//Has to be first for StackAllocator swap overload to be taken
//into account (at least using GCC 4.0.1)
#include "stack_allocator.h"
#include <deque>
#include <algorithm>
#if !defined (STLPORT) || defined (_STLP_USE_EXCEPTIONS)
# include <stdexcept>
#endif
#include "cppunit/cppunit_proxy.h"
#if !defined (STLPORT) || defined(_STLP_USE_NAMESPACES)
using namespace std;
#endif
//
// TestCase class
//
class DequeTest : public CPPUNIT_NS::TestCase
{
CPPUNIT_TEST_SUITE(DequeTest);
CPPUNIT_TEST(deque1);
CPPUNIT_TEST(at);
CPPUNIT_TEST(insert);
CPPUNIT_TEST(erase);
CPPUNIT_TEST(auto_ref);
CPPUNIT_TEST(allocator_with_state);
#if defined (STLPORT) && defined (_STLP_NO_MEMBER_TEMPLATES)
CPPUNIT_IGNORE;
#endif
CPPUNIT_TEST(optimizations_check);
CPPUNIT_TEST_SUITE_END();
protected:
void deque1();
void insert();
void erase();
void at();
void auto_ref();
void allocator_with_state();
void optimizations_check();
};
CPPUNIT_TEST_SUITE_REGISTRATION(DequeTest);
//
// tests implementation
//
void DequeTest::deque1()
{
deque<int> d;
d.push_back(4);
d.push_back(9);
d.push_back(16);
d.push_front(1);
CPPUNIT_ASSERT( d[0] == 1 );
CPPUNIT_ASSERT( d[1] == 4 );
CPPUNIT_ASSERT( d[2] == 9 );
CPPUNIT_ASSERT( d[3] == 16 );
d.pop_front();
d[2] = 25;
CPPUNIT_ASSERT( d[0] == 4 );
CPPUNIT_ASSERT( d[1] == 9 );
CPPUNIT_ASSERT( d[2] == 25 );
//Some compile time tests:
deque<int>::iterator dit = d.begin();
deque<int>::const_iterator cdit(d.begin());
CPPUNIT_ASSERT( (dit - cdit) == 0 );
CPPUNIT_ASSERT( (cdit - dit) == 0 );
CPPUNIT_ASSERT( (dit - dit) == 0 );
CPPUNIT_ASSERT( (cdit - cdit) == 0 );
CPPUNIT_ASSERT(!((dit < cdit) || (dit > cdit) || (dit != cdit) || !(dit <= cdit) || !(dit >= cdit)));
}
void DequeTest::insert()
{
deque<int> d;
d.push_back(0);
d.push_back(1);
d.push_back(2);
CPPUNIT_ASSERT( d.size() == 3 );
deque<int>::iterator dit;
//Insertion before begin:
dit = d.insert(d.begin(), 3);
CPPUNIT_ASSERT( dit != d.end() );
CPPUNIT_CHECK( *dit == 3 );
CPPUNIT_ASSERT( d.size() == 4 );
CPPUNIT_ASSERT( d[0] == 3 );
//Insertion after begin:
dit = d.insert(d.begin() + 1, 4);
CPPUNIT_ASSERT( dit != d.end() );
CPPUNIT_CHECK( *dit == 4 );
CPPUNIT_ASSERT( d.size() == 5 );
CPPUNIT_ASSERT( d[1] == 4 );
//Insertion at end:
dit = d.insert(d.end(), 5);
CPPUNIT_ASSERT( dit != d.end() );
CPPUNIT_CHECK( *dit == 5 );
CPPUNIT_ASSERT( d.size() == 6 );
CPPUNIT_ASSERT( d[5] == 5 );
//Insertion before last element:
dit = d.insert(d.end() - 1, 6);
CPPUNIT_ASSERT( dit != d.end() );
CPPUNIT_CHECK( *dit == 6 );
CPPUNIT_ASSERT( d.size() == 7 );
CPPUNIT_ASSERT( d[5] == 6 );
//Insertion of several elements before begin
d.insert(d.begin(), 2, 7);
CPPUNIT_ASSERT( d.size() == 9 );
CPPUNIT_ASSERT( d[0] == 7 );
CPPUNIT_ASSERT( d[1] == 7 );
//Insertion of several elements after begin
//There is more elements to insert than elements before insertion position
d.insert(d.begin() + 1, 2, 8);
CPPUNIT_ASSERT( d.size() == 11 );
CPPUNIT_ASSERT( d[1] == 8 );
CPPUNIT_ASSERT( d[2] == 8 );
//There is less elements to insert than elements before insertion position
d.insert(d.begin() + 3, 2, 9);
CPPUNIT_ASSERT( d.size() == 13 );
CPPUNIT_ASSERT( d[3] == 9 );
CPPUNIT_ASSERT( d[4] == 9 );
//Insertion of several elements at end:
d.insert(d.end(), 2, 10);
CPPUNIT_ASSERT( d.size() == 15 );
CPPUNIT_ASSERT( d[14] == 10 );
CPPUNIT_ASSERT( d[13] == 10 );
//Insertion of several elements before last:
//There is more elements to insert than elements after insertion position
d.insert(d.end() - 1, 2, 11);
CPPUNIT_ASSERT( d.size() == 17 );
CPPUNIT_ASSERT( d[15] == 11 );
CPPUNIT_ASSERT( d[14] == 11 );
//There is less elements to insert than elements after insertion position
d.insert(d.end() - 3, 2, 12);
CPPUNIT_ASSERT( d.size() == 19 );
CPPUNIT_ASSERT( d[15] == 12 );
CPPUNIT_ASSERT( d[14] == 12 );
}
void DequeTest::at() {
deque<int> d;
deque<int> const& cd = d;
d.push_back(10);
CPPUNIT_ASSERT( d.at(0) == 10 );
d.at(0) = 20;
CPPUNIT_ASSERT( cd.at(0) == 20 );
#if !defined (STLPORT) || defined (_STLP_USE_EXCEPTIONS)
for (;;) {
try {
d.at(1) = 20;
CPPUNIT_ASSERT(false);
}
catch (out_of_range const&) {
return;
}
catch (...) {
CPPUNIT_ASSERT(false);
}
}
#endif
}
void DequeTest::auto_ref()
{
int i;
deque<int> ref;
for (i = 0; i < 5; ++i) {
ref.push_back(i);
}
deque<deque<int> > d_d_int(1, ref);
d_d_int.push_back(d_d_int[0]);
d_d_int.push_back(ref);
d_d_int.push_back(d_d_int[0]);
d_d_int.push_back(d_d_int[0]);
d_d_int.push_back(ref);
for (i = 0; i < 5; ++i) {
CPPUNIT_ASSERT( d_d_int[i] == ref );
}
}
void DequeTest::allocator_with_state()
{
char buf1[1024];
StackAllocator<int> stack1(buf1, buf1 + sizeof(buf1));
char buf2[1024];
StackAllocator<int> stack2(buf2, buf2 + sizeof(buf2));
{
typedef deque<int, StackAllocator<int> > DequeInt;
DequeInt dint1(10, 0, stack1);
DequeInt dint1Cpy(dint1);
DequeInt dint2(10, 1, stack2);
DequeInt dint2Cpy(dint2);
dint1.swap(dint2);
CPPUNIT_ASSERT( dint1.get_allocator().swaped() );
CPPUNIT_ASSERT( dint2.get_allocator().swaped() );
CPPUNIT_ASSERT( dint1 == dint2Cpy );
CPPUNIT_ASSERT( dint2 == dint1Cpy );
CPPUNIT_ASSERT( dint1.get_allocator() == stack2 );
CPPUNIT_ASSERT( dint2.get_allocator() == stack1 );
}
CPPUNIT_ASSERT( stack1.ok() );
CPPUNIT_ASSERT( stack2.ok() );
}
struct Point {
int x, y;
};
struct PointEx : public Point {
PointEx() : builtFromBase(false) {}
PointEx(const Point&) : builtFromBase(true) {}
bool builtFromBase;
};
#if defined (STLPORT)
# if defined (_STLP_USE_NAMESPACES)
namespace std {
# endif
_STLP_TEMPLATE_NULL
struct __type_traits<PointEx> {
typedef __false_type has_trivial_default_constructor;
typedef __true_type has_trivial_copy_constructor;
typedef __true_type has_trivial_assignment_operator;
typedef __true_type has_trivial_destructor;
typedef __true_type is_POD_type;
};
# if defined (_STLP_USE_NAMESPACES)
}
# endif
#endif
//This test check that deque implementation do not over optimize
//operation as PointEx copy constructor is trivial
void DequeTest::optimizations_check()
{
#if !defined (STLPORT) || !defined (_STLP_NO_MEMBER_TEMPLATES)
deque<Point> d1(1);
CPPUNIT_ASSERT( d1.size() == 1 );
deque<PointEx> d2(d1.begin(), d1.end());
CPPUNIT_ASSERT( d2.size() == 1 );
CPPUNIT_ASSERT( d2[0].builtFromBase == true );
d2.insert(d2.end(), d1.begin(), d1.end());
CPPUNIT_ASSERT( d2.size() == 2 );
CPPUNIT_ASSERT( d2[1].builtFromBase == true );
#endif
}
void DequeTest::erase()
{
deque<int> dint;
dint.push_back(3);
dint.push_front(2);
dint.push_back(4);
dint.push_front(1);
dint.push_back(5);
dint.push_front(0);
dint.push_back(6);
deque<int>::iterator it(dint.begin() + 1);
CPPUNIT_ASSERT( *it == 1 );
dint.erase(dint.begin());
CPPUNIT_ASSERT( *it == 1 );
it = dint.end() - 2;
CPPUNIT_ASSERT( *it == 5 );
dint.erase(dint.end() - 1);
CPPUNIT_ASSERT( *it == 5 );
dint.push_back(6);
dint.push_front(0);
it = dint.begin() + 2;
CPPUNIT_ASSERT( *it == 2 );
dint.erase(dint.begin(), dint.begin() + 2);
CPPUNIT_ASSERT( *it == 2 );
it = dint.end() - 3;
CPPUNIT_ASSERT( *it == 4 );
dint.erase(dint.end() - 2, dint.end());
CPPUNIT_ASSERT( *it == 4 );
}
#if (!defined (STLPORT) || \
(!defined (_STLP_USE_PTR_SPECIALIZATIONS) || defined (_STLP_CLASS_PARTIAL_SPECIALIZATION))) && \
(!defined (_MSC_VER) || (_MSC_VER > 1400)) && \
(!defined(__GNUC__) || (__GNUC__ < 4) || (__GNUC_MINOR__ < 3))
/* Simple compilation test: Check that nested types like iterator
* can be access even if type used to instanciate container is not
* yet completely defined.
*/
class IncompleteClass
{
deque<IncompleteClass> instances;
typedef deque<IncompleteClass>::size_type size;
};
#endif