/*
 * Copyright 2013 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.
 */

//#define LOG_NDEBUG 0

#include <GLES2/gl2.h>
#include <GLES2/gl2ext.h>

#include <utils/String8.h>

#include "ProgramCache.h"
#include "Program.h"
#include "Description.h"

namespace android {
// -----------------------------------------------------------------------------------------------


/*
 * A simple formatter class to automatically add the endl and
 * manage the indentation.
 */

class Formatter;
static Formatter& indent(Formatter& f);
static Formatter& dedent(Formatter& f);

class Formatter {
    String8 mString;
    int mIndent;
    typedef Formatter& (*FormaterManipFunc)(Formatter&);
    friend Formatter& indent(Formatter& f);
    friend Formatter& dedent(Formatter& f);
public:
    Formatter() : mIndent(0) {}

    String8 getString() const {
        return mString;
    }

    friend Formatter& operator << (Formatter& out, const char* in) {
        for (int i=0 ; i<out.mIndent ; i++) {
            out.mString.append("    ");
        }
        out.mString.append(in);
        out.mString.append("\n");
        return out;
    }
    friend inline Formatter& operator << (Formatter& out, const String8& in) {
        return operator << (out, in.string());
    }
    friend inline Formatter& operator<<(Formatter& to, FormaterManipFunc func) {
        return (*func)(to);
    }
};
Formatter& indent(Formatter& f) {
    f.mIndent++;
    return f;
}
Formatter& dedent(Formatter& f) {
    f.mIndent--;
    return f;
}

// -----------------------------------------------------------------------------------------------

ANDROID_SINGLETON_STATIC_INSTANCE(ProgramCache)

ProgramCache::ProgramCache() {
    // Until surfaceflinger has a dependable blob cache on the filesystem,
    // generate shaders on initialization so as to avoid jank.
    primeCache();
}

ProgramCache::~ProgramCache() {
}

void ProgramCache::primeCache() {
    uint32_t shaderCount = 0;
    uint32_t keyMask = Key::BLEND_MASK | Key::OPACITY_MASK |
                       Key::PLANE_ALPHA_MASK | Key::TEXTURE_MASK;
    // Prime the cache for all combinations of the above masks,
    // leaving off the experimental color matrix mask options.

    nsecs_t timeBefore = systemTime();
    for (uint32_t keyVal = 0; keyVal <= keyMask; keyVal++) {
        Key shaderKey;
        shaderKey.set(keyMask, keyVal);
        uint32_t tex = shaderKey.getTextureTarget();
        if (tex != Key::TEXTURE_OFF &&
            tex != Key::TEXTURE_EXT &&
            tex != Key::TEXTURE_2D) {
            continue;
        }
        Program* program = mCache.valueFor(shaderKey);
        if (program == NULL) {
            program = generateProgram(shaderKey);
            mCache.add(shaderKey, program);
            shaderCount++;
        }
    }

    // Keys that are actually used by blurring.
    // This is obtained by log msg from useProgram()
    uint32_t blurringKeys[] = {
        0x01000015,
        0x01000011,
    };
    for (size_t i=0; i<sizeof(blurringKeys)/sizeof(blurringKeys[0]); ++i) {
        Key shaderKey;
        shaderKey.set(blurringKeys[i], blurringKeys[i]);
        Program* program = mCache.valueFor(shaderKey);
        if (program == NULL) {
            program = generateProgram(shaderKey);
            mCache.add(shaderKey, program);
            shaderCount++;
        }
    }

    nsecs_t timeAfter = systemTime();
    float compileTimeMs = static_cast<float>(timeAfter - timeBefore) / 1.0E6;
    ALOGD("SF. shader cache generated - %u shaders in %f ms\n", shaderCount, compileTimeMs);
}

ProgramCache::Key ProgramCache::computeKey(const Description& description) {
    Key needs;
    needs.set(Key::TEXTURE_MASK,
            !description.mTextureEnabled ? Key::TEXTURE_OFF :
            description.mTexture.getTextureTarget() == GL_TEXTURE_EXTERNAL_OES ? Key::TEXTURE_EXT :
            description.mTexture.getTextureTarget() == GL_TEXTURE_2D           ? Key::TEXTURE_2D :
            Key::TEXTURE_OFF)
    .set(Key::PLANE_ALPHA_MASK,
            (description.mPlaneAlpha < 1) ? Key::PLANE_ALPHA_LT_ONE : Key::PLANE_ALPHA_EQ_ONE)
    .set(Key::BLEND_MASK,
            description.mPremultipliedAlpha ? Key::BLEND_PREMULT : Key::BLEND_NORMAL)
    .set(Key::OPACITY_MASK,
            description.mOpaque ? Key::OPACITY_OPAQUE : Key::OPACITY_TRANSLUCENT)
    .set(Key::COLOR_MATRIX_MASK,
            description.mColorMatrixEnabled ? Key::COLOR_MATRIX_ON :  Key::COLOR_MATRIX_OFF)
    .set(Key::TEXTURE_MASKING_MASK,
            !description.mMaskTextureEnabled ? Key::TEXTURE_MASKING_OFF :
            description.mMaskTexture.getTextureTarget() == GL_TEXTURE_EXTERNAL_OES ? Key::TEXTURE_MASKING_EXT :
            description.mMaskTexture.getTextureTarget() == GL_TEXTURE_2D           ? Key::TEXTURE_MASKING_2D :
            Key::TEXTURE_MASKING_OFF);
    return needs;
}

String8 ProgramCache::generateVertexShader(const Key& needs) {
    Formatter vs;
    if (needs.isTexturing()) {
        vs << "attribute vec4 texCoords;"
           << "varying vec2 outTexCoords;";
    }
    vs << "attribute vec4 position;"
       << "uniform mat4 projection;"
       << "uniform mat4 texture;"
       << "void main(void) {" << indent
       << "gl_Position = projection * position;";
    if (needs.isTexturing()) {
       vs << "outTexCoords = (texture * texCoords).st;";
    }
    vs << dedent << "}";
    return vs.getString();
}

String8 ProgramCache::generateFragmentShader(const Key& needs) {
    Formatter fs;
    if (needs.getTextureTarget() == Key::TEXTURE_EXT) {
        fs << "#extension GL_OES_EGL_image_external : require";
    }

    // default precision is required-ish in fragment shaders
    fs << "precision mediump float;";

    if (needs.getTextureTarget() == Key::TEXTURE_EXT) {
        fs << "uniform samplerExternalOES sampler;"
           << "varying vec2 outTexCoords;";
    } else if (needs.getTextureTarget() == Key::TEXTURE_2D) {
        fs << "uniform sampler2D sampler;"
           << "varying vec2 outTexCoords;";
    } else if (needs.getTextureTarget() == Key::TEXTURE_OFF) {
        fs << "uniform vec4 color;";
    }
    if (needs.getTextureMaskingTarget() == Key::TEXTURE_MASKING_EXT) {
        fs << "uniform samplerExternalOES samplerMask;";
    } else if (needs.getTextureMaskingTarget() == Key::TEXTURE_MASKING_2D) {
        fs << "uniform sampler2D samplerMask;";
    }
    if (needs.getTextureMaskingTarget() != Key::TEXTURE_MASKING_OFF) {
        fs << "uniform float maskAlphaThreshold;";
    }
    if (needs.hasPlaneAlpha()) {
        fs << "uniform float alphaPlane;";
    }
    if (needs.hasColorMatrix()) {
        fs << "uniform mat4 colorMatrix;";
    }
    fs << "void main(void) {" << indent;
    if (needs.isTexturing()) {
        if (needs.getTextureMaskingTarget() != Key::TEXTURE_MASKING_OFF) {
            fs << "if (texture2D(samplerMask, outTexCoords).a <= maskAlphaThreshold) discard;"
               << "gl_FragColor = texture2D(sampler, outTexCoords);";
        } else {
            fs << "gl_FragColor = texture2D(sampler, outTexCoords);";
        }
    } else {
        fs << "gl_FragColor = color;";
    }
    if (needs.isOpaque()) {
        fs << "gl_FragColor.a = 1.0;";
    }
    if (needs.hasPlaneAlpha()) {
        // modulate the alpha value with planeAlpha
        if (needs.isPremultiplied()) {
            // ... and the color too if we're premultiplied
            fs << "gl_FragColor *= alphaPlane;";
        } else {
            fs << "gl_FragColor.a *= alphaPlane;";
        }
    }

    if (needs.hasColorMatrix()) {
        if (!needs.isOpaque() && needs.isPremultiplied()) {
            // un-premultiply if needed before linearization
            fs << "gl_FragColor.rgb = gl_FragColor.rgb/gl_FragColor.a;";
        }
        fs << "vec4 transformed = colorMatrix * vec4(gl_FragColor.rgb, 1);";
        fs << "gl_FragColor.rgb = transformed.rgb/transformed.a;";
        if (!needs.isOpaque() && needs.isPremultiplied()) {
            // and re-premultiply if needed after gamma correction
            fs << "gl_FragColor.rgb = gl_FragColor.rgb*gl_FragColor.a;";
        }
    }

    fs << dedent << "}";
    return fs.getString();
}

Program* ProgramCache::generateProgram(const Key& needs) {
    // vertex shader
    String8 vs = generateVertexShader(needs);

    // fragment shader
    String8 fs = generateFragmentShader(needs);

    Program* program = new Program(needs, vs.string(), fs.string());
    return program;
}

void ProgramCache::useProgram(const Description& description) {

    // generate the key for the shader based on the description
    Key needs(computeKey(description));

     // look-up the program in the cache
    Program* program = mCache.valueFor(needs);
    if (program == NULL) {
        // we didn't find our program, so generate one...
        nsecs_t time = -systemTime();
        program = generateProgram(needs);
        mCache.add(needs, program);
        time += systemTime();
    }

    // here we have a suitable program for this description
    if (program->isValid()) {
        program->use();
        program->setUniforms(description);
    }
}


} /* namespace android */