c-libp2p/secio/secio.c
2017-03-09 12:49:47 -05:00

938 lines
32 KiB
C

#include <stdlib.h>
#include <stdio.h> // for debugging, can remove
#include <string.h>
#include <stdint.h>
#include <errno.h>
#include <arpa/inet.h>
#include <endian.h>
#include "libp2p/secio/secio.h"
#include "libp2p/secio/propose.h"
#include "libp2p/secio/exchange.h"
#include "libp2p/net/multistream.h"
#include "libp2p/net/p2pnet.h"
#include "libp2p/crypto/ephemeral.h"
#include "libp2p/crypto/sha1.h"
#include "libp2p/crypto/sha256.h"
#include "libp2p/crypto/sha512.h"
#include "libp2p/utils/string_list.h"
#include "libp2p/utils/vector.h"
#include "mbedtls/md.h"
#include "mbedtls/cipher.h"
#include "mbedtls/md_internal.h"
const char* SupportedExchanges = "P-256,P-384,P-521";
const char* SupportedCiphers = "AES-256,AES-128,Blowfish";
const char* SupportedHashes = "SHA256,SHA512";
/***
* Create a new SecureSession struct
* @returns a pointer to a new SecureSession object
*/
struct SecureSession* libp2p_secio_secure_session_new() {
struct SecureSession* ss = (struct SecureSession*) malloc(sizeof(struct SecureSession));
if (ss == NULL)
return NULL;
ss->insecure_stream = NULL;
ss->secure_stream = NULL;
return ss;
}
/***
* Clean up resources from a SecureSession struct
* @param in the SecureSession to be deallocated
*/
void libp2p_secio_secure_session_free(struct SecureSession* in) {
//TODO: should we close the socket?
free(in);
}
/**
* Generate a random nonce
* @param results where to put the results
* @param length the length of the nonce
* @returns true(1) on success, otherwise false(0)
*/
int libp2p_secio_generate_nonce(char* results, int length) {
FILE* fd = fopen("/dev/urandom", "r");
fread(results, 1, length, fd);
fclose(fd);
return 1;
}
/**
* Compute a hash based on a Propose struct
* @param in the struct Propose
* @param result where to put the result (should be char[32])
* @returns true(1) on success
*/
int libp2p_secio_hash(unsigned char* key, size_t key_size, unsigned char* nonce, size_t nonce_size, unsigned char result[32]) {
// append public key and nonce
mbedtls_sha256_context ctx;
libp2p_crypto_hashing_sha256_init(&ctx);
libp2p_crypto_hashing_sha256_update(&ctx, key, key_size);
libp2p_crypto_hashing_sha256_update(&ctx, nonce, nonce_size);
libp2p_crypto_hashing_sha256_finish(&ctx, result);
libp2p_crypto_hashing_sha256_free(&ctx);
return 1;
}
/***
* Compare 2 hashes lexicographically
* @param a the a side
* @param b the b side
* @param length the length of a and b
* @returns a -1, 0, or 1
*/
int libp2p_secio_bytes_compare(const char* a, const char* b, int length) {
for(int i = 0; i < length; i++) {
if (b[i] > a[i])
return -1;
if (a[i] > b[i])
return 1;
}
return 0;
}
int libp2p_secio_string_allocate(char* in, char** out) {
*out = (char*)malloc(strlen(in) + 1);
strcpy(*out, in);
return 1;
}
struct StringList* libp2p_secio_split_list(const char* list, int list_size) {
struct StringList* head = NULL;
struct StringList* last = NULL;
struct StringList* current = NULL;
char* curr_tok = NULL;
// make a copy
char copy[list_size+1];
memcpy(&copy[0], list, list_size);
copy[list_size] = 0;
curr_tok = strtok(copy, ",");
while (curr_tok != NULL) {
current = libp2p_utils_string_list_new();
libp2p_secio_string_allocate(curr_tok, &current->string);
if ( head == NULL) {
head = current;
last = current;
} else {
last->next = current;
}
last = current;
curr_tok = strtok(NULL, ",");
}
return head;
}
/**
* Compare 2 lists, and pick the best one
* @param order which carries more weight
* @param local_list the list to compare
* @param local_list_size the size of the list
* @param remote_list the list to compare
* @param remote_list_size the size of the list
* @param results where to put the results (NOTE: Allocate memory for this)
* @returns true(1) on success, otherwise, false(0)
*/
int libp2p_secio_select_best(int order, const char* local_list, int local_list_size, const char* remote_list, int remote_list_size, char** results) {
struct StringList* lead_head = libp2p_secio_split_list(local_list, local_list_size);
struct StringList* follower_head = NULL;
struct StringList* lead = NULL;
struct StringList* follower = NULL;
int match = 0;
//shortcut
if (order == 0)
{
libp2p_secio_string_allocate(lead_head->string, results);
match = 1;
goto exit;
}
// this list doesn't match. Do further investigation
if (order > 0) { // lead is local
follower_head = libp2p_secio_split_list(remote_list, remote_list_size);
} else {
follower_head = lead_head;
lead_head = libp2p_secio_split_list(remote_list, remote_list_size);
}
lead = lead_head;
follower = follower_head;
// now work through the list, looking for a match
while ( lead != NULL ) {
while (follower != NULL) {
if (strcmp(lead->string, follower->string) == 0) {
libp2p_secio_string_allocate(lead->string, results);
match = 1;
break;
}
follower = follower->next;
}
if (match)
break;
follower = follower_head;
lead = lead->next;
}
exit:
if (lead_head != NULL)
libp2p_utils_string_list_free(lead_head);
if (follower_head != NULL)
libp2p_utils_string_list_free(follower_head);
return match;
}
/**
* Check to see if the signature is correct based on the given bytes in "in"
* @param public_key the public key to use
* @param in the bytes that were signed
* @param in_length the number of bytes
* @param signature the signature that was given to us
* @param signature_length the length of the signature
* @returns true(1) if the signature is correct, false(0) otherwise
*/
int libp2p_secio_verify_signature(struct PublicKey* public_key, const unsigned char* in, size_t in_length, unsigned char* signature) {
if (public_key->type == KEYTYPE_RSA) {
struct RsaPublicKey rsa_key = {0};
rsa_key.der = (char*)public_key->data;
rsa_key.der_length = public_key->data_size;
return libp2p_crypto_rsa_verify(&rsa_key, in, in_length, signature);
}
// TODO: Implement this method for non-RSA
return 0;
}
/**
* Sign data
* @param private_key the key to use
* @param in the bytes to sign
* @param in_length the number of bytes
* @param signature the result
* @param signature_size the size of the result
* @returns true(1) on success, otherwise false(0)
*/
int libp2p_secio_sign(struct PrivateKey* private_key, const char* in, size_t in_length, unsigned char** signature, size_t* signature_size) {
if (private_key->type == KEYTYPE_RSA) {
struct RsaPrivateKey rsa_key = {0};
rsa_key.der = (char*)private_key->data;
rsa_key.der_length = private_key->data_size;
return libp2p_crypto_rsa_sign(&rsa_key, in, in_length, signature, signature_size);
}
// TODO: Implement this method for non-RSA
return 0;
}
/**
* Generate 2 keys by stretching the secret key
* @param cipherType the cipher type (i.e. "AES-128")
* @param hashType the hash type (i.e. "SHA256")
* @param secret the secret key
* @param secret_size the length of the secret key
* @param k1 one of the resultant keys
* @param k2 one of the resultant keys
* @returns true(1) on success, otherwise 0 (false)
*/
int libp2p_secio_stretch_keys(char* cipherType, char* hashType, unsigned char* secret, size_t secret_size, struct StretchedKey** k1_ptr, struct StretchedKey** k2_ptr) {
int retVal = 0, num_filled = 0, hmac_size = 20;
struct StretchedKey* k1;
struct StretchedKey* k2;
unsigned char* result = NULL;;
size_t result_size = 0;
char* seed = "key expansion";
unsigned char* temp = NULL;
unsigned char a_hash[32];
unsigned char b_hash[32];
k1 = libp2p_crypto_ephemeral_stretched_key_new();
if (k1 == NULL)
goto exit;
k2 = libp2p_crypto_ephemeral_stretched_key_new();
if (k2_ptr == NULL)
goto exit;
// pick the right cipher
if (strcmp(cipherType, "AES-128") == 0) {
k1->iv_size = 16;
k2->iv_size = 16;
k1->cipher_size = 16;
k2->cipher_size = 16;
} else if (strcmp(cipherType, "AES-256") == 0) {
k1->iv_size = 16;
k2->iv_size = 16;
k1->cipher_size = 32;
k2->cipher_size = 32;
} else if (strcmp(cipherType, "Blowfish") == 0) {
k1->iv_size = 8;
k2->iv_size = 8;
k1->cipher_size = 32;
k2->cipher_size = 32;
} else {
goto exit;
}
// pick the right hash
// TODO: this
/*
if (strcmp(hashType, "SHA1") == 0) {
hash_func = libp2p_crypto_hashing_sha1;
hash_size = 40;
} else if (strcmp(hashType, "SHA256") == 0) {
hash_func = libp2p_crypto_hashing_sha256;
hash_size = 32;
} else if (strcmp(hashType, "SHA512") == 0) {
hash_func = libp2p_crypto_hashing_sha512;
hash_size = 64;
} else {
goto exit;
}
*/
//TODO: make this work for all hashes, not just SHA256
result_size = 2 * (k1->iv_size + k1->cipher_size * hmac_size);
result = malloc(result_size);
if (result == NULL)
goto exit;
mbedtls_md_context_t ctx;
mbedtls_md_setup(&ctx, &mbedtls_sha256_info, 1);
mbedtls_md_hmac_starts(&ctx, secret, secret_size);
mbedtls_md_hmac_update(&ctx, (unsigned char*)seed, strlen(seed));
mbedtls_md_hmac_finish(&ctx, a_hash);
// now we have our first hash. Begin to fill the result buffer
while (num_filled < result_size) {
mbedtls_md_hmac_reset(&ctx);
mbedtls_md_hmac_update(&ctx, a_hash, 32);
mbedtls_md_hmac_update(&ctx, (unsigned char*)seed, strlen(seed));
mbedtls_md_hmac_finish(&ctx, b_hash);
int todo = 32;
if (todo + num_filled > result_size)
todo = result_size - num_filled;
memcpy(&result[num_filled], b_hash, todo);
num_filled += todo;
mbedtls_md_hmac_reset(&ctx);
mbedtls_md_hmac_update(&ctx, a_hash, 32);
mbedtls_md_hmac_finish(&ctx, a_hash);
}
// now we have a big result. Cut it up into pieces
if (temp != NULL)
free(temp);
temp = result;
k1->mac_size = hmac_size;
k1->iv = malloc(k1->iv_size);
memcpy(k1->iv, temp, k1->iv_size);
temp += k1->iv_size;
k1->cipher_key = malloc(k1->cipher_size);
memcpy(k1->cipher_key, temp, k1->cipher_size);
temp += k1->cipher_size;
k1->mac_key = malloc(k1->mac_size);
memcpy(k1->mac_key, temp, k1->mac_size);
temp += k1->mac_size;
k2->mac_size = hmac_size;
k2->iv = malloc(k2->iv_size);
memcpy(k2->iv, temp, k2->iv_size);
temp += k2->iv_size;
k2->cipher_key = malloc(k2->cipher_size);
memcpy(k2->cipher_key, temp, k2->cipher_size);
temp += k2->cipher_size;
k2->mac_key = malloc(k2->mac_size);
memcpy(k2->mac_key, temp, k2->mac_size);
temp += k2->mac_size;
temp = NULL;
retVal = 1;
// cleanup
exit:
*k1_ptr = k1;
*k2_ptr = k2;
if (retVal != 1) {
if (*k1_ptr != NULL)
libp2p_crypto_ephemeral_stretched_key_free(*k1_ptr);
if (*k2_ptr != NULL)
libp2p_crypto_ephemeral_stretched_key_free(*k2_ptr);
*k1_ptr = NULL;
*k2_ptr = NULL;
}
if (temp != NULL)
free(temp);
if (result != NULL)
free(result);
return retVal;
}
int libp2p_secio_make_mac_and_cipher(struct SecureSession* session, struct StretchedKey* stretched_key) {
// mac
if (strcmp(session->chosen_hash, "SHA1") == 0) {
stretched_key->mac_size = 40;
} else if (strcmp(session->chosen_hash, "SHA512") == 0) {
stretched_key->mac_size = 64;
} else if (strcmp(session->chosen_hash, "SHA256") == 0) {
//stretched_key->mac_size = 32;
} else {
return 0;
}
//TODO: Research this question..
// this was already made during the key stretch. Why make it again?
/*
stretched_key->mac_key = malloc(stretched_key->mac_size);
session->mac_function(stretched_key->cipher_key, stretched_key->cipher_size, stretched_key->mac_key);
*/
// block cipher
if (strcmp(session->chosen_cipher, "AES-128") || strcmp(session->chosen_cipher, "AES-256") == 0) {
//we already have the key
} else if (strcmp(session->chosen_cipher, "Blowfish") == 0) {
//TODO: Implement blowfish
return 0;
} else {
return 0;
}
//TODO: set up the encrypted streams
return 1;
}
/***
* Write bytes to an unencrypted stream
* @param session the session information
* @param bytes the bytes to write
* @param data_length the number of bytes to write
* @returns the number of bytes written
*/
int libp2p_secio_unencrypted_write(struct SecureSession* session, unsigned char* bytes, size_t data_length) {
int num_bytes = 0;
if (data_length > 0) { // only do this is if there is something to send
// first send the size
uint32_t size = htonl(data_length);
char* size_as_char = (char*)&size;
int left = 4;
int written = 0;
int written_this_time = 0;
do {
written_this_time = socket_write(*((int*)session->insecure_stream->socket_descriptor), &size_as_char[written], left, 0);
if (written_this_time < 0) {
written_this_time = 0;
if ( (errno == EAGAIN) || (errno == EWOULDBLOCK)) {
// TODO: use epoll or select to wait for socket to be writable
} else {
return 0;
}
}
left = left - written_this_time;
} while (left > 0);
// then send the actual data
left = data_length;
written = 0;
do {
written_this_time = socket_write(*((int*)session->insecure_stream->socket_descriptor), (char*)&bytes[written], left, 0);
if (written_this_time < 0) {
written_this_time = 0;
if ( (errno == EAGAIN) || (errno == EWOULDBLOCK)) {
// TODO: use epoll or select to wait for socket to be writable
} else {
return 0;
}
}
left = left - written_this_time;
written += written_this_time;
} while (left > 0);
num_bytes = written;
} // there was something to send
return num_bytes;
}
/***
* Read bytes from the incoming stream
* @param session the session information
* @param results where to put the bytes read
* @param results_size the size of the results
* @returns the number of bytes read
*/
int libp2p_secio_unencrypted_read(struct SecureSession* session, unsigned char** results, size_t* results_size) {
uint32_t buffer_size;
// first read the 4 byte integer
char* size = (char*)&buffer_size;
int left = 4;
int read = 0;
int read_this_time = 0;
do {
read_this_time = socket_read(*((int*)session->insecure_stream->socket_descriptor), &size[read], 1, 0);
if (read_this_time < 0) {
read_this_time = 0;
if ( (errno == EAGAIN) || (errno == EWOULDBLOCK)) {
// TODO: use epoll or select to wait for socket to be writable
} else {
fprintf(stderr, "Error in libp2p_secio_unencrypted_read: %s\n", strerror(errno));
return 0;
}
}
if (read == 0 && size[0] == 10) {
// a spurious \n
// write over this value by not adding it
} else {
left = left - read_this_time;
read += read_this_time;
}
} while (left > 0);
buffer_size = ntohl(buffer_size);
if (buffer_size == 0)
return 0;
// now read the number of bytes we've found, minus the 4 that we just read
left = buffer_size;
read = 0;
read_this_time = 0;
*results = malloc(left);
unsigned char* ptr = *results;
do {
read_this_time = socket_read(*((int*)session->insecure_stream->socket_descriptor), (char*)&ptr[read], left, 0);
if (read_this_time < 0) {
read_this_time = 0;
if ( (errno == EAGAIN) || (errno == EWOULDBLOCK)) {
// TODO: use epoll or select to wait for socket to be writable
} else {
return 0;
}
}
left = left - read_this_time;
} while (left > 0);
*results_size = buffer_size;
return buffer_size;
}
/**
* Encrypt data before being sent out an insecure stream
* @param session the session information
* @param incoming the incoming data
* @param incoming_size the size of the incoming data
* @param outgoing where to put the results
* @param outgoing_size the amount of memory allocated
* @returns true(1) on success, otherwise false(0)
*/
int libp2p_secio_encrypt(const struct SecureSession* session, const unsigned char* incoming, size_t incoming_size, unsigned char** outgoing, size_t* outgoing_size) {
unsigned char* buffer = NULL;
size_t buffer_size = 0;
//TODO switch between ciphers
mbedtls_cipher_context_t cipher_ctx;
mbedtls_cipher_init(&cipher_ctx);
mbedtls_cipher_setup(&cipher_ctx, mbedtls_cipher_info_from_type(MBEDTLS_CIPHER_AES_256_CTR));
mbedtls_cipher_setkey(&cipher_ctx, session->local_stretched_key->cipher_key, session->local_stretched_key->cipher_size * 8, MBEDTLS_ENCRYPT);
buffer_size = incoming_size + mbedtls_cipher_get_block_size(&cipher_ctx) + 32;
buffer = malloc(buffer_size);
memset(buffer, 0, buffer_size);
mbedtls_cipher_crypt(&cipher_ctx, session->local_stretched_key->iv, session->local_stretched_key->iv_size, incoming, incoming_size, buffer, &buffer_size);
mbedtls_cipher_free(&cipher_ctx);
// mac the data, and append it
mbedtls_md_context_t ctx;
mbedtls_md_setup(&ctx, &mbedtls_sha256_info, 1);
mbedtls_md_hmac_starts(&ctx, session->local_stretched_key->mac_key, session->local_stretched_key->mac_size);
mbedtls_md_hmac_update(&ctx, buffer, buffer_size);
mbedtls_md_hmac_finish(&ctx, &buffer[buffer_size]);
mbedtls_md_free(&ctx);
// put it all in outgoing
*outgoing_size = buffer_size + 32;
*outgoing = malloc(*outgoing_size);
memcpy(*outgoing, buffer, *outgoing_size);
free(buffer);
return 1;
}
/**
* Write to an encrypted stream
* @param session the session parameters
* @param bytes the bytes to write
* @param num_bytes the number of bytes to write
* @returns the number of bytes written
*/
int libp2p_secio_encrypted_write(void* stream_context, const unsigned char* bytes, size_t num_bytes) {
struct SecureSession* session = (struct SecureSession*) stream_context;
// writer uses the local cipher and mac
unsigned char* buffer = NULL;
size_t buffer_size = 0;
if (!libp2p_secio_encrypt(session, bytes, num_bytes, &buffer, &buffer_size))
return 0;
int retVal = libp2p_secio_unencrypted_write(session, buffer, buffer_size);
free(buffer);
return retVal;
}
/**
* Unencrypt data that was read from the stream
* @param session the session information
* @param incoming the incoming bytes
* @param incoming_size the number of incoming bytes
* @param outgoing where to put the results
* @param outgoing_size the amount of memory allocated for the results
* @returns number of unencrypted bytes
*/
int libp2p_secio_decrypt(const struct SecureSession* session, const unsigned char* incoming, size_t incoming_size, unsigned char** outgoing, size_t* outgoing_size) {
size_t data_section_size = incoming_size - 32;
*outgoing_size = 0;
unsigned char* buffer;
size_t buffer_size;
// verify MAC
//TODO make this more generic to use more than SHA256
mbedtls_md_context_t ctx;
mbedtls_md_setup(&ctx, &mbedtls_sha256_info, 1);
mbedtls_md_hmac_starts(&ctx, session->remote_stretched_key->mac_key, session->remote_stretched_key->mac_size);
mbedtls_md_hmac_update(&ctx, incoming, data_section_size);
unsigned char generated_mac[32];
mbedtls_md_hmac_finish(&ctx, generated_mac);
mbedtls_md_free(&ctx);
// 2. check the mac to see if it is the same
int retVal = memcmp(&incoming[data_section_size], generated_mac, 32);
if (retVal != 0)
return 0;
mbedtls_cipher_context_t cipher_ctx;
mbedtls_cipher_init(&cipher_ctx);
mbedtls_cipher_setup(&cipher_ctx, mbedtls_cipher_info_from_type(MBEDTLS_CIPHER_AES_256_CTR));
mbedtls_cipher_setkey(&cipher_ctx, session->remote_stretched_key->cipher_key, session->remote_stretched_key->cipher_size * 8, MBEDTLS_DECRYPT);
mbedtls_cipher_set_iv(&cipher_ctx, session->remote_stretched_key->iv, session->remote_stretched_key->iv_size);
buffer_size = data_section_size + mbedtls_cipher_get_block_size(&cipher_ctx);
buffer = malloc(buffer_size);
mbedtls_cipher_update(&cipher_ctx, incoming, data_section_size, buffer, &buffer_size);
*outgoing = malloc(buffer_size);
*outgoing_size = buffer_size;
memcpy(*outgoing, buffer, buffer_size);
return *outgoing_size;
}
/**
* Read from an encrypted stream
* @param session the session parameters
* @param bytes where the bytes will be stored
* @param num_bytes the number of bytes read from the stream
* @returns the number of bytes read
*/
int libp2p_secio_encrypted_read(void* stream_context, unsigned char** bytes, size_t* num_bytes) {
struct SecureSession* session = (struct SecureSession*)stream_context;
// reader uses the remote cipher and mac
// read the data
unsigned char* incoming = NULL;
size_t incoming_size = 0;
if (libp2p_secio_unencrypted_read(session, &incoming, &incoming_size) <= 0)
return 0;
return libp2p_secio_decrypt(session, incoming, incoming_size, bytes, num_bytes);
}
/***
* performs initial communication over an insecure channel to share
* keys, IDs, and initiate connection. This is a framed messaging system
* NOTE: session must contain a valid socket_descriptor that is a multistream.
* @param local_session the secure session to be filled
* @param private_key our private key to use
* @param remote_requested it is the other side that requested the upgrade to secio
* @returns true(1) on success, false(0) otherwise
*/
int libp2p_secio_handshake(struct SecureSession* local_session, struct RsaPrivateKey* private_key, int remote_requested) {
int retVal = 0;
size_t results_size = 0, bytes_written = 0;
unsigned char* propose_in_bytes = NULL; // the remote protobuf
size_t propose_in_size = 0;
unsigned char* propose_out_bytes = NULL; // the local protobuf
size_t propose_out_size = 0;
unsigned char* results = NULL;
struct Propose* propose_out = NULL;
struct Propose* propose_in = NULL;
struct PublicKey* public_key = NULL;
unsigned char order_hash_in[32] = {0};
unsigned char order_hash_out[32] = {0};
int order = 0;;
struct Exchange* exchange_in = NULL;
struct Exchange* exchange_out = NULL;
unsigned char* exchange_out_protobuf = NULL;
size_t exchange_out_protobuf_size = 0;
char* char_buffer = NULL;
size_t char_buffer_length = 0;
struct StretchedKey* k1 = NULL, *k2 = NULL;
struct PrivateKey* priv = NULL;
struct PublicKey pub_key = {0};
char* remote_peer_id = NULL;
//TODO: make sure we're not talking to ourself
// prepare the multistream send of the protocol ID
const unsigned char* protocol = (unsigned char*)"/secio/1.0.0\n";
int protocol_len = strlen((char*)protocol);
unsigned char* total = malloc(protocol_len + propose_out_size);
memcpy(total, protocol, protocol_len);
memcpy(&total[protocol_len], propose_out_bytes, propose_out_size);
bytes_written = libp2p_net_multistream_write(local_session, total, protocol_len + propose_out_size);
free(total);
if (bytes_written <= 0)
goto exit;
if (!remote_requested) {
// we should get back the secio confirmation
bytes_written = libp2p_net_multistream_read(local_session, &results, &results_size);
if (bytes_written < 5 || strstr((char*)results, "secio") == NULL)
goto exit;
free(results);
results = NULL;
results_size = 0;
}
// generate 16 byte nonce
if (!libp2p_secio_generate_nonce(&local_session->local_nonce[0], 16)) {
goto exit;
}
// Build the proposal to be sent to the new connection:
propose_out = libp2p_secio_propose_new();
libp2p_secio_propose_set_property((void**)&propose_out->rand, &propose_out->rand_size, local_session->local_nonce, 16);
// public key - protobuf it and stick it in propose_out
pub_key.type = KEYTYPE_RSA;
pub_key.data_size = private_key->public_key_length;
pub_key.data = malloc(pub_key.data_size);
memcpy(pub_key.data, private_key->public_key_der, private_key->public_key_length);
results_size = libp2p_crypto_public_key_protobuf_encode_size(&pub_key);
results = malloc(results_size);
if (results == NULL) {
free(pub_key.data);
goto exit;
}
if (libp2p_crypto_public_key_protobuf_encode(&pub_key, results, results_size, &results_size) == 0) {
free(pub_key.data);
goto exit;
}
free(pub_key.data);
propose_out->public_key_size = results_size;
propose_out->public_key = malloc(results_size);
memcpy(propose_out->public_key, results, results_size);
free(results);
results = NULL;
results_size = 0;
// supported exchanges
libp2p_secio_propose_set_property((void**)&propose_out->exchanges, &propose_out->exchanges_size, SupportedExchanges, strlen(SupportedExchanges));
// supported ciphers
libp2p_secio_propose_set_property((void**)&propose_out->ciphers, &propose_out->ciphers_size, SupportedCiphers, strlen(SupportedCiphers));
// supported hashes
libp2p_secio_propose_set_property((void**)&propose_out->hashes, &propose_out->hashes_size, SupportedHashes, strlen(SupportedHashes));
// send proposal
propose_out_size = libp2p_secio_propose_protobuf_encode_size(propose_out);
propose_out_bytes = (unsigned char*)malloc(propose_out_size);
if (libp2p_secio_propose_protobuf_encode(propose_out, propose_out_bytes, propose_out_size, &propose_out_size) == 0)
goto exit;
bytes_written = libp2p_secio_unencrypted_write(local_session, propose_out_bytes, propose_out_size);
if (bytes_written < propose_out_size)
goto exit;
// now receive the proposal from the new connection
bytes_written = libp2p_secio_unencrypted_read(local_session, &propose_in_bytes, &propose_in_size);
if (bytes_written <= 0)
goto exit;
if (!libp2p_secio_propose_protobuf_decode(propose_in_bytes, propose_in_size, &propose_in))
goto exit;
// get their nonce
if (propose_in->rand_size != 16)
goto exit;
memcpy(local_session->remote_nonce, propose_in->rand, 16);
// get public key and put it in a struct PublicKey
if (!libp2p_crypto_public_key_protobuf_decode(propose_in->public_key, propose_in->public_key_size, &public_key))
goto exit;
// generate their peer id
libp2p_crypto_public_key_to_peer_id(public_key, &remote_peer_id);
// negotiate encryption parameters NOTE: SelectBest must match, otherwise this won't work
// first determine order
libp2p_secio_hash(propose_in->public_key, propose_in->public_key_size, propose_out->rand, propose_out->rand_size, order_hash_in);
libp2p_secio_hash(propose_out->public_key, propose_out->public_key_size, propose_in->rand, propose_in->rand_size, order_hash_out);
order = libp2p_secio_bytes_compare((char*)order_hash_in, (char*)order_hash_out, 32);
// curve
if (libp2p_secio_select_best(order, propose_out->exchanges, propose_out->exchanges_size, propose_in->exchanges, propose_in->exchanges_size, &local_session->chosen_curve) == 0)
goto exit;
// cipher
if (libp2p_secio_select_best(order, propose_out->ciphers, propose_out->ciphers_size, propose_in->ciphers, propose_in->ciphers_size, &local_session->chosen_cipher) == 0)
goto exit;
// hash
if (libp2p_secio_select_best(order, propose_out->hashes, propose_out->hashes_size, propose_in->hashes, propose_in->hashes_size, &local_session->chosen_hash) == 0)
goto exit;
// generate EphemeralPubKey
if (libp2p_crypto_ephemeral_keypair_generate(local_session->chosen_curve, &local_session->ephemeral_private_key) == 0)
goto exit;
// build buffer to sign
char_buffer_length = propose_in_size + propose_out_size + local_session->ephemeral_private_key->public_key->bytes_size - 1;
char_buffer = malloc(char_buffer_length);
if (char_buffer == NULL)
goto exit;
memcpy(&char_buffer[0], propose_out_bytes, propose_out_size);
memcpy(&char_buffer[propose_out_size], propose_in_bytes, propose_in_size);
memcpy(&char_buffer[propose_in_size + propose_out_size], &local_session->ephemeral_private_key->public_key->bytes[1], local_session->ephemeral_private_key->public_key->bytes_size-1);
// send Exchange packet
exchange_out = libp2p_secio_exchange_new();
if (exchange_out == NULL)
goto exit;
// don't send the first byte (to stay compatible with GO version)
exchange_out->epubkey = (unsigned char*)malloc(local_session->ephemeral_private_key->public_key->bytes_size - 1);
if (exchange_out->epubkey == NULL)
goto exit;
memcpy(exchange_out->epubkey, &local_session->ephemeral_private_key->public_key->bytes[1], local_session->ephemeral_private_key->public_key->bytes_size - 1);
exchange_out->epubkey_size = local_session->ephemeral_private_key->public_key->bytes_size - 1;
priv = libp2p_crypto_private_key_new();
priv->type = KEYTYPE_RSA;
priv->data = (unsigned char*)private_key->der;
priv->data_size = private_key->der_length;
libp2p_secio_sign(priv, char_buffer, char_buffer_length, &exchange_out->signature, &exchange_out->signature_size);
free(char_buffer);
char_buffer = NULL;
// yes, this is an improper disposal, but it gets the job done without fuss
free(priv);
exchange_out_protobuf_size = libp2p_secio_exchange_protobuf_encode_size(exchange_out);
exchange_out_protobuf = (unsigned char*)malloc(exchange_out_protobuf_size);
if (exchange_out_protobuf == NULL)
goto exit;
libp2p_secio_exchange_protobuf_encode(exchange_out, exchange_out_protobuf, exchange_out_protobuf_size, &bytes_written);
exchange_out_protobuf_size = bytes_written;
bytes_written = libp2p_secio_unencrypted_write(local_session, exchange_out_protobuf, exchange_out_protobuf_size);
if (exchange_out_protobuf_size != bytes_written)
goto exit;
free(exchange_out_protobuf);
exchange_out_protobuf = NULL;
// end of send Exchange packet
// receive Exchange packet
bytes_written = libp2p_secio_unencrypted_read(local_session, &results, &results_size);
if (bytes_written == 0)
goto exit;
libp2p_secio_exchange_protobuf_decode(results, results_size, &exchange_in);
free(results);
results = NULL;
// end of receive Exchange packet
// parse and verify
local_session->remote_ephemeral_public_key_size = exchange_in->epubkey_size + 1;
local_session->remote_ephemeral_public_key = malloc(local_session->remote_ephemeral_public_key_size);
local_session->remote_ephemeral_public_key[0] = exchange_in->epubkey_size;
memcpy(&local_session->remote_ephemeral_public_key[1], exchange_in->epubkey, exchange_in->epubkey_size);
// signature verification
char_buffer_length = propose_in_size + propose_out_size + local_session->remote_ephemeral_public_key_size - 1;
char_buffer = malloc(char_buffer_length);
if (char_buffer == NULL)
goto exit;
memcpy(&char_buffer[0], propose_in_bytes, propose_in_size);
memcpy(&char_buffer[propose_in_size], propose_out_bytes, propose_out_size);
memcpy(&char_buffer[propose_in_size + propose_out_size], &local_session->remote_ephemeral_public_key[1], local_session->remote_ephemeral_public_key_size - 1);
if (!libp2p_secio_verify_signature(public_key, (unsigned char*)char_buffer, char_buffer_length, exchange_in->signature))
goto exit;
free(char_buffer);
char_buffer = NULL;
// 2.2 generate shared key
if (!libp2p_crypto_ephemeral_generate_shared_secret(local_session->ephemeral_private_key, local_session->remote_ephemeral_public_key, local_session->remote_ephemeral_public_key_size))
goto exit;
local_session->shared_key_size = local_session->ephemeral_private_key->public_key->shared_key_size;
local_session->shared_key = malloc(local_session->shared_key_size);
memcpy(local_session->shared_key, local_session->ephemeral_private_key->public_key->shared_key, local_session->shared_key_size);
// generate 2 sets of keys (stretching)
if (!libp2p_secio_stretch_keys(local_session->chosen_cipher, local_session->chosen_hash, local_session->shared_key, local_session->shared_key_size, &k1, &k2))
goto exit;
if (order > 1) {
local_session->local_stretched_key = k1;
local_session->remote_stretched_key = k2;
} else {
local_session->local_stretched_key = k2;
local_session->remote_stretched_key = k1;
}
// prepare MAC + cipher
if (strcmp(local_session->chosen_hash, "SHA1") == 0) {
local_session->mac_function = libp2p_crypto_hashing_sha1;
} else if (strcmp(local_session->chosen_hash, "SHA512") == 0) {
local_session->mac_function = libp2p_crypto_hashing_sha512;
} else if (strcmp(local_session->chosen_hash, "SHA256") == 0) {
local_session->mac_function = libp2p_crypto_hashing_sha256;
} else {
return 0;
}
libp2p_secio_make_mac_and_cipher(local_session, local_session->local_stretched_key);
libp2p_secio_make_mac_and_cipher(local_session, local_session->remote_stretched_key);
// send expected message (their nonce) to verify encryption works
if (libp2p_secio_encrypted_write(local_session, (unsigned char*)local_session->remote_nonce, 16) <= 0)
goto exit;
// receive our nonce to verify encryption works
if (libp2p_secio_encrypted_read(local_session, &results, &results_size) <= 0)
goto exit;
if (results_size != 16)
goto exit;
if (libp2p_secio_bytes_compare((char*)results, local_session->local_nonce, 16) != 0)
goto exit;
// set up the secure stream in the struct
local_session->secure_stream = libp2p_net_multistream_stream_new(*((int*)local_session->insecure_stream->socket_descriptor));
local_session->secure_stream->read = libp2p_secio_encrypted_read;
local_session->secure_stream->write = libp2p_secio_encrypted_write;
// set secure as default
local_session->default_stream = local_session->secure_stream;
retVal = 1;
exit:
if (propose_in_bytes != NULL)
free(propose_in_bytes);
if (propose_out_bytes != NULL)
free(propose_out_bytes);
if (results != NULL)
free(results);
if (char_buffer != NULL)
free(char_buffer);
if (public_key != NULL)
libp2p_crypto_public_key_free(public_key);
if (remote_peer_id != NULL)
free(remote_peer_id);
if (exchange_out != NULL)
libp2p_secio_exchange_free(exchange_out);
if (exchange_out_protobuf != NULL)
free(exchange_out_protobuf);
if (exchange_in != NULL)
libp2p_secio_exchange_free(exchange_in);
libp2p_secio_propose_free(propose_out);
libp2p_secio_propose_free(propose_in);
return retVal;
}