lib/minicrypto-pem.c - third_party/github/h2o/picotls - Git at Google

 /*
  * Copyright (c) 2017,2018 Christian Huitema
  *
  * Permission is hereby granted, free of charge, to any person obtaining a copy
  * of this software and associated documentation files (the "Software"), to
  * deal in the Software without restriction, including without limitation the
  * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
  * sell copies of the Software, and to permit persons to whom the Software is
  * furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be included in
  * all copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
  * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
  * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
  * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
  * IN THE SOFTWARE.
  */
 #include <fcntl.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #ifdef _WINDOWS
 #include "wincompat.h"
 #else
 #include <unistd.h>
 #endif
 #include "picotls.h"
 #include "picotls/minicrypto.h"
 #include "picotls/asn1.h"
 #include "picotls/pembase64.h"

 /*
  * This function could be declared as static, but we want to access it
  * in the unit tests.
  */
 size_t ptls_minicrypto_asn1_decode_private_key(ptls_asn1_pkcs8_private_key_t *pkey, int *decode_error,
                                                ptls_minicrypto_log_ctx_t *log_ctx)
 {
     uint8_t *bytes = pkey->vec.base;
     size_t bytes_max = pkey->vec.len;

     /* read the ASN1 messages */
     size_t byte_index = 0;
     uint32_t seq0_length = 0;
     size_t last_byte0;
     uint32_t seq1_length = 0;
     size_t last_byte1 = 0;
     uint32_t oid_length;
     size_t last_oid_byte;
     uint32_t key_data_length;
     size_t key_data_last;

     /* start with sequence */
     byte_index = ptls_asn1_get_expected_type_and_length(bytes, bytes_max, byte_index, 0x30, &seq0_length, NULL, &last_byte0,
                                                         decode_error, log_ctx);

     if (*decode_error == 0 && bytes_max != last_byte0) {
         byte_index = ptls_asn1_error_message("Length larger than message", bytes_max, byte_index, 0, log_ctx);
         *decode_error = PTLS_ERROR_BER_EXCESSIVE_LENGTH;
     }

     if (*decode_error == 0) {
         /* get first component: version, INTEGER, expect value 0 */
         if (byte_index + 3 > bytes_max) {
             byte_index = ptls_asn1_error_message("Cannot find key version", bytes_max, byte_index, 0, log_ctx);
             *decode_error = PTLS_ERROR_INCORRECT_PEM_KEY_VERSION;
         } else if (bytes[byte_index] != 0x02 || bytes[byte_index + 1] != 0x01 || bytes[byte_index + 2] != 0x00) {
             *decode_error = PTLS_ERROR_INCORRECT_PEM_KEY_VERSION;
             byte_index = ptls_asn1_error_message("Incorrect PEM Version", bytes_max, byte_index, 0, log_ctx);
         } else {
             byte_index += 3;
             if (log_ctx != NULL) {
                 log_ctx->fn(log_ctx->ctx, "   Version = 1,\n");
             }
         }
     }

     if (*decode_error == 0) {
         /* open embedded sequence */
         byte_index = ptls_asn1_get_expected_type_and_length(bytes, bytes_max, byte_index, 0x30, &seq1_length, NULL, &last_byte1,
                                                             decode_error, log_ctx);
     }

     if (*decode_error == 0) {
         if (log_ctx != NULL) {
             log_ctx->fn(log_ctx->ctx, "   Algorithm Identifier:\n");
         }
         /* get length of OID */
         byte_index = ptls_asn1_get_expected_type_and_length(bytes, last_byte1, byte_index, 0x06, &oid_length, NULL, &last_oid_byte,
                                                             decode_error, log_ctx);

         if (*decode_error == 0) {
             if (log_ctx != NULL) {
                 /* print the OID value */
                 log_ctx->fn(log_ctx->ctx, "      Algorithm:");
                 ptls_asn1_dump_content(bytes + byte_index, oid_length, 0, log_ctx);
                 log_ctx->fn(log_ctx->ctx, ",\n");
             }
             pkey->algorithm_index = byte_index;
             pkey->algorithm_length = oid_length;
             byte_index += oid_length;
         }
     }

     if (*decode_error == 0) {
         /* get parameters, ANY */
         if (log_ctx != NULL) {
             log_ctx->fn(log_ctx->ctx, "      Parameters:\n");
         }

         if (last_byte1 <= byte_index) {
             pkey->parameters_index = 0;
             pkey->parameters_length = 0;
         } else {
             pkey->parameters_index = byte_index;

             pkey->parameters_length =
                 (uint32_t)ptls_asn1_validation_recursive(bytes + byte_index, last_byte1 - byte_index, decode_error, 2, log_ctx);
             if (*decode_error == 0) {
                 byte_index += pkey->parameters_length;
             }
         }
         if (log_ctx != NULL) {
             log_ctx->fn(log_ctx->ctx, "\n");
         }
         /* close sequence */
         if (*decode_error == 0 && byte_index != last_byte1) {
             byte_index = ptls_asn1_error_message("Length larger than element", bytes_max, byte_index, 2, log_ctx);
             *decode_error = PTLS_ERROR_BER_ELEMENT_TOO_SHORT;
         }
     }

     /* get octet string, key */
     if (*decode_error == 0) {
         byte_index = ptls_asn1_get_expected_type_and_length(bytes, last_byte0, byte_index, 0x04, &key_data_length, NULL,
                                                             &key_data_last, decode_error, log_ctx);

         if (*decode_error == 0) {
             pkey->key_data_index = byte_index;
             pkey->key_data_length = key_data_length;
             byte_index += key_data_length;

             if (log_ctx != NULL) {
                 log_ctx->fn(log_ctx->ctx, "   Key data (%d bytes):\n", key_data_length);

                 (void)ptls_asn1_validation_recursive(bytes + pkey->key_data_index, key_data_length, decode_error, 1, log_ctx);
                 log_ctx->fn(log_ctx->ctx, "\n");
             }
         }
     }

     if (*decode_error == 0 && byte_index != last_byte0) {
         byte_index = ptls_asn1_error_message("Length larger than element", bytes_max, byte_index, 0, log_ctx);
         *decode_error = PTLS_ERROR_BER_ELEMENT_TOO_SHORT;
     }

     if (log_ctx != NULL) {
         log_ctx->fn(log_ctx->ctx, "\n");
     }

     return byte_index;
 }

 static int ptls_pem_parse_private_key(char const *pem_fname, ptls_asn1_pkcs8_private_key_t *pkey,
                                       ptls_minicrypto_log_ctx_t *log_ctx)
 {
     size_t nb_keys = 0;
     int ret = ptls_load_pem_objects(pem_fname, "PRIVATE KEY", &pkey->vec, 1, &nb_keys);

     if (ret == 0) {
         if (nb_keys != 1) {
             ret = PTLS_ERROR_PEM_LABEL_NOT_FOUND;
         }
     }

     if (ret == 0 && nb_keys == 1) {
         int decode_error = 0;

         if (log_ctx != NULL) {
             log_ctx->fn(log_ctx->ctx, "\nFound PRIVATE KEY, length = %d bytes\n", (int)pkey->vec.len);
         }

         (void)ptls_minicrypto_asn1_decode_private_key(pkey, &decode_error, log_ctx);

         if (decode_error != 0) {
             ret = decode_error;
         }
     }

     return ret;
 }

 static const uint8_t ptls_asn1_algorithm_ecdsa[] = {0x2a, 0x86, 0x48, 0xce, 0x3d, 0x02, 0x01};

 static const uint8_t ptls_asn1_curve_secp256r1[] = {0x2a, 0x86, 0x48, 0xce, 0x3d, 0x03, 0x01, 0x07};

 static int ptls_set_ecdsa_private_key(ptls_context_t *ctx, ptls_asn1_pkcs8_private_key_t *pkey, ptls_minicrypto_log_ctx_t *log_ctx)
 {
     uint8_t *bytes = pkey->vec.base + pkey->parameters_index;
     size_t bytes_max = pkey->parameters_length;
     size_t byte_index = 0;
     uint8_t *curve_id = NULL;
     uint32_t curve_id_length = 0;
     int decode_error = 0;
     uint32_t seq_length;
     size_t last_byte = 0;
     uint8_t *ecdsa_key_data = NULL;
     uint32_t ecdsa_key_data_length = 0;
     size_t ecdsa_key_data_last = 0;

     /* We expect the parameters to include just the curve ID */

     byte_index = ptls_asn1_get_expected_type_and_length(bytes, bytes_max, byte_index, 0x06, &curve_id_length, NULL, &last_byte,
                                                         &decode_error, log_ctx);

     if (decode_error == 0 && bytes_max != last_byte) {
         byte_index = ptls_asn1_error_message("Length larger than parameters", bytes_max, byte_index, 0, log_ctx);
         decode_error = PTLS_ERROR_BER_EXCESSIVE_LENGTH;
     }

     if (decode_error == 0) {
         curve_id = bytes + byte_index;

         if (log_ctx != NULL) {
             /* print the OID value */
             log_ctx->fn(log_ctx->ctx, "Curve: ");
             ptls_asn1_dump_content(curve_id, curve_id_length, 0, log_ctx);
             log_ctx->fn(log_ctx->ctx, "\n");
         }
     }

     /* We expect the key data to follow the ECDSA structure per RFC 5915 */
     bytes = pkey->vec.base + pkey->key_data_index;
     bytes_max = pkey->key_data_length;
     byte_index = 0;

     /* decode the wrapping sequence */
     if (decode_error == 0) {
         byte_index = ptls_asn1_get_expected_type_and_length(bytes, bytes_max, byte_index, 0x30, &seq_length, NULL, &last_byte,
                                                             &decode_error, log_ctx);
     }

     if (decode_error == 0 && bytes_max != last_byte) {
         byte_index = ptls_asn1_error_message("Length larger than key data", bytes_max, byte_index, 0, log_ctx);
         decode_error = PTLS_ERROR_BER_ELEMENT_TOO_SHORT;
     }

     /* verify and skip the version number 1 */
     if (decode_error == 0) {
         /* get first component: version, INTEGER, expect value 0 */
         if (byte_index + 3 > bytes_max) {
             byte_index = ptls_asn1_error_message("Cannot find ECDSA Key Data Version", bytes_max, byte_index, 0, log_ctx);
             decode_error = PTLS_ERROR_INCORRECT_ASN1_ECDSA_KEY_SYNTAX;
         } else if (bytes[byte_index] != 0x02 || bytes[byte_index + 1] != 0x01 || bytes[byte_index + 2] != 0x01) {
             decode_error = PTLS_ERROR_INCORRECT_PEM_ECDSA_KEY_VERSION;
             byte_index = ptls_asn1_error_message("Incorrect ECDSA Key Data Version", bytes_max, byte_index, 0, log_ctx);
         } else {
             byte_index += 3;
             if (log_ctx != NULL) {
                 log_ctx->fn(log_ctx->ctx, "ECDSA Version = 1,\n");
             }
         }
     }

     /* obtain the octet string that contains the ECDSA private key */
     if (decode_error == 0) {
         byte_index = ptls_asn1_get_expected_type_and_length(bytes, last_byte, byte_index, 0x04, &ecdsa_key_data_length, NULL,
                                                             &ecdsa_key_data_last, &decode_error, log_ctx);

         if (decode_error == 0) {
             ecdsa_key_data = bytes + byte_index;
         }
     }

     /* If everything is fine, associate the ECDSA key with the context */
     if (curve_id_length == sizeof(ptls_asn1_curve_secp256r1) && curve_id != NULL &&
         memcmp(curve_id, ptls_asn1_curve_secp256r1, sizeof(ptls_asn1_curve_secp256r1)) == 0) {
         if (SECP256R1_PRIVATE_KEY_SIZE != ecdsa_key_data_length) {
             decode_error = PTLS_ERROR_INCORRECT_PEM_ECDSA_KEYSIZE;
             if (log_ctx != NULL) {
                 /* print the OID value */
                 log_ctx->fn(log_ctx->ctx, "Wrong SECP256R1 key length, %d instead of %d.\n", ecdsa_key_data_length,
                             SECP256R1_PRIVATE_KEY_SIZE);
             }
         } else {
             ptls_minicrypto_secp256r1sha256_sign_certificate_t *minicrypto_sign_certificate;

             minicrypto_sign_certificate = (ptls_minicrypto_secp256r1sha256_sign_certificate_t *)malloc(
                 sizeof(ptls_minicrypto_secp256r1sha256_sign_certificate_t));

             if (minicrypto_sign_certificate == NULL) {
                 decode_error = PTLS_ERROR_NO_MEMORY;
             } else {
                 memset(minicrypto_sign_certificate, 0, sizeof(ptls_minicrypto_secp256r1sha256_sign_certificate_t));
                 decode_error = ptls_minicrypto_init_secp256r1sha256_sign_certificate(
                     minicrypto_sign_certificate, ptls_iovec_init(ecdsa_key_data, ecdsa_key_data_length));
             }
             if (decode_error == 0) {
                 ctx->sign_certificate = &minicrypto_sign_certificate->super;

                 if (log_ctx != NULL) {
                     /* print the OID value */
                     log_ctx->fn(log_ctx->ctx, "Initialized SECP512R1 signing key with %d bytes.\n", ecdsa_key_data_length);
                 }
             } else if (log_ctx != NULL) {
                 log_ctx->fn(log_ctx->ctx, "SECP512R1 init with %d bytes returns %d.\n", ecdsa_key_data_length, decode_error);
             }
         }
     } else {
         decode_error = PTLS_ERROR_INCORRECT_PEM_ECDSA_CURVE;
         if (log_ctx != NULL) {
             /* print the OID value */
             log_ctx->fn(log_ctx->ctx, "Curve is not supported for signatures.\n");
         }
     }

     return decode_error;
 }

 int ptls_minicrypto_load_private_key(ptls_context_t *ctx, char const *pem_fname)
 {
     ptls_asn1_pkcs8_private_key_t pkey = {{0}};
     int ret = ptls_pem_parse_private_key(pem_fname, &pkey, NULL);

     if (ret != 0)
         goto err;

     /* Check that this is the expected key type.
      * At this point, the minicrypto library only supports ECDSA keys.
      * In theory, we could add support for RSA keys at some point.
      */
     if (pkey.algorithm_length != sizeof(ptls_asn1_algorithm_ecdsa) ||
         memcmp(pkey.vec.base + pkey.algorithm_index, ptls_asn1_algorithm_ecdsa, sizeof(ptls_asn1_algorithm_ecdsa)) != 0) {
         ret = -1;
         goto err;
     }

     ret = ptls_set_ecdsa_private_key(ctx, &pkey, NULL);

 err:
     if (pkey.vec.base) {
         ptls_clear_memory(pkey.vec.base, pkey.vec.len);
         free(pkey.vec.base);
     }
     return ret;
 }
	/*
	* Copyright (c) 2017,2018 Christian Huitema
	*
	* Permission is hereby granted, free of charge, to any person obtaining a copy
	* of this software and associated documentation files (the "Software"), to
	* deal in the Software without restriction, including without limitation the
	* rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
	* sell copies of the Software, and to permit persons to whom the Software is
	* furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in
	* all copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
	* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
	* IN THE SOFTWARE.
	*/
	#include <fcntl.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>
	#ifdef _WINDOWS
	#include "wincompat.h"
	#else
	#include <unistd.h>
	#endif
	#include "picotls.h"
	#include "picotls/minicrypto.h"
	#include "picotls/asn1.h"
	#include "picotls/pembase64.h"

	/*
	* This function could be declared as static, but we want to access it
	* in the unit tests.
	*/
	size_t ptls_minicrypto_asn1_decode_private_key(ptls_asn1_pkcs8_private_key_t pkey, int decode_error,
	ptls_minicrypto_log_ctx_t *log_ctx)
	{
	uint8_t *bytes = pkey->vec.base;
	size_t bytes_max = pkey->vec.len;

	/* read the ASN1 messages */
	size_t byte_index = 0;
	uint32_t seq0_length = 0;
	size_t last_byte0;
	uint32_t seq1_length = 0;
	size_t last_byte1 = 0;
	uint32_t oid_length;
	size_t last_oid_byte;
	uint32_t key_data_length;
	size_t key_data_last;

	/* start with sequence */
	byte_index = ptls_asn1_get_expected_type_and_length(bytes, bytes_max, byte_index, 0x30, &seq0_length, NULL, &last_byte0,
	decode_error, log_ctx);

	if (*decode_error == 0 && bytes_max != last_byte0) {
	byte_index = ptls_asn1_error_message("Length larger than message", bytes_max, byte_index, 0, log_ctx);
	*decode_error = PTLS_ERROR_BER_EXCESSIVE_LENGTH;
	}

	if (*decode_error == 0) {
	/* get first component: version, INTEGER, expect value 0 */
	if (byte_index + 3 > bytes_max) {
	byte_index = ptls_asn1_error_message("Cannot find key version", bytes_max, byte_index, 0, log_ctx);
	*decode_error = PTLS_ERROR_INCORRECT_PEM_KEY_VERSION;
	} else if (bytes[byte_index] != 0x02 \|\| bytes[byte_index + 1] != 0x01 \|\| bytes[byte_index + 2] != 0x00) {
	*decode_error = PTLS_ERROR_INCORRECT_PEM_KEY_VERSION;
	byte_index = ptls_asn1_error_message("Incorrect PEM Version", bytes_max, byte_index, 0, log_ctx);
	} else {
	byte_index += 3;
	if (log_ctx != NULL) {
	log_ctx->fn(log_ctx->ctx, " Version = 1,\n");
	}
	}
	}

	if (*decode_error == 0) {
	/* open embedded sequence */
	byte_index = ptls_asn1_get_expected_type_and_length(bytes, bytes_max, byte_index, 0x30, &seq1_length, NULL, &last_byte1,
	decode_error, log_ctx);
	}

	if (*decode_error == 0) {
	if (log_ctx != NULL) {
	log_ctx->fn(log_ctx->ctx, " Algorithm Identifier:\n");
	}
	/* get length of OID */
	byte_index = ptls_asn1_get_expected_type_and_length(bytes, last_byte1, byte_index, 0x06, &oid_length, NULL, &last_oid_byte,
	decode_error, log_ctx);

	if (*decode_error == 0) {
	if (log_ctx != NULL) {
	/* print the OID value */
	log_ctx->fn(log_ctx->ctx, " Algorithm:");
	ptls_asn1_dump_content(bytes + byte_index, oid_length, 0, log_ctx);
	log_ctx->fn(log_ctx->ctx, ",\n");
	}
	pkey->algorithm_index = byte_index;
	pkey->algorithm_length = oid_length;
	byte_index += oid_length;
	}
	}

	if (*decode_error == 0) {
	/* get parameters, ANY */
	if (log_ctx != NULL) {
	log_ctx->fn(log_ctx->ctx, " Parameters:\n");
	}

	if (last_byte1 <= byte_index) {
	pkey->parameters_index = 0;
	pkey->parameters_length = 0;
	} else {
	pkey->parameters_index = byte_index;

	pkey->parameters_length =
	(uint32_t)ptls_asn1_validation_recursive(bytes + byte_index, last_byte1 - byte_index, decode_error, 2, log_ctx);
	if (*decode_error == 0) {
	byte_index += pkey->parameters_length;
	}
	}
	if (log_ctx != NULL) {
	log_ctx->fn(log_ctx->ctx, "\n");
	}
	/* close sequence */
	if (*decode_error == 0 && byte_index != last_byte1) {
	byte_index = ptls_asn1_error_message("Length larger than element", bytes_max, byte_index, 2, log_ctx);
	*decode_error = PTLS_ERROR_BER_ELEMENT_TOO_SHORT;
	}
	}

	/* get octet string, key */
	if (*decode_error == 0) {
	byte_index = ptls_asn1_get_expected_type_and_length(bytes, last_byte0, byte_index, 0x04, &key_data_length, NULL,
	&key_data_last, decode_error, log_ctx);

	if (*decode_error == 0) {
	pkey->key_data_index = byte_index;
	pkey->key_data_length = key_data_length;
	byte_index += key_data_length;

	if (log_ctx != NULL) {
	log_ctx->fn(log_ctx->ctx, " Key data (%d bytes):\n", key_data_length);

	(void)ptls_asn1_validation_recursive(bytes + pkey->key_data_index, key_data_length, decode_error, 1, log_ctx);
	log_ctx->fn(log_ctx->ctx, "\n");
	}
	}
	}

	if (*decode_error == 0 && byte_index != last_byte0) {
	byte_index = ptls_asn1_error_message("Length larger than element", bytes_max, byte_index, 0, log_ctx);
	*decode_error = PTLS_ERROR_BER_ELEMENT_TOO_SHORT;
	}

	if (log_ctx != NULL) {
	log_ctx->fn(log_ctx->ctx, "\n");
	}

	return byte_index;
	}

	static int ptls_pem_parse_private_key(char const pem_fname, ptls_asn1_pkcs8_private_key_t pkey,
	ptls_minicrypto_log_ctx_t *log_ctx)
	{
	size_t nb_keys = 0;
	int ret = ptls_load_pem_objects(pem_fname, "PRIVATE KEY", &pkey->vec, 1, &nb_keys);

	if (ret == 0) {
	if (nb_keys != 1) {
	ret = PTLS_ERROR_PEM_LABEL_NOT_FOUND;
	}
	}

	if (ret == 0 && nb_keys == 1) {
	int decode_error = 0;

	if (log_ctx != NULL) {
	log_ctx->fn(log_ctx->ctx, "\nFound PRIVATE KEY, length = %d bytes\n", (int)pkey->vec.len);
	}

	(void)ptls_minicrypto_asn1_decode_private_key(pkey, &decode_error, log_ctx);

	if (decode_error != 0) {
	ret = decode_error;
	}
	}

	return ret;
	}

	static const uint8_t ptls_asn1_algorithm_ecdsa[] = {0x2a, 0x86, 0x48, 0xce, 0x3d, 0x02, 0x01};

	static const uint8_t ptls_asn1_curve_secp256r1[] = {0x2a, 0x86, 0x48, 0xce, 0x3d, 0x03, 0x01, 0x07};

	static int ptls_set_ecdsa_private_key(ptls_context_t ctx, ptls_asn1_pkcs8_private_key_t pkey, ptls_minicrypto_log_ctx_t *log_ctx)
	{
	uint8_t *bytes = pkey->vec.base + pkey->parameters_index;
	size_t bytes_max = pkey->parameters_length;
	size_t byte_index = 0;
	uint8_t *curve_id = NULL;
	uint32_t curve_id_length = 0;
	int decode_error = 0;
	uint32_t seq_length;
	size_t last_byte = 0;
	uint8_t *ecdsa_key_data = NULL;
	uint32_t ecdsa_key_data_length = 0;
	size_t ecdsa_key_data_last = 0;

	/* We expect the parameters to include just the curve ID */

	byte_index = ptls_asn1_get_expected_type_and_length(bytes, bytes_max, byte_index, 0x06, &curve_id_length, NULL, &last_byte,
	&decode_error, log_ctx);

	if (decode_error == 0 && bytes_max != last_byte) {
	byte_index = ptls_asn1_error_message("Length larger than parameters", bytes_max, byte_index, 0, log_ctx);
	decode_error = PTLS_ERROR_BER_EXCESSIVE_LENGTH;
	}

	if (decode_error == 0) {
	curve_id = bytes + byte_index;

	if (log_ctx != NULL) {
	/* print the OID value */
	log_ctx->fn(log_ctx->ctx, "Curve: ");
	ptls_asn1_dump_content(curve_id, curve_id_length, 0, log_ctx);
	log_ctx->fn(log_ctx->ctx, "\n");
	}
	}

	/* We expect the key data to follow the ECDSA structure per RFC 5915 */
	bytes = pkey->vec.base + pkey->key_data_index;
	bytes_max = pkey->key_data_length;
	byte_index = 0;

	/* decode the wrapping sequence */
	if (decode_error == 0) {
	byte_index = ptls_asn1_get_expected_type_and_length(bytes, bytes_max, byte_index, 0x30, &seq_length, NULL, &last_byte,
	&decode_error, log_ctx);
	}

	if (decode_error == 0 && bytes_max != last_byte) {
	byte_index = ptls_asn1_error_message("Length larger than key data", bytes_max, byte_index, 0, log_ctx);
	decode_error = PTLS_ERROR_BER_ELEMENT_TOO_SHORT;
	}

	/* verify and skip the version number 1 */
	if (decode_error == 0) {
	/* get first component: version, INTEGER, expect value 0 */
	if (byte_index + 3 > bytes_max) {
	byte_index = ptls_asn1_error_message("Cannot find ECDSA Key Data Version", bytes_max, byte_index, 0, log_ctx);
	decode_error = PTLS_ERROR_INCORRECT_ASN1_ECDSA_KEY_SYNTAX;
	} else if (bytes[byte_index] != 0x02 \|\| bytes[byte_index + 1] != 0x01 \|\| bytes[byte_index + 2] != 0x01) {
	decode_error = PTLS_ERROR_INCORRECT_PEM_ECDSA_KEY_VERSION;
	byte_index = ptls_asn1_error_message("Incorrect ECDSA Key Data Version", bytes_max, byte_index, 0, log_ctx);
	} else {
	byte_index += 3;
	if (log_ctx != NULL) {
	log_ctx->fn(log_ctx->ctx, "ECDSA Version = 1,\n");
	}
	}
	}

	/* obtain the octet string that contains the ECDSA private key */
	if (decode_error == 0) {
	byte_index = ptls_asn1_get_expected_type_and_length(bytes, last_byte, byte_index, 0x04, &ecdsa_key_data_length, NULL,
	&ecdsa_key_data_last, &decode_error, log_ctx);

	if (decode_error == 0) {
	ecdsa_key_data = bytes + byte_index;
	}
	}

	/* If everything is fine, associate the ECDSA key with the context */
	if (curve_id_length == sizeof(ptls_asn1_curve_secp256r1) && curve_id != NULL &&
	memcmp(curve_id, ptls_asn1_curve_secp256r1, sizeof(ptls_asn1_curve_secp256r1)) == 0) {
	if (SECP256R1_PRIVATE_KEY_SIZE != ecdsa_key_data_length) {
	decode_error = PTLS_ERROR_INCORRECT_PEM_ECDSA_KEYSIZE;
	if (log_ctx != NULL) {
	/* print the OID value */
	log_ctx->fn(log_ctx->ctx, "Wrong SECP256R1 key length, %d instead of %d.\n", ecdsa_key_data_length,
	SECP256R1_PRIVATE_KEY_SIZE);
	}
	} else {
	ptls_minicrypto_secp256r1sha256_sign_certificate_t *minicrypto_sign_certificate;

	minicrypto_sign_certificate = (ptls_minicrypto_secp256r1sha256_sign_certificate_t *)malloc(
	sizeof(ptls_minicrypto_secp256r1sha256_sign_certificate_t));

	if (minicrypto_sign_certificate == NULL) {
	decode_error = PTLS_ERROR_NO_MEMORY;
	} else {
	memset(minicrypto_sign_certificate, 0, sizeof(ptls_minicrypto_secp256r1sha256_sign_certificate_t));
	decode_error = ptls_minicrypto_init_secp256r1sha256_sign_certificate(
	minicrypto_sign_certificate, ptls_iovec_init(ecdsa_key_data, ecdsa_key_data_length));
	}
	if (decode_error == 0) {
	ctx->sign_certificate = &minicrypto_sign_certificate->super;

	if (log_ctx != NULL) {
	/* print the OID value */
	log_ctx->fn(log_ctx->ctx, "Initialized SECP512R1 signing key with %d bytes.\n", ecdsa_key_data_length);
	}
	} else if (log_ctx != NULL) {
	log_ctx->fn(log_ctx->ctx, "SECP512R1 init with %d bytes returns %d.\n", ecdsa_key_data_length, decode_error);
	}
	}
	} else {
	decode_error = PTLS_ERROR_INCORRECT_PEM_ECDSA_CURVE;
	if (log_ctx != NULL) {
	/* print the OID value */
	log_ctx->fn(log_ctx->ctx, "Curve is not supported for signatures.\n");
	}
	}

	return decode_error;
	}

	int ptls_minicrypto_load_private_key(ptls_context_t ctx, char const pem_fname)
	{
	ptls_asn1_pkcs8_private_key_t pkey = {{0}};
	int ret = ptls_pem_parse_private_key(pem_fname, &pkey, NULL);

	if (ret != 0)
	goto err;

	/* Check that this is the expected key type.
	* At this point, the minicrypto library only supports ECDSA keys.
	* In theory, we could add support for RSA keys at some point.
	*/
	if (pkey.algorithm_length != sizeof(ptls_asn1_algorithm_ecdsa) \|\|
	memcmp(pkey.vec.base + pkey.algorithm_index, ptls_asn1_algorithm_ecdsa, sizeof(ptls_asn1_algorithm_ecdsa)) != 0) {
	ret = -1;
	goto err;
	}

	ret = ptls_set_ecdsa_private_key(ctx, &pkey, NULL);

	err:
	if (pkey.vec.base) {
	ptls_clear_memory(pkey.vec.base, pkey.vec.len);
	free(pkey.vec.base);
	}
	return ret;
	}