libs/rational/rational_test.cpp
/* * A test program for boost/rational.hpp. * Change the typedef at the beginning of run_tests() to try out different * integer types. (These tests are designed only for signed integer * types. They should work for short, int and long.) * * (C) Copyright Stephen Silver, 2001. Permission to copy, use, modify, sell * and distribute this software is granted provided this copyright notice * appears in all copies. This software is provided "as is" without express or * implied warranty, and with no claim as to its suitability for any purpose. * * Incorporated into the boost rational number library, and modified and * extended, by Paul Moore, with permission. */ // Revision History // 04 Mar 01 Patches for Intel C++ and GCC (David Abrahams) #include "boost/rational.hpp" #include "boost/operators.hpp" #include <cstdlib> #include <iomanip> #include <iostream> #include <cstring> #ifndef BOOST_NO_STRINGSTREAM # include <sstream> #else # include <strstream> namespace { class unfreezer { public: unfreezer(std::ostrstream& s) : m_stream(s) {} ~unfreezer() { m_stream.freeze(false); } private: std::ostrstream& m_stream; }; } #endif // We can override this on the compile, as -DINT_TYPE=short or whatever. // The default test is against rational<long>. #ifndef INT_TYPE #define INT_TYPE long #endif namespace { // This is a trivial user-defined wrapper around the built in int type. // It can be used as a test type for rational<> class MyInt : boost::operators<MyInt> { int val; public: MyInt(int n = 0) : val(n) {} friend MyInt operator+ (const MyInt&); friend MyInt operator- (const MyInt&); MyInt& operator+= (const MyInt& rhs) { val += rhs.val; return *this; } MyInt& operator-= (const MyInt& rhs) { val -= rhs.val; return *this; } MyInt& operator*= (const MyInt& rhs) { val *= rhs.val; return *this; } MyInt& operator/= (const MyInt& rhs) { val /= rhs.val; return *this; } MyInt& operator%= (const MyInt& rhs) { val %= rhs.val; return *this; } MyInt& operator|= (const MyInt& rhs) { val |= rhs.val; return *this; } MyInt& operator&= (const MyInt& rhs) { val &= rhs.val; return *this; } MyInt& operator^= (const MyInt& rhs) { val ^= rhs.val; return *this; } const MyInt& operator++() { ++val; return *this; } const MyInt& operator--() { --val; return *this; } bool operator< (const MyInt& rhs) const { return val < rhs.val; } bool operator== (const MyInt& rhs) const { return val == rhs.val; } bool operator! () const { return !val; } friend std::istream& operator>>(std::istream&, MyInt&); friend std::ostream& operator<<(std::ostream&, const MyInt&); }; inline MyInt operator+(const MyInt& rhs) { return rhs; } inline MyInt operator-(const MyInt& rhs) { return MyInt(-rhs.val); } inline std::istream& operator>>(std::istream& is, MyInt& i) { is >> i.val; return is; } inline std::ostream& operator<<(std::ostream& os, const MyInt& i) { os << i.val; return os; } inline MyInt abs(MyInt rhs) { if (rhs < MyInt()) rhs = -rhs; return rhs; } // Test statistics static unsigned int total_count; static unsigned int error_count; // Check a specific assertion void Check(bool ok, const char *s, int line) { ++total_count; if (!ok) { std::cout << "Failed test " << s << " at line " << line << '\n'; ++error_count; } #ifdef SHOW_SUCCESSES std::cout << "Passed test " << s << '\n'; #endif } #define CHECK(x) Check((x), #x, __LINE__) // The basic test suite void run_tests() { typedef INT_TYPE IntType; typedef boost::rational<IntType> rat; error_count = 0; total_count = 0; /* gcd tests */ CHECK(( boost::gcd<IntType>(1,-1) == 1 )); CHECK(( boost::gcd<IntType>(-1,1) == 1 )); CHECK(( boost::gcd<IntType>(1,1) == 1 )); CHECK(( boost::gcd<IntType>(-1,-1) == 1 )); CHECK(( boost::gcd<IntType>(0,0) == 0 )); CHECK(( boost::gcd<IntType>(7,0) == 7 )); CHECK(( boost::gcd<IntType>(0,9) == 9 )); CHECK(( boost::gcd<IntType>(-7,0) == 7 )); CHECK(( boost::gcd<IntType>(0,-9) == 9 )); CHECK(( boost::gcd<IntType>(42,30) == 6 )); CHECK(( boost::gcd<IntType>(6,-9) == 3 )); CHECK(( boost::gcd<IntType>(-10,-10) == 10 )); CHECK(( boost::gcd<IntType>(-25,-10) == 5 )); /* lcm tests */ CHECK(( boost::lcm<IntType>(1,-1) == 1 )); CHECK(( boost::lcm<IntType>(-1,1) == 1 )); CHECK(( boost::lcm<IntType>(1,1) == 1 )); CHECK(( boost::lcm<IntType>(-1,-1) == 1 )); CHECK(( boost::lcm<IntType>(0,0) == 0 )); CHECK(( boost::lcm<IntType>(6,0) == 0 )); CHECK(( boost::lcm<IntType>(0,7) == 0 )); CHECK(( boost::lcm<IntType>(-5,0) == 0 )); CHECK(( boost::lcm<IntType>(0,-4) == 0 )); CHECK(( boost::lcm<IntType>(18,30) == 90 )); CHECK(( boost::lcm<IntType>(-6,9) == 18 )); CHECK(( boost::lcm<IntType>(-10,-10) == 10 )); CHECK(( boost::lcm<IntType>(25,-10) == 50 )); /* initialization tests */ rat r1, r2(0), r3(1), r4(-3), r5(7,2), r6(5,15), r7(14,-21), r8(-4,6), r9(-14,-70); CHECK(( r1.numerator() == 0 )); CHECK(( r2.numerator() == 0 )); CHECK(( r3.numerator() == 1 )); CHECK(( r4.numerator() == -3 )); CHECK(( r5.numerator() == 7 )); CHECK(( r6.numerator() == 1 )); CHECK(( r7.numerator() == -2 )); CHECK(( r8.numerator() == -2 )); CHECK(( r9.numerator() == 1 )); CHECK(( r1.denominator() == 1 )); CHECK(( r2.denominator() == 1 )); CHECK(( r3.denominator() == 1 )); CHECK(( r4.denominator() == 1 )); CHECK(( r5.denominator() == 2 )); CHECK(( r6.denominator() == 3 )); CHECK(( r7.denominator() == 3 )); CHECK(( r8.denominator() == 3 )); CHECK(( r9.denominator() == 5 )); /* assign() tests */ r1.assign(6,8); CHECK(( r1.numerator() == 3 )); CHECK(( r1.denominator() == 4 )); r1.assign(0,-7); CHECK(( r1.numerator() == 0 )); CHECK(( r1.denominator() == 1 )); /* comparison tests */ CHECK(( r1 == r2 )); CHECK(( r2 != r3 )); CHECK(( r4 < r3 )); CHECK(( r4 <= r5 )); CHECK(( r1 <= r2 )); CHECK(( r5 > r6 )); CHECK(( r5 >= r6 )); CHECK(( r7 >= r8 )); CHECK(( !(r3 == r2) )); CHECK(( !(r1 != r2) )); CHECK(( !(r1 < r2) )); CHECK(( !(r5 < r6) )); CHECK(( !(r9 <= r2) )); CHECK(( !(r8 > r7) )); CHECK(( !(r8 > r2) )); CHECK(( !(r4 >= r6) )); CHECK(( r1 == 0 )); CHECK(( r2 != -1 )); CHECK(( r3 < 2 )); CHECK(( r4 <= -3 )); CHECK(( r5 > 3 )); CHECK(( r6 >= 0 )); CHECK(( 0 == r2 )); CHECK(( 0 != r7 )); CHECK(( -1 < r8 )); CHECK(( -2 <= r9 )); CHECK(( 1 > r1 )); CHECK(( 1 >= r3 )); /* increment/decrement tests */ CHECK(( r1++ == r2 )); CHECK(( r1 != r2 )); CHECK(( r1 == r3 )); CHECK(( --r1 == r2 )); CHECK(( r8-- == r7 )); CHECK(( r8 != r7 )); CHECK(( ++r8 == r7 )); /* abs tests */ #ifdef BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP // This is a nasty hack, required because some compilers do not implement // "Koenig Lookup". Basically, if I call abs(r), the C++ standard says that // the compiler should look for a definition of abs in the namespace which // contains r's class (in this case boost) - among other places. using boost::abs; #endif CHECK(( abs(r2) == r2 )); CHECK(( abs(r5) == r5 )); CHECK(( abs(r8) == rat(2,3) )); /* addition/subtraction tests */ CHECK(( rat(1,2) + rat(1,2) == 1 )); CHECK(( rat(11,3) + rat(1,2) == rat(25,6) )); CHECK(( rat(-8,3) + rat(1,5) == rat(-37,15) )); CHECK(( rat(-7,6) + rat(1,7) == rat(1,7) - rat(7,6) )); CHECK(( rat(13,5) - rat(1,2) == rat(21,10) )); CHECK(( rat(22,3) + 1 == rat(25,3) )); CHECK(( rat(12,7) - 2 == rat(-2,7) )); CHECK(( 3 + rat(4,5) == rat(19,5) )); CHECK(( 4 - rat(9,2) == rat(-1,2) )); rat r0(11); r0 -= rat(20,3); CHECK(( r0 == rat(13,3) )); r0 += rat(1,2); CHECK(( r0 == rat(29,6) )); r0 -= 5; CHECK(( r0 == rat(1,-6) )); r0 += rat(1,5); CHECK(( r0 == rat(1,30) )); r0 += 2; CHECK(( r0 == rat(61,30) )); /* assignment tests */ r0 = rat(1,10); CHECK(( r0 == rat(1,10) )); r0 = -9; CHECK(( r0 == rat(-9,1) )); /* unary operator tests */ CHECK(( +r5 == r5 )); CHECK(( -r3 != r3 )); CHECK(( -(-r3) == r3 )); CHECK(( -r4 == 3 )); CHECK(( !r2 )); CHECK(( !!r3 )); /* multiplication tests */ CHECK(( rat(1,3) * rat(-3,4) == rat(-1,4) )); CHECK(( rat(2,5) * 7 == rat(14,5) )); CHECK(( -2 * rat(1,6) == rat(-1,3) )); r0 = rat(3,7); r0 *= 14; CHECK(( r0 == 6 )); r0 *= rat(3,8); CHECK(( r0 == rat(9,4) )); /* division tests */ CHECK(( rat(-1,20) / rat(4,5) == rat(-1,16) )); CHECK(( rat(5,6) / 7 == rat(5,42) )); CHECK(( 8 / rat(2,7) == 28 )); r0 = rat(4,3); r0 /= rat(5,4); CHECK(( r0 == rat(16,15) )); r0 /= 4; CHECK(( r0 == rat(4,15) )); CHECK(( rat(-1)/rat(-3) == rat(1,3) )); /* tests for operations on self */ r0 = rat(4,3); r0 += r0; CHECK(( r0 == rat(8,3) )); r0 *= r0; CHECK(( r0 == rat(64,9) )); r0 /= r0; CHECK(( r0 == rat(1,1) )); r0 -= r0; CHECK(( r0 == rat(0,1) )); /* operator<< and operator>> tests */ #ifndef BOOST_NO_STRINGSTREAM std::ostringstream oss; oss << rat(44,14); CHECK(( oss.str() == "22/7" )); typedef std::istringstream input_string_stream; #else std::ostrstream oss; oss << rat(44,14) << char(); auto unfreezer unfreeze(oss); CHECK(( !std::strcmp(oss.str(), "22/7") )); typedef std::istrstream input_string_stream; #endif { input_string_stream iss(""); iss >> r0; CHECK(( !iss )); } { input_string_stream iss("42"); iss >> r0; CHECK(( !iss )); } { input_string_stream iss("57A"); iss >> r0; CHECK(( !iss )); } { input_string_stream iss("20-20"); iss >> r0; CHECK(( !iss )); } { input_string_stream iss("1/"); iss >> r0; CHECK(( !iss )); } { input_string_stream iss("1/ 2"); iss >> r0; CHECK(( !iss )); } { input_string_stream iss("1 /2"); iss >> r0; CHECK(( !iss )); } { int n; input_string_stream iss("1/2 12"); CHECK(( iss >> r0 >> n )); CHECK(( r0 == rat(1,2) )); CHECK(( n == 12 )); } { input_string_stream iss("34/67"); CHECK(( iss >> r0 )); CHECK(( r0 == rat(34,67) )); } { input_string_stream iss("-3/-6"); CHECK(( iss >> r0 )); CHECK(( r0 == rat(1,2) )); } /* rational cast tests */ /* Note that these are not generic. The problem is that rational_cast<T> * requires a conversion from IntType to T. However, for a user-defined * IntType, it is not possible to define such a conversion except as * an operator T(). This causes problems with overloading resolution. */ { boost::rational<int> half(1,2); CHECK(( boost::rational_cast<double>(half) == 0.5 )); CHECK(( boost::rational_cast<int>(half) == 0 )); } /* End of main tests. */ /* mean number of times a fair 6-sided die must be thrown until each side has appeared at least once */ r0 = IntType(0); for (int i=1; i<=6; ++i) r0 += rat(1,i); r0 *= 6; CHECK(( r0 == rat(147,10) )); } } // namespace // Macro hacking: STR(INT_TYPE) gives the integer type defined by the user *as // a string* for reporting below... #define STR(x) STR2(x) #define STR2(x) #x int main() { std::cout << "Running tests for boost::rational<" STR(INT_TYPE) ">\n\n"; std::cout << "Implementation issue: the minimal size for a rational\n" << "is twice the size of the underlying integer type.\n\n" << "Checking to see if space is being wasted.\n"; std::cout << " sizeof(" STR(INT_TYPE) ") == " << sizeof(INT_TYPE) << "\n"; std::cout << " sizeof(boost::rational<" STR(INT_TYPE) ">) == " << sizeof(boost::rational<INT_TYPE>) << "\n\n"; if (sizeof(boost::rational<INT_TYPE>) > 2 * sizeof(INT_TYPE)) std::cout << "Implementation has included padding bytes\n\n"; else std::cout << "Implementation has minimal size\n\n"; try { run_tests(); } catch ( ... ) { std::cout << "Unexpected exception!\n"; return EXIT_FAILURE; } unsigned int success_count = total_count - error_count; unsigned int pct = 100 * success_count / total_count; std::cout << success_count << "/" << total_count << " tests succeeded (" << pct << "%). \n"; return error_count; }