_claim("iss", claim(str)); }
/**
* Set subject claim
* \param str Subject to set
* \return *this to allow for method chaining
*/
builder& set_subject(const std::string& str) { return set_payload_claim("sub", claim(str)); }
/**
* Set audience claim
* \param l Audience set
* \return *this to allow for method chaining
*/
builder& set_audience(const std::set<std::string>& l) { return set_payload_claim("aud", claim(l)); }
/**
* Set audience claim
* \param aud Single audience
* \return *this to allow for method chaining
*/
builder& set_audience(const std::string& aud) { return set_payload_claim("aud", claim(aud)); }
/**
* Set expires at claim
* \param d Expires time
* \return *this to allow for method chaining
*/
builder& set_expires_at(const date& d) { return set_payload_claim("exp", claim(d)); }
/**
* Set not before claim
* \param d First valid time
* \return *this to allow for method chaining
*/
builder& set_not_before(const date& d) { return set_payload_claim("nbf", claim(d)); }
/**
* Set issued at claim
* \param d Issued at time, should be current time
* \return *this to allow for method chaining
*/
builder& set_issued_at(const date& d) { return set_payload_claim("iat", claim(d)); }
/**
* Set id claim
* \param str ID to set
* \return *this to allow for method chaining
*/
builder& set_id(const std::string& str) { return set_payload_claim("jti", claim(str)); }
/**
* Sign token and return result
* \param algo Instance of an algorithm to sign the token with
* \return Final token as a string
*/
template<typename T>
std::string sign(const T& algo) const {
picojson::object obj_header;
obj_header["alg"] = picojson::value(algo.name());
for (auto& e : header_claims) {
obj_header[e.first] = e.second.to_json();
}
picojson::object obj_payload;
for (auto& e : payload_claims) {
obj_payload.insert({ e.first, e.second.to_json() });
}
auto encode = [](const std::string& data) {
auto base = base::encode<alphabet::base64url>(data);
auto pos = base.find(alphabet::base64url::fill());
base = base.substr(0, pos);
return base;
};
std::string header = encode(picojson::value(obj_header).serialize());
std::string payload = encode(picojson::value(obj_payload).serialize());
std::string token = header + "." + payload;
return token + "." + encode(algo.sign(token));
}
};
/**
* Verifier class used to check if a decoded token contains all claims required by your application and has a valid signature.
*/
template<typename Clock>
class verifier {
struct algo_base {
virtual ~algo_base() {}
virtual void verify(const std::string& data, const std::string& sig) = 0;
};
template<typename T>
struct algo : public algo_base {
T alg;
explicit algo(T a) : alg(a) {}
virtual void verify(const std::string& data, const std::string& sig) override {
alg.verify(data, sig);
}
};
/// Required claims
std::unordered_map<std::string, claim> claims;
/// Leeway time for exp, nbf and iat
size_t default_leeway = 0;
/// Instance of clock type
Clock clock;
/// Supported algorithms
std::unordered_map<std::string, std::shared_ptr<algo_base>> algs;
public:
/**
* Constructor for building a new verifier instance
* \param c Clock instance
*/
explicit verifier(Clock c) : clock(c) {}
/**
* Set default leeway to use.
* \param leeway Default leeway to use if not specified otherwise
* \return *this to allow chaining
*/
verifier& leeway(size_t leeway) { default_leeway = leeway; return *this; }
/**
* Set leeway for expires at.
* If not specified the default leeway will be used.
* \param leeway Set leeway to use for expires at.
* \return *this to allow chaining
*/
verifier& expires_at_leeway(size_t leeway) { return with_claim("exp", claim(std::chrono::system_clock::from_time_t(leeway))); }
/**
* Set leeway for not before.
* If not specified the default leeway will be used.
* \param leeway Set leeway to use for not before.
* \return *this to allow chaining
*/
verifier& not_before_leeway(size_t leeway) { return with_claim("nbf", claim(std::chrono::system_clock::from_time_t(leeway))); }
/**
* Set leeway for issued at.
* If not specified the default leeway will be used.
* \param leeway Set leeway to use for issued at.
* \return *this to allow chaining
*/
verifier& issued_at_leeway(size_t leeway) { return with_claim("iat", claim(std::chrono::system_clock::from_time_t(leeway))); }
/**
* Set an issuer to check for.
* Check is casesensitive.
* \param iss Issuer to check for.
* \return *this to allow chaining
*/
verifier& with_issuer(const std::string& iss) { return with_claim("iss", claim(iss)); }
/**
* Set a subject to check for.
* Check is casesensitive.
* \param sub Subject to check for.
* \return *this to allow chaining
*/
verifier& with_subject(const std::string& sub) { return with_claim("sub", claim(sub)); }
/**
* Set an audience to check for.
* If any of the specified audiences is not present in the token the check fails.
* \param aud Audience to check for.
* \return *this to allow chaining
*/
verifier& with_audience(const std::set<std::string>& aud) { return with_claim("aud", claim(aud)); }
/**
* Set an id to check for.
* Check is casesensitive.
* \param id ID to check for.
* \return *this to allow chaining
*/
verifier& with_id(const std::string& id) { return with_claim("jti", claim(id)); }
/**
* Specify a claim to check for.
* \param name Name of the claim to check for
* \param c Claim to check for
* \return *this to allow chaining
*/
verifier& with_claim(const std::string& name, claim c) { claims[name] = c; return *this; }
/**
* Add an algorithm available for checking.
* \param alg Algorithm to allow
* \return *this to allow chaining
*/
template<typename Algorithm>
verifier& allow_algorithm(Algorithm alg) {
algs[alg.name()] = std::make_shared<algo<Algorithm>>(alg);
return *this;
}
/**
* Verify the given token.
* \param jwt Token to check
* \throws token_verification_exception Verification failed
*/
void verify(const decoded_jwt& jwt) const {
const std::string data = jwt.get_header_base64() + "." + jwt.get_payload_base64();
const std::string sig = jwt.get_signature();
const std::string& algo = jwt.get_algorithm();
if (algs.count(algo) == 0)
throw token_verification_exception("wrong algorithm");
algs.at(algo)->verify(data, sig);
auto assert_claim_eq = [](const decoded_jwt& jwt, const std::string& key, const claim& c) {
if (!jwt.has_payload_claim(key))
throw token_verification_exception("decoded_jwt is missing " + key + " claim");
auto& jc = jwt.get_payload_claim(key);
if (jc.get_type() != c.get_type())
throw token_verification_exception("claim " + key + " type mismatch");
if (c.get_type() == claim::type::int64) {
if (c.as_date() != jc.as_date())
throw token_verification_exception("claim " + key + " does not match expected");
}
else if (c.get_type() == claim::type::array) {
auto s1 = c.as_set();
auto s2 = jc.as_set();
if (s1.size() != s2.size())
throw token_verification_exception("claim " + key + " does not match expected");
auto it1 = s1.cbegin();
auto it2 = s2.cbegin();
while (it1 != s1.cend() && it2 != s2.cend()) {
if (*it1++ != *it2++)
throw token_verification_exception("claim " + key + " does not match expected");
}
}
else if (c.get_type() == claim::type::string) {
if (c.as_string() != jc.as_string())
throw token_verification_exception("claim " + key + " does not match expected");
}
else throw token_verification_exception("internal error");
};
auto time = clock.now();
if (jwt.has_expires_at()) {
auto leeway = claims.count("exp") == 1 ? std::chrono::system_clock::to_time_t(claims.at("exp").as_date()) : default_leeway;
auto exp = jwt.get_expires_at();
if (time > exp + std::chrono::seconds(leeway))
throw token_verification_exception("token expired");
}
if (jwt.has_issued_at()) {
auto leeway = claims.count("iat") == 1 ? std::chrono::system_clock::to_time_t(claims.at("iat").as_date()) : default_leeway;
auto iat = jwt.get_issued_at();
if (time < iat - std::chrono::seconds(leeway))
throw token_verification_exception("token expired");
}
if (jwt.has_not_before()) {
auto leeway = claims.count("nbf") == 1 ? std::chrono::system_clock::to_time_t(claims.at("nbf").as_date()) : default_leeway;
auto nbf = jwt.get_not_before();
if (time < nbf - std::chrono::seconds(leeway))
throw token_verification_exception("token expired");
}
for (auto& c : claims)
{
if (c.first == "exp" || c.first == "iat" || c.first == "nbf") {
// Nothing to do here, already checked
}
else if (c.first == "aud") {
if (!jwt.has_audience())
throw token_verification_exception("token doesn't contain the required audience");
auto aud = jwt.get_audience();
auto expected = c.second.as_set();
for (auto& e : expected)
if (aud.count(e) == 0)
throw token_verification_exception("token doesn't contain the required audience");
}
else {
assert_claim_eq(jwt, c.first, c.second);
}
}
}
};
/**
* Create a verifier using the given clock
* \param c Clock instance to use
* \return verifier instance
*/
template<typename Clock>
verifier<Clock> verify(Clock c) {
return verifier<Clock>(c);
}
/**
* Default clock class using std::chrono::system_clock as a backend.
*/
struct default_clock {
std::chrono::system_clock::time_point now() const {
return std::chrono::system_clock::now();
}
};
/**
* Create a verifier using the default clock
* \return verifier instance
*/
inline
verifier<default_clock> verify() {
return verify<default_clock>({});
}
/**
* Return a builder instance to create a new token
*/
inline
builder create() {
return builder();
}
/**
* Decode a token
* \param token Token to decode
* \return Decoded token
* \throws std::invalid_argument Token is not in correct format
* \throws std::runtime_error Base64 decoding failed or invalid json
*/
inline
decoded_jwt decode(const std::string& token) {
return decoded_jwt(token);
}
}
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