// ----------------------------------------------------------- // Copyright (c) 2001 Jeremy Siek // Copyright (c) 2003-2006, 2008 Gennaro Prota // Copyright (c) 2014 Ahmed Charles // Copyright (c) 2014 Riccardo Marcangelo // Copyright (c) 2018 Evgeny Shulgin // // Distributed under the Boost Software License, Version 1.0. // (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // // ----------------------------------------------------------- #ifndef BOOST_BITSET_TEST_HPP_GP_20040319 #define BOOST_BITSET_TEST_HPP_GP_20040319 #include #if !defined (BOOST_NO_STD_LOCALE) # include #endif #include #include // used for operator<< #include // for (basic_string and) getline() #include // for std::min #include // is sometimes macro-guarded :-( #include #include #include #include template inline bool nth_bit(Block num, std::size_t n) { #ifndef NDEBUG #ifdef __BORLANDC__ // Borland deduces Block as a const qualified type, // and thus finds numeric_limits to be zero :( // (though not directly relevant here, see also // lib issue 559) int block_width = sizeof(Block) * CHAR_BIT; #else int block_width = std::numeric_limits::digits; #endif assert(n < (std::size_t) block_width); #endif return (num >> n) & 1; } // A long, 'irregular', string useful for various tests std::string get_long_string() { const char * const p = // 6 5 4 3 2 1 // 3210987654321098765432109876543210987654321098765432109876543210 "1110011100011110000011110000011111110000000000000110101110000000" "1010101000011100011101010111110000101011111000001111100011100011" "0000000110000001000000111100000111100010101111111000000011100011" "1111111111111111111111111111111111111111111111111111111111111100" "1000001100000001111111111111110000000011111000111100001010100000" "101000111100011010101110011011000000010"; return std::string(p); } class scoped_temp_file { public: scoped_temp_file() : m_path(boost::filesystem::unique_path()) { } ~scoped_temp_file() { boost::filesystem::remove(m_path); } const boost::filesystem::path& path() const { return m_path; } private: boost::filesystem::path m_path; }; #if defined BOOST_OLD_IOSTREAMS || defined BOOST_NO_STD_LOCALE template bool is_one_or_zero(const Stream & /*s*/, char c) { return c == '1' || c == '0'; } template bool is_white_space(const Stream & /*s*/, char c) { return std::isspace(c); } #else template bool is_one_or_zero(const Stream& s, Ch c) { typedef typename Stream::traits_type Tr; const Ch zero = s.widen('0'); const Ch one = s.widen('1'); return Tr::eq(c, one) || Tr::eq(c, zero); } template bool is_white_space(const Stream & s, Ch c) { // NOTE: the using directive is to satisfy Borland 5.6.4 // with its own library (STLport), which doesn't // like std::isspace(c, loc) using namespace std; return isspace(c, s.getloc()); } #endif // defined BOOST_OLD_IOSTREAMS template bool has_flags(const Stream& s, std::ios::iostate flags) { return (s.rdstate() & flags) != std::ios::goodbit; } // constructors // default (can't do this generically) template struct bitset_test { typedef typename Bitset::block_type Block; BOOST_STATIC_CONSTANT(int, bits_per_block = Bitset::bits_per_block); // from unsigned long // // Note: this is templatized so that we check that the do-the-right-thing // constructor dispatch is working correctly. // template static void from_unsigned_long(NumBits num_bits, Value num) { // An object of size sz = num_bits is constructed: // - the first m bit positions are initialized to the corresponding // bit values in num (m being the smaller of sz and ulong_width) // // - any remaining bit positions are initialized to zero // Bitset b(static_cast(num_bits), static_cast(num)); // OK, we can now cast to size_type typedef typename Bitset::size_type size_type; const size_type sz = static_cast(num_bits); BOOST_TEST(b.size() == sz); const std::size_t ulong_width = std::numeric_limits::digits; size_type m = sz; if (ulong_width < sz) m = ulong_width; size_type i = 0; for ( ; i < m; ++i) BOOST_TEST(b.test(i) == nth_bit(static_cast(num), i)); for ( ; i < sz; ++i) BOOST_TEST(b.test(i) == 0); } // from string // // Note: The corresponding function in dynamic_bitset (constructor // from a string) has several default arguments. Actually we don't // test the correct working of those defaults here (except for the // default of num_bits). I'm not sure what to do in this regard. // // Note2: the default argument expression for num_bits doesn't use // static_cast, to avoid a gcc 2.95.3 'sorry, not implemented' // template static void from_string(const std::basic_string& str, std::size_t pos, std::size_t max_char, std::size_t num_bits = (std::size_t)(-1)) { std::size_t rlen = (std::min)(max_char, str.size() - pos); // The resulting size N of the bitset is num_bits, if // that is different from the default arg, rlen otherwise. // Put M = the smaller of N and rlen, then character // position pos + M - 1 corresponds to bit position zero. // Subsequent decreasing character positions correspond to // increasing bit positions. const bool size_upon_string = num_bits == (std::size_t)(-1); Bitset b = size_upon_string ? Bitset(str, pos, max_char) : Bitset(str, pos, max_char, num_bits); const std::size_t actual_size = size_upon_string? rlen : num_bits; BOOST_TEST(b.size() == actual_size); std::size_t m = (std::min)(num_bits, rlen); std::size_t j; for (j = 0; j < m; ++j) BOOST_TEST(b[j] == (str[pos + m - 1 - j] == '1')); // If M < N, remaining bit positions are zero for (; j < actual_size; ++j) BOOST_TEST(b[j] == 0); } static void to_block_range(const Bitset & b /*, BlockOutputIterator result*/) { typedef typename Bitset::size_type size_type; Block sentinel = 0xF0; int s = 8; // number of sentinels (must be *even*) int offset = s/2; std::vector v(b.num_blocks() + s, sentinel); boost::to_block_range(b, v.begin() + offset); assert(v.size() >= (size_type)s && (s >= 2) && (s % 2 == 0)); // check sentinels at both ends for(int i = 0; i < s/2; ++i) { BOOST_TEST(v[i] == sentinel); BOOST_TEST(v[v.size()-1-i] == sentinel); } typename std::vector::const_iterator p = v.begin() + offset; for(size_type n = 0; n < b.num_blocks(); ++n, ++p) { typename Bitset::block_width_type i = 0; for(; i < bits_per_block; ++i) { size_type bit = n * bits_per_block + i; BOOST_TEST(nth_bit(*p, i) == (bit < b.size()? b[bit] : 0)); } } } // TODO from_block_range (below) should be splitted // PRE: std::equal(first1, last1, first2) == true static void from_block_range(const std::vector& blocks) { { // test constructor from block range Bitset bset(blocks.begin(), blocks.end()); std::size_t n = blocks.size(); for (std::size_t b = 0; b < n; ++b) { typename Bitset::block_width_type i = 0; for (; i < bits_per_block; ++i) { std::size_t bit = b * bits_per_block + i; BOOST_TEST(bset[bit] == nth_bit(blocks[b], i)); } } BOOST_TEST(bset.size() == n * bits_per_block); } { // test boost::from_block_range const typename Bitset::size_type n = blocks.size(); Bitset bset(n * bits_per_block); boost::from_block_range(blocks.begin(), blocks.end(), bset); for (std::size_t b = 0; b < n; ++b) { typename Bitset::block_width_type i = 0; for (; i < bits_per_block; ++i) { std::size_t bit = b * bits_per_block + i; BOOST_TEST(bset[bit] == nth_bit(blocks[b], i)); } } BOOST_TEST(n <= bset.num_blocks()); } } // copy constructor (absent from std::bitset) static void copy_constructor(const Bitset& b) { Bitset copy(b); BOOST_TEST(b == copy); // Changes to the copy do not affect the original if (b.size() > 0) { std::size_t pos = copy.size() / 2; copy.flip(pos); BOOST_TEST(copy[pos] != b[pos]); } } // copy assignment operator (absent from std::bitset) static void copy_assignment_operator(const Bitset& lhs, const Bitset& rhs) { Bitset b(lhs); b = rhs; b = b; // self assignment check BOOST_TEST(b == rhs); // Changes to the copy do not affect the original if (b.size() > 0) { std::size_t pos = b.size() / 2; b.flip(pos); BOOST_TEST(b[pos] != rhs[pos]); } } static void max_size(const Bitset& b) { BOOST_TEST(b.max_size() > 0); } #ifndef BOOST_NO_CXX11_RVALUE_REFERENCES // move constructor (absent from std::bitset) static void move_constructor(const Bitset& b) { Bitset copy(boost::move(b)); BOOST_TEST(b == copy); } // move assignment operator (absent from std::bitset) static void move_assignment_operator(const Bitset& lhs, const Bitset& rhs) { Bitset b(lhs); Bitset c(rhs); b = boost::move(c); b = boost::move(b); // self assignment check BOOST_TEST(b == rhs); } #endif // BOOST_NO_CXX11_RVALUE_REFERENCES static void swap(const Bitset& lhs, const Bitset& rhs) { // bitsets must be swapped Bitset copy1(lhs); Bitset copy2(rhs); copy1.swap(copy2); BOOST_TEST(copy1 == rhs); BOOST_TEST(copy2 == lhs); // references must be stable under a swap for(typename Bitset::size_type i = 0; i < lhs.size(); ++i) { Bitset b1(lhs); Bitset b2(rhs); typename Bitset::reference ref = b1[i]; bool x = ref; if (i < b2.size()) b2[i] = !x; // make sure b2[i] is different b1.swap(b2); BOOST_TEST(b2[i] == x); // now it must be equal.. b2.flip(i); BOOST_TEST(ref == b2[i]); // .. and ref must be into b2 BOOST_TEST(ref == !x); } } static void resize(const Bitset& lhs) { Bitset b(lhs); // Test no change in size b.resize(lhs.size()); BOOST_TEST(b == lhs); // Test increase in size b.resize(lhs.size() * 2, true); std::size_t i; for (i = 0; i < lhs.size(); ++i) BOOST_TEST(b[i] == lhs[i]); for (; i < b.size(); ++i) BOOST_TEST(b[i] == true); // Test decrease in size b.resize(lhs.size()); for (i = 0; i < lhs.size(); ++i) BOOST_TEST(b[i] == lhs[i]); } static void clear(const Bitset& lhs) { Bitset b(lhs); b.clear(); BOOST_TEST(b.size() == 0); } static void pop_back(const Bitset& lhs) { Bitset b(lhs); b.pop_back(); BOOST_TEST(b.size() == lhs.size() - 1); for (std::size_t i = 0; i < b.size(); ++i) BOOST_TEST(b[i] == lhs[i]); b.pop_back(); BOOST_TEST(b.size() == lhs.size() - 2); for (std::size_t j = 0; j < b.size(); ++j) BOOST_TEST(b[j] == lhs[j]); } static void append_bit(const Bitset& lhs) { Bitset b(lhs); b.push_back(true); BOOST_TEST(b.size() == lhs.size() + 1); BOOST_TEST(b[b.size() - 1] == true); for (std::size_t i = 0; i < lhs.size(); ++i) BOOST_TEST(b[i] == lhs[i]); b.push_back(false); BOOST_TEST(b.size() == lhs.size() + 2); BOOST_TEST(b[b.size() - 1] == false); BOOST_TEST(b[b.size() - 2] == true); for (std::size_t j = 0; j < lhs.size(); ++j) BOOST_TEST(b[j] == lhs[j]); } static void append_block(const Bitset& lhs) { Bitset b(lhs); Block value(128); b.append(value); BOOST_TEST(b.size() == lhs.size() + bits_per_block); for (typename Bitset::block_width_type i = 0; i < bits_per_block; ++i) BOOST_TEST(b[lhs.size() + i] == bool((value >> i) & 1)); } static void append_block_range(const Bitset& lhs, const std::vector& blocks) { Bitset b(lhs), c(lhs); b.append(blocks.begin(), blocks.end()); for (typename std::vector::const_iterator i = blocks.begin(); i != blocks.end(); ++i) c.append(*i); BOOST_TEST(b == c); } // operator[] and reference members // PRE: b[i] == bit_vec[i] static void operator_bracket(const Bitset& lhs, const std::vector& bit_vec) { Bitset b(lhs); std::size_t i, j, k; // x = b[i] // x = ~b[i] for (i = 0; i < b.size(); ++i) { bool x = b[i]; BOOST_TEST(x == bit_vec[i]); x = ~b[i]; BOOST_TEST(x == !bit_vec[i]); } Bitset prev(b); // b[i] = x for (j = 0; j < b.size(); ++j) { bool x = !prev[j]; b[j] = x; for (k = 0; k < b.size(); ++k) if (j == k) BOOST_TEST(b[k] == x); else BOOST_TEST(b[k] == prev[k]); b[j] = prev[j]; } b.flip(); // b[i] = b[j] for (i = 0; i < b.size(); ++i) { b[i] = prev[i]; for (j = 0; j < b.size(); ++j) { if (i == j) BOOST_TEST(b[j] == prev[j]); else BOOST_TEST(b[j] == !prev[j]); } b[i] = !prev[i]; } // b[i].flip() for (i = 0; i < b.size(); ++i) { b[i].flip(); for (j = 0; j < b.size(); ++j) { if (i == j) BOOST_TEST(b[j] == prev[j]); else BOOST_TEST(b[j] == !prev[j]); } b[i].flip(); } } //=========================================================================== // bitwise operators // bitwise and assignment // PRE: b.size() == rhs.size() static void and_assignment(const Bitset& b, const Bitset& rhs) { Bitset lhs(b); Bitset prev(lhs); lhs &= rhs; // Clears each bit in lhs for which the corresponding bit in rhs is // clear, and leaves all other bits unchanged. for (std::size_t I = 0; I < lhs.size(); ++I) if (rhs[I] == 0) BOOST_TEST(lhs[I] == 0); else BOOST_TEST(lhs[I] == prev[I]); } // PRE: b.size() == rhs.size() static void or_assignment(const Bitset& b, const Bitset& rhs) { Bitset lhs(b); Bitset prev(lhs); lhs |= rhs; // Sets each bit in lhs for which the corresponding bit in rhs is set, and // leaves all other bits unchanged. for (std::size_t I = 0; I < lhs.size(); ++I) if (rhs[I] == 1) BOOST_TEST(lhs[I] == 1); else BOOST_TEST(lhs[I] == prev[I]); } // PRE: b.size() == rhs.size() static void xor_assignment(const Bitset& b, const Bitset& rhs) { Bitset lhs(b); Bitset prev(lhs); lhs ^= rhs; // Flips each bit in lhs for which the corresponding bit in rhs is set, // and leaves all other bits unchanged. for (std::size_t I = 0; I < lhs.size(); ++I) if (rhs[I] == 1) BOOST_TEST(lhs[I] == !prev[I]); else BOOST_TEST(lhs[I] == prev[I]); } // PRE: b.size() == rhs.size() static void sub_assignment(const Bitset& b, const Bitset& rhs) { Bitset lhs(b); Bitset prev(lhs); lhs -= rhs; // Resets each bit in lhs for which the corresponding bit in rhs is set, // and leaves all other bits unchanged. for (std::size_t I = 0; I < lhs.size(); ++I) if (rhs[I] == 1) BOOST_TEST(lhs[I] == 0); else BOOST_TEST(lhs[I] == prev[I]); } static void shift_left_assignment(const Bitset& b, std::size_t pos) { Bitset lhs(b); Bitset prev(lhs); lhs <<= pos; // Replaces each bit at position I in lhs with the following value: // - If I < pos, the new value is zero // - If I >= pos, the new value is the previous value of the bit at // position I - pos for (std::size_t I = 0; I < lhs.size(); ++I) if (I < pos) BOOST_TEST(lhs[I] == 0); else BOOST_TEST(lhs[I] == prev[I - pos]); } static void shift_right_assignment(const Bitset& b, std::size_t pos) { Bitset lhs(b); Bitset prev(lhs); lhs >>= pos; // Replaces each bit at position I in lhs with the following value: // - If pos >= N - I, the new value is zero // - If pos < N - I, the new value is the previous value of the bit at // position I + pos std::size_t N = lhs.size(); for (std::size_t I = 0; I < N; ++I) if (pos >= N - I) BOOST_TEST(lhs[I] == 0); else BOOST_TEST(lhs[I] == prev[I + pos]); } static void set_all(const Bitset& b) { Bitset lhs(b); lhs.set(); for (std::size_t I = 0; I < lhs.size(); ++I) BOOST_TEST(lhs[I] == 1); } static void set_one(const Bitset& b, std::size_t pos, bool value) { Bitset lhs(b); std::size_t N = lhs.size(); if (pos < N) { Bitset prev(lhs); // Stores a new value in the bit at position pos in lhs. lhs.set(pos, value); BOOST_TEST(lhs[pos] == value); // All other values of lhs remain unchanged for (std::size_t I = 0; I < N; ++I) if (I != pos) BOOST_TEST(lhs[I] == prev[I]); } else { // Not in range, doesn't satisfy precondition. } } static void set_segment(const Bitset& b, std::size_t pos, std::size_t len, bool value) { Bitset lhs(b); std::size_t N = lhs.size(); Bitset prev(lhs); lhs.set(pos, len, value); for (std::size_t I = 0; I < N; ++I) { if (I < pos || I >= pos + len) BOOST_TEST(lhs[I] == prev[I]); else BOOST_TEST(lhs[I] == value); } } static void reset_all(const Bitset& b) { Bitset lhs(b); // Resets all bits in lhs lhs.reset(); for (std::size_t I = 0; I < lhs.size(); ++I) BOOST_TEST(lhs[I] == 0); } static void reset_one(const Bitset& b, std::size_t pos) { Bitset lhs(b); std::size_t N = lhs.size(); if (pos < N) { Bitset prev(lhs); lhs.reset(pos); // Resets the bit at position pos in lhs BOOST_TEST(lhs[pos] == 0); // All other values of lhs remain unchanged for (std::size_t I = 0; I < N; ++I) if (I != pos) BOOST_TEST(lhs[I] == prev[I]); } else { // Not in range, doesn't satisfy precondition. } } static void reset_segment(const Bitset& b, std::size_t pos, std::size_t len) { Bitset lhs(b); std::size_t N = lhs.size(); Bitset prev(lhs); lhs.reset(pos, len); for (std::size_t I = 0; I < N; ++I) { if (I < pos || I >= pos + len) BOOST_TEST(lhs[I] == prev[I]); else BOOST_TEST(!lhs[I]); } } static void operator_flip(const Bitset& b) { Bitset lhs(b); Bitset x(lhs); BOOST_TEST(~lhs == x.flip()); } static void flip_all(const Bitset& b) { Bitset lhs(b); std::size_t N = lhs.size(); Bitset prev(lhs); lhs.flip(); // Toggles all the bits in lhs for (std::size_t I = 0; I < N; ++I) BOOST_TEST(lhs[I] == !prev[I]); } static void flip_one(const Bitset& b, std::size_t pos) { Bitset lhs(b); std::size_t N = lhs.size(); if (pos < N) { Bitset prev(lhs); lhs.flip(pos); // Toggles the bit at position pos in lhs BOOST_TEST(lhs[pos] == !prev[pos]); // All other values of lhs remain unchanged for (std::size_t I = 0; I < N; ++I) if (I != pos) BOOST_TEST(lhs[I] == prev[I]); } else { // Not in range, doesn't satisfy precondition. } } static void flip_segment(const Bitset& b, std::size_t pos, std::size_t len) { Bitset lhs(b); std::size_t N = lhs.size(); Bitset prev(lhs); lhs.flip(pos, len); for (std::size_t I = 0; I < N; ++I) { if (I < pos || I >= pos + len) BOOST_TEST(lhs[I] == prev[I]); else BOOST_TEST(lhs[I] != prev[I]); } } // empty static void empty(const Bitset& b) { BOOST_TEST(b.empty() == (b.size() == 0)); } // to_ulong() static void to_ulong(const Bitset& lhs) { typedef unsigned long result_type; std::size_t n = std::numeric_limits::digits; std::size_t sz = lhs.size(); bool will_overflow = false; for (std::size_t i = n; i < sz; ++i) { if (lhs.test(i) != 0) { will_overflow = true; break; } } if (will_overflow) { try { (void)lhs.to_ulong(); BOOST_TEST(false); // It should have thrown an exception } catch (std::overflow_error & ex) { // Good! BOOST_TEST(!!ex.what()); } catch (...) { BOOST_TEST(false); // threw the wrong exception } } else { result_type num = lhs.to_ulong(); // Be sure the number is right if (sz == 0) BOOST_TEST(num == 0); else { for (std::size_t i = 0; i < sz; ++i) BOOST_TEST(lhs[i] == (i < n ? nth_bit(num, i) : 0)); } } } // to_string() static void to_string(const Bitset& b) { std::string str; boost::to_string(b, str); BOOST_TEST(str.size() == b.size()); for (std::size_t i = 0; i < b.size(); ++i) BOOST_TEST(str[b.size() - 1 - i] ==(b.test(i)? '1':'0')); } static void count(const Bitset& b) { std::size_t c = b.count(); std::size_t actual = 0; for (std::size_t i = 0; i < b.size(); ++i) if (b[i]) ++actual; BOOST_TEST(c == actual); } static void size(const Bitset& b) { BOOST_TEST(Bitset(b).set().count() == b.size()); } static void capacity_test_one(const Bitset& lhs) { //empty bitset Bitset b(lhs); BOOST_TEST(b.capacity() == 0); } static void capacity_test_two(const Bitset& lhs) { //bitset constructed with size "100" Bitset b(lhs); BOOST_TEST(b.capacity() >= 100); b.resize(200); BOOST_TEST(b.capacity() >= 200); } static void reserve_test_one(const Bitset& lhs) { //empty bitset Bitset b(lhs); b.reserve(16); BOOST_TEST(b.capacity() >= 16); } static void reserve_test_two(const Bitset& lhs) { //bitset constructed with size "100" Bitset b(lhs); BOOST_TEST(b.capacity() >= 100); b.reserve(60); BOOST_TEST(b.size() == 100); BOOST_TEST(b.capacity() >= 100); b.reserve(160); BOOST_TEST(b.size() == 100); BOOST_TEST(b.capacity() >= 160); } static void shrink_to_fit_test_one(const Bitset& lhs) { //empty bitset Bitset b(lhs); b.shrink_to_fit(); BOOST_TEST(b.size() == 0); BOOST_TEST(b.capacity() == 0); } static void shrink_to_fit_test_two(const Bitset& lhs) { //bitset constructed with size "100" Bitset b(lhs); b.shrink_to_fit(); BOOST_TEST(b.capacity() >= 100); BOOST_TEST(b.size() == 100); b.reserve(200); BOOST_TEST(b.capacity() >= 200); BOOST_TEST(b.size() == 100); b.shrink_to_fit(); BOOST_TEST(b.capacity() < 200); BOOST_TEST(b.size() == 100); } static void all(const Bitset& b) { BOOST_TEST(b.all() == (b.count() == b.size())); bool result = true; for(std::size_t i = 0; i < b.size(); ++i) if(!b[i]) { result = false; break; } BOOST_TEST(b.all() == result); } static void any(const Bitset& b) { BOOST_TEST(b.any() == (b.count() != 0)); bool result = false; for(std::size_t i = 0; i < b.size(); ++i) if(b[i]) { result = true; break; } BOOST_TEST(b.any() == result); } static void none(const Bitset& b) { bool result = true; for(std::size_t i = 0; i < b.size(); ++i) { if(b[i]) { result = false; break; } } BOOST_TEST(b.none() == result); // sanity BOOST_TEST(b.none() == !b.any()); BOOST_TEST(b.none() == (b.count() == 0)); } static void subset(const Bitset& a, const Bitset& b) { BOOST_TEST(a.size() == b.size()); // PRE bool is_subset = true; if (b.size()) { // could use b.any() but let's be safe for(std::size_t i = 0; i < a.size(); ++i) { if(a.test(i) && !b.test(i)) { is_subset = false; break; } } } else { // sanity BOOST_TEST(a.count() == 0); BOOST_TEST(a.any() == false); //is_subset = (a.any() == false); } BOOST_TEST(a.is_subset_of(b) == is_subset); } static void proper_subset(const Bitset& a, const Bitset& b) { // PRE: a.size() == b.size() BOOST_TEST(a.size() == b.size()); bool is_proper = false; if (b.size() != 0) { // check it's a subset subset(a, b); // is it proper? for (std::size_t i = 0; i < a.size(); ++i) { if (!a.test(i) && b.test(i)) { is_proper = true; // sanity BOOST_TEST(a.count() < b.count()); BOOST_TEST(b.any()); } } } BOOST_TEST(a.is_proper_subset_of(b) == is_proper); if (is_proper) BOOST_TEST(b.is_proper_subset_of(a) != is_proper);// antisymmetry } static void intersects(const Bitset& a, const Bitset& b) { bool have_intersection = false; typename Bitset::size_type m = a.size() < b.size() ? a.size() : b.size(); for(typename Bitset::size_type i = 0; i < m && !have_intersection; ++i) if(a[i] == true && b[i] == true) have_intersection = true; BOOST_TEST(a.intersects(b) == have_intersection); // also check commutativity BOOST_TEST(b.intersects(a) == have_intersection); } static void find_first(const Bitset& b) { // find first non-null bit, if any typename Bitset::size_type i = 0; while (i < b.size() && b[i] == 0) ++i; if (i == b.size()) BOOST_TEST(b.find_first() == Bitset::npos); // not found; else { BOOST_TEST(b.find_first() == i); BOOST_TEST(b.test(i) == true); } } static void find_next(const Bitset& b, typename Bitset::size_type prev) { BOOST_TEST(next_bit_on(b, prev) == b.find_next(prev)); } static void operator_equal(const Bitset& a, const Bitset& b) { if (a == b) { for (std::size_t I = 0; I < a.size(); ++I) BOOST_TEST(a[I] == b[I]); } else { if (a.size() == b.size()) { bool diff = false; for (std::size_t I = 0; I < a.size(); ++I) if (a[I] != b[I]) { diff = true; break; } BOOST_TEST(diff); } } } static void operator_not_equal(const Bitset& a, const Bitset& b) { if (a != b) { if (a.size() == b.size()) { bool diff = false; for (std::size_t I = 0; I < a.size(); ++I) if (a[I] != b[I]) { diff = true; break; } BOOST_TEST(diff); } } else { for (std::size_t I = 0; I < a.size(); ++I) BOOST_TEST(a[I] == b[I]); } } static bool less_than(const Bitset& a, const Bitset& b) { typedef BOOST_DEDUCED_TYPENAME Bitset::size_type size_type; size_type asize(a.size()); size_type bsize(b.size()); if (!bsize) { return false; } else if (!asize) { return true; } else { // Compare from most significant to least. size_type leqsize(std::min BOOST_PREVENT_MACRO_SUBSTITUTION(asize,bsize)); size_type I; for (I = 0; I < leqsize; ++I,--asize,--bsize) { size_type i = asize-1; size_type j = bsize-1; if (a[i] < b[j]) return true; else if (a[i] > b[j]) return false; // if (a[i] = b[j]) skip to next } return (a.size() < b.size()); } } static typename Bitset::size_type next_bit_on(const Bitset& b, typename Bitset::size_type prev) { // helper function for find_next() // if (b.none() == true || prev == Bitset::npos) return Bitset::npos; ++prev; if (prev >= b.size()) return Bitset::npos; typename Bitset::size_type i = prev; while (i < b.size() && b[i] == 0) ++i; return i==b.size() ? Bitset::npos : i; } static void operator_less_than(const Bitset& a, const Bitset& b) { if (less_than(a, b)) BOOST_TEST(a < b); else BOOST_TEST(!(a < b)); } static void operator_greater_than(const Bitset& a, const Bitset& b) { if (less_than(a, b) || a == b) BOOST_TEST(!(a > b)); else BOOST_TEST(a > b); } static void operator_less_than_eq(const Bitset& a, const Bitset& b) { if (less_than(a, b) || a == b) BOOST_TEST(a <= b); else BOOST_TEST(!(a <= b)); } static void operator_greater_than_eq(const Bitset& a, const Bitset& b) { if (less_than(a, b)) BOOST_TEST(!(a >= b)); else BOOST_TEST(a >= b); } static void test_bit(const Bitset& b, std::size_t pos) { Bitset lhs(b); std::size_t N = lhs.size(); if (pos < N) { BOOST_TEST(lhs.test(pos) == lhs[pos]); } else { // Not in range, doesn't satisfy precondition. } } static void test_set_bit(const Bitset& b, std::size_t pos, bool value) { Bitset lhs(b); std::size_t N = lhs.size(); if (pos < N) { Bitset prev(lhs); // Stores a new value in the bit at position pos in lhs. BOOST_TEST(lhs.test_set(pos, value) == prev[pos]); BOOST_TEST(lhs[pos] == value); // All other values of lhs remain unchanged for (std::size_t I = 0; I < N; ++I) if (I != pos) BOOST_TEST(lhs[I] == prev[I]); } else { // Not in range, doesn't satisfy precondition. } } static void operator_shift_left(const Bitset& lhs, std::size_t pos) { Bitset x(lhs); BOOST_TEST((lhs << pos) == (x <<= pos)); } static void operator_shift_right(const Bitset& lhs, std::size_t pos) { Bitset x(lhs); BOOST_TEST((lhs >> pos) == (x >>= pos)); } // operator| static void operator_or(const Bitset& lhs, const Bitset& rhs) { Bitset x(lhs); BOOST_TEST((lhs | rhs) == (x |= rhs)); } // operator& static void operator_and(const Bitset& lhs, const Bitset& rhs) { Bitset x(lhs); BOOST_TEST((lhs & rhs) == (x &= rhs)); } // operator^ static void operator_xor(const Bitset& lhs, const Bitset& rhs) { Bitset x(lhs); BOOST_TEST((lhs ^ rhs) == (x ^= rhs)); } // operator- static void operator_sub(const Bitset& lhs, const Bitset& rhs) { Bitset x(lhs); BOOST_TEST((lhs - rhs) == (x -= rhs)); } //------------------------------------------------------------------------------ // I/O TESTS // The following tests assume the results of extraction (i.e.: contents, // state and width of is, contents of b) only depend on input (the string // str). In other words, they don't consider "unexpected" errors such as // stream corruption or out of memory. The reason is simple: if e.g. the // stream buffer throws, the stream layer may eat the exception and // transform it into a badbit. But we can't trust the stream state here, // because one of the things that we want to test is exactly whether it // is set correctly. Similarly for insertion. // // To provide for these cases would require that the test functions know // in advance whether the stream buffer and/or allocations will fail, and // when; that is, we should write both a special allocator and a special // stream buffer capable of throwing "on demand" and pass them here. // Seems overkill for these kinds of unit tests. //------------------------------------------------------------------------- // operator<<( [basic_]ostream, template static void stream_inserter(const Bitset & b, Stream & s, const char * file_name ) { #if defined BOOST_OLD_IOSTREAMS typedef char char_type; typedef std::string string_type; typedef ifstream corresponding_input_stream_type; #else typedef typename Stream::char_type char_type; typedef std::basic_string string_type; typedef std::basic_ifstream corresponding_input_stream_type; std::ios::iostate except = s.exceptions(); #endif typedef typename Bitset::size_type size_type; std::streamsize w = s.width(); char_type fill_char = s.fill(); std::ios::iostate oldstate = s.rdstate(); bool stream_was_good = s.good(); bool did_throw = false; try { s << b; } #if defined BOOST_OLD_IOSTREAMS catch(...) { BOOST_TEST(false); } #else catch (const std::ios_base::failure &) { BOOST_TEST((except & s.rdstate()) != 0); did_throw = true; } catch (...) { did_throw = true; } #endif BOOST_TEST(did_throw || !stream_was_good || (s.width() == 0)); if (!stream_was_good) { BOOST_TEST(s.good() == false); // this should actually be oldstate == s.rdstate() // but some implementations add badbit in the // sentry constructor // BOOST_TEST((oldstate & s.rdstate()) == oldstate); BOOST_TEST(s.width() == w); } else { if(!did_throw) BOOST_TEST(s.width() == 0); // This test require that os be an output _and_ input stream. // Of course dynamic_bitset's operator << doesn't require that. size_type total_len = w <= 0 || static_cast(w) < b.size()? b.size() : static_cast(w); const string_type padding (total_len - b.size(), fill_char); string_type expected; boost::to_string(b, expected); if ((s.flags() & std::ios::adjustfield) != std::ios::left) expected = padding + expected; else expected = expected + padding; assert(expected.length() == total_len); // close, and reopen the file stream to verify contents s.close(); corresponding_input_stream_type is(file_name); string_type contents; std::getline(is, contents, char_type()); BOOST_TEST(contents == expected); } } // operator>>( [basic_]istream template static void stream_extractor(Bitset& b, Stream& is, String& str ) { // save necessary info then do extraction // const std::streamsize w = is.width(); Bitset a_copy(b); bool stream_was_good = is.good(); bool did_throw = false; #if defined BOOST_OLD_IOSTREAMS bool has_stream_exceptions = false; is >> b; #else const std::ios::iostate except = is.exceptions(); bool has_stream_exceptions = true; try { is >> b; } catch(const std::ios::failure &) { did_throw = true; } // postconditions BOOST_TEST(except == is.exceptions()); // paranoid #endif //------------------------------------------------------------------ // postconditions BOOST_TEST(b.size() <= b.max_size()); if(w > 0) BOOST_TEST(b.size() <= static_cast(w)); // throw if and only if required if(has_stream_exceptions) { const bool exceptional_state = has_flags(is, is.exceptions()); BOOST_TEST(exceptional_state == did_throw); } typedef typename String::size_type size_type; typedef typename String::value_type Ch; size_type after_digits = 0; if(!stream_was_good) { BOOST_TEST(has_flags(is, std::ios::failbit)); BOOST_TEST(b == a_copy); BOOST_TEST(is.width() == (did_throw ? w : 0)); } else { // stream was good(), parse the string; // it may contain three parts, all of which are optional // {spaces} {digits} {non-digits} // opt opt opt // // The values of b.max_size() and is.width() may lead to // ignore part of the digits, if any. size_type pos = 0; size_type len = str.length(); // {spaces} for( ; pos < len && is_white_space(is, str[pos]); ++pos) {} size_type after_spaces = pos; // {digits} or part of them const typename Bitset::size_type max_digits = w > 0 && static_cast(w) < b.max_size() ? static_cast(w) : b.max_size(); for( ; pos < len && (pos - after_spaces) < max_digits; ++pos) { if(!is_one_or_zero(is, str[pos])) break; } after_digits = pos; size_type num_digits = after_digits - after_spaces; // eofbit if((after_digits == len && max_digits > num_digits )) BOOST_TEST(has_flags(is, std::ios::eofbit)); else BOOST_TEST(!has_flags(is, std::ios::eofbit)); // failbit <=> there are no digits, except for the library // issue explained below. // if(num_digits == 0) { if(after_digits == len && has_stream_exceptions && (is.exceptions() & std::ios::eofbit) != std::ios::goodbit) { // This is a special case related to library issue 195: // reaching eof when skipping whitespaces in the sentry ctor. // The resolution says the sentry constructor should set *both* // eofbit and failbit; but many implementations deliberately // set eofbit only. See for instance: // http://gcc.gnu.org/ml/libstdc++/2000-q1/msg00086.html // BOOST_TEST(did_throw); } else { BOOST_TEST(has_flags(is, std::ios::failbit)); } } else BOOST_TEST(!has_flags(is, std::ios::failbit)); if(num_digits == 0 && after_digits == len) { // The VC6 library has a bug/non-conformity in the sentry // constructor. It uses code like // // skip whitespaces... // int_type _C = rdbuf()->sgetc(); // while (!_Tr::eq_int_type(_Tr::eof(), _C) ... // // For an empty file the while statement is never "entered" // and the stream remains in good() state; thus the sentry // object gives "true" when converted to bool. This is worse // than the case above, because not only failbit is not set, // but no bit is set at all, end we end up clearing the // bitset though there's nothing in the file to be extracted. // Note that the dynamic_bitset docs say a sentry object is // constructed and then converted to bool, thus we rely on // what the underlying library does. // #if !defined(BOOST_DINKUMWARE_STDLIB) || (BOOST_DINKUMWARE_STDLIB >= 306) BOOST_TEST(b == a_copy); #else BOOST_TEST(b.empty() == true); #endif } else { String sub = str.substr(after_spaces, num_digits); BOOST_TEST(b == Bitset(sub)); } // check width BOOST_TEST(is.width() == 0 || (after_digits == len && num_digits == 0 && did_throw)); } // clear the stream to allow further reading then // retrieve any remaining chars with a single getline() is.exceptions(std::ios::goodbit); is.clear(); String remainder; std::getline(is, remainder, Ch()); if(stream_was_good) BOOST_TEST(remainder == str.substr(after_digits)); else BOOST_TEST(remainder == str); } }; #endif // include guard