#define __DALI_TEST_SUITE_UTILS_H__
/*
- * Copyright (c) 2015 Samsung Electronics Co., Ltd.
+ * Copyright (c) 2017 Samsung Electronics Co., Ltd.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
// EXTERNAL INCLUDES
#include <cstdarg>
+#include <cstdio>
#include <iostream>
+#include <cstring>
+#include <string>
// INTERNAL INCLUDES
#include <dali/public-api/dali-core.h>
+#include <test-compare-types.h>
void tet_infoline(const char*str);
void tet_printf(const char *format, ...);
#define STRINGIZE_I(text) #text
#define STRINGIZE(text) STRINGIZE_I(text)
-// the following is the other compilers way of token pasting, gcc seems to just concatenate strings automatically
-//#define TOKENPASTE(x,y) x ## y
-#define TOKENPASTE(x,y) x y
-#define TOKENPASTE2(x,y) TOKENPASTE( x, y )
-#define TEST_LOCATION TOKENPASTE2( "Test failed in ", TOKENPASTE2( __FILE__, TOKENPASTE2( ", line ", STRINGIZE(__LINE__) ) ) )
+/**
+ * Inspired by https://stackoverflow.com/questions/1706346/file-macro-manipulation-handling-at-compile-time
+ * answer by Chetan Reddy
+ */
+constexpr int32_t basenameIndex( const char * const path, const int32_t index = 0, const int32_t slashIndex = -1 )
+{
+ return path[ index ]
+ ? ( path[ index ] == '/'
+ ? basenameIndex( path, index + 1, index )
+ : basenameIndex( path, index + 1, slashIndex ) )
+ : ( slashIndex + 1 );
+}
+
+#define __FILELINE__ ( { static const int32_t basenameIdx = basenameIndex( __FILE__ ); \
+ static_assert (basenameIdx >= 0, "compile-time basename" ); \
+ __FILE__ ":" STRINGIZE(__LINE__) + basenameIdx ; } )
+
+#define TEST_LOCATION __FILELINE__
+#define TEST_INNER_LOCATION(x) ( std::string(x) + " (" + STRINGIZE(__LINE__) + ")" ).c_str()
#define TET_UNDEF 2
#define TET_FAIL 1
#define TET_PASS 0
-extern int test_return_value;
+extern int32_t test_return_value;
-void tet_result(int value);
+void tet_result(int32_t value);
#define END_TEST \
return ((test_return_value>0)?1:0)
} \
else \
{ \
- fprintf(stderr, "%s Failed in %s at line %d\n", __PRETTY_FUNCTION__, __FILE__, __LINE__); \
+ fprintf(stderr, "Test failed in %s, condition: %s\n", __FILELINE__, #condition ); \
tet_result(TET_FAIL); \
throw("TET_FAIL"); \
}
-template <typename Type>
-inline bool CompareType(Type value1, Type value2, float epsilon);
-
-/**
- * A helper for fuzzy-comparing Vector2 objects
- * @param[in] vector1 the first object
- * @param[in] vector2 the second object
- * @param[in] epsilon difference threshold
- * @returns true if difference is smaller than epsilon threshold, false otherwise
- */
-template <>
-inline bool CompareType<float>(float value1, float value2, float epsilon)
-{
- return fabsf(value1 - value2) < epsilon;
-}
-
-/**
- * A helper for fuzzy-comparing Vector2 objects
- * @param[in] vector1 the first object
- * @param[in] vector2 the second object
- * @param[in] epsilon difference threshold
- * @returns true if difference is smaller than epsilon threshold, false otherwise
- */
-template <>
-inline bool CompareType<Vector2>(Vector2 vector1, Vector2 vector2, float epsilon)
-{
- return fabsf(vector1.x - vector2.x)<epsilon && fabsf(vector1.y - vector2.y)<epsilon;
-}
-
-/**
- * A helper for fuzzy-comparing Vector3 objects
- * @param[in] vector1 the first object
- * @param[in] vector2 the second object
- * @param[in] epsilon difference threshold
- * @returns true if difference is smaller than epsilon threshold, false otherwise
- */
-template <>
-inline bool CompareType<Vector3>(Vector3 vector1, Vector3 vector2, float epsilon)
-{
- return fabsf(vector1.x - vector2.x)<epsilon &&
- fabsf(vector1.y - vector2.y)<epsilon &&
- fabsf(vector1.z - vector2.z)<epsilon;
-}
-
-
-/**
- * A helper for fuzzy-comparing Vector4 objects
- * @param[in] vector1 the first object
- * @param[in] vector2 the second object
- * @param[in] epsilon difference threshold
- * @returns true if difference is smaller than epsilon threshold, false otherwise
- */
-template <>
-inline bool CompareType<Vector4>(Vector4 vector1, Vector4 vector2, float epsilon)
-{
- return fabsf(vector1.x - vector2.x)<epsilon &&
- fabsf(vector1.y - vector2.y)<epsilon &&
- fabsf(vector1.z - vector2.z)<epsilon &&
- fabsf(vector1.w - vector2.w)<epsilon;
-}
-
-template <>
-inline bool CompareType<Quaternion>(Quaternion q1, Quaternion q2, float epsilon)
-{
- Quaternion q2N = -q2; // These quaternions represent the same rotation
- return CompareType<Vector4>(q1.mVector, q2.mVector, epsilon) || CompareType<Vector4>(q1.mVector, q2N.mVector, epsilon);
-}
-
-template <>
-inline bool CompareType<Radian>(Radian q1, Radian q2, float epsilon)
-{
- return CompareType<float>(q1.radian, q2.radian, epsilon);
-}
-
-template <>
-inline bool CompareType<Degree>(Degree q1, Degree q2, float epsilon)
-{
- return CompareType<float>(q1.degree, q2.degree, epsilon);
-}
bool operator==(TimePeriod a, TimePeriod b);
std::ostream& operator<<( std::ostream& ostream, TimePeriod value );
template<typename Type>
inline void DALI_TEST_EQUALS(Type value1, Type value2, const char* location)
{
- if (!(value1 == value2))
+ if( !CompareType<Type>(value1, value2, 0.01f) )
{
std::ostringstream o;
o << value1 << " == " << value2 << std::endl;
- fprintf(stderr, "%s, checking %s", location, o.str().c_str());
+ fprintf(stderr, "Test failed in %s, checking %s", location, o.str().c_str());
tet_result(TET_FAIL);
+ throw("TET_FAIL"); \
}
else
{
}
}
+/**
+ * Test whether two values are equal.
+ * @param[in] value1 The first value
+ * @param[in] value2 The second value
+ */
+#define DALI_TEST_EQUAL( v1, v2 ) DALI_TEST_EQUALS( v1, v2, __FILELINE__ )
+
template<typename Type>
inline void DALI_TEST_EQUALS(Type value1, Type value2, float epsilon, const char* location)
{
{
std::ostringstream o;
o << value1 << " == " << value2 << std::endl;
- fprintf(stderr, "%s, checking %s", location, o.str().c_str());
+ fprintf(stderr, "Test failed in %s, checking %s", location, o.str().c_str());
tet_result(TET_FAIL);
+ throw("TET_FAIL"); \
}
else
{
}
}
+template<typename Type>
+inline void DALI_TEST_NOT_EQUALS(Type value1, Type value2, float epsilon, const char* location)
+{
+ if( CompareType<Type>(value1, value2, epsilon) )
+ {
+ std::ostringstream o;
+ o << value1 << " != " << value2 << std::endl;
+ fprintf(stderr, "Test failed in %s, checking %s", location, o.str().c_str());
+ tet_result(TET_FAIL);
+ throw("TET_FAIL"); \
+ }
+ else
+ {
+ tet_result(TET_PASS);
+ }
+}
+
+
/**
* Test whether two TimePeriods are within a certain distance of each other.
* @param[in] value1 The first value
{
if ((fabs(value1.durationSeconds - value2.durationSeconds) > epsilon))
{
- fprintf(stderr, "%s, checking durations %f == %f, epsilon %f\n", location, value1.durationSeconds, value2.durationSeconds, epsilon);
+ fprintf(stderr, "Test failed in %s, checking durations %f == %f, epsilon %f\n", location, value1.durationSeconds, value2.durationSeconds, epsilon);
tet_result(TET_FAIL);
+ throw("TET_FAIL"); \
}
else if ((fabs(value1.delaySeconds - value2.delaySeconds) > epsilon))
{
- fprintf(stderr, "%s, checking delays %f == %f, epsilon %f\n", location, value1.delaySeconds, value2.delaySeconds, epsilon);
+ fprintf(stderr, "Test failed in %s, checking delays %f == %f, epsilon %f\n", location, value1.delaySeconds, value2.delaySeconds, epsilon);
tet_result(TET_FAIL);
+ throw("TET_FAIL"); \
}
else
{
void DALI_TEST_EQUALS( const BaseHandle& baseHandle1, const BaseHandle& baseHandle2, const char* location );
/**
- * Test whether a size_t value and an unsigned int are equal.
+ * Test whether a size_t value and an uint32_t are equal.
* @param[in] value1 The first value
* @param[in] value2 The second value
* @param[in] location The TEST_LOCATION macro should be used here
*/
-void DALI_TEST_EQUALS( const size_t value1, const unsigned int value2, const char* location );
+void DALI_TEST_EQUALS( const size_t value1, const uint32_t value2, const char* location );
/**
- * Test whether an unsigned int and a size_t value and are equal.
+ * Test whether an uint32_t and a size_t value and are equal.
* @param[in] value1 The first value
* @param[in] value2 The second value
* @param[in] location The TEST_LOCATION macro should be used here
*/
-void DALI_TEST_EQUALS( const unsigned int value1, const size_t value2, const char* location );
+void DALI_TEST_EQUALS( const uint32_t value1, const size_t value2, const char* location );
/**
* Test whether two Matrix3 objects are equal.
{
if (strcmp(str1, str2))
{
- fprintf(stderr, "%s, checking '%s' == '%s'\n", location, str1, str2);
+ fprintf(stderr, "Test failed in %s, checking '%s' == '%s'\n", location, str1, str2);
tet_result(TET_FAIL);
+ throw("TET_FAIL"); \
}
else
{
* @param[in] str2 The second string
* @param[in] location The TEST_LOCATION macro should be used here
*/
+void DALI_TEST_EQUALS( Property::Value& str1, const char* str2, const char* location);
+
+/**
+ * Test whether two strings are equal.
+ * @param[in] str1 The first string
+ * @param[in] str2 The second string
+ * @param[in] location The TEST_LOCATION macro should be used here
+ */
void DALI_TEST_EQUALS( const std::string &str1, const char* str2, const char* location);
/**
{
if (!(value1 > value2))
{
- std::cerr << location << ", checking " << value1 <<" > " << value2 << "\n";
+ std::cerr << "Test failed in " << location << ", checking " << value1 <<" > " << value2 << "\n";
tet_result(TET_FAIL);
+ throw("TET_FAIL"); \
}
else
{
tet_printf("Assertion %s failed at %s\n", e.condition, e.location );
}
+/**
+ * Test that given piece of code triggers the right assertion
+ * Fails the test if the assert didn't occur.
+ * Turns off logging during the execution of the code to avoid excessive false positive log output from the assertions
+ * @param expressions code to execute
+ * @param assertstring the substring expected in the assert
+ */
+#define DALI_TEST_ASSERTION( expressions, assertstring ) \
+try \
+{ \
+ TestApplication::EnableLogging( false ); \
+ expressions; \
+ TestApplication::EnableLogging( true ); \
+ fprintf(stderr, "Test failed in %s, expected assert: '%s' didn't occur\n", __FILELINE__, assertstring ); \
+ tet_result(TET_FAIL); \
+ throw("TET_FAIL"); } \
+catch( Dali::DaliException& e ) \
+{ \
+ DALI_TEST_ASSERT( e, assertstring, TEST_LOCATION ); \
+}
+
// Functor to test whether an Applied signal is emitted
struct ConstraintAppliedCheck
{
// Helper to Create buffer image
BufferImage CreateBufferImage();
-BufferImage CreateBufferImage(int width, int height, const Vector4& color);
+BufferImage CreateBufferImage(int32_t width, int32_t height, const Vector4& color);
+
+
+// Prepare a resource image to be loaded. Should be called before creating the ResourceImage
+void PrepareResourceImage( TestApplication& application, uint32_t imageWidth, uint32_t imageHeight, Pixel::Format pixelFormat );
+
+// Test namespace to prevent pollution of Dali namespace, add Test helper functions here
+namespace Test
+{
+/**
+ * @brief
+ *
+ * Helper to check object destruction occurred
+ * 1) In main part of code create an ObjectDestructionTracker
+ * 2) Within sub section of main create object Actor test and call Start with Actor to test for destruction
+ * 3) Perform code which is expected to destroy Actor
+ * 4) Back in main part of code use IsDestroyed() to test if Actor was destroyed
+ */
+class ObjectDestructionTracker : public ConnectionTracker
+{
+public:
+
+ /**
+ * @brief Call in main part of code
+ */
+ ObjectDestructionTracker();
+
+ /**
+ * @brief Call in sub bock of code where the Actor being checked is still alive.
+ *
+ * @param[in] actor Actor to be checked for destruction
+ */
+ void Start( Actor actor );
+
+ /**
+ * @brief Call to check if Actor alive or destroyed.
+ *
+ * @return bool true if Actor was destroyed
+ */
+ bool IsDestroyed();
+
+private:
+ bool mRefObjectDestroyed;
+};
+
+} // namespace Test
#endif // __DALI_TEST_SUITE_UTILS_H__