/*
* Copyright (C) 2008-2012 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.
*/
package android.renderscript;
import java.io.IOException;
import java.io.InputStream;
import android.content.res.Resources;
import android.content.res.AssetManager;
import android.graphics.Bitmap;
import android.graphics.BitmapFactory;
import android.view.Surface;
import android.graphics.SurfaceTexture;
import android.util.Log;
import android.util.TypedValue;
/**
*
* Memory allocation class for renderscript. An allocation combines a
* {@link android.renderscript.Type} with the memory to provide storage for user data and objects.
* This implies that all memory in Renderscript is typed.
*
*
* Allocations are the primary way data moves into and out of scripts. Memory is user
* synchronized and it's possible for allocations to exist in multiple memory spaces
* concurrently. Currently those spaces are:
*
* - Script: accessable by RS scripts.
* - Graphics Texture: accessable as a graphics texture.
* - Graphics Vertex: accessable as graphical vertex data.
* - Graphics Constants: Accessable as constants in user shaders
*
*
*
* For example, when creating a allocation for a texture, the user can
* specify its memory spaces as both script and textures. This means that it can both
* be used as script binding and as a GPU texture for rendering. To maintain
* synchronization if a script modifies an allocation used by other targets it must
* call a synchronizing function to push the updates to the memory, otherwise the results
* are undefined.
*
* By default, Android system side updates are always applied to the script accessable
* memory. If this is not present, they are then applied to the various HW
* memory types. A {@link android.renderscript.Allocation#syncAll syncAll()}
* call is necessary after the script data is updated to
* keep the other memory spaces in sync.
*
* Allocation data is uploaded in one of two primary ways. For simple
* arrays there are copyFrom() functions that take an array from the control code and
* copy it to the slave memory store. Both type checked and unchecked copies are provided.
* The unchecked variants exist to allow apps to copy over arrays of structures from a
* control language that does not support structures.
*
*
*
Developer Guides
*
For more information about creating an application that uses Renderscript, read the
* Renderscript developer guide.
*
**/
public class Allocation extends BaseObj {
Type mType;
Bitmap mBitmap;
int mUsage;
Allocation mAdaptedAllocation;
boolean mConstrainedLOD;
boolean mConstrainedFace;
boolean mConstrainedY;
boolean mConstrainedZ;
boolean mReadAllowed = true;
boolean mWriteAllowed = true;
int mSelectedY;
int mSelectedZ;
int mSelectedLOD;
Type.CubemapFace mSelectedFace = Type.CubemapFace.POSITIVE_X;
int mCurrentDimX;
int mCurrentDimY;
int mCurrentDimZ;
int mCurrentCount;
/**
* The usage of the allocation. These signal to renderscript
* where to place the allocation in memory.
*
* SCRIPT The allocation will be bound to and accessed by
* scripts.
*/
public static final int USAGE_SCRIPT = 0x0001;
/**
* GRAPHICS_TEXTURE The allocation will be used as a texture
* source by one or more graphics programs.
*
*/
public static final int USAGE_GRAPHICS_TEXTURE = 0x0002;
/**
* GRAPHICS_VERTEX The allocation will be used as a graphics
* mesh.
*
*/
public static final int USAGE_GRAPHICS_VERTEX = 0x0004;
/**
* GRAPHICS_CONSTANTS The allocation will be used as the source
* of shader constants by one or more programs.
*
*/
public static final int USAGE_GRAPHICS_CONSTANTS = 0x0008;
/**
* USAGE_GRAPHICS_RENDER_TARGET The allocation will be used as a
* target for offscreen rendering
*
*/
public static final int USAGE_GRAPHICS_RENDER_TARGET = 0x0010;
/**
* USAGE_IO_INPUT The allocation will be used as SurfaceTexture
* consumer. This usage will cause the allocation to be created
* read only.
*
*/
public static final int USAGE_IO_INPUT = 0x0020;
/**
* USAGE_IO_OUTPUT The allocation will be used as a
* SurfaceTexture producer. The dimensions and format of the
* SurfaceTexture will be forced to those of the allocation.
*
*/
public static final int USAGE_IO_OUTPUT = 0x0040;
/**
* Controls mipmap behavior when using the bitmap creation and
* update functions.
*/
public enum MipmapControl {
/**
* No mipmaps will be generated and the type generated from the
* incoming bitmap will not contain additional LODs.
*/
MIPMAP_NONE(0),
/**
* A Full mipmap chain will be created in script memory. The
* type of the allocation will contain a full mipmap chain. On
* upload to graphics the full chain will be transfered.
*/
MIPMAP_FULL(1),
/**
* The type of the allocation will be the same as MIPMAP_NONE.
* It will not contain mipmaps. On upload to graphics the
* graphics copy of the allocation data will contain a full
* mipmap chain generated from the top level in script memory.
*/
MIPMAP_ON_SYNC_TO_TEXTURE(2);
int mID;
MipmapControl(int id) {
mID = id;
}
}
private int getIDSafe() {
if (mAdaptedAllocation != null) {
return mAdaptedAllocation.getID(mRS);
}
return getID(mRS);
}
/**
* Get the element of the type of the Allocation.
*
* @return Element that describes the structure of data in the
* allocation
*
*/
public Element getElement() {
return mType.getElement();
}
/**
* Get the usage flags of the Allocation.
*
* @return usage flags associated with the allocation. e.g.
* script, texture, etc.
*
*/
public int getUsage() {
return mUsage;
}
/**
* Get the size of the Allocation in bytes.
*
* @return size of the Allocation in bytes.
*
*/
public int getBytesSize() {
return mType.getCount() * mType.getElement().getBytesSize();
}
private void updateCacheInfo(Type t) {
mCurrentDimX = t.getX();
mCurrentDimY = t.getY();
mCurrentDimZ = t.getZ();
mCurrentCount = mCurrentDimX;
if (mCurrentDimY > 1) {
mCurrentCount *= mCurrentDimY;
}
if (mCurrentDimZ > 1) {
mCurrentCount *= mCurrentDimZ;
}
}
Allocation(int id, RenderScript rs, Type t, int usage) {
super(id, rs);
if ((usage & ~(USAGE_SCRIPT |
USAGE_GRAPHICS_TEXTURE |
USAGE_GRAPHICS_VERTEX |
USAGE_GRAPHICS_CONSTANTS |
USAGE_GRAPHICS_RENDER_TARGET |
USAGE_IO_INPUT |
USAGE_IO_OUTPUT)) != 0) {
throw new RSIllegalArgumentException("Unknown usage specified.");
}
if ((usage & USAGE_IO_INPUT) != 0) {
mWriteAllowed = false;
if ((usage & ~(USAGE_IO_INPUT |
USAGE_GRAPHICS_TEXTURE |
USAGE_SCRIPT)) != 0) {
throw new RSIllegalArgumentException("Invalid usage combination.");
}
}
mType = t;
mUsage = usage;
if (t != null) {
updateCacheInfo(t);
}
}
private void validateIsInt32() {
if ((mType.mElement.mType == Element.DataType.SIGNED_32) ||
(mType.mElement.mType == Element.DataType.UNSIGNED_32)) {
return;
}
throw new RSIllegalArgumentException(
"32 bit integer source does not match allocation type " + mType.mElement.mType);
}
private void validateIsInt16() {
if ((mType.mElement.mType == Element.DataType.SIGNED_16) ||
(mType.mElement.mType == Element.DataType.UNSIGNED_16)) {
return;
}
throw new RSIllegalArgumentException(
"16 bit integer source does not match allocation type " + mType.mElement.mType);
}
private void validateIsInt8() {
if ((mType.mElement.mType == Element.DataType.SIGNED_8) ||
(mType.mElement.mType == Element.DataType.UNSIGNED_8)) {
return;
}
throw new RSIllegalArgumentException(
"8 bit integer source does not match allocation type " + mType.mElement.mType);
}
private void validateIsFloat32() {
if (mType.mElement.mType == Element.DataType.FLOAT_32) {
return;
}
throw new RSIllegalArgumentException(
"32 bit float source does not match allocation type " + mType.mElement.mType);
}
private void validateIsObject() {
if ((mType.mElement.mType == Element.DataType.RS_ELEMENT) ||
(mType.mElement.mType == Element.DataType.RS_TYPE) ||
(mType.mElement.mType == Element.DataType.RS_ALLOCATION) ||
(mType.mElement.mType == Element.DataType.RS_SAMPLER) ||
(mType.mElement.mType == Element.DataType.RS_SCRIPT) ||
(mType.mElement.mType == Element.DataType.RS_MESH) ||
(mType.mElement.mType == Element.DataType.RS_PROGRAM_FRAGMENT) ||
(mType.mElement.mType == Element.DataType.RS_PROGRAM_VERTEX) ||
(mType.mElement.mType == Element.DataType.RS_PROGRAM_RASTER) ||
(mType.mElement.mType == Element.DataType.RS_PROGRAM_STORE)) {
return;
}
throw new RSIllegalArgumentException(
"Object source does not match allocation type " + mType.mElement.mType);
}
@Override
void updateFromNative() {
super.updateFromNative();
int typeID = mRS.nAllocationGetType(getID(mRS));
if(typeID != 0) {
mType = new Type(typeID, mRS);
mType.updateFromNative();
updateCacheInfo(mType);
}
}
/**
* Get the type of the Allocation.
*
* @return Type
*
*/
public Type getType() {
return mType;
}
/**
* Propagate changes from one usage of the allocation to the
* remaining usages of the allocation.
*
*/
public void syncAll(int srcLocation) {
switch (srcLocation) {
case USAGE_SCRIPT:
case USAGE_GRAPHICS_CONSTANTS:
case USAGE_GRAPHICS_TEXTURE:
case USAGE_GRAPHICS_VERTEX:
break;
default:
throw new RSIllegalArgumentException("Source must be exactly one usage type.");
}
mRS.validate();
mRS.nAllocationSyncAll(getIDSafe(), srcLocation);
}
/**
* Send a buffer to the output stream. The contents of the
* Allocation will be undefined after this operation.
*
*/
public void ioSend() {
if ((mUsage & USAGE_IO_OUTPUT) == 0) {
throw new RSIllegalArgumentException(
"Can only send buffer if IO_OUTPUT usage specified.");
}
mRS.validate();
mRS.nAllocationIoSend(getID(mRS));
}
/**
* Delete once code is updated.
* @hide
*/
public void ioSendOutput() {
ioSend();
}
/**
* Receive the latest input into the Allocation.
*
*/
public void ioReceive() {
if ((mUsage & USAGE_IO_INPUT) == 0) {
throw new RSIllegalArgumentException(
"Can only receive if IO_INPUT usage specified.");
}
mRS.validate();
mRS.nAllocationIoReceive(getID(mRS));
}
/**
* Copy an array of RS objects to the allocation.
*
* @param d Source array.
*/
public void copyFrom(BaseObj[] d) {
mRS.validate();
validateIsObject();
if (d.length != mCurrentCount) {
throw new RSIllegalArgumentException("Array size mismatch, allocation sizeX = " +
mCurrentCount + ", array length = " + d.length);
}
int i[] = new int[d.length];
for (int ct=0; ct < d.length; ct++) {
i[ct] = d[ct].getID(mRS);
}
copy1DRangeFromUnchecked(0, mCurrentCount, i);
}
private void validateBitmapFormat(Bitmap b) {
Bitmap.Config bc = b.getConfig();
switch (bc) {
case ALPHA_8:
if (mType.getElement().mKind != Element.DataKind.PIXEL_A) {
throw new RSIllegalArgumentException("Allocation kind is " +
mType.getElement().mKind + ", type " +
mType.getElement().mType +
" of " + mType.getElement().getBytesSize() +
" bytes, passed bitmap was " + bc);
}
break;
case ARGB_8888:
if ((mType.getElement().mKind != Element.DataKind.PIXEL_RGBA) ||
(mType.getElement().getBytesSize() != 4)) {
throw new RSIllegalArgumentException("Allocation kind is " +
mType.getElement().mKind + ", type " +
mType.getElement().mType +
" of " + mType.getElement().getBytesSize() +
" bytes, passed bitmap was " + bc);
}
break;
case RGB_565:
if ((mType.getElement().mKind != Element.DataKind.PIXEL_RGB) ||
(mType.getElement().getBytesSize() != 2)) {
throw new RSIllegalArgumentException("Allocation kind is " +
mType.getElement().mKind + ", type " +
mType.getElement().mType +
" of " + mType.getElement().getBytesSize() +
" bytes, passed bitmap was " + bc);
}
break;
case ARGB_4444:
if ((mType.getElement().mKind != Element.DataKind.PIXEL_RGBA) ||
(mType.getElement().getBytesSize() != 2)) {
throw new RSIllegalArgumentException("Allocation kind is " +
mType.getElement().mKind + ", type " +
mType.getElement().mType +
" of " + mType.getElement().getBytesSize() +
" bytes, passed bitmap was " + bc);
}
break;
}
}
private void validateBitmapSize(Bitmap b) {
if((mCurrentDimX != b.getWidth()) || (mCurrentDimY != b.getHeight())) {
throw new RSIllegalArgumentException("Cannot update allocation from bitmap, sizes mismatch");
}
}
/**
* Copy an allocation from an array. This variant is not type
* checked which allows an application to fill in structured
* data from an array.
*
* @param d the source data array
*/
public void copyFromUnchecked(int[] d) {
mRS.validate();
copy1DRangeFromUnchecked(0, mCurrentCount, d);
}
/**
* Copy an allocation from an array. This variant is not type
* checked which allows an application to fill in structured
* data from an array.
*
* @param d the source data array
*/
public void copyFromUnchecked(short[] d) {
mRS.validate();
copy1DRangeFromUnchecked(0, mCurrentCount, d);
}
/**
* Copy an allocation from an array. This variant is not type
* checked which allows an application to fill in structured
* data from an array.
*
* @param d the source data array
*/
public void copyFromUnchecked(byte[] d) {
mRS.validate();
copy1DRangeFromUnchecked(0, mCurrentCount, d);
}
/**
* Copy an allocation from an array. This variant is not type
* checked which allows an application to fill in structured
* data from an array.
*
* @param d the source data array
*/
public void copyFromUnchecked(float[] d) {
mRS.validate();
copy1DRangeFromUnchecked(0, mCurrentCount, d);
}
/**
* Copy an allocation from an array. This variant is type
* checked and will generate exceptions if the Allocation type
* is not a 32 bit integer type.
*
* @param d the source data array
*/
public void copyFrom(int[] d) {
mRS.validate();
copy1DRangeFrom(0, mCurrentCount, d);
}
/**
* Copy an allocation from an array. This variant is type
* checked and will generate exceptions if the Allocation type
* is not a 16 bit integer type.
*
* @param d the source data array
*/
public void copyFrom(short[] d) {
mRS.validate();
copy1DRangeFrom(0, mCurrentCount, d);
}
/**
* Copy an allocation from an array. This variant is type
* checked and will generate exceptions if the Allocation type
* is not a 8 bit integer type.
*
* @param d the source data array
*/
public void copyFrom(byte[] d) {
mRS.validate();
copy1DRangeFrom(0, mCurrentCount, d);
}
/**
* Copy an allocation from an array. This variant is type
* checked and will generate exceptions if the Allocation type
* is not a 32 bit float type.
*
* @param d the source data array
*/
public void copyFrom(float[] d) {
mRS.validate();
copy1DRangeFrom(0, mCurrentCount, d);
}
/**
* Copy an allocation from a bitmap. The height, width, and
* format of the bitmap must match the existing allocation.
*
* @param b the source bitmap
*/
public void copyFrom(Bitmap b) {
mRS.validate();
validateBitmapSize(b);
validateBitmapFormat(b);
mRS.nAllocationCopyFromBitmap(getID(mRS), b);
}
/**
* This is only intended to be used by auto-generate code reflected from the
* renderscript script files.
*
* @param xoff
* @param fp
*/
public void setFromFieldPacker(int xoff, FieldPacker fp) {
mRS.validate();
int eSize = mType.mElement.getBytesSize();
final byte[] data = fp.getData();
int count = data.length / eSize;
if ((eSize * count) != data.length) {
throw new RSIllegalArgumentException("Field packer length " + data.length +
" not divisible by element size " + eSize + ".");
}
copy1DRangeFromUnchecked(xoff, count, data);
}
/**
* This is only intended to be used by auto-generate code reflected from the
* renderscript script files.
*
* @param xoff
* @param component_number
* @param fp
*/
public void setFromFieldPacker(int xoff, int component_number, FieldPacker fp) {
mRS.validate();
if (component_number >= mType.mElement.mElements.length) {
throw new RSIllegalArgumentException("Component_number " + component_number + " out of range.");
}
if(xoff < 0) {
throw new RSIllegalArgumentException("Offset must be >= 0.");
}
final byte[] data = fp.getData();
int eSize = mType.mElement.mElements[component_number].getBytesSize();
eSize *= mType.mElement.mArraySizes[component_number];
if (data.length != eSize) {
throw new RSIllegalArgumentException("Field packer sizelength " + data.length +
" does not match component size " + eSize + ".");
}
mRS.nAllocationElementData1D(getIDSafe(), xoff, mSelectedLOD,
component_number, data, data.length);
}
private void data1DChecks(int off, int count, int len, int dataSize) {
mRS.validate();
if(off < 0) {
throw new RSIllegalArgumentException("Offset must be >= 0.");
}
if(count < 1) {
throw new RSIllegalArgumentException("Count must be >= 1.");
}
if((off + count) > mCurrentCount) {
throw new RSIllegalArgumentException("Overflow, Available count " + mCurrentCount +
", got " + count + " at offset " + off + ".");
}
if(len < dataSize) {
throw new RSIllegalArgumentException("Array too small for allocation type.");
}
}
/**
* Generate a mipmap chain. Requires the type of the allocation
* include mipmaps.
*
* This function will generate a complete set of mipmaps from
* the top level lod and place them into the script memoryspace.
*
* If the allocation is also using other memory spaces a
* followup sync will be required.
*/
public void generateMipmaps() {
mRS.nAllocationGenerateMipmaps(getID(mRS));
}
/**
* Copy part of an allocation from an array. This variant is
* not type checked which allows an application to fill in
* structured data from an array.
*
* @param off The offset of the first element to be copied.
* @param count The number of elements to be copied.
* @param d the source data array
*/
public void copy1DRangeFromUnchecked(int off, int count, int[] d) {
int dataSize = mType.mElement.getBytesSize() * count;
data1DChecks(off, count, d.length * 4, dataSize);
mRS.nAllocationData1D(getIDSafe(), off, mSelectedLOD, count, d, dataSize);
}
/**
* Copy part of an allocation from an array. This variant is
* not type checked which allows an application to fill in
* structured data from an array.
*
* @param off The offset of the first element to be copied.
* @param count The number of elements to be copied.
* @param d the source data array
*/
public void copy1DRangeFromUnchecked(int off, int count, short[] d) {
int dataSize = mType.mElement.getBytesSize() * count;
data1DChecks(off, count, d.length * 2, dataSize);
mRS.nAllocationData1D(getIDSafe(), off, mSelectedLOD, count, d, dataSize);
}
/**
* Copy part of an allocation from an array. This variant is
* not type checked which allows an application to fill in
* structured data from an array.
*
* @param off The offset of the first element to be copied.
* @param count The number of elements to be copied.
* @param d the source data array
*/
public void copy1DRangeFromUnchecked(int off, int count, byte[] d) {
int dataSize = mType.mElement.getBytesSize() * count;
data1DChecks(off, count, d.length, dataSize);
mRS.nAllocationData1D(getIDSafe(), off, mSelectedLOD, count, d, dataSize);
}
/**
* Copy part of an allocation from an array. This variant is
* not type checked which allows an application to fill in
* structured data from an array.
*
* @param off The offset of the first element to be copied.
* @param count The number of elements to be copied.
* @param d the source data array
*/
public void copy1DRangeFromUnchecked(int off, int count, float[] d) {
int dataSize = mType.mElement.getBytesSize() * count;
data1DChecks(off, count, d.length * 4, dataSize);
mRS.nAllocationData1D(getIDSafe(), off, mSelectedLOD, count, d, dataSize);
}
/**
* Copy part of an allocation from an array. This variant is
* type checked and will generate exceptions if the Allocation
* type is not a 32 bit integer type.
*
* @param off The offset of the first element to be copied.
* @param count The number of elements to be copied.
* @param d the source data array
*/
public void copy1DRangeFrom(int off, int count, int[] d) {
validateIsInt32();
copy1DRangeFromUnchecked(off, count, d);
}
/**
* Copy part of an allocation from an array. This variant is
* type checked and will generate exceptions if the Allocation
* type is not a 16 bit integer type.
*
* @param off The offset of the first element to be copied.
* @param count The number of elements to be copied.
* @param d the source data array
*/
public void copy1DRangeFrom(int off, int count, short[] d) {
validateIsInt16();
copy1DRangeFromUnchecked(off, count, d);
}
/**
* Copy part of an allocation from an array. This variant is
* type checked and will generate exceptions if the Allocation
* type is not a 8 bit integer type.
*
* @param off The offset of the first element to be copied.
* @param count The number of elements to be copied.
* @param d the source data array
*/
public void copy1DRangeFrom(int off, int count, byte[] d) {
validateIsInt8();
copy1DRangeFromUnchecked(off, count, d);
}
/**
* Copy part of an allocation from an array. This variant is
* type checked and will generate exceptions if the Allocation
* type is not a 32 bit float type.
*
* @param off The offset of the first element to be copied.
* @param count The number of elements to be copied.
* @param d the source data array.
*/
public void copy1DRangeFrom(int off, int count, float[] d) {
validateIsFloat32();
copy1DRangeFromUnchecked(off, count, d);
}
/**
* Copy part of an allocation from another allocation.
*
* @param off The offset of the first element to be copied.
* @param count The number of elements to be copied.
* @param data the source data allocation.
* @param dataOff off The offset of the first element in data to
* be copied.
*/
public void copy1DRangeFrom(int off, int count, Allocation data, int dataOff) {
mRS.nAllocationData2D(getIDSafe(), off, 0,
mSelectedLOD, mSelectedFace.mID,
count, 1, data.getID(mRS), dataOff, 0,
data.mSelectedLOD, data.mSelectedFace.mID);
}
private void validate2DRange(int xoff, int yoff, int w, int h) {
if (mAdaptedAllocation != null) {
} else {
if (xoff < 0 || yoff < 0) {
throw new RSIllegalArgumentException("Offset cannot be negative.");
}
if (h < 0 || w < 0) {
throw new RSIllegalArgumentException("Height or width cannot be negative.");
}
if (((xoff + w) > mCurrentDimX) || ((yoff + h) > mCurrentDimY)) {
throw new RSIllegalArgumentException("Updated region larger than allocation.");
}
}
}
/**
* Copy a rectangular region from the array into the allocation.
* The incoming array is assumed to be tightly packed.
*
* @param xoff X offset of the region to update
* @param yoff Y offset of the region to update
* @param w Width of the incoming region to update
* @param h Height of the incoming region to update
* @param data to be placed into the allocation
*/
public void copy2DRangeFrom(int xoff, int yoff, int w, int h, byte[] data) {
mRS.validate();
validate2DRange(xoff, yoff, w, h);
mRS.nAllocationData2D(getIDSafe(), xoff, yoff, mSelectedLOD, mSelectedFace.mID,
w, h, data, data.length);
}
public void copy2DRangeFrom(int xoff, int yoff, int w, int h, short[] data) {
mRS.validate();
validate2DRange(xoff, yoff, w, h);
mRS.nAllocationData2D(getIDSafe(), xoff, yoff, mSelectedLOD, mSelectedFace.mID,
w, h, data, data.length * 2);
}
public void copy2DRangeFrom(int xoff, int yoff, int w, int h, int[] data) {
mRS.validate();
validate2DRange(xoff, yoff, w, h);
mRS.nAllocationData2D(getIDSafe(), xoff, yoff, mSelectedLOD, mSelectedFace.mID,
w, h, data, data.length * 4);
}
public void copy2DRangeFrom(int xoff, int yoff, int w, int h, float[] data) {
mRS.validate();
validate2DRange(xoff, yoff, w, h);
mRS.nAllocationData2D(getIDSafe(), xoff, yoff, mSelectedLOD, mSelectedFace.mID,
w, h, data, data.length * 4);
}
/**
* Copy a rectangular region into the allocation from another
* allocation.
*
* @param xoff X offset of the region to update.
* @param yoff Y offset of the region to update.
* @param w Width of the incoming region to update.
* @param h Height of the incoming region to update.
* @param data source allocation.
* @param dataXoff X offset in data of the region to update.
* @param dataYoff Y offset in data of the region to update.
*/
public void copy2DRangeFrom(int xoff, int yoff, int w, int h,
Allocation data, int dataXoff, int dataYoff) {
mRS.validate();
validate2DRange(xoff, yoff, w, h);
mRS.nAllocationData2D(getIDSafe(), xoff, yoff,
mSelectedLOD, mSelectedFace.mID,
w, h, data.getID(mRS), dataXoff, dataYoff,
data.mSelectedLOD, data.mSelectedFace.mID);
}
/**
* Copy a bitmap into an allocation. The height and width of
* the update will use the height and width of the incoming
* bitmap.
*
* @param xoff X offset of the region to update
* @param yoff Y offset of the region to update
* @param data the bitmap to be copied
*/
public void copy2DRangeFrom(int xoff, int yoff, Bitmap data) {
mRS.validate();
validateBitmapFormat(data);
validate2DRange(xoff, yoff, data.getWidth(), data.getHeight());
mRS.nAllocationData2D(getIDSafe(), xoff, yoff, mSelectedLOD, mSelectedFace.mID, data);
}
/**
* Copy from the Allocation into a Bitmap. The bitmap must
* match the dimensions of the Allocation.
*
* @param b The bitmap to be set from the Allocation.
*/
public void copyTo(Bitmap b) {
mRS.validate();
validateBitmapFormat(b);
validateBitmapSize(b);
mRS.nAllocationCopyToBitmap(getID(mRS), b);
}
/**
* Copy from the Allocation into a byte array. The array must
* be at least as large as the Allocation. The allocation must
* be of an 8 bit elemental type.
*
* @param d The array to be set from the Allocation.
*/
public void copyTo(byte[] d) {
validateIsInt8();
mRS.validate();
mRS.nAllocationRead(getID(mRS), d);
}
/**
* Copy from the Allocation into a short array. The array must
* be at least as large as the Allocation. The allocation must
* be of an 16 bit elemental type.
*
* @param d The array to be set from the Allocation.
*/
public void copyTo(short[] d) {
validateIsInt16();
mRS.validate();
mRS.nAllocationRead(getID(mRS), d);
}
/**
* Copy from the Allocation into a int array. The array must be
* at least as large as the Allocation. The allocation must be
* of an 32 bit elemental type.
*
* @param d The array to be set from the Allocation.
*/
public void copyTo(int[] d) {
validateIsInt32();
mRS.validate();
mRS.nAllocationRead(getID(mRS), d);
}
/**
* Copy from the Allocation into a float array. The array must
* be at least as large as the Allocation. The allocation must
* be of an 32 bit float elemental type.
*
* @param d The array to be set from the Allocation.
*/
public void copyTo(float[] d) {
validateIsFloat32();
mRS.validate();
mRS.nAllocationRead(getID(mRS), d);
}
/**
* Resize a 1D allocation. The contents of the allocation are
* preserved. If new elements are allocated objects are created
* with null contents and the new region is otherwise undefined.
*
* If the new region is smaller the references of any objects
* outside the new region will be released.
*
* A new type will be created with the new dimension.
*
* @param dimX The new size of the allocation.
*/
public synchronized void resize(int dimX) {
if ((mType.getY() > 0)|| (mType.getZ() > 0) || mType.hasFaces() || mType.hasMipmaps()) {
throw new RSInvalidStateException("Resize only support for 1D allocations at this time.");
}
mRS.nAllocationResize1D(getID(mRS), dimX);
mRS.finish(); // Necessary because resize is fifoed and update is async.
int typeID = mRS.nAllocationGetType(getID(mRS));
mType = new Type(typeID, mRS);
mType.updateFromNative();
updateCacheInfo(mType);
}
/**
* Resize a 2D allocation. The contents of the allocation are
* preserved. If new elements are allocated objects are created
* with null contents and the new region is otherwise undefined.
*
* If the new region is smaller the references of any objects
* outside the new region will be released.
*
* A new type will be created with the new dimension.
*
* @hide
* @param dimX The new size of the allocation.
* @param dimY The new size of the allocation.
*/
public void resize(int dimX, int dimY) {
if ((mType.getZ() > 0) || mType.hasFaces() || mType.hasMipmaps()) {
throw new RSInvalidStateException(
"Resize only support for 2D allocations at this time.");
}
if (mType.getY() == 0) {
throw new RSInvalidStateException(
"Resize only support for 2D allocations at this time.");
}
mRS.nAllocationResize2D(getID(mRS), dimX, dimY);
mRS.finish(); // Necessary because resize is fifoed and update is async.
int typeID = mRS.nAllocationGetType(getID(mRS));
mType = new Type(typeID, mRS);
mType.updateFromNative();
updateCacheInfo(mType);
}
// creation
static BitmapFactory.Options mBitmapOptions = new BitmapFactory.Options();
static {
mBitmapOptions.inScaled = false;
}
/**
*
* @param type renderscript type describing data layout
* @param mips specifies desired mipmap behaviour for the
* allocation
* @param usage bit field specifying how the allocation is
* utilized
*/
static public Allocation createTyped(RenderScript rs, Type type, MipmapControl mips, int usage) {
rs.validate();
if (type.getID(rs) == 0) {
throw new RSInvalidStateException("Bad Type");
}
int id = rs.nAllocationCreateTyped(type.getID(rs), mips.mID, usage, 0);
if (id == 0) {
throw new RSRuntimeException("Allocation creation failed.");
}
return new Allocation(id, rs, type, usage);
}
/**
* Creates a renderscript allocation with the size specified by
* the type and no mipmaps generated by default
*
* @param rs Context to which the allocation will belong.
* @param type renderscript type describing data layout
* @param usage bit field specifying how the allocation is
* utilized
*
* @return allocation
*/
static public Allocation createTyped(RenderScript rs, Type type, int usage) {
return createTyped(rs, type, MipmapControl.MIPMAP_NONE, usage);
}
/**
* Creates a renderscript allocation for use by the script with
* the size specified by the type and no mipmaps generated by
* default
*
* @param rs Context to which the allocation will belong.
* @param type renderscript type describing data layout
*
* @return allocation
*/
static public Allocation createTyped(RenderScript rs, Type type) {
return createTyped(rs, type, MipmapControl.MIPMAP_NONE, USAGE_SCRIPT);
}
/**
* Creates a renderscript allocation with a specified number of
* given elements
*
* @param rs Context to which the allocation will belong.
* @param e describes what each element of an allocation is
* @param count specifies the number of element in the allocation
* @param usage bit field specifying how the allocation is
* utilized
*
* @return allocation
*/
static public Allocation createSized(RenderScript rs, Element e,
int count, int usage) {
rs.validate();
Type.Builder b = new Type.Builder(rs, e);
b.setX(count);
Type t = b.create();
int id = rs.nAllocationCreateTyped(t.getID(rs), MipmapControl.MIPMAP_NONE.mID, usage, 0);
if (id == 0) {
throw new RSRuntimeException("Allocation creation failed.");
}
return new Allocation(id, rs, t, usage);
}
/**
* Creates a renderscript allocation with a specified number of
* given elements
*
* @param rs Context to which the allocation will belong.
* @param e describes what each element of an allocation is
* @param count specifies the number of element in the allocation
*
* @return allocation
*/
static public Allocation createSized(RenderScript rs, Element e, int count) {
return createSized(rs, e, count, USAGE_SCRIPT);
}
static Element elementFromBitmap(RenderScript rs, Bitmap b) {
final Bitmap.Config bc = b.getConfig();
if (bc == Bitmap.Config.ALPHA_8) {
return Element.A_8(rs);
}
if (bc == Bitmap.Config.ARGB_4444) {
return Element.RGBA_4444(rs);
}
if (bc == Bitmap.Config.ARGB_8888) {
return Element.RGBA_8888(rs);
}
if (bc == Bitmap.Config.RGB_565) {
return Element.RGB_565(rs);
}
throw new RSInvalidStateException("Bad bitmap type: " + bc);
}
static Type typeFromBitmap(RenderScript rs, Bitmap b,
MipmapControl mip) {
Element e = elementFromBitmap(rs, b);
Type.Builder tb = new Type.Builder(rs, e);
tb.setX(b.getWidth());
tb.setY(b.getHeight());
tb.setMipmaps(mip == MipmapControl.MIPMAP_FULL);
return tb.create();
}
/**
* Creates a renderscript allocation from a bitmap
*
* @param rs Context to which the allocation will belong.
* @param b bitmap source for the allocation data
* @param mips specifies desired mipmap behaviour for the
* allocation
* @param usage bit field specifying how the allocation is
* utilized
*
* @return renderscript allocation containing bitmap data
*
*/
static public Allocation createFromBitmap(RenderScript rs, Bitmap b,
MipmapControl mips,
int usage) {
rs.validate();
Type t = typeFromBitmap(rs, b, mips);
int id = rs.nAllocationCreateFromBitmap(t.getID(rs), mips.mID, b, usage);
if (id == 0) {
throw new RSRuntimeException("Load failed.");
}
return new Allocation(id, rs, t, usage);
}
/**
*
*
* @hide
*
*/
public SurfaceTexture getSurfaceTexture() {
if ((mUsage & USAGE_IO_INPUT) == 0) {
throw new RSInvalidStateException("Allocation is not a surface texture.");
}
int id = mRS.nAllocationGetSurfaceTextureID(getID(mRS));
SurfaceTexture st = new SurfaceTexture(id);
mRS.nAllocationGetSurfaceTextureID2(getID(mRS), st);
return st;
}
/**
* For allocations used with io operations, returns the handle
* onto a raw buffer that is being managed by the screen
* compositor.
*
* @return Surface object associated with allocation
*
*/
public Surface getSurface() {
return new Surface(getSurfaceTexture());
}
/**
* Associate a surface for io output with this allocation
*
* @param sur Surface to associate with allocation
*/
public void setSurface(Surface sur) {
mRS.validate();
if ((mUsage & USAGE_IO_OUTPUT) == 0) {
throw new RSInvalidStateException("Allocation is not USAGE_IO_OUTPUT.");
}
mRS.nAllocationSetSurface(getID(mRS), sur);
}
/**
* @hide
*/
public void setSurfaceTexture(SurfaceTexture st) {
mRS.validate();
if ((mUsage & USAGE_IO_OUTPUT) == 0) {
throw new RSInvalidStateException("Allocation is not USAGE_IO_OUTPUT.");
}
Surface s = new Surface(st);
mRS.nAllocationSetSurface(getID(mRS), s);
}
/**
* Creates a non-mipmapped renderscript allocation to use as a
* graphics texture
*
* @param rs Context to which the allocation will belong.
* @param b bitmap source for the allocation data
*
* @return renderscript allocation containing bitmap data
*
*/
static public Allocation createFromBitmap(RenderScript rs, Bitmap b) {
return createFromBitmap(rs, b, MipmapControl.MIPMAP_NONE,
USAGE_GRAPHICS_TEXTURE);
}
/**
* Creates a cubemap allocation from a bitmap containing the
* horizontal list of cube faces. Each individual face must be
* the same size and power of 2
*
* @param rs Context to which the allocation will belong.
* @param b bitmap with cubemap faces layed out in the following
* format: right, left, top, bottom, front, back
* @param mips specifies desired mipmap behaviour for the cubemap
* @param usage bit field specifying how the cubemap is utilized
*
* @return allocation containing cubemap data
*
*/
static public Allocation createCubemapFromBitmap(RenderScript rs, Bitmap b,
MipmapControl mips,
int usage) {
rs.validate();
int height = b.getHeight();
int width = b.getWidth();
if (width % 6 != 0) {
throw new RSIllegalArgumentException("Cubemap height must be multiple of 6");
}
if (width / 6 != height) {
throw new RSIllegalArgumentException("Only square cube map faces supported");
}
boolean isPow2 = (height & (height - 1)) == 0;
if (!isPow2) {
throw new RSIllegalArgumentException("Only power of 2 cube faces supported");
}
Element e = elementFromBitmap(rs, b);
Type.Builder tb = new Type.Builder(rs, e);
tb.setX(height);
tb.setY(height);
tb.setFaces(true);
tb.setMipmaps(mips == MipmapControl.MIPMAP_FULL);
Type t = tb.create();
int id = rs.nAllocationCubeCreateFromBitmap(t.getID(rs), mips.mID, b, usage);
if(id == 0) {
throw new RSRuntimeException("Load failed for bitmap " + b + " element " + e);
}
return new Allocation(id, rs, t, usage);
}
/**
* Creates a non-mipmapped cubemap allocation for use as a
* graphics texture from a bitmap containing the horizontal list
* of cube faces. Each individual face must be the same size and
* power of 2
*
* @param rs Context to which the allocation will belong.
* @param b bitmap with cubemap faces layed out in the following
* format: right, left, top, bottom, front, back
*
* @return allocation containing cubemap data
*
*/
static public Allocation createCubemapFromBitmap(RenderScript rs,
Bitmap b) {
return createCubemapFromBitmap(rs, b, MipmapControl.MIPMAP_NONE,
USAGE_GRAPHICS_TEXTURE);
}
/**
* Creates a cubemap allocation from 6 bitmaps containing
* the cube faces. All the faces must be the same size and
* power of 2
*
* @param rs Context to which the allocation will belong.
* @param xpos cubemap face in the positive x direction
* @param xneg cubemap face in the negative x direction
* @param ypos cubemap face in the positive y direction
* @param yneg cubemap face in the negative y direction
* @param zpos cubemap face in the positive z direction
* @param zneg cubemap face in the negative z direction
* @param mips specifies desired mipmap behaviour for the cubemap
* @param usage bit field specifying how the cubemap is utilized
*
* @return allocation containing cubemap data
*
*/
static public Allocation createCubemapFromCubeFaces(RenderScript rs,
Bitmap xpos,
Bitmap xneg,
Bitmap ypos,
Bitmap yneg,
Bitmap zpos,
Bitmap zneg,
MipmapControl mips,
int usage) {
int height = xpos.getHeight();
if (xpos.getWidth() != height ||
xneg.getWidth() != height || xneg.getHeight() != height ||
ypos.getWidth() != height || ypos.getHeight() != height ||
yneg.getWidth() != height || yneg.getHeight() != height ||
zpos.getWidth() != height || zpos.getHeight() != height ||
zneg.getWidth() != height || zneg.getHeight() != height) {
throw new RSIllegalArgumentException("Only square cube map faces supported");
}
boolean isPow2 = (height & (height - 1)) == 0;
if (!isPow2) {
throw new RSIllegalArgumentException("Only power of 2 cube faces supported");
}
Element e = elementFromBitmap(rs, xpos);
Type.Builder tb = new Type.Builder(rs, e);
tb.setX(height);
tb.setY(height);
tb.setFaces(true);
tb.setMipmaps(mips == MipmapControl.MIPMAP_FULL);
Type t = tb.create();
Allocation cubemap = Allocation.createTyped(rs, t, mips, usage);
AllocationAdapter adapter = AllocationAdapter.create2D(rs, cubemap);
adapter.setFace(Type.CubemapFace.POSITIVE_X);
adapter.copyFrom(xpos);
adapter.setFace(Type.CubemapFace.NEGATIVE_X);
adapter.copyFrom(xneg);
adapter.setFace(Type.CubemapFace.POSITIVE_Y);
adapter.copyFrom(ypos);
adapter.setFace(Type.CubemapFace.NEGATIVE_Y);
adapter.copyFrom(yneg);
adapter.setFace(Type.CubemapFace.POSITIVE_Z);
adapter.copyFrom(zpos);
adapter.setFace(Type.CubemapFace.NEGATIVE_Z);
adapter.copyFrom(zneg);
return cubemap;
}
/**
* Creates a non-mipmapped cubemap allocation for use as a
* graphics texture from 6 bitmaps containing
* the cube faces. All the faces must be the same size and
* power of 2
*
* @param rs Context to which the allocation will belong.
* @param xpos cubemap face in the positive x direction
* @param xneg cubemap face in the negative x direction
* @param ypos cubemap face in the positive y direction
* @param yneg cubemap face in the negative y direction
* @param zpos cubemap face in the positive z direction
* @param zneg cubemap face in the negative z direction
*
* @return allocation containing cubemap data
*
*/
static public Allocation createCubemapFromCubeFaces(RenderScript rs,
Bitmap xpos,
Bitmap xneg,
Bitmap ypos,
Bitmap yneg,
Bitmap zpos,
Bitmap zneg) {
return createCubemapFromCubeFaces(rs, xpos, xneg, ypos, yneg,
zpos, zneg, MipmapControl.MIPMAP_NONE,
USAGE_GRAPHICS_TEXTURE);
}
/**
* Creates a renderscript allocation from the bitmap referenced
* by resource id
*
* @param rs Context to which the allocation will belong.
* @param res application resources
* @param id resource id to load the data from
* @param mips specifies desired mipmap behaviour for the
* allocation
* @param usage bit field specifying how the allocation is
* utilized
*
* @return renderscript allocation containing resource data
*
*/
static public Allocation createFromBitmapResource(RenderScript rs,
Resources res,
int id,
MipmapControl mips,
int usage) {
rs.validate();
Bitmap b = BitmapFactory.decodeResource(res, id);
Allocation alloc = createFromBitmap(rs, b, mips, usage);
b.recycle();
return alloc;
}
/**
* Creates a non-mipmapped renderscript allocation to use as a
* graphics texture from the bitmap referenced by resource id
*
* @param rs Context to which the allocation will belong.
* @param res application resources
* @param id resource id to load the data from
*
* @return renderscript allocation containing resource data
*
*/
static public Allocation createFromBitmapResource(RenderScript rs,
Resources res,
int id) {
return createFromBitmapResource(rs, res, id,
MipmapControl.MIPMAP_NONE,
USAGE_GRAPHICS_TEXTURE);
}
/**
* Creates a renderscript allocation containing string data
* encoded in UTF-8 format
*
* @param rs Context to which the allocation will belong.
* @param str string to create the allocation from
* @param usage bit field specifying how the allocaiton is
* utilized
*
*/
static public Allocation createFromString(RenderScript rs,
String str,
int usage) {
rs.validate();
byte[] allocArray = null;
try {
allocArray = str.getBytes("UTF-8");
Allocation alloc = Allocation.createSized(rs, Element.U8(rs), allocArray.length, usage);
alloc.copyFrom(allocArray);
return alloc;
}
catch (Exception e) {
throw new RSRuntimeException("Could not convert string to utf-8.");
}
}
}