/*
Copyright (c) 2018 tevador
This file is part of RandomX.
RandomX is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
RandomX is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with RandomX. If not, see.
*/
#include
#include
#include
#include "virtual_machine.hpp"
#include "common.hpp"
#include "aes_hash.hpp"
#include "blake2/blake2.h"
#include "intrin_portable.h"
#include "allocator.hpp"
randomx_vm::~randomx_vm() {
}
void randomx_vm::resetRoundingMode() {
rx_reset_float_state();
}
namespace randomx {
static inline uint64_t getSmallPositiveFloatBits(uint64_t entropy) {
auto exponent = entropy >> 59; //0..31
auto mantissa = entropy & mantissaMask;
exponent += exponentBias;
exponent &= exponentMask;
exponent <<= mantissaSize;
return exponent | mantissa;
}
static inline uint64_t getStaticExponent(uint64_t entropy) {
auto exponent = constExponentBits;
exponent |= (entropy >> (64 - staticExponentBits)) << dynamicExponentBits;
exponent <<= mantissaSize;
return exponent;
}
static inline uint64_t getFloatMask(uint64_t entropy) {
constexpr uint64_t mask22bit = (1ULL << 22) - 1;
return (entropy & mask22bit) | getStaticExponent(entropy);
}
}
void randomx_vm::initialize() {
store64(®.a[0].lo, randomx::getSmallPositiveFloatBits(program.getEntropy(0)));
store64(®.a[0].hi, randomx::getSmallPositiveFloatBits(program.getEntropy(1)));
store64(®.a[1].lo, randomx::getSmallPositiveFloatBits(program.getEntropy(2)));
store64(®.a[1].hi, randomx::getSmallPositiveFloatBits(program.getEntropy(3)));
store64(®.a[2].lo, randomx::getSmallPositiveFloatBits(program.getEntropy(4)));
store64(®.a[2].hi, randomx::getSmallPositiveFloatBits(program.getEntropy(5)));
store64(®.a[3].lo, randomx::getSmallPositiveFloatBits(program.getEntropy(6)));
store64(®.a[3].hi, randomx::getSmallPositiveFloatBits(program.getEntropy(7)));
mem.ma = program.getEntropy(8) & randomx::CacheLineAlignMask;
mem.mx = program.getEntropy(10);
auto addressRegisters = program.getEntropy(12);
config.readReg0 = 0 + (addressRegisters & 1);
addressRegisters >>= 1;
config.readReg1 = 2 + (addressRegisters & 1);
addressRegisters >>= 1;
config.readReg2 = 4 + (addressRegisters & 1);
addressRegisters >>= 1;
config.readReg3 = 6 + (addressRegisters & 1);
datasetOffset = (program.getEntropy(13) & randomx::DatasetExtraItems) * randomx::CacheLineSize;
store64(&config.eMask[0], randomx::getFloatMask(program.getEntropy(14)));
store64(&config.eMask[1], randomx::getFloatMask(program.getEntropy(15)));
}
namespace randomx {
alignas(16) volatile static rx_vec_i128 aesDummy;
template
VmBase::~VmBase() {
Allocator::freeMemory(scratchpad, ScratchpadSize);
}
template
void VmBase::allocate() {
if (datasetPtr == nullptr)
throw std::invalid_argument("Cache/Dataset not set");
if (!softAes) { //if hardware AES is not supported, it's better to fail now than to return a ticking bomb
rx_vec_i128 tmp = rx_load_vec_i128((const rx_vec_i128*)&aesDummy);
tmp = rx_aesenc_vec_i128(tmp, tmp);
rx_store_vec_i128((rx_vec_i128*)&aesDummy, tmp);
}
scratchpad = (uint8_t*)Allocator::allocMemory(ScratchpadSize);
}
template
void VmBase::getFinalResult(void* out, size_t outSize) {
hashAes1Rx4(scratchpad, ScratchpadSize, ®.a);
blake2b(out, outSize, ®, sizeof(RegisterFile), nullptr, 0);
}
template
void VmBase::initScratchpad(void* seed) {
fillAes1Rx4(seed, ScratchpadSize, scratchpad);
}
template
void VmBase::generateProgram(void* seed) {
fillAes1Rx4(seed, sizeof(program), &program);
}
template class VmBase, false>;
template class VmBase, true>;
template class VmBase;
template class VmBase;
}