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faster_mitm.hpp
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faster_mitm.hpp
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/**
* PEIGEN: a Platform for Evaluation, Implementation, and Generation of S-boxes
*
* Copyright 2019 by
* Zhenzhen Bao <baozhenzhen10[at]gmail.com>
* Jian Guo <guojian[at]ntu.edu.sg>
* San Ling <lingsan[at]ntu.edu.sg>
* Yu Sasaki <yu[dot]sasaki[dot]sk@hco.ntt.co.jp>
*
* This platform is developed based on the open source application
* <http://jeremy.jean.free.fr/pub/fse2018_layer_implementations.tar.gz>
* Optimizing Implementations of Lightweight Building Blocks
*
* Copyright 2017 by
* Jade Tourteaux <Jade[dot]Tourteaux[at]gmail.com>
* Jérémy Jean <Jean[dot]Jeremy[at]gmail.com>
*
* We follow the same copyright policy.
*
* This file is part of some open source application.
*
* Some open source application 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.
*
* Some open source application 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 Foobar. If not, see <http://www.gnu.org/licenses/>.
*
* @license GPL-3.0+ <http://spdx.org/licenses/GPL-3.0+>
*/
#ifndef FASTER_MITM_H__
#define FASTER_MITM_H__
using namespace std;
using namespace Peigen::depth;
#define NDEBUG
#include <assert.h>
#ifdef PRINT
#undef PRINT
#endif
#ifdef MAX_VEC_NODES
#undef MAX_VEC_NODES
#endif
#ifdef pre_parse_args
#undef pre_parse_args
#endif
#ifdef post_parse_args
#undef post_parse_args
#endif
#ifdef NDEBUG
#define PRINT(fmt, ...) ((void)0)
#else
#define PRINT(fmt, ...) printf(fmt, (unsigned long)(__LINE__), ##__VA_ARGS__)
#endif
#define MAX_VEC_NODES (max_nodes>>1UL)
#define pre_parse_args() \
int myargc = 0; \
char* myargv[50]; \
string args_tmp = "x " + args; \
char * args_str = new char [args_tmp.length() + 1]; \
strcpy(args_str, args_tmp.c_str()); \
char * p = strtok(args_str," "); \
while( p != 0) \
{ \
myargv[myargc] = p; \
p = strtok(NULL, " "); \
myargc++; \
} \
myargv[myargc] = NULL; \
int opt; \
optind = 0;
#define post_parse_args() \
delete [] args_str; \
max_nodes = max_ram * 100000000UL / sizeof(bool_function_t<N>); \
if (gate_maoi1 == 1) gate_xor2 = 0; \
if (gate_moai1 == 1) gate_xnor2 = 0;
template<int N>
void faster<N>::pre_compute(string args)
{
clock_t t1 = clock();
pre_parse_args();
while ((opt = getopt_long(myargc, myargv, "c:vap:f:r:", longopts, NULL)) != EOF)
{
switch(opt)
{
case 'a': all_gates(); break;
case 'v': verbose = true; break;
case 'c': pre_l = abs(atoi(optarg))*100; cout << "Precompute Limit : "<< optarg << endl; break;
case 'p': omp_nb_threads = (atoi(optarg)); cout << "Thread number : "<< omp_nb_threads<<endl;break;
case 'f': conf_file = optarg; break;
case 'r': max_ram = atol(optarg); break;
case '?': fprintf(stderr, "wrong cmd line");
}
}
post_parse_args();
genImpInfo();
init_b(conf_file);
pre_computing();
reset();
t1 = clock() - t1;
cout << "Pre-computation takes time (mins): " << (((double)t1) / (CLOCKS_PER_SEC * 60.0)) << endl;
}
template<int N>
void faster<N>::pre_computing()
{
function_t<N> f1 = function_t<N>::INPUT_DEFAULT();
f1.sort();
f1_succ.clear();
f1_succ.insert(pair<int, set<bool_function_t<N> > >(0, {f1.coordinates[0]}));
for (int i = 1; i < N; i++ ) f1_succ[0].insert(f1.coordinates[i]);
count_list = 0;
while (count_list <= pre_l)
{
expand(count_list);
if(verbose && (count_list%100) == 0) cout << count_list << endl;
count_list++;
write_pre_bin();
}
}
template<int N>
void faster<N>::write_pre_bin()
{
auto find = [](const set<bool_function_t<N> > & func_set, const bit_slice_l_t<N> & bit_slice)
{
for(auto set_it = func_set.begin(); set_it != func_set.end(); set_it++)
{
if (set_it->bit_slice == bit_slice)
{
return set_it;
}
}
return func_set.end();
};
ofstream fout;
size_t bool_function_s = sizeof(bool_function_t<N>);
for (auto map_it = f1_succ.begin(); map_it != f1_succ.end(); map_it++)
{
string pre_filen = "pre_" + imp_info + "_" + to_string(map_it->first) + ".bin";
fout.open(pre_filen, ios::binary);
for (auto set_it = map_it->second.begin(); set_it != map_it->second.end(); set_it++)
{
fout.write((char *)&(set_it->bit_slice), sizeof(bit_slice_l_t<N>));
fout.write((char *)&(set_it->info_op), sizeof(uint8_t));
bit_slice_l_t<N> opv_tmp;
auto map2_it = f1_succ.begin();
switch(set_it->info_op)
{
case NOP : break;
case NAND3 :
case NOR3 :
case OR3 :
case AND3 :
opv_tmp = set_it->operands[2]->bit_slice;
map2_it = f1_succ.begin();
while (map2_it->first < map_it->first)
{
auto func_t = find(map2_it->second, opv_tmp);
if (func_t != map2_it->second.end())
{
fout.write((char *)&(map2_it->first), sizeof(int));
fout.write((char *)&(opv_tmp), sizeof(bit_slice_l_t<N>));
break;
}
map2_it++;
}
assert(map2_it->first < map_it->first);
case AND2 :
case NAND2 :
case OR2 :
case NOR2 :
case XOR2 :
case XNOR2 :
case MOAI1 :
case MAOI1 :
case ANDN2 :
case ORN2 :
opv_tmp = set_it->operands[1]->bit_slice;
map2_it = f1_succ.begin();
while (map2_it->first < map_it->first)
{
auto func_t = find(map2_it->second, opv_tmp);
if (func_t != map2_it->second.end())
{
fout.write((char *)&(map2_it->first), sizeof(int));
fout.write((char *)&(opv_tmp), sizeof(bit_slice_l_t<N>));
break;
}
map2_it++;
}
assert(map2_it->first < map_it->first);
case NOT1 :
opv_tmp = set_it->operands[0]->bit_slice;
map2_it = f1_succ.begin();
while (map2_it->first < map_it->first)
{
auto func_t = find(map2_it->second, opv_tmp);
if (func_t != map2_it->second.end())
{
fout.write((char *)&(map2_it->first), sizeof(int));
fout.write((char *)&(opv_tmp), sizeof(bit_slice_l_t<N>));
break;
}
map2_it++;
}
assert(map2_it->first < map_it->first);
break;
default : cout << "Write file error. Exit." << endl; exit(1);
}
fout.write((char *)&(set_it->area), sizeof(int));
}
fout.close();
}
}
template<int N>
void faster<N>::read_pre_bin()
{
auto find = [](const set<bool_function_t<N> > & func_set, const bit_slice_l_t<N> & bit_slice)
{
for(auto set_it = func_set.begin(); set_it != func_set.end(); set_it++)
{
if (set_it->bit_slice == bit_slice)
{
return set_it;
}
}
return func_set.end();
};
ifstream fin;
bool_function_t<N> f_t;
int lambda = 0;
size_t bool_function_s = sizeof(bool_function_t<N>);
f1_succ.clear();
while (lambda <= (pre_l + max_GE))
{
string pre_filen = "pre_" + imp_info + "_" + to_string(lambda) + ".bin";
fin.open(pre_filen, ios::binary);
if (fin)
{
set<bool_function_t<N> > new_list;
f1_succ.insert(pair<int, set<bool_function_t<N> > >(lambda, new_list));
auto to_insert = &(f1_succ[lambda]);
int depth;
bit_slice_l_t<N> opv_tmp;
while (fin.read((char*)&(f_t.bit_slice), sizeof(bit_slice_l_t<N>)))
{
assert(fin);
fin.read((char *)&(f_t.info_op), sizeof(uint8_t));
assert(fin);
f_t.operands[0] = NULL;
f_t.operands[1] = NULL;
f_t.operands[2] = NULL;
switch(f_t.info_op)
{
case NOP :
break;
case NAND3 :
case NOR3 :
case OR3 :
case AND3 :assert(fin);
fin.read((char *)&(depth), sizeof(int));
assert(fin);
fin.read((char *)&(opv_tmp), sizeof(bit_slice_l_t<N>));
f_t.operands[2] = &(*(find(f1_succ[depth],opv_tmp)));
case AND2 :
case NAND2 :
case OR2 :
case NOR2 :
case XOR2 :
case XNOR2 :
case MOAI1 :
case MAOI1 :
case ANDN2 :
case ORN2 :assert(fin);
fin.read((char *)&(depth), sizeof(int));
assert(fin);
fin.read((char *)&(opv_tmp), sizeof(bit_slice_l_t<N>));
f_t.operands[1] = &(*(find(f1_succ[depth],opv_tmp)));
case NOT1 :assert(fin);
fin.read((char *)&(depth), sizeof(int));
assert(fin);
fin.read((char *)&(opv_tmp), sizeof(bit_slice_l_t<N>));
f_t.operands[0] = &(*(find(f1_succ[depth],opv_tmp)));
break;
default :
cout << "Read binary file error. Exit. ";
fin.close();
exit(1);
}
assert(fin);
fin.read((char *)&(f_t.area), sizeof(int));
to_insert->insert(f_t);
}
}
fin.close();
lambda++;
}
}
template<int N>
void faster<N>::search_batch(string args)
{
function_t<N> f1 = function_t<N>::INPUT_DEFAULT();
target = function_t<N>::INPUT_DEFAULT();
string sboxesfile = "sboxes" + to_string(N) + ".txt";
pre_parse_args();
while ((opt = getopt_long(myargc, myargv, "i:o:l:c:vwap:f:r:", longopts, NULL)) != EOF)
{
switch(opt)
{
case 'c': pre_l = atoi(optarg)*100; cout << "Precomputed Limit : "<< optarg << endl; break;
case 'a': all_gates(); break;
case 'v': verbose = true; break;
case 'w': write_in_file = true; break;
case 'i': f1.parse_function(optarg); break;
case 'o': sboxesfile = optarg; break;
case 'l': l = abs(atoi(optarg))*100; cout << "Lambda : "<< optarg << endl; break;
case 'p': omp_nb_threads = (atoi(optarg)); cout << "Thread number : "<< omp_nb_threads<<endl;break;
case 'f': conf_file = optarg; break;
case 'r': max_ram = atol(optarg); break;
case '?': fprintf(stderr, "wrong cmd line");
}
}
post_parse_args();
genImpInfo();
init_b(conf_file);
ifstream sboxes(sboxesfile);
string instance_LUT;
read_pre_bin();
for(string line; getline(sboxes, line); )
{
istringstream instance_line(line);
if(getline(instance_line, instance_name, ','))
{
if(getline(instance_line, instance_LUT))
{
clock_t t1 = clock();
init_varbles();
target.parse_function(instance_LUT);
cout << "From : " << f1.to_string() << endl;
cout << "To : " << target.to_string() << endl;
mitm(f1);
double best_depth = (double)(shortest_path)/100;
double best_area = (double)(smallest_area)/100;
cout << "Best Depth: " << best_depth << " GE "
<< " Area: " << best_area << " GE " << endl;
statistician.open(imp_info + "__" + "statistics.csv", ios::app);
statistician << instance_name << "," << best_depth << "," << best_area << endl;
statistician.close();
t1 = clock() - t1;
cout << "Takes time (mins): " << (((double)t1) / (CLOCKS_PER_SEC * 60.0)) << endl;
}
}
}
reset();
}
template<int N>
double faster<N>::search_single(string args)
{
clock_t t1 = clock();
function_t<N> f1 = function_t<N>::INPUT_DEFAULT();
target = function_t<N>::INPUT_DEFAULT();
string instance_LUT;
instance_name = "";
pre_parse_args();
while ((opt = getopt_long(myargc, myargv, "i:o:c:l:vwap:f:r:n:", longopts, NULL)) != EOF)
{
switch(opt)
{
case 'c': pre_l = atoi(optarg)*100; cout << "Precomputed Limit : "<< optarg << endl; break;
case 'a': all_gates(); break;
case 'v': verbose = true; break;
case 'w': write_in_file = true; break;
case 'i': f1.parse_function(optarg); break;
case 'o': target.parse_function(optarg); instance_LUT = optarg; break;
case 'n': instance_name = optarg; break;
case 'l': l = abs(atoi(optarg))*100; cout << "Lambda : "<< optarg << endl; break;
case 'p': omp_nb_threads = (atoi(optarg)); cout << "Thread number : "<< omp_nb_threads<<endl;break;
case 'f': conf_file = optarg; break;
case 'r': max_ram = atol(optarg); break;
case '?': fprintf(stderr, "wrong cmd line");
}
}
post_parse_args();
if(instance_name == "")
{
instance_name = instance_LUT;
}
genImpInfo();
init_b(conf_file);
read_pre_bin();
init_varbles();
cout << "From : " << f1.to_string() << endl;
cout << "To : " << target.to_string() << endl;
mitm(f1);
double best_depth = (double)(shortest_path)/100;
double best_area = (double)(smallest_area)/100;
cout << "Best Depth: " << best_depth << " GE "
<< " Area: " << best_area << " GE " << endl;
statistician.open(imp_info + "__" + "statistics.csv", ios::app);
statistician << instance_name << "," << best_depth << "," << best_area << endl;
statistician.close();
reset();
t1 = clock() - t1;
cout << "Takes time (mins): " << (((double)t1) / (CLOCKS_PER_SEC * 60.0)) << endl;
return best_depth;
}
template<int N>
void faster<N>::mitm(function_t<N> f1)
{
start = f1;
count_list = 0;
if (pre_l < 0)
{
f1_succ.insert(pair<int, set<bool_function_t<N> > >(0, {f1.coordinates[0]}));
for (int i = 1; i < N; i++) f1_succ[0].insert(f1.coordinates[i]);
}
else
{
auto map_it = f1_succ.begin();
while (map_it != f1_succ.end())
{
count_list = map_it->first;
if (count_list <= shortest_path)
{
for (auto it_tmp = (*map_it).second.begin(); it_tmp != (*map_it).second.end(); it_tmp++)
{
if(is_in_graphe_collision(count_list, 0, (*it_tmp)))
{
get_implementation();
}
}
map_it++;
}
else
{
break;
}
}
if(shortest_path <= pre_l)
{
return;
}
count_list = pre_l + 1;
}
while(count_list <= l)
{
if (count_list > pre_l)
{
expand(count_list);
pre_l = count_list;
}
if(verbose && (count_list%100) == 0) cout << "\033[0;32m" << count_list << "\033[0m" << endl;
count_list++;
if(count_list > shortest_path)
{
if (count_list > pre_l) write_pre_bin();
exit_m();
return;
}
}
if(verbose) print_graphe_info();
if (count_list > pre_l)
{
write_pre_bin();
pre_l = count_list;
}
exit_m();
return;
}
template<int N>
void faster<N>::expand(int lambda)
{
auto remove_dup = [](vector<bool_function_t<N> > * succ_vecs_pt, int i)
{
vector<bool_function_t<N> > * tmp0 = &(succ_vecs_pt[i]);
vector<bool_function_t<N> > * tmp1 = &(succ_vecs_pt[i^1]);
tmp1->clear();
sort(tmp0->begin(), tmp0->end());
auto it0 = tmp0->begin();
tmp1->push_back(*it0);
it0++;
while (it0 != tmp0->end())
{
if (it0->bit_slice != tmp1->back().bit_slice)
{
tmp1->push_back(*it0);
}
it0++;
}
};
auto to_expand = f1_succ.find(lambda);
if(to_expand != f1_succ.end())
{
for(auto bool_op : b)
{
int bool_op_cost = bool_op.op_cost;
vector<bool_function_t<N> > successors[2];
successors[0].reserve(MAX_VEC_NODES);
successors[1].reserve(MAX_VEC_NODES);
vector<bool_function_t<N> >* succ_vec_pt;
int i = 0;
succ_vec_pt = &(successors[i]);
switch (bool_op.op_id)
{
case NOT1 :
for(auto f1 = (*to_expand).second.begin(); f1 != (*to_expand).second.end(); f1++)
{
bool_op_one_input(&(*f1), succ_vec_pt, bool_op);
if (succ_vec_pt->size() >= MAX_VEC_NODES)
{
PRINT("Line:: %lu: Before remove_dup successors.size(): %lu\n", succ_vec_pt->size());
remove_dup(successors, i);
i = i ^ 1;
succ_vec_pt = &(successors[i]);
PRINT("Line:: %lu: After remove_dup successors.size(): %lu\n", succ_vec_pt->size());
}
}
break;
case AND2 :
case OR2 :
case NAND2 :
case NOR2 :
case XOR2 :
case XNOR2 :
case MAOI1 :
case MOAI1 :
for(auto f1 = (*to_expand).second.begin(); f1 != (*to_expand).second.end(); f1++)
{
for(auto f2map = f1_succ.begin(); f2map != to_expand; f2map++)
{
for (auto f2 = (*f2map).second.begin(); f2 != (*f2map).second.end(); f2++)
{
bool_op_two_inputs(&(*f1), &(*f2), succ_vec_pt, bool_op);
if (succ_vec_pt->size() >= MAX_VEC_NODES)
{
PRINT("Line:: %lu: Before remove_dup successors.size(): %lu\n", succ_vec_pt->size());
remove_dup(successors, i);
i = i ^ 1;
succ_vec_pt = &(successors[i]);
PRINT("Line:: %lu: After remove_dup successors.size(): %lu\n", succ_vec_pt->size());
}
}
}
for (auto f2 = (*to_expand).second.begin(); f2 != f1; f2++)
{
bool_op_two_inputs(&(*f1), &(*f2), succ_vec_pt, bool_op);
if (succ_vec_pt->size() >= MAX_VEC_NODES)
{
PRINT("Line:: %lu: Before remove_dup successors.size(): %lu\n", succ_vec_pt->size());
remove_dup(successors, i);
i = i ^ 1;
succ_vec_pt = &(successors[i]);
PRINT("Line:: %lu: After remove_dup successors.size(): %lu\n", succ_vec_pt->size());
}
}
}
break;
case ANDN2 :
case ORN2 :
for(auto f1 = (*to_expand).second.begin(); f1 != (*to_expand).second.end(); f1++)
{
for(auto f2map = f1_succ.begin(); f2map != to_expand; f2map++)
{
for (auto f2 = (*f2map).second.begin(); f2 != (*f2map).second.end(); f2++)
{
bool_op_two_inputs(&(*f1), &(*f2), succ_vec_pt, bool_op);
bool_op_two_inputs(&(*f2), &(*f1), succ_vec_pt, bool_op);
if (succ_vec_pt->size() >= MAX_VEC_NODES)
{
PRINT("Line:: %lu: Before remove_dup successors.size(): %lu\n", succ_vec_pt->size());
remove_dup(successors, i);
i = i ^ 1;
succ_vec_pt = &(successors[i]);
PRINT("Line:: %lu: After remove_dup successors.size(): %lu\n", succ_vec_pt->size());
}
}
}
for (auto f2 = (*to_expand).second.begin(); f2 != f1; f2++)
{
bool_op_two_inputs(&(*f1), &(*f2), succ_vec_pt, bool_op);
bool_op_two_inputs(&(*f2), &(*f1), succ_vec_pt, bool_op);
if (succ_vec_pt->size() >= MAX_VEC_NODES)
{
PRINT("Line:: %lu: Before remove_dup successors.size(): %lu\n", succ_vec_pt->size());
remove_dup(successors, i);
i = i ^ 1;
succ_vec_pt = &(successors[i]);
PRINT("Line:: %lu: After remove_dup successors.size(): %lu\n", succ_vec_pt->size());
}
}
}
break;
case AND3 :
case OR3 :
case NAND3 :
case NOR3 :
for(auto f1 = (*to_expand).second.begin(); f1 != (*to_expand).second.end(); f1++)
{
for(auto f2map = f1_succ.begin(); f2map != to_expand; f2map++)
{
for (auto f2 = (*f2map).second.begin(); f2 != (*f2map).second.end(); f2++)
{
for(auto f3map = f1_succ.begin(); f3map != f2map; f3map++)
{
for (auto f3 = (*f3map).second.begin(); f3 != (*f3map).second.end(); f3++)
{
bool_op_three_inputs(&(*f1), &(*f2), &(*f3), succ_vec_pt, bool_op);
if (succ_vec_pt->size() >= MAX_VEC_NODES)
{
PRINT("Line:: %lu: Before remove_dup successors.size(): %lu\n", succ_vec_pt->size());
remove_dup(successors, i);
i = i ^ 1;
succ_vec_pt = &(successors[i]);
PRINT("Line:: %lu: After remove_dup successors.size(): %lu\n", succ_vec_pt->size());
}
}
}
for (auto f3 = (*f2map).second.begin(); f3 != f2; f3++)
{
bool_op_three_inputs(&(*f1), &(*f2), &(*f3), succ_vec_pt, bool_op);
if (succ_vec_pt->size() >= MAX_VEC_NODES)
{
PRINT("Line:: %lu: Before remove_dup successors.size(): %lu\n", succ_vec_pt->size());
remove_dup(successors, i);
i = i ^ 1;
succ_vec_pt = &(successors[i]);
PRINT("Line:: %lu: After remove_dup successors.size(): %lu\n", succ_vec_pt->size());
}
}
}
}
for (auto f2 = (*to_expand).second.begin(); f2 != f1; f2++)
{
for (auto f3 = (*to_expand).second.begin(); f3 != f2; f3++)
{
bool_op_three_inputs(&(*f1), &(*f2), &(*f3), succ_vec_pt, bool_op);
if (succ_vec_pt->size() >= MAX_VEC_NODES)
{
PRINT("Line:: %lu: Before remove_dup successors.size(): %lu\n", succ_vec_pt->size());
remove_dup(successors, i);
i = i ^ 1;
succ_vec_pt = &(successors[i]);
PRINT("Line:: %lu: After remove_dup successors.size(): %lu\n", succ_vec_pt->size());
}
}
}
}
break;
}
if(succ_vec_pt->size() != 0)
{
PRINT("Line:: %lu: Before remove_dup successors.size(): %lu\n", succ_vec_pt->size());
remove_dup(successors, i);
i = i ^ 1;
succ_vec_pt = &(successors[i]);
PRINT("Line:: %lu: After remove_dup successors.size(): %lu\n", succ_vec_pt->size());
auto s = f1_succ.find(lambda + bool_op_cost);
set<bool_function_t<N> > new_list;
v_list_process(lambda, bool_op_cost, succ_vec_pt, &new_list);
if(s != f1_succ.end())
{
s->second.insert(new_list.begin(), new_list.end());
}
else
{
f1_succ.insert(pair<int,set<bool_function_t<N> > >(lambda + bool_op_cost, new_list));
}
}
}
}
}
template<int N>
void faster<N>::v_list_process(int lambda, int op_cost, vector<bool_function_t<N> > *tmp,
set<bool_function_t<N> > *to_insert)
{
PRINT("Entering v_list_process\n");
#pragma omp parallel for num_threads(omp_nb_threads)
for(auto it_tmp = tmp->begin(); it_tmp < tmp->end(); it_tmp++)
{
if(!is_in_graphe(lambda, op_cost, (*it_tmp)))
{
#pragma omp critical
{
to_insert->insert(*it_tmp);
nodes_cmp++;
if(nodes_cmp == max_nodes)
{
exit_m();
}
if(lambda > pre_l)
{
if(is_in_graphe_collision(lambda, op_cost, (*it_tmp)))
{
get_implementation();
}
}
}
}
}
PRINT("Leaving v_list_process\n");
}
template<int N>
bool faster<N>::is_in_graphe(int lambda, int op_cost, bool_function_t<N> f)
{
auto find = [](const set<bool_function_t<N> > & func_set, const bit_slice_l_t<N> & bit_slice)
{
for(auto set_it = func_set.begin(); set_it != func_set.end(); set_it++)
{
if (set_it->bit_slice == bit_slice)
{
return set_it;
}
}
return func_set.end();
};
for(auto it = f1_succ.begin(); it != f1_succ.end() ; it++)
{
auto found_f = find((*it).second, f.bit_slice);
if(found_f != (*it).second.end())
{
if(((*it).first > lambda+op_cost) || (((*it).first == lambda+op_cost) && ((*found_f).area > f.area)))
{
#pragma omp critical (UpdateGraphe)
{
(*it).second.erase(found_f);
}
return false;
}
return true;
}
}
return false;
}
template<int N>
bool faster<N>::is_in_graphe_collision(int lambda, int op_cost, bool_function_t<N> f)
{
for (int i = 0; i < N; i++)
{
if (f.bit_slice == target.coordinates[i].bit_slice)
{
if(lambda + op_cost <= (int)target.depth[i])
{
target.depth[i] = lambda + op_cost;
target.coordinates[i] = f;
flag |= (1UL << i);
if (flag == FOUND_ALL)
{
return true;
}
}
break;
}
}
return false;
}
#ifdef PRINT
#undef PRINT
#endif
#ifdef MAX_VEC_NODES
#undef MAX_VEC_NODES
#endif
#ifdef pre_parse_args
#undef pre_parse_args
#endif
#ifdef post_parse_args
#undef post_parse_args
#endif
#endif // #define FASTER_MITM_H__