// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2011 Benoit Jacob <jacob.benoit.1@gmail.com> // // This Source Code Form is subject to the terms of the Mozilla // Public License v. 2.0. If a copy of the MPL was not distributed // with this file, You can obtain one at http://mozilla.org/MPL/2.0/. #include "main.h" #define VERIFY_THROWS_BADALLOC(a) { \ bool threw = false; \ try { \ a; \ } \ catch (std::bad_alloc&) { threw = true; } \ VERIFY(threw && "should have thrown bad_alloc: " #a); \ } typedef DenseIndex Index; template<typename MatrixType> void triggerMatrixBadAlloc(Index rows, Index cols) { VERIFY_THROWS_BADALLOC( MatrixType m(rows, cols) ); VERIFY_THROWS_BADALLOC( MatrixType m; m.resize(rows, cols) ); VERIFY_THROWS_BADALLOC( MatrixType m; m.conservativeResize(rows, cols) ); } template<typename VectorType> void triggerVectorBadAlloc(Index size) { VERIFY_THROWS_BADALLOC( VectorType v(size) ); VERIFY_THROWS_BADALLOC( VectorType v; v.resize(size) ); VERIFY_THROWS_BADALLOC( VectorType v; v.conservativeResize(size) ); } void test_sizeoverflow() { // there are 2 levels of overflow checking. first in PlainObjectBase.h we check for overflow in rows*cols computations. // this is tested in tests of the form times_itself_gives_0 * times_itself_gives_0 // Then in Memory.h we check for overflow in size * sizeof(T) computations. // this is tested in tests of the form times_4_gives_0 * sizeof(float) size_t times_itself_gives_0 = size_t(1) << (8 * sizeof(Index) / 2); VERIFY(times_itself_gives_0 * times_itself_gives_0 == 0); size_t times_4_gives_0 = size_t(1) << (8 * sizeof(Index) - 2); VERIFY(times_4_gives_0 * 4 == 0); size_t times_8_gives_0 = size_t(1) << (8 * sizeof(Index) - 3); VERIFY(times_8_gives_0 * 8 == 0); triggerMatrixBadAlloc<MatrixXf>(times_itself_gives_0, times_itself_gives_0); triggerMatrixBadAlloc<MatrixXf>(times_itself_gives_0 / 4, times_itself_gives_0); triggerMatrixBadAlloc<MatrixXf>(times_4_gives_0, 1); triggerMatrixBadAlloc<MatrixXd>(times_itself_gives_0, times_itself_gives_0); triggerMatrixBadAlloc<MatrixXd>(times_itself_gives_0 / 8, times_itself_gives_0); triggerMatrixBadAlloc<MatrixXd>(times_8_gives_0, 1); triggerVectorBadAlloc<VectorXf>(times_4_gives_0); triggerVectorBadAlloc<VectorXd>(times_8_gives_0); }