Below is the file 'checks/bigint.cpp' from this revision. You can also download the file.
#include <vector> #include <string> #include <fstream> #include <iostream> #include <cstdlib> #include <botan/bigint.h> #include <botan/exceptn.h> #include <botan/numthry.h> #include <botan/libstate.h> using namespace Botan; #include "common.h" #define DEBUG 0 u32bit check_add(const std::vector<std::string>&); u32bit check_sub(const std::vector<std::string>&); u32bit check_mul(const std::vector<std::string>&); u32bit check_sqr(const std::vector<std::string>&); u32bit check_div(const std::vector<std::string>&); u32bit check_mod(const std::vector<std::string>&); u32bit check_shr(const std::vector<std::string>&); u32bit check_shl(const std::vector<std::string>&); u32bit check_powmod(const std::vector<std::string>&); u32bit check_primetest(const std::vector<std::string>&); u32bit do_bigint_tests(const std::string& filename) { std::ifstream test_data(filename.c_str()); if(!test_data) throw Botan::Stream_IO_Error("Couldn't open test file " + filename); u32bit errors = 0, alg_count = 0; std::string algorithm; bool first = true; u32bit counter = 0; while(!test_data.eof()) { if(test_data.bad() || test_data.fail()) throw Botan::Stream_IO_Error("File I/O error reading from " + filename); std::string line; std::getline(test_data, line); strip(line); if(line.size() == 0) continue; // Do line continuation while(line[line.size()-1] == '\\' && !test_data.eof()) { line.replace(line.size()-1, 1, ""); std::string nextline; std::getline(test_data, nextline); strip(nextline); if(nextline.size() == 0) continue; line += nextline; } if(line[0] == '[' && line[line.size() - 1] == ']') { algorithm = line.substr(1, line.size() - 2); alg_count = 0; counter = 0; if(!first) std::cout << std::endl; std::cout << "Testing BigInt " << algorithm << ": "; std::cout.flush(); first = false; continue; } std::vector<std::string> substr = parse(line); #if DEBUG std::cout << "Testing: " << algorithm << std::endl; #endif u32bit new_errors = 0; if(algorithm.find("Addition") != std::string::npos) new_errors = check_add(substr); else if(algorithm.find("Subtraction") != std::string::npos) new_errors = check_sub(substr); else if(algorithm.find("Multiplication") != std::string::npos) new_errors = check_mul(substr); else if(algorithm.find("Square") != std::string::npos) new_errors = check_sqr(substr); else if(algorithm.find("Division") != std::string::npos) new_errors = check_div(substr); else if(algorithm.find("Modulo") != std::string::npos) new_errors = check_mod(substr); else if(algorithm.find("LeftShift") != std::string::npos) new_errors = check_shl(substr); else if(algorithm.find("RightShift") != std::string::npos) new_errors = check_shr(substr); else if(algorithm.find("ModExp") != std::string::npos) new_errors = check_powmod(substr); else if(algorithm.find("PrimeTest") != std::string::npos) new_errors = check_primetest(substr); else std::cout << "Unknown MPI test " << algorithm << std::endl; if(counter % 3 == 0) { std::cout << '.'; std::cout.flush(); } counter++; alg_count++; errors += new_errors; if(new_errors) std::cout << "ERROR: BigInt " << algorithm << " failed test #" << std::dec << alg_count << std::endl; } std::cout << std::endl; return errors; } // c==expected, d==a op b, e==a op= b u32bit results(std::string op, const BigInt& a, const BigInt& b, const BigInt& c, const BigInt& d, const BigInt& e) { std::string op1 = "operator" + op; std::string op2 = op1 + "="; if(c == d && d == e) return 0; else { std::cout << std::endl; std::cout << "ERROR: " << op1 << std::endl; std::cout << "a = " << std::hex << a << std::endl; std::cout << "b = " << std::hex << b << std::endl; std::cout << "c = " << std::hex << c << std::endl; std::cout << "d = " << std::hex << d << std::endl; std::cout << "e = " << std::hex << e << std::endl; if(d != e) { std::cout << "ERROR: " << op1 << " | " << op2 << " mismatch" << std::endl; } return 1; } } u32bit check_add(const std::vector<std::string>& args) { BigInt a(args[0]); BigInt b(args[1]); BigInt c(args[2]); BigInt d = a + b; BigInt e = a; e += b; if(results("+", a, b, c, d, e)) return 1; d = b + a; e = b; e += a; return results("+", a, b, c, d, e); } u32bit check_sub(const std::vector<std::string>& args) { BigInt a(args[0]); BigInt b(args[1]); BigInt c(args[2]); BigInt d = a - b; BigInt e = a; e -= b; return results("-", a, b, c, d, e); } u32bit check_mul(const std::vector<std::string>& args) { BigInt a(args[0]); BigInt b(args[1]); BigInt c(args[2]); /* std::cout << "a = " << args[0] << "\n" << "b = " << args[1] << std::endl; */ /* This makes it more likely the fast multiply algorithms will be usable, which is what we really want to test here (the simple n^2 multiply is pretty well tested at this point). */ a.grow_reg(32); b.grow_reg(32); BigInt d = a * b; BigInt e = a; e *= b; if(results("*", a, b, c, d, e)) return 1; d = b * a; e = b; e *= a; return results("*", a, b, c, d, e); } u32bit check_sqr(const std::vector<std::string>& args) { BigInt a(args[0]); BigInt b(args[1]); a.grow_reg(16); b.grow_reg(16); BigInt c = square(a); BigInt d = a * a; return results("sqr", a, a, b, c, d); } u32bit check_div(const std::vector<std::string>& args) { BigInt a(args[0]); BigInt b(args[1]); BigInt c(args[2]); BigInt d = a / b; BigInt e = a; e /= b; return results("/", a, b, c, d, e); } u32bit check_mod(const std::vector<std::string>& args) { BigInt a(args[0]); BigInt b(args[1]); BigInt c(args[2]); BigInt d = a % b; BigInt e = a; e %= b; u32bit got = results("%", a, b, c, d, e); if(got) return got; word b_word = b.word_at(0); /* Won't work for us, just pick one at random */ while(b_word == 0) for(u32bit j = 0; j != 2*sizeof(word); j++) b_word = (b_word << 4) ^ global_state().random(); b = b_word; c = a % b; /* we declare the BigInt % BigInt version to be correct here */ word d2 = a % b_word; e = a; e %= b_word; return results("%(word)", a, b, c, d2, e); } u32bit check_shl(const std::vector<std::string>& args) { BigInt a(args[0]); u32bit b = std::atoi(args[1].c_str()); BigInt c(args[2]); BigInt d = a << b; BigInt e = a; e <<= b; return results("<<", a, b, c, d, e); } u32bit check_shr(const std::vector<std::string>& args) { BigInt a(args[0]); u32bit b = std::atoi(args[1].c_str()); BigInt c(args[2]); BigInt d = a >> b; BigInt e = a; e >>= b; return results(">>", a, b, c, d, e); } /* Make sure that (a^b)%m == r */ u32bit check_powmod(const std::vector<std::string>& args) { BigInt a(args[0]); BigInt b(args[1]); BigInt m(args[2]); BigInt c(args[3]); BigInt r = power_mod(a, b, m); if(c != r) { std::cout << "ERROR: power_mod" << std::endl; std::cout << "a = " << std::hex << a << std::endl; std::cout << "b = " << std::hex << b << std::endl; std::cout << "m = " << std::hex << m << std::endl; std::cout << "c = " << std::hex << c << std::endl; std::cout << "r = " << std::hex << r << std::endl; return 1; } return 0; } /* Make sure that n is prime or not prime, according to should_be_prime */ u32bit check_primetest(const std::vector<std::string>& args) { BigInt n(args[0]); bool should_be_prime = (args[1] == "1"); bool is_prime = Botan::verify_prime(n); if(is_prime != should_be_prime) { std::cout << "ERROR: verify_prime" << std::endl; std::cout << "n = " << n << std::endl; std::cout << is_prime << " != " << should_be_prime << std::endl; } return 0; }