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8 changed files with 27 additions and 130 deletions

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@ -1,9 +1,6 @@
MIT License MIT License
Copyright (c) 2019 AGORISE, LTD. Copyright (c) 2017 BitShares Munich IVS
An International Business Company, Cyprus Reg# ΗΕ375959
Contains works from BitShares Munich IVS
Permission is hereby granted, free of charge, to any person obtaining a copy Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal of this software and associated documentation files (the "Software"), to deal

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@ -9,7 +9,7 @@
* @param binary_data_size the size of the results buffer * @param binary_data_size the size of the results buffer
* @returns true(1) on success * @returns true(1) on success
*/ */
int multiaddr_encoding_base58_decode(const char* base58, size_t base58_size, unsigned char** binary_data, size_t *binary_data_size); int multiaddr_encoding_base58_decode(const unsigned char* base58, size_t base58_size, unsigned char** binary_data, size_t *binary_data_size);
/** /**
* encode an array of bytes into a base58 string * encode an array of bytes into a base58 string

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@ -87,20 +87,4 @@ int multiaddress_get_ip_port(const struct MultiAddress* in);
*/ */
char* multiaddress_get_peer_id(const struct MultiAddress* in); char* multiaddress_get_peer_id(const struct MultiAddress* in);
/**
* Check to see how these two addresses compare
* @param a side A
* @param b side B
* @returns <0 if B > A; >0 if A > B; 0 if A == B
*/
int multiaddress_compare(const struct MultiAddress* a, const struct MultiAddress* b);
/**
* Check to see how these two addresses compare, ignoring IP address, only looking at ID hash
* @param a side A
* @param b side B
* @returns <0 if B > A; >0 if A > B; 0 if A == B
*/
int multiaddress_compare_id(const struct MultiAddress* a, const struct MultiAddress* b);
#endif #endif

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@ -53,7 +53,7 @@ struct MultiAddress* multiaddress_new_from_bytes(const uint8_t* byteaddress, int
} }
out->bsize = size; out->bsize = size;
memcpy(out->bytes, byteaddress, size); memcpy(out->bytes, byteaddress, size);
if(!bytes_to_string(&out->string,byteaddress,size)) if(!bytes_to_string(&out->string,byteaddress,size)==1)
{ {
multiaddress_free(out); multiaddress_free(out);
return NULL; return NULL;
@ -347,51 +347,3 @@ int multiaddress_decapsulate(struct MultiAddress * result, char * srci)
} }
} }
/**
* Check to see how these two addresses compare
* @param a side A
* @param b side B
* @returns <0 if B > A; >0 if A > B; 0 if A == B
*/
int multiaddress_compare(const struct MultiAddress* a, const struct MultiAddress* b) {
if (a == NULL && b == NULL)
return 0;
if (a == NULL && b != NULL)
return -1;
if (a != NULL && b == NULL)
return 1;
int total = b->bsize - a->bsize;
if (total != 0)
return total;
for(size_t i = 0; i < b->bsize; i++) {
total = b->bytes[i] - a->bytes[i];
if (total != 0)
return total;
}
return 0;
}
/**
* Check to see how these two addresses compare, ignoring IP address,
* only looking at the first /ipfs/ID hash
* @param a side A
* @param b side B
* @returns <0 if B > A; >0 if A > B; 0 if A == B
*/
int multiaddress_compare_id(const struct MultiAddress* a, const struct MultiAddress* b) {
char* a_id = multiaddress_get_peer_id(a);
char* b_id = multiaddress_get_peer_id(b);
if (a_id == NULL && b_id == NULL)
return 0;
if (a_id == NULL && b_id != NULL)
return -1;
if (a_id != NULL && b_id == NULL)
return 1;
int retVal = strcmp(a_id, b_id);
if (a_id != NULL)
free(a_id);
if (b_id != NULL)
free(b_id);
return retVal;
}

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@ -172,7 +172,7 @@ int is_valid_ipv6(char *str)
{ {
str++; str++;
if(ishexdigit(*str) || (*str==0 && hncount < MAX_HEX_NUMBER_COUNT )) if(ishexdigit(*str)||*str==0&&hncount<MAX_HEX_NUMBER_COUNT)
{ {
packed=1; packed=1;
hncount++; hncount++;
@ -299,7 +299,6 @@ char * int2ip(int inputintip)
* @param results where to put the resultant string * @param results where to put the resultant string
* @param in_bytes the bytes to unserialize * @param in_bytes the bytes to unserialize
* @param in_bytes_size the length of the bytes array * @param in_bytes_size the length of the bytes array
* @returns 0 on error, otherwise 1
*/ */
int bytes_to_string(char** buffer, const uint8_t* in_bytes, int in_bytes_size) int bytes_to_string(char** buffer, const uint8_t* in_bytes, int in_bytes_size)
{ {
@ -315,7 +314,7 @@ int bytes_to_string(char** buffer, const uint8_t* in_bytes, int in_bytes_size)
// set up variables // set up variables
load_protocols(&head); load_protocols(&head);
memset(hex, 0, (in_bytes_size * 2) + 1); memset(hex, 0, (in_bytes_size * 2) + 1);
char* tmp = (char*)Var_To_Hex((char*)in_bytes, size); char* tmp = Var_To_Hex(in_bytes, size);
memcpy(hex, tmp, in_bytes_size * 2); memcpy(hex, tmp, in_bytes_size * 2);
free(tmp); free(tmp);
pid[2] = 0; pid[2] = 0;
@ -392,8 +391,8 @@ int bytes_to_string(char** buffer, const uint8_t* in_bytes, int in_bytes_size)
memcpy(IPFS_ADDR, &hex[lastpos], addrsize); memcpy(IPFS_ADDR, &hex[lastpos], addrsize);
// convert the address from hex values to a binary array // convert the address from hex values to a binary array
size_t num_bytes = 0; size_t num_bytes = 0;
unsigned char* addrbuf = Hex_To_Var((char*)IPFS_ADDR, &num_bytes); unsigned char* addrbuf = Hex_To_Var(IPFS_ADDR, &num_bytes);
size_t b58_size = strlen((char*)IPFS_ADDR); size_t b58_size = strlen(IPFS_ADDR);
unsigned char b58[b58_size]; unsigned char b58[b58_size];
memset(b58, 0, b58_size); memset(b58, 0, b58_size);
unsigned char *ptr_b58 = b58; unsigned char *ptr_b58 = b58;
@ -408,7 +407,7 @@ int bytes_to_string(char** buffer, const uint8_t* in_bytes, int in_bytes_size)
strcat(results, "/"); strcat(results, "/");
strcat(results, protocol->name); strcat(results, protocol->name);
strcat(results, "/"); strcat(results, "/");
strcat(results, (char*)b58); strcat(results, b58);
} }
} }
strcat(results, "/"); strcat(results, "/");
@ -638,7 +637,7 @@ int string_to_bytes(uint8_t** finalbytes, size_t* realbbsize, const char* strx,
{ {
if(strx[0] != '/') if(strx[0] != '/')
{ {
fprintf(stderr, "multiaddr:string_to_bytes: Error, must start with '/' : [%s].\n", strx); printf("Error, must start with '/'\n");
return 0; return 0;
} }
@ -685,7 +684,7 @@ int string_to_bytes(uint8_t** finalbytes, size_t* realbbsize, const char* strx,
{ {
char* s_to_b = NULL; char* s_to_b = NULL;
int s_to_b_size = 0; int s_to_b_size = 0;
if( strcmp(address_string_to_bytes(protx, wp,strlen(wp), &s_to_b, &s_to_b_size), "ERR") == 0) if(address_string_to_bytes(protx, wp,strlen(wp), &s_to_b, &s_to_b_size) == "ERR")
{ {
malf = 1; malf = 1;
} }

View file

@ -3,27 +3,6 @@
#include "multiaddr/multiaddr.h" #include "multiaddr/multiaddr.h"
#include "multiaddr/varhexutils.h" #include "multiaddr/varhexutils.h"
int test_new_like_libp2p() {
int retVal = 0;
char* ip = "10.211.55.2";
int port = 4001;
char str[strlen(ip) + 50];
sprintf(str, "/ip4/%s/tcp/%d/", ip, port);
struct MultiAddress* ma_string = multiaddress_new_from_string(str);
// convert to binary
struct MultiAddress* ma_binary = multiaddress_new_from_bytes(ma_string->bytes, ma_string->bsize);
if (strcmp(ma_string->string, ma_binary->string) != 0) {
fprintf(stderr, "%s does not equal %s\n", ma_string->string, ma_binary->string);
goto exit;
}
retVal = 1;
exit:
multiaddress_free(ma_string);
multiaddress_free(ma_binary);
return retVal;
}
int test_new_from_string() { int test_new_from_string() {
struct MultiAddress* a = multiaddress_new_from_string("/ip4/127.0.0.1/tcp/8080/"); struct MultiAddress* a = multiaddress_new_from_string("/ip4/127.0.0.1/tcp/8080/");
printf("Number of Bytes: %lu, Bytes: ", a->bsize); printf("Number of Bytes: %lu, Bytes: ", a->bsize);
@ -41,7 +20,7 @@ int test_full() {
printf("INITIAL: %s\n",addrstr); printf("INITIAL: %s\n",addrstr);
struct MultiAddress* a; struct MultiAddress* a;
a= multiaddress_new_from_string(addrstr); a= multiaddress_new_from_string(addrstr);
unsigned char* tmp = Var_To_Hex((char*)a->bytes, a->bsize); unsigned char* tmp = Var_To_Hex(a->bytes, a->bsize);
printf("TEST BYTES: %s\n", tmp); printf("TEST BYTES: %s\n", tmp);
free(tmp); free(tmp);
@ -50,19 +29,19 @@ int test_full() {
printf("A STRING:%s\n",a->string); printf("A STRING:%s\n",a->string);
multiaddress_encapsulate(a,"/udp/3333/"); multiaddress_encapsulate(a,"/udp/3333/");
printf("A STRING ENCAPSULATED:%s\n",a->string); printf("A STRING ENCAPSULATED:%s\n",a->string);
tmp = Var_To_Hex((char*)a->bytes, a->bsize); tmp = Var_To_Hex(a->bytes, a->bsize);
printf("TEST BYTES: %s\n", tmp); printf("TEST BYTES: %s\n", tmp);
free(tmp); free(tmp);
multiaddress_decapsulate(a,"udp"); multiaddress_decapsulate(a,"udp");
printf("A STRING DECAPSULATED UDP:%s\n",a->string); printf("A STRING DECAPSULATED UDP:%s\n",a->string);
tmp = Var_To_Hex((char*)a->bytes, a->bsize); tmp = Var_To_Hex(a->bytes, a->bsize);
printf("TEST BYTES: %s\n", tmp); printf("TEST BYTES: %s\n", tmp);
free(tmp); free(tmp);
multiaddress_encapsulate(a,"/udp/3333/"); multiaddress_encapsulate(a,"/udp/3333/");
printf("A STRING ENCAPSULATED UDP: %s\n",a->string); printf("A STRING ENCAPSULATED UDP: %s\n",a->string);
multiaddress_encapsulate(a,"/ipfs/QmYwAPJzv5CZsnA625s3Xf2nemtYgPpHdWEz79ojWnPbdG"); multiaddress_encapsulate(a,"/ipfs/QmYwAPJzv5CZsnA625s3Xf2nemtYgPpHdWEz79ojWnPbdG");
printf("A STRING ENCAPSULATED IPFS:%s\n",a->string); printf("A STRING ENCAPSULATED IPFS:%s\n",a->string);
tmp = Var_To_Hex((char*)a->bytes, a->bsize); tmp = Var_To_Hex(a->bytes, a->bsize);
printf("TEST BYTES: %s\n", tmp); printf("TEST BYTES: %s\n", tmp);
free(tmp); free(tmp);
printf("TEST BYTE SIZE: %lu\n",a->bsize); printf("TEST BYTE SIZE: %lu\n",a->bsize);
@ -153,7 +132,7 @@ int test_multiaddr_peer_id() {
// switch to bytes and back again to verify the peer id follows... // switch to bytes and back again to verify the peer id follows...
// 1. display the original bytes // 1. display the original bytes
result = (char*)Var_To_Hex((char*)addr->bytes, addr->bsize); result = Var_To_Hex(addr->bytes, addr->bsize);
fprintf(stderr, "Original Bytes: %s\n", result); fprintf(stderr, "Original Bytes: %s\n", result);
free(result); free(result);
result = NULL; result = NULL;
@ -161,13 +140,13 @@ int test_multiaddr_peer_id() {
// make a new MultiAddress from bytes // make a new MultiAddress from bytes
bytes = malloc(addr->bsize); bytes = malloc(addr->bsize);
memcpy(bytes, addr->bytes, addr->bsize); memcpy(bytes, addr->bytes, addr->bsize);
addr2 = multiaddress_new_from_bytes((unsigned char*)bytes, addr->bsize); addr2 = multiaddress_new_from_bytes(bytes, addr->bsize);
free(bytes); free(bytes);
bytes = NULL; bytes = NULL;
// 2. Display the resultant bytes // 2. Display the resultant bytes
result = (char*)Var_To_Hex((char*)addr2->bytes, addr2->bsize); result = Var_To_Hex(addr2->bytes, addr2->bsize);
fprintf(stderr, "New Bytes: %s\n", result); fprintf(stderr, "New Bytes: %s\n", result);
free(result); free(result);
result = NULL; result = NULL;

View file

@ -10,8 +10,7 @@ const char* names[] = {
"test_multiaddr_utils", "test_multiaddr_utils",
"test_multiaddr_peer_id", "test_multiaddr_peer_id",
"test_multiaddr_get_peer_id", "test_multiaddr_get_peer_id",
"test_multiaddr_bytes", "test_multiaddr_bytes"
"test_new_like_libp2p"
}; };
int (*funcs[])(void) = { int (*funcs[])(void) = {
@ -22,8 +21,7 @@ int (*funcs[])(void) = {
test_multiaddr_utils, test_multiaddr_utils,
test_multiaddr_peer_id, test_multiaddr_peer_id,
test_multiaddr_get_peer_id, test_multiaddr_get_peer_id,
test_multiaddr_bytes, test_multiaddr_bytes
test_new_like_libp2p
}; };
int testit(const char* name, int (*func)(void)) { int testit(const char* name, int (*func)(void)) {

View file

@ -51,26 +51,14 @@ uint32_t * Varint_To_Num_32(uint8_t TON32INPUT[60]) //VARINT TO UINT32_t
uvarint_decode32(TON32INPUT, 60, &varintdecode_032); uvarint_decode32(TON32INPUT, 60, &varintdecode_032);
return &varintdecode_032; return &varintdecode_032;
} }
/** //
* Converts a 64 bit integer into a hex string
* @param int2hex the 64 bit integer
* @returns a hex representation as a string (leading zero if necessary)
*/
char * Int_To_Hex(uint64_t int2hex) //VAR[binformat] TO HEX char * Int_To_Hex(uint64_t int2hex) //VAR[binformat] TO HEX
{ {
static char result[50]; static char int2hex_result[800]="\0";
memset(result, 0, 50); memset(int2hex_result,0,sizeof(int2hex_result));
sprintf(result, "%02lX", int2hex); sprintf (int2hex_result, "%02lX", int2hex);
int slen = strlen(result); return int2hex_result;
if (slen % 2 != 0) {
for(int i = slen; i >= 0; --i) {
result[i+1] = result[i];
}
result[0] = '0';
}
return result;
} }
uint64_t Hex_To_Int(char * hax) uint64_t Hex_To_Int(char * hax)
{ {
char * hex = NULL; char * hex = NULL;
@ -103,7 +91,7 @@ void vthconvert(const unsigned char* in, int in_size, unsigned char** out)
unsigned char *ptr = *out; unsigned char *ptr = *out;
for (int i = 0; i < in_size; i++) { for (int i = 0; i < in_size; i++) {
sprintf((char*)&ptr[i * 2], "%02x", in[i]); sprintf(&ptr[i * 2], "%02x", in[i]);
} }
} }
@ -182,7 +170,7 @@ void convert2(char * convert_result2, uint8_t * bufhx)
{ {
uint8_t * buf = NULL; uint8_t * buf = NULL;
buf = bufhx; buf = bufhx;
char conv_proc[4]="\0"; char conv_proc[3]="\0";
conv_proc[3] = '\0'; conv_proc[3] = '\0';
bzero(conv_proc, 3); bzero(conv_proc, 3);
int i; int i;
@ -237,7 +225,7 @@ uint32_t HexVar_To_Num_32(char theHEXstring[]) //HEXIFIED VAR TO UINT32_T
char codo[800] = "\0"; char codo[800] = "\0";
bzero(codo,800); bzero(codo,800);
strcpy(codo, theHEXstring); strcpy(codo, theHEXstring);
char code[4] = "\0"; char code[3] = "\0";
bzero(code,3); bzero(code,3);
code[3] = '\0'; code[3] = '\0';
int x = 0; int x = 0;