java/tests/RsTest_11/src/com/android/rs/test/fp_mad.rs - platform/frameworks/rs - Git at Google

 #include "shared.rsh"

 const int TEST_COUNT = 1;

 static float data_f1[1025];
 static float4 data_f4[1025];

 static void test_mad4(uint32_t index) {
     start();

     float total = 0;
     // Do ~1 billion ops
     for (int ct=0; ct < 1000 * (1000 / 80); ct++) {
         for (int i=0; i < (1000); i++) {
             data_f4[i] = (data_f4[i] * 0.02f +
                           data_f4[i+1] * 0.04f +
                           data_f4[i+2] * 0.05f +
                           data_f4[i+3] * 0.1f +
                           data_f4[i+4] * 0.2f +
                           data_f4[i+5] * 0.2f +
                           data_f4[i+6] * 0.1f +
                           data_f4[i+7] * 0.05f +
                           data_f4[i+8] * 0.04f +
                           data_f4[i+9] * 0.02f + 1.f);
         }
     }

     float time = end(index);
     rsDebug("fp_mad4 M ops", 1000.f / time);
 }

 static void test_mad(uint32_t index) {
     start();

     float total = 0;
     // Do ~1 billion ops
     for (int ct=0; ct < 1000 * (1000 / 20); ct++) {
         for (int i=0; i < (1000); i++) {
             data_f1[i] = (data_f1[i] * 0.02f +
                           data_f1[i+1] * 0.04f +
                           data_f1[i+2] * 0.05f +
                           data_f1[i+3] * 0.1f +
                           data_f1[i+4] * 0.2f +
                           data_f1[i+5] * 0.2f +
                           data_f1[i+6] * 0.1f +
                           data_f1[i+7] * 0.05f +
                           data_f1[i+8] * 0.04f +
                           data_f1[i+9] * 0.02f + 1.f);
         }
     }

     float time = end(index);
     rsDebug("fp_mad M ops", 1000.f / time);
 }

 static void test_norm(uint32_t index) {
     start();

     float total = 0;
     // Do ~10 M ops
     for (int ct=0; ct < 1000 * 10; ct++) {
         for (int i=0; i < (1000); i++) {
             data_f4[i] = normalize(data_f4[i]);
         }
     }

     float time = end(index);
     rsDebug("fp_norm M ops", 10.f / time);
 }

 static void test_sincos4(uint32_t index) {
     start();

     float total = 0;
     // Do ~10 M ops
     for (int ct=0; ct < 1000 * 10 / 4; ct++) {
         for (int i=0; i < (1000); i++) {
             data_f4[i] = sin(data_f4[i]) * cos(data_f4[i]);
         }
     }

     float time = end(index);
     rsDebug("fp_sincos4 M ops", 10.f / time);
 }

 static void test_sincos(uint32_t index) {
     start();

     float total = 0;
     // Do ~10 M ops
     for (int ct=0; ct < 1000 * 10; ct++) {
         for (int i=0; i < (1000); i++) {
             data_f1[i] = sin(data_f1[i]) * cos(data_f1[i]);
         }
     }

     float time = end(index);
     rsDebug("fp_sincos M ops", 10.f / time);
 }

 static void test_clamp(uint32_t index) {
     start();

     // Do ~100 M ops
     for (int ct=0; ct < 1000 * 100; ct++) {
         for (int i=0; i < (1000); i++) {
             data_f1[i] = clamp(data_f1[i], -1.f, 1.f);
         }
     }

     float time = end(index);
     rsDebug("fp_clamp M ops", 100.f / time);

     start();
     // Do ~100 M ops
     for (int ct=0; ct < 1000 * 100; ct++) {
         for (int i=0; i < (1000); i++) {
             if (data_f1[i] < -1.f) data_f1[i] = -1.f;
             if (data_f1[i] > -1.f) data_f1[i] = 1.f;
         }
     }

     time = end(index);
     rsDebug("fp_clamp ref M ops", 100.f / time);
 }

 static void test_clamp4(uint32_t index) {
     start();

     float total = 0;
     // Do ~100 M ops
     for (int ct=0; ct < 1000 * 100 /4; ct++) {
         for (int i=0; i < (1000); i++) {
             data_f4[i] = clamp(data_f4[i], -1.f, 1.f);
         }
     }

     float time = end(index);
     rsDebug("fp_clamp4 M ops", 100.f / time);
 }

 void fp_mad_test(uint32_t index, int test_num) {
     int x;
     for (x=0; x < 1025; x++) {
         data_f1[x] = (x & 0xf) * 0.1f;
         data_f4[x].x = (x & 0xf) * 0.1f;
         data_f4[x].y = (x & 0xf0) * 0.1f;
         data_f4[x].z = (x & 0x33) * 0.1f;
         data_f4[x].w = (x & 0x77) * 0.1f;
     }

     test_mad4(index);
     test_mad(index);

     for (x=0; x < 1025; x++) {
         data_f1[x] = (x & 0xf) * 0.1f + 1.f;
         data_f4[x].x = (x & 0xf) * 0.1f + 1.f;
         data_f4[x].y = (x & 0xf0) * 0.1f + 1.f;
         data_f4[x].z = (x & 0x33) * 0.1f + 1.f;
         data_f4[x].w = (x & 0x77) * 0.1f + 1.f;
     }

     test_norm(index);
     test_sincos4(index);
     test_sincos(index);
     test_clamp4(index);
     test_clamp(index);

     // TODO Actually verify test result accuracy
     rsDebug("fp_mad_test PASSED", 0);
     rsSendToClientBlocking(RS_MSG_TEST_PASSED);
 }
	#include "shared.rsh"

	const int TEST_COUNT = 1;

	static float data_f1[1025];
	static float4 data_f4[1025];

	static void test_mad4(uint32_t index) {
	start();

	float total = 0;
	// Do ~1 billion ops
	for (int ct=0; ct < 1000 * (1000 / 80); ct++) {
	for (int i=0; i < (1000); i++) {
	data_f4[i] = (data_f4[i] * 0.02f +
	data_f4[i+1] * 0.04f +
	data_f4[i+2] * 0.05f +
	data_f4[i+3] * 0.1f +
	data_f4[i+4] * 0.2f +
	data_f4[i+5] * 0.2f +
	data_f4[i+6] * 0.1f +
	data_f4[i+7] * 0.05f +
	data_f4[i+8] * 0.04f +
	data_f4[i+9] * 0.02f + 1.f);
	}
	}

	float time = end(index);
	rsDebug("fp_mad4 M ops", 1000.f / time);
	}

	static void test_mad(uint32_t index) {
	start();

	float total = 0;
	// Do ~1 billion ops
	for (int ct=0; ct < 1000 * (1000 / 20); ct++) {
	for (int i=0; i < (1000); i++) {
	data_f1[i] = (data_f1[i] * 0.02f +
	data_f1[i+1] * 0.04f +
	data_f1[i+2] * 0.05f +
	data_f1[i+3] * 0.1f +
	data_f1[i+4] * 0.2f +
	data_f1[i+5] * 0.2f +
	data_f1[i+6] * 0.1f +
	data_f1[i+7] * 0.05f +
	data_f1[i+8] * 0.04f +
	data_f1[i+9] * 0.02f + 1.f);
	}
	}

	float time = end(index);
	rsDebug("fp_mad M ops", 1000.f / time);
	}

	static void test_norm(uint32_t index) {
	start();

	float total = 0;
	// Do ~10 M ops
	for (int ct=0; ct < 1000 * 10; ct++) {
	for (int i=0; i < (1000); i++) {
	data_f4[i] = normalize(data_f4[i]);
	}
	}

	float time = end(index);
	rsDebug("fp_norm M ops", 10.f / time);
	}

	static void test_sincos4(uint32_t index) {
	start();

	float total = 0;
	// Do ~10 M ops
	for (int ct=0; ct < 1000 * 10 / 4; ct++) {
	for (int i=0; i < (1000); i++) {
	data_f4[i] = sin(data_f4[i]) * cos(data_f4[i]);
	}
	}

	float time = end(index);
	rsDebug("fp_sincos4 M ops", 10.f / time);
	}

	static void test_sincos(uint32_t index) {
	start();

	float total = 0;
	// Do ~10 M ops
	for (int ct=0; ct < 1000 * 10; ct++) {
	for (int i=0; i < (1000); i++) {
	data_f1[i] = sin(data_f1[i]) * cos(data_f1[i]);
	}
	}

	float time = end(index);
	rsDebug("fp_sincos M ops", 10.f / time);
	}

	static void test_clamp(uint32_t index) {
	start();

	// Do ~100 M ops
	for (int ct=0; ct < 1000 * 100; ct++) {
	for (int i=0; i < (1000); i++) {
	data_f1[i] = clamp(data_f1[i], -1.f, 1.f);
	}
	}

	float time = end(index);
	rsDebug("fp_clamp M ops", 100.f / time);

	start();
	// Do ~100 M ops
	for (int ct=0; ct < 1000 * 100; ct++) {
	for (int i=0; i < (1000); i++) {
	if (data_f1[i] < -1.f) data_f1[i] = -1.f;
	if (data_f1[i] > -1.f) data_f1[i] = 1.f;
	}
	}

	time = end(index);
	rsDebug("fp_clamp ref M ops", 100.f / time);
	}

	static void test_clamp4(uint32_t index) {
	start();

	float total = 0;
	// Do ~100 M ops
	for (int ct=0; ct < 1000 * 100 /4; ct++) {
	for (int i=0; i < (1000); i++) {
	data_f4[i] = clamp(data_f4[i], -1.f, 1.f);
	}
	}

	float time = end(index);
	rsDebug("fp_clamp4 M ops", 100.f / time);
	}

	void fp_mad_test(uint32_t index, int test_num) {
	int x;
	for (x=0; x < 1025; x++) {
	data_f1[x] = (x & 0xf) * 0.1f;
	data_f4[x].x = (x & 0xf) * 0.1f;
	data_f4[x].y = (x & 0xf0) * 0.1f;
	data_f4[x].z = (x & 0x33) * 0.1f;
	data_f4[x].w = (x & 0x77) * 0.1f;
	}

	test_mad4(index);
	test_mad(index);

	for (x=0; x < 1025; x++) {
	data_f1[x] = (x & 0xf) * 0.1f + 1.f;
	data_f4[x].x = (x & 0xf) * 0.1f + 1.f;
	data_f4[x].y = (x & 0xf0) * 0.1f + 1.f;
	data_f4[x].z = (x & 0x33) * 0.1f + 1.f;
	data_f4[x].w = (x & 0x77) * 0.1f + 1.f;
	}

	test_norm(index);
	test_sincos4(index);
	test_sincos(index);
	test_clamp4(index);
	test_clamp(index);

	// TODO Actually verify test result accuracy
	rsDebug("fp_mad_test PASSED", 0);
	rsSendToClientBlocking(RS_MSG_TEST_PASSED);
	}