Peerplays_Blockchain/peerplays-fc
1
0
Fork 0
Code Issues Pull requests Projects Releases Packages Wiki Activity Actions

Merge pull request #7 from steemit/equihash_security

Browse source 
Implement test_canonical_order and test_intermediate_zeros for equihash
This commit is contained in:
Michael Vandeberg 2017-01-05 14:18:12 -05:00 committed by GitHub
commit 72cd69bed9
4 changed files with 213 additions and 4 deletions
Show stats Download patch file Download diff file Expand all files Collapse all files

3
include/fc/crypto/equihash.hpp
View file

@ -11,7 +11,8 @@ namespace fc { namespace equihash {
sha256 seed;
std::vector< uint32_t > inputs;
bool is_valid() const;
bool is_valid( bool test_canonical_order = false, bool test_intermediate_zeros = false ) const;
void canonize_indexes();
static proof hash( uint32_t n, uint32_t k, sha256 seed );
};

12
src/crypto/equihash.cpp
View file

@ -23,11 +23,21 @@ namespace fc { namespace equihash {
return new_seed;
}
bool proof::is_valid() const
bool proof::is_valid( bool test_canonical_order, bool test_intermediate_zeros ) const
{
_POW::Proof test( n, k, sha_to_seed( seed ), EQUIHASH_NONCE, inputs );
if( test_canonical_order && !test.CheckIndexesCanon() )
return false;
if( test_intermediate_zeros )
return test.FullTest();
return test.Test();
}
void proof::canonize_indexes()
{
_POW::Proof p( n, k, sha_to_seed( seed ), EQUIHASH_NONCE, inputs );
_POW::Proof p_canon = p.CanonizeIndexes();
inputs = p_canon.inputs;
}
proof proof::hash( uint32_t n, uint32_t k, sha256 seed )

3
vendor/equihash/include/equihash/pow.hpp vendored
View file

@ -64,6 +64,9 @@ namespace _POW{
Proof():n(0),k(1),seed(0),nonce(0),inputs(std::vector<Input>()) {};
bool Test();
bool FullTest()const;
bool CheckIndexesCanon()const;
Proof CanonizeIndexes()const;
};
class Tuple {

199
vendor/equihash/src/pow.cpp vendored
View file

@ -8,6 +8,15 @@ Modifications by Steemit, Inc. 2016
#include <equihash/blake2.h>
#include <algorithm>
#ifdef EQUIHASH_POW_VERBOSE
#include <iomanip>
#include <iostream>
#define EQUIHASH_LOG(s) \
std::cerr << s << std::endl;
#else
#define EQUIHASH_LOG(s)
#endif
static uint64_t rdtsc(void) {
#ifdef _MSC_VER
@ -158,7 +167,9 @@ Proof Equihash::FindProof(){
dup = true;
}
if (!dup)
return solutions[i];
{
return solutions[i].CanonizeIndexes();
}
}
}
return Proof(n, k, seed, nonce, std::vector<uint32_t>());
@ -188,12 +199,85 @@ Proof Equihash::FindProof( Nonce _nonce )
dup = true;
}
if (!dup)
return solutions[i];
{
return solutions[i].CanonizeIndexes();
}
}
return Proof(n, k, seed, nonce, std::vector<uint32_t>());
}
Proof Proof::CanonizeIndexes()const
{
// We consider the index values in the inputs array to be the leaf nodes of a binary
// tree, and the inner nodes to be labelled with the XOR of the corresponding vector
// elements.
//
// Define a binary tree to be canonically sorted if, for each inner node, the least
// leaf descendant of the left child is less than the least leaf descendant of the
// right child.
//
// This method puts the inputs into canonical order without altering the inner node
// labels. Thus canonization preserves the validity of the proof and the
// footprint of Wagner's algorithm.
//
// We use a bottom-up traversal, dividing the input into successively larger power-of-2
// blocks and swapping the two half-blocks if non-canonical.
//
// Say a block is least-first if the least element is the first element.
//
// If each half-block is least-first, the conditional swap ensures the full block will also
// be least-first. The half-blocks in the initial iteration are obviously least-first
// (they only have a single element!). So by induction, at each later iteration the half-blocks
// of that iteration are least-first (since they were the full blocks of the previous iteration,
// which were made least-first by the previous iteration's conditional swap).
//
// As a consequence, no search is necessary to find the least element in each half-block,
// it is always the first element in the half-block.
std::vector< uint32_t > new_inputs = inputs;
size_t input_size = inputs.size();
size_t half_size = 1;
size_t block_size = 2;
while( block_size <= input_size )
{
for( size_t i=0; i+block_size<=input_size; i+=block_size )
{
auto ita = new_inputs.begin()+i, itb = ita+half_size;
if( (*ita) >= (*itb) )
{
std::swap_ranges( ita, itb, itb );
}
}
half_size = block_size;
block_size += block_size;
}
return Proof(n, k, seed, nonce, new_inputs);
}
bool Proof::CheckIndexesCanon()const
{
// This method is logically identical to CanonizeIndexes() but will return false
// instead of swapping elements.
size_t input_size = inputs.size();
size_t half_size = 1;
size_t block_size = 2;
while( block_size <= input_size )
{
for( size_t i=0; i+block_size<=input_size; i+=block_size )
{
auto ita = inputs.begin()+i, itb = ita+half_size;
if( (*ita) >= (*itb) )
return false;
}
half_size = block_size;
block_size += block_size;
}
return true;
}
bool Proof::Test()
{
uint32_t input[SEED_LENGTH + 2];
@ -218,3 +302,114 @@ bool Proof::Test()
return b;
}
bool Proof::FullTest()const
{
// Length must be 2**k
if( inputs.size() != size_t(1 << k) )
{
EQUIHASH_LOG( "PoW failed length test" );
return false;
}
// Ensure all values are distinct
std::vector<Input> sorted_inputs = inputs;
std::sort( sorted_inputs.begin(), sorted_inputs.end() );
for( size_t i=1; i<inputs.size(); i++ )
{
if( sorted_inputs[i-1] >= sorted_inputs[i] )
{
EQUIHASH_LOG( "PoW failed distinct test" );
return false;
}
}
// Ensure all values are canonically indexed
/*
if( !CheckIndexesCanon() )
return false;
*/
// Initialize blocks array
uint32_t input[SEED_LENGTH + 2];
for( size_t i=0; i<SEED_LENGTH; i++ )
input[i] = seed[i];
input[SEED_LENGTH] = nonce;
input[SEED_LENGTH + 1] = 0;
uint32_t buf[MAX_N / 4];
std::vector< std::vector< uint32_t > > blocks;
const uint32_t max_input = uint32_t(1) << (n / (k + 1) + 1);
for( size_t i=0; i<inputs.size(); i++ )
{
input[SEED_LENGTH + 1] = inputs[i];
if( inputs[i] >= max_input )
{
EQUIHASH_LOG( "PoW failed max_input test" );
return false;
}
blake2b((uint8_t*)buf, &input, NULL, sizeof(buf), sizeof(input), 0);
blocks.emplace_back();
std::vector<uint32_t>& x = blocks.back();
x.resize(k+1);
for( size_t j=0; j<(k+1); j++ )
{
//select j-th block of n/(k+1) bits
x[j] = buf[j] >> (32 - n / (k + 1));
}
}
while( true )
{
#ifdef EQUIHASH_POW_VERBOSE
std::cerr << "\n\nBegin loop iteration\n";
for( const std::vector< uint32_t >& x : blocks )
{
for( const uint32_t& e : x )
std::cerr << std::hex << std::setw(5) << e << " ";
std::cerr << std::endl;
}
#endif
size_t count = blocks.size();
if( count == 0 )
{
EQUIHASH_LOG( "PoW failed with count == 0" );
return false;
}
if( count == 1 )
{
if( blocks[0].size() != 1 )
{
EQUIHASH_LOG( "PoW failed due to vector size" );
return false;
}
if( blocks[0][0] != 0 )
{
EQUIHASH_LOG( "PoW failed because final bits are not zero" );
return false;
}
return true;
}
if( (count&1) != 0 )
{
EQUIHASH_LOG( "PoW failed with odd count" );
return false;
}
for( size_t i=0,new_i=0; i<count; i+=2,new_i++ )
{
if( blocks[i][0] != blocks[i+1][0] )
{
EQUIHASH_LOG( "PoW failed because leading element of vector pair does not match" );
return false;
}
for( size_t j=1; j<blocks[i].size(); j++ )
blocks[new_i][j-1] = blocks[i][j] ^ blocks[i+1][j];
blocks[new_i].resize(blocks[new_i].size()-1);
}
blocks.resize(blocks.size() >> 1);
}
}