tests/tests/renderscript/src/android/renderscript/cts/generated/TestAsinh.java - platform/cts - Git at Google

 /*
  * Copyright (C) 2015 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 // Don't edit this file!  It is auto-generated by frameworks/rs/api/gen_runtime.

 package android.renderscript.cts;

 import android.renderscript.Allocation;
 import android.renderscript.RSRuntimeException;
 import android.renderscript.Element;

 public class TestAsinh extends RSBaseCompute {

     private ScriptC_TestAsinh script;
     private ScriptC_TestAsinhRelaxed scriptRelaxed;

     @Override
     protected void setUp() throws Exception {
         super.setUp();
         script = new ScriptC_TestAsinh(mRS);
         scriptRelaxed = new ScriptC_TestAsinhRelaxed(mRS);
     }

     public class ArgumentsFloatFloat {
         public float inV;
         public Target.Floaty out;
     }

     private void checkAsinhFloatFloat() {
         Allocation inV = createRandomAllocation(mRS, Element.DataType.FLOAT_32, 1, 0x2cdf6bfa7c4a48f4l, false);
         try {
             Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 1), INPUTSIZE);
             script.forEach_testAsinhFloatFloat(inV, out);
             verifyResultsAsinhFloatFloat(inV, out, false);
         } catch (Exception e) {
             throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloatFloat: " + e.toString());
         }
         try {
             Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 1), INPUTSIZE);
             scriptRelaxed.forEach_testAsinhFloatFloat(inV, out);
             verifyResultsAsinhFloatFloat(inV, out, true);
         } catch (Exception e) {
             throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloatFloat: " + e.toString());
         }
     }

     private void verifyResultsAsinhFloatFloat(Allocation inV, Allocation out, boolean relaxed) {
         float[] arrayInV = new float[INPUTSIZE * 1];
         inV.copyTo(arrayInV);
         float[] arrayOut = new float[INPUTSIZE * 1];
         out.copyTo(arrayOut);
         for (int i = 0; i < INPUTSIZE; i++) {
             for (int j = 0; j < 1 ; j++) {
                 // Extract the inputs.
                 ArgumentsFloatFloat args = new ArgumentsFloatFloat();
                 args.inV = arrayInV[i];
                 // Figure out what the outputs should have been.
                 Target target = new Target(relaxed);
                 CoreMathVerifier.computeAsinh(args, target);
                 // Validate the outputs.
                 boolean valid = true;
                 if (!args.out.couldBe(arrayOut[i * 1 + j])) {
                     valid = false;
                 }
                 if (!valid) {
                     StringBuilder message = new StringBuilder();
                     message.append("Input inV: ");
                     message.append(String.format("%14.8g {%8x} %15a",
                             args.inV, Float.floatToRawIntBits(args.inV), args.inV));
                     message.append("\n");
                     message.append("Expected output out: ");
                     message.append(args.out.toString());
                     message.append("\n");
                     message.append("Actual   output out: ");
                     message.append(String.format("%14.8g {%8x} %15a",
                             arrayOut[i * 1 + j], Float.floatToRawIntBits(arrayOut[i * 1 + j]), arrayOut[i * 1 + j]));
                     if (!args.out.couldBe(arrayOut[i * 1 + j])) {
                         message.append(" FAIL");
                     }
                     message.append("\n");
                     assertTrue("Incorrect output for checkAsinhFloatFloat" +
                             (relaxed ? "_relaxed" : "") + ":\n" + message.toString(), valid);
                 }
             }
         }
     }

     private void checkAsinhFloat2Float2() {
         Allocation inV = createRandomAllocation(mRS, Element.DataType.FLOAT_32, 2, 0x198d997279032b38l, false);
         try {
             Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 2), INPUTSIZE);
             script.forEach_testAsinhFloat2Float2(inV, out);
             verifyResultsAsinhFloat2Float2(inV, out, false);
         } catch (Exception e) {
             throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat2Float2: " + e.toString());
         }
         try {
             Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 2), INPUTSIZE);
             scriptRelaxed.forEach_testAsinhFloat2Float2(inV, out);
             verifyResultsAsinhFloat2Float2(inV, out, true);
         } catch (Exception e) {
             throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat2Float2: " + e.toString());
         }
     }

     private void verifyResultsAsinhFloat2Float2(Allocation inV, Allocation out, boolean relaxed) {
         float[] arrayInV = new float[INPUTSIZE * 2];
         inV.copyTo(arrayInV);
         float[] arrayOut = new float[INPUTSIZE * 2];
         out.copyTo(arrayOut);
         for (int i = 0; i < INPUTSIZE; i++) {
             for (int j = 0; j < 2 ; j++) {
                 // Extract the inputs.
                 ArgumentsFloatFloat args = new ArgumentsFloatFloat();
                 args.inV = arrayInV[i * 2 + j];
                 // Figure out what the outputs should have been.
                 Target target = new Target(relaxed);
                 CoreMathVerifier.computeAsinh(args, target);
                 // Validate the outputs.
                 boolean valid = true;
                 if (!args.out.couldBe(arrayOut[i * 2 + j])) {
                     valid = false;
                 }
                 if (!valid) {
                     StringBuilder message = new StringBuilder();
                     message.append("Input inV: ");
                     message.append(String.format("%14.8g {%8x} %15a",
                             args.inV, Float.floatToRawIntBits(args.inV), args.inV));
                     message.append("\n");
                     message.append("Expected output out: ");
                     message.append(args.out.toString());
                     message.append("\n");
                     message.append("Actual   output out: ");
                     message.append(String.format("%14.8g {%8x} %15a",
                             arrayOut[i * 2 + j], Float.floatToRawIntBits(arrayOut[i * 2 + j]), arrayOut[i * 2 + j]));
                     if (!args.out.couldBe(arrayOut[i * 2 + j])) {
                         message.append(" FAIL");
                     }
                     message.append("\n");
                     assertTrue("Incorrect output for checkAsinhFloat2Float2" +
                             (relaxed ? "_relaxed" : "") + ":\n" + message.toString(), valid);
                 }
             }
         }
     }

     private void checkAsinhFloat3Float3() {
         Allocation inV = createRandomAllocation(mRS, Element.DataType.FLOAT_32, 3, 0x198f628d6f1e4c16l, false);
         try {
             Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 3), INPUTSIZE);
             script.forEach_testAsinhFloat3Float3(inV, out);
             verifyResultsAsinhFloat3Float3(inV, out, false);
         } catch (Exception e) {
             throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat3Float3: " + e.toString());
         }
         try {
             Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 3), INPUTSIZE);
             scriptRelaxed.forEach_testAsinhFloat3Float3(inV, out);
             verifyResultsAsinhFloat3Float3(inV, out, true);
         } catch (Exception e) {
             throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat3Float3: " + e.toString());
         }
     }

     private void verifyResultsAsinhFloat3Float3(Allocation inV, Allocation out, boolean relaxed) {
         float[] arrayInV = new float[INPUTSIZE * 4];
         inV.copyTo(arrayInV);
         float[] arrayOut = new float[INPUTSIZE * 4];
         out.copyTo(arrayOut);
         for (int i = 0; i < INPUTSIZE; i++) {
             for (int j = 0; j < 3 ; j++) {
                 // Extract the inputs.
                 ArgumentsFloatFloat args = new ArgumentsFloatFloat();
                 args.inV = arrayInV[i * 4 + j];
                 // Figure out what the outputs should have been.
                 Target target = new Target(relaxed);
                 CoreMathVerifier.computeAsinh(args, target);
                 // Validate the outputs.
                 boolean valid = true;
                 if (!args.out.couldBe(arrayOut[i * 4 + j])) {
                     valid = false;
                 }
                 if (!valid) {
                     StringBuilder message = new StringBuilder();
                     message.append("Input inV: ");
                     message.append(String.format("%14.8g {%8x} %15a",
                             args.inV, Float.floatToRawIntBits(args.inV), args.inV));
                     message.append("\n");
                     message.append("Expected output out: ");
                     message.append(args.out.toString());
                     message.append("\n");
                     message.append("Actual   output out: ");
                     message.append(String.format("%14.8g {%8x} %15a",
                             arrayOut[i * 4 + j], Float.floatToRawIntBits(arrayOut[i * 4 + j]), arrayOut[i * 4 + j]));
                     if (!args.out.couldBe(arrayOut[i * 4 + j])) {
                         message.append(" FAIL");
                     }
                     message.append("\n");
                     assertTrue("Incorrect output for checkAsinhFloat3Float3" +
                             (relaxed ? "_relaxed" : "") + ":\n" + message.toString(), valid);
                 }
             }
         }
     }

     private void checkAsinhFloat4Float4() {
         Allocation inV = createRandomAllocation(mRS, Element.DataType.FLOAT_32, 4, 0x19912ba865396cf4l, false);
         try {
             Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 4), INPUTSIZE);
             script.forEach_testAsinhFloat4Float4(inV, out);
             verifyResultsAsinhFloat4Float4(inV, out, false);
         } catch (Exception e) {
             throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat4Float4: " + e.toString());
         }
         try {
             Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 4), INPUTSIZE);
             scriptRelaxed.forEach_testAsinhFloat4Float4(inV, out);
             verifyResultsAsinhFloat4Float4(inV, out, true);
         } catch (Exception e) {
             throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat4Float4: " + e.toString());
         }
     }

     private void verifyResultsAsinhFloat4Float4(Allocation inV, Allocation out, boolean relaxed) {
         float[] arrayInV = new float[INPUTSIZE * 4];
         inV.copyTo(arrayInV);
         float[] arrayOut = new float[INPUTSIZE * 4];
         out.copyTo(arrayOut);
         for (int i = 0; i < INPUTSIZE; i++) {
             for (int j = 0; j < 4 ; j++) {
                 // Extract the inputs.
                 ArgumentsFloatFloat args = new ArgumentsFloatFloat();
                 args.inV = arrayInV[i * 4 + j];
                 // Figure out what the outputs should have been.
                 Target target = new Target(relaxed);
                 CoreMathVerifier.computeAsinh(args, target);
                 // Validate the outputs.
                 boolean valid = true;
                 if (!args.out.couldBe(arrayOut[i * 4 + j])) {
                     valid = false;
                 }
                 if (!valid) {
                     StringBuilder message = new StringBuilder();
                     message.append("Input inV: ");
                     message.append(String.format("%14.8g {%8x} %15a",
                             args.inV, Float.floatToRawIntBits(args.inV), args.inV));
                     message.append("\n");
                     message.append("Expected output out: ");
                     message.append(args.out.toString());
                     message.append("\n");
                     message.append("Actual   output out: ");
                     message.append(String.format("%14.8g {%8x} %15a",
                             arrayOut[i * 4 + j], Float.floatToRawIntBits(arrayOut[i * 4 + j]), arrayOut[i * 4 + j]));
                     if (!args.out.couldBe(arrayOut[i * 4 + j])) {
                         message.append(" FAIL");
                     }
                     message.append("\n");
                     assertTrue("Incorrect output for checkAsinhFloat4Float4" +
                             (relaxed ? "_relaxed" : "") + ":\n" + message.toString(), valid);
                 }
             }
         }
     }

     public void testAsinh() {
         checkAsinhFloatFloat();
         checkAsinhFloat2Float2();
         checkAsinhFloat3Float3();
         checkAsinhFloat4Float4();
     }
 }
	/*
	* Copyright (C) 2015 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	// Don't edit this file! It is auto-generated by frameworks/rs/api/gen_runtime.

	package android.renderscript.cts;

	import android.renderscript.Allocation;
	import android.renderscript.RSRuntimeException;
	import android.renderscript.Element;

	public class TestAsinh extends RSBaseCompute {

	private ScriptC_TestAsinh script;
	private ScriptC_TestAsinhRelaxed scriptRelaxed;

	@Override
	protected void setUp() throws Exception {
	super.setUp();
	script = new ScriptC_TestAsinh(mRS);
	scriptRelaxed = new ScriptC_TestAsinhRelaxed(mRS);
	}

	public class ArgumentsFloatFloat {
	public float inV;
	public Target.Floaty out;
	}

	private void checkAsinhFloatFloat() {
	Allocation inV = createRandomAllocation(mRS, Element.DataType.FLOAT_32, 1, 0x2cdf6bfa7c4a48f4l, false);
	try {
	Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 1), INPUTSIZE);
	script.forEach_testAsinhFloatFloat(inV, out);
	verifyResultsAsinhFloatFloat(inV, out, false);
	} catch (Exception e) {
	throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloatFloat: " + e.toString());
	}
	try {
	Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 1), INPUTSIZE);
	scriptRelaxed.forEach_testAsinhFloatFloat(inV, out);
	verifyResultsAsinhFloatFloat(inV, out, true);
	} catch (Exception e) {
	throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloatFloat: " + e.toString());
	}
	}

	private void verifyResultsAsinhFloatFloat(Allocation inV, Allocation out, boolean relaxed) {
	float[] arrayInV = new float[INPUTSIZE * 1];
	inV.copyTo(arrayInV);
	float[] arrayOut = new float[INPUTSIZE * 1];
	out.copyTo(arrayOut);
	for (int i = 0; i < INPUTSIZE; i++) {
	for (int j = 0; j < 1 ; j++) {
	// Extract the inputs.
	ArgumentsFloatFloat args = new ArgumentsFloatFloat();
	args.inV = arrayInV[i];
	// Figure out what the outputs should have been.
	Target target = new Target(relaxed);
	CoreMathVerifier.computeAsinh(args, target);
	// Validate the outputs.
	boolean valid = true;
	if (!args.out.couldBe(arrayOut[i * 1 + j])) {
	valid = false;
	}
	if (!valid) {
	StringBuilder message = new StringBuilder();
	message.append("Input inV: ");
	message.append(String.format("%14.8g {%8x} %15a",
	args.inV, Float.floatToRawIntBits(args.inV), args.inV));
	message.append("\n");
	message.append("Expected output out: ");
	message.append(args.out.toString());
	message.append("\n");
	message.append("Actual output out: ");
	message.append(String.format("%14.8g {%8x} %15a",
	arrayOut[i * 1 + j], Float.floatToRawIntBits(arrayOut[i * 1 + j]), arrayOut[i * 1 + j]));
	if (!args.out.couldBe(arrayOut[i * 1 + j])) {
	message.append(" FAIL");
	}
	message.append("\n");
	assertTrue("Incorrect output for checkAsinhFloatFloat" +
	(relaxed ? "_relaxed" : "") + ":\n" + message.toString(), valid);
	}
	}
	}
	}

	private void checkAsinhFloat2Float2() {
	Allocation inV = createRandomAllocation(mRS, Element.DataType.FLOAT_32, 2, 0x198d997279032b38l, false);
	try {
	Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 2), INPUTSIZE);
	script.forEach_testAsinhFloat2Float2(inV, out);
	verifyResultsAsinhFloat2Float2(inV, out, false);
	} catch (Exception e) {
	throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat2Float2: " + e.toString());
	}
	try {
	Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 2), INPUTSIZE);
	scriptRelaxed.forEach_testAsinhFloat2Float2(inV, out);
	verifyResultsAsinhFloat2Float2(inV, out, true);
	} catch (Exception e) {
	throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat2Float2: " + e.toString());
	}
	}

	private void verifyResultsAsinhFloat2Float2(Allocation inV, Allocation out, boolean relaxed) {
	float[] arrayInV = new float[INPUTSIZE * 2];
	inV.copyTo(arrayInV);
	float[] arrayOut = new float[INPUTSIZE * 2];
	out.copyTo(arrayOut);
	for (int i = 0; i < INPUTSIZE; i++) {
	for (int j = 0; j < 2 ; j++) {
	// Extract the inputs.
	ArgumentsFloatFloat args = new ArgumentsFloatFloat();
	args.inV = arrayInV[i * 2 + j];
	// Figure out what the outputs should have been.
	Target target = new Target(relaxed);
	CoreMathVerifier.computeAsinh(args, target);
	// Validate the outputs.
	boolean valid = true;
	if (!args.out.couldBe(arrayOut[i * 2 + j])) {
	valid = false;
	}
	if (!valid) {
	StringBuilder message = new StringBuilder();
	message.append("Input inV: ");
	message.append(String.format("%14.8g {%8x} %15a",
	args.inV, Float.floatToRawIntBits(args.inV), args.inV));
	message.append("\n");
	message.append("Expected output out: ");
	message.append(args.out.toString());
	message.append("\n");
	message.append("Actual output out: ");
	message.append(String.format("%14.8g {%8x} %15a",
	arrayOut[i * 2 + j], Float.floatToRawIntBits(arrayOut[i * 2 + j]), arrayOut[i * 2 + j]));
	if (!args.out.couldBe(arrayOut[i * 2 + j])) {
	message.append(" FAIL");
	}
	message.append("\n");
	assertTrue("Incorrect output for checkAsinhFloat2Float2" +
	(relaxed ? "_relaxed" : "") + ":\n" + message.toString(), valid);
	}
	}
	}
	}

	private void checkAsinhFloat3Float3() {
	Allocation inV = createRandomAllocation(mRS, Element.DataType.FLOAT_32, 3, 0x198f628d6f1e4c16l, false);
	try {
	Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 3), INPUTSIZE);
	script.forEach_testAsinhFloat3Float3(inV, out);
	verifyResultsAsinhFloat3Float3(inV, out, false);
	} catch (Exception e) {
	throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat3Float3: " + e.toString());
	}
	try {
	Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 3), INPUTSIZE);
	scriptRelaxed.forEach_testAsinhFloat3Float3(inV, out);
	verifyResultsAsinhFloat3Float3(inV, out, true);
	} catch (Exception e) {
	throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat3Float3: " + e.toString());
	}
	}

	private void verifyResultsAsinhFloat3Float3(Allocation inV, Allocation out, boolean relaxed) {
	float[] arrayInV = new float[INPUTSIZE * 4];
	inV.copyTo(arrayInV);
	float[] arrayOut = new float[INPUTSIZE * 4];
	out.copyTo(arrayOut);
	for (int i = 0; i < INPUTSIZE; i++) {
	for (int j = 0; j < 3 ; j++) {
	// Extract the inputs.
	ArgumentsFloatFloat args = new ArgumentsFloatFloat();
	args.inV = arrayInV[i * 4 + j];
	// Figure out what the outputs should have been.
	Target target = new Target(relaxed);
	CoreMathVerifier.computeAsinh(args, target);
	// Validate the outputs.
	boolean valid = true;
	if (!args.out.couldBe(arrayOut[i * 4 + j])) {
	valid = false;
	}
	if (!valid) {
	StringBuilder message = new StringBuilder();
	message.append("Input inV: ");
	message.append(String.format("%14.8g {%8x} %15a",
	args.inV, Float.floatToRawIntBits(args.inV), args.inV));
	message.append("\n");
	message.append("Expected output out: ");
	message.append(args.out.toString());
	message.append("\n");
	message.append("Actual output out: ");
	message.append(String.format("%14.8g {%8x} %15a",
	arrayOut[i * 4 + j], Float.floatToRawIntBits(arrayOut[i * 4 + j]), arrayOut[i * 4 + j]));
	if (!args.out.couldBe(arrayOut[i * 4 + j])) {
	message.append(" FAIL");
	}
	message.append("\n");
	assertTrue("Incorrect output for checkAsinhFloat3Float3" +
	(relaxed ? "_relaxed" : "") + ":\n" + message.toString(), valid);
	}
	}
	}
	}

	private void checkAsinhFloat4Float4() {
	Allocation inV = createRandomAllocation(mRS, Element.DataType.FLOAT_32, 4, 0x19912ba865396cf4l, false);
	try {
	Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 4), INPUTSIZE);
	script.forEach_testAsinhFloat4Float4(inV, out);
	verifyResultsAsinhFloat4Float4(inV, out, false);
	} catch (Exception e) {
	throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat4Float4: " + e.toString());
	}
	try {
	Allocation out = Allocation.createSized(mRS, getElement(mRS, Element.DataType.FLOAT_32, 4), INPUTSIZE);
	scriptRelaxed.forEach_testAsinhFloat4Float4(inV, out);
	verifyResultsAsinhFloat4Float4(inV, out, true);
	} catch (Exception e) {
	throw new RSRuntimeException("RenderScript. Can't invoke forEach_testAsinhFloat4Float4: " + e.toString());
	}
	}

	private void verifyResultsAsinhFloat4Float4(Allocation inV, Allocation out, boolean relaxed) {
	float[] arrayInV = new float[INPUTSIZE * 4];
	inV.copyTo(arrayInV);
	float[] arrayOut = new float[INPUTSIZE * 4];
	out.copyTo(arrayOut);
	for (int i = 0; i < INPUTSIZE; i++) {
	for (int j = 0; j < 4 ; j++) {
	// Extract the inputs.
	ArgumentsFloatFloat args = new ArgumentsFloatFloat();
	args.inV = arrayInV[i * 4 + j];
	// Figure out what the outputs should have been.
	Target target = new Target(relaxed);
	CoreMathVerifier.computeAsinh(args, target);
	// Validate the outputs.
	boolean valid = true;
	if (!args.out.couldBe(arrayOut[i * 4 + j])) {
	valid = false;
	}
	if (!valid) {
	StringBuilder message = new StringBuilder();
	message.append("Input inV: ");
	message.append(String.format("%14.8g {%8x} %15a",
	args.inV, Float.floatToRawIntBits(args.inV), args.inV));
	message.append("\n");
	message.append("Expected output out: ");
	message.append(args.out.toString());
	message.append("\n");
	message.append("Actual output out: ");
	message.append(String.format("%14.8g {%8x} %15a",
	arrayOut[i * 4 + j], Float.floatToRawIntBits(arrayOut[i * 4 + j]), arrayOut[i * 4 + j]));
	if (!args.out.couldBe(arrayOut[i * 4 + j])) {
	message.append(" FAIL");
	}
	message.append("\n");
	assertTrue("Incorrect output for checkAsinhFloat4Float4" +
	(relaxed ? "_relaxed" : "") + ":\n" + message.toString(), valid);
	}
	}
	}
	}

	public void testAsinh() {
	checkAsinhFloatFloat();
	checkAsinhFloat2Float2();
	checkAsinhFloat3Float3();
	checkAsinhFloat4Float4();
	}
	}