Main.java Source code

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Here is the source code for Main.java

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//package com.java2s;
/* Copyright 2015 The TensorFlow Authors. All Rights Reserved.
    
 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.
 ==============================================================================*/

import android.graphics.Matrix;

public class Main {
    /**
     * Returns a transformation matrix from one reference frame into another.
     * Handles cropping (if maintaining aspect ratio is desired) and rotation.
     *
     * @param srcWidth Width of source frame.
     * @param srcHeight Height of source frame.
     * @param dstWidth Width of destination frame.
     * @param dstHeight Height of destination frame.
     * @param applyRotation Amount of rotation to apply from one frame to another.
     *  Must be a multiple of 90.
     * @param maintainAspectRatio If true, will ensure that scaling in x and y remains constant,
     * cropping the image if necessary.
     * @return The transformation fulfilling the desired requirements.
     */
    public static Matrix getTransformationMatrix(final int srcWidth, final int srcHeight, final int dstWidth,
            final int dstHeight, final int applyRotation, final boolean maintainAspectRatio) {
        final Matrix matrix = new Matrix();

        if (applyRotation != 0) {
            // Translate so center of image is at origin.
            matrix.postTranslate(-srcWidth / 2.0f, -srcHeight / 2.0f);

            // Rotate around origin.
            matrix.postRotate(applyRotation);
        }

        // Account for the already applied rotation, if any, and then determine how
        // much scaling is needed for each axis.
        final boolean transpose = (Math.abs(applyRotation) + 90) % 180 == 0;

        final int inWidth = transpose ? srcHeight : srcWidth;
        final int inHeight = transpose ? srcWidth : srcHeight;

        // Apply scaling if necessary.
        if (inWidth != dstWidth || inHeight != dstHeight) {
            final float scaleFactorX = dstWidth / (float) inWidth;
            final float scaleFactorY = dstHeight / (float) inHeight;

            if (maintainAspectRatio) {
                // Scale by minimum factor so that dst is filled completely while
                // maintaining the aspect ratio. Some image may fall off the edge.
                final float scaleFactor = Math.max(scaleFactorX, scaleFactorY);
                matrix.postScale(scaleFactor, scaleFactor);
            } else {
                // Scale exactly to fill dst from src.
                matrix.postScale(scaleFactorX, scaleFactorY);
            }
        }

        if (applyRotation != 0) {
            // Translate back from origin centered reference to destination frame.
            matrix.postTranslate(dstWidth / 2.0f, dstHeight / 2.0f);
        }

        return matrix;
    }
}