//===----------------------------------------------------------------------===// // // The LLVM Compiler Infrastructure // // This file is dual licensed under the MIT and the University of Illinois Open // Source Licenses. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // template void remove_if(Predicate pred); #include #include #include #include "min_allocator.h" #include "counting_predicates.hpp" bool g(int i) { return i < 3; } int main() { { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list C; const T t1[] = {0, 5, 5, 0, 0, 0, 5}; const T t2[] = {5, 5, 5}; C c1(std::begin(t1), std::end(t1)); C c2(std::begin(t2), std::end(t2)); Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == std::distance(std::begin(t1), std::end(t1))); } { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list C; const T t1[] = {0, 0, 0, 0}; C c1(std::begin(t1), std::end(t1)); C c2; Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == std::distance(std::begin(t1), std::end(t1))); } { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list C; const T t1[] = {5, 5, 5}; const T t2[] = {5, 5, 5}; C c1(std::begin(t1), std::end(t1)); C c2(std::begin(t2), std::end(t2)); Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == std::distance(std::begin(t1), std::end(t1))); } { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list C; C c1; C c2; Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == 0); } { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list C; const T t1[] = {5, 5, 5, 0}; const T t2[] = {5, 5, 5}; C c1(std::begin(t1), std::end(t1)); C c2(std::begin(t2), std::end(t2)); Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == std::distance(std::begin(t1), std::end(t1))); } #if __cplusplus >= 201103L { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list> C; const T t1[] = {0, 5, 5, 0, 0, 0, 5}; const T t2[] = {5, 5, 5}; C c1(std::begin(t1), std::end(t1)); C c2(std::begin(t2), std::end(t2)); Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == std::distance(std::begin(t1), std::end(t1))); } { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list> C; const T t1[] = {0, 0, 0, 0}; C c1(std::begin(t1), std::end(t1)); C c2; Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == std::distance(std::begin(t1), std::end(t1))); } { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list> C; const T t1[] = {5, 5, 5}; const T t2[] = {5, 5, 5}; C c1(std::begin(t1), std::end(t1)); C c2(std::begin(t2), std::end(t2)); Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == std::distance(std::begin(t1), std::end(t1))); } { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list> C; C c1; C c2; Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == 0); } { typedef int T; typedef unary_counting_predicate Predicate; typedef std::forward_list> C; const T t1[] = {5, 5, 5, 0}; const T t2[] = {5, 5, 5}; C c1(std::begin(t1), std::end(t1)); C c2(std::begin(t2), std::end(t2)); Predicate cp(g); c1.remove_if(std::ref(cp)); assert(c1 == c2); assert(cp.count() == std::distance(std::begin(t1), std::end(t1))); } #endif }