/* * Copyright (C) 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. */ package android.support.v8.renderscript; import java.lang.reflect.Field; import android.util.Log; /** *

An Element represents one item within an {@link * android.support.v8.renderscript.Allocation}. An Element is roughly * equivalent to a C type in a RenderScript kernel. Elements may be basic or * complex. Some basic elements are

A complex element is * roughly equivalent to a C struct and contains a number of basic or complex * Elements. From Java code, a complex element contains a list of sub-elements * and names that represents a particular data structure. Structs used in RS * scripts are available to Java code by using the * {@code ScriptField_structname} class that is reflected from a particular * script.

* *

Basic Elements are comprised of a {@link * android.support.v8.renderscript.Element.DataType} and a {@link * android.support.v8.renderscript.Element.DataKind}. The DataType encodes C * type information of an Element, while the DataKind encodes how that Element * should be interpreted by a {@link android.support.v8.renderscript.Sampler}. * Note that {@link android.support.v8.renderscript.Allocation} objects with * DataKind {@link android.support.v8.renderscript.Element.DataKind#USER} cannot * be used as input for a {@link android.support.v8.renderscript.Sampler}. In * general, {@link android.support.v8.renderscript.Allocation} objects that are * intended for use with a {@link android.support.v8.renderscript.Sampler} * should use bitmap-derived Elements such as * {@link android.support.v8.renderscript.Element#RGBA_8888} or {@link * android.support.v8.renderscript#Element.A_8}.

* *
*

Developer Guides

*

For more information about creating an application that uses RenderScript, * read the * RenderScript * developer guide.

*
**/ public class Element extends BaseObj { int mSize; Element[] mElements; String[] mElementNames; int[] mArraySizes; int[] mOffsetInBytes; int[] mVisibleElementMap; DataType mType; DataKind mKind; boolean mNormalized; int mVectorSize; private void updateVisibleSubElements() { if (mElements == null) { return; } int noPaddingFieldCount = 0; int fieldCount = mElementNames.length; // Find out how many elements are not padding for (int ct = 0; ct < fieldCount; ct ++) { if (mElementNames[ct].charAt(0) != '#') { noPaddingFieldCount ++; } } mVisibleElementMap = new int[noPaddingFieldCount]; // Make a map that points us at non-padding elements for (int ct = 0, ctNoPadding = 0; ct < fieldCount; ct ++) { if (mElementNames[ct].charAt(0) != '#') { mVisibleElementMap[ctNoPadding ++] = ct; } } } /** * @return element size in bytes */ public int getBytesSize() { return mSize; } /** * Returns the number of vector components. 2 for float2, 4 for * float4, etc. * @return element vector size */ public int getVectorSize() { return mVectorSize; } /** * DataType represents the basic type information for a basic element. The * naming convention follows. For numeric types it is FLOAT, * SIGNED, or UNSIGNED followed by the _BITS where BITS is the * size of the data. BOOLEAN is a true / false (1,0) * represented in an 8 bit container. The UNSIGNED variants * with multiple bit definitions are for packed graphical data * formats and represent vectors with per vector member sizes * which are treated as a single unit for packing and alignment * purposes. * * MATRIX the three matrix types contain FLOAT_32 elements and are treated * as 32 bits for alignment purposes. * * RS_* objects. 32 bit opaque handles. */ public enum DataType { NONE (0, 0), //FLOAT_16 (1, 2), FLOAT_32 (2, 4), FLOAT_64 (3, 8), SIGNED_8 (4, 1), SIGNED_16 (5, 2), SIGNED_32 (6, 4), SIGNED_64 (7, 8), UNSIGNED_8 (8, 1), UNSIGNED_16 (9, 2), UNSIGNED_32 (10, 4), UNSIGNED_64 (11, 8), BOOLEAN(12, 1), UNSIGNED_5_6_5 (13, 2), UNSIGNED_5_5_5_1 (14, 2), UNSIGNED_4_4_4_4 (15, 2), MATRIX_4X4 (16, 64), MATRIX_3X3 (17, 36), MATRIX_2X2 (18, 16), RS_ELEMENT (1000, 4), RS_TYPE (1001, 4), RS_ALLOCATION (1002, 4), RS_SAMPLER (1003, 4), RS_SCRIPT (1004, 4); int mID; int mSize; DataType(int id, int size) { mID = id; mSize = size; } } /** * The special interpretation of the data if required. This is primarly * useful for graphical data. USER indicates no special interpretation is * expected. PIXEL is used in conjunction with the standard data types for * representing texture formats. */ public enum DataKind { USER (0), PIXEL_L (7), PIXEL_A (8), PIXEL_LA (9), PIXEL_RGB (10), PIXEL_RGBA (11), PIXEL_DEPTH (12), PIXEL_YUV(13); int mID; DataKind(int id) { mID = id; } } /** * Return if a element is too complex for use as a data source for a Mesh or * a Program. * * @return boolean */ public boolean isComplex() { if (mElements == null) { return false; } for (int ct=0; ct < mElements.length; ct++) { if (mElements[ct].mElements != null) { return true; } } return false; } /** * Elements could be simple, such as an int or a float, or a * structure with multiple sub elements, such as a collection of * floats, float2, float4. This function returns zero for simple * elements or the number of sub-elements otherwise. * @return number of sub-elements in this element */ public int getSubElementCount() { if (mVisibleElementMap == null) { return 0; } return mVisibleElementMap.length; } /** * For complex elements, this function will return the * sub-element at index * @param index index of the sub-element to return * @return sub-element in this element at given index */ public Element getSubElement(int index) { if (mVisibleElementMap == null) { throw new RSIllegalArgumentException("Element contains no sub-elements"); } if (index < 0 || index >= mVisibleElementMap.length) { throw new RSIllegalArgumentException("Illegal sub-element index"); } return mElements[mVisibleElementMap[index]]; } /** * For complex elements, this function will return the * sub-element name at index * @param index index of the sub-element * @return sub-element in this element at given index */ public String getSubElementName(int index) { if (mVisibleElementMap == null) { throw new RSIllegalArgumentException("Element contains no sub-elements"); } if (index < 0 || index >= mVisibleElementMap.length) { throw new RSIllegalArgumentException("Illegal sub-element index"); } return mElementNames[mVisibleElementMap[index]]; } /** * For complex elements, some sub-elements could be statically * sized arrays. This function will return the array size for * sub-element at index * @param index index of the sub-element * @return array size of sub-element in this element at given index */ public int getSubElementArraySize(int index) { if (mVisibleElementMap == null) { throw new RSIllegalArgumentException("Element contains no sub-elements"); } if (index < 0 || index >= mVisibleElementMap.length) { throw new RSIllegalArgumentException("Illegal sub-element index"); } return mArraySizes[mVisibleElementMap[index]]; } /** * This function specifies the location of a sub-element within * the element * @param index index of the sub-element * @return offset in bytes of sub-element in this element at given index */ public int getSubElementOffsetBytes(int index) { if (mVisibleElementMap == null) { throw new RSIllegalArgumentException("Element contains no sub-elements"); } if (index < 0 || index >= mVisibleElementMap.length) { throw new RSIllegalArgumentException("Illegal sub-element index"); } return mOffsetInBytes[mVisibleElementMap[index]]; } /** * @return element data type */ public DataType getDataType() { return mType; } /** * @return element data kind */ public DataKind getDataKind() { return mKind; } /** * Utility function for returning an Element containing a single Boolean. * * @param rs Context to which the element will belong. * * @return Element */ public static Element BOOLEAN(RenderScript rs) { if(rs.mElement_BOOLEAN == null) { rs.mElement_BOOLEAN = createUser(rs, DataType.BOOLEAN); } return rs.mElement_BOOLEAN; } /** * Utility function for returning an Element containing a single UNSIGNED_8. * * @param rs Context to which the element will belong. * * @return Element */ public static Element U8(RenderScript rs) { if(rs.mElement_U8 == null) { rs.mElement_U8 = createUser(rs, DataType.UNSIGNED_8); } return rs.mElement_U8; } /** * Utility function for returning an Element containing a single SIGNED_8. * * @param rs Context to which the element will belong. * * @return Element */ public static Element I8(RenderScript rs) { if(rs.mElement_I8 == null) { rs.mElement_I8 = createUser(rs, DataType.SIGNED_8); } return rs.mElement_I8; } public static Element U16(RenderScript rs) { if(rs.mElement_U16 == null) { rs.mElement_U16 = createUser(rs, DataType.UNSIGNED_16); } return rs.mElement_U16; } public static Element I16(RenderScript rs) { if(rs.mElement_I16 == null) { rs.mElement_I16 = createUser(rs, DataType.SIGNED_16); } return rs.mElement_I16; } public static Element U32(RenderScript rs) { if(rs.mElement_U32 == null) { rs.mElement_U32 = createUser(rs, DataType.UNSIGNED_32); } return rs.mElement_U32; } public static Element I32(RenderScript rs) { if(rs.mElement_I32 == null) { rs.mElement_I32 = createUser(rs, DataType.SIGNED_32); } return rs.mElement_I32; } public static Element U64(RenderScript rs) { if(rs.mElement_U64 == null) { rs.mElement_U64 = createUser(rs, DataType.UNSIGNED_64); } return rs.mElement_U64; } public static Element I64(RenderScript rs) { if(rs.mElement_I64 == null) { rs.mElement_I64 = createUser(rs, DataType.SIGNED_64); } return rs.mElement_I64; } public static Element F32(RenderScript rs) { if(rs.mElement_F32 == null) { rs.mElement_F32 = createUser(rs, DataType.FLOAT_32); } return rs.mElement_F32; } public static Element F64(RenderScript rs) { if(rs.mElement_F64 == null) { rs.mElement_F64 = createUser(rs, DataType.FLOAT_64); } return rs.mElement_F64; } public static Element ELEMENT(RenderScript rs) { if(rs.mElement_ELEMENT == null) { rs.mElement_ELEMENT = createUser(rs, DataType.RS_ELEMENT); } return rs.mElement_ELEMENT; } public static Element TYPE(RenderScript rs) { if(rs.mElement_TYPE == null) { rs.mElement_TYPE = createUser(rs, DataType.RS_TYPE); } return rs.mElement_TYPE; } public static Element ALLOCATION(RenderScript rs) { if(rs.mElement_ALLOCATION == null) { rs.mElement_ALLOCATION = createUser(rs, DataType.RS_ALLOCATION); } return rs.mElement_ALLOCATION; } public static Element SAMPLER(RenderScript rs) { if(rs.mElement_SAMPLER == null) { rs.mElement_SAMPLER = createUser(rs, DataType.RS_SAMPLER); } return rs.mElement_SAMPLER; } public static Element SCRIPT(RenderScript rs) { if(rs.mElement_SCRIPT == null) { rs.mElement_SCRIPT = createUser(rs, DataType.RS_SCRIPT); } return rs.mElement_SCRIPT; } public static Element A_8(RenderScript rs) { if(rs.mElement_A_8 == null) { rs.mElement_A_8 = createPixel(rs, DataType.UNSIGNED_8, DataKind.PIXEL_A); } return rs.mElement_A_8; } public static Element RGB_565(RenderScript rs) { if(rs.mElement_RGB_565 == null) { rs.mElement_RGB_565 = createPixel(rs, DataType.UNSIGNED_5_6_5, DataKind.PIXEL_RGB); } return rs.mElement_RGB_565; } public static Element RGB_888(RenderScript rs) { if(rs.mElement_RGB_888 == null) { rs.mElement_RGB_888 = createPixel(rs, DataType.UNSIGNED_8, DataKind.PIXEL_RGB); } return rs.mElement_RGB_888; } public static Element RGBA_5551(RenderScript rs) { if(rs.mElement_RGBA_5551 == null) { rs.mElement_RGBA_5551 = createPixel(rs, DataType.UNSIGNED_5_5_5_1, DataKind.PIXEL_RGBA); } return rs.mElement_RGBA_5551; } public static Element RGBA_4444(RenderScript rs) { if(rs.mElement_RGBA_4444 == null) { rs.mElement_RGBA_4444 = createPixel(rs, DataType.UNSIGNED_4_4_4_4, DataKind.PIXEL_RGBA); } return rs.mElement_RGBA_4444; } public static Element RGBA_8888(RenderScript rs) { if(rs.mElement_RGBA_8888 == null) { rs.mElement_RGBA_8888 = createPixel(rs, DataType.UNSIGNED_8, DataKind.PIXEL_RGBA); } return rs.mElement_RGBA_8888; } public static Element F32_2(RenderScript rs) { if(rs.mElement_FLOAT_2 == null) { rs.mElement_FLOAT_2 = createVector(rs, DataType.FLOAT_32, 2); } return rs.mElement_FLOAT_2; } public static Element F32_3(RenderScript rs) { if(rs.mElement_FLOAT_3 == null) { rs.mElement_FLOAT_3 = createVector(rs, DataType.FLOAT_32, 3); } return rs.mElement_FLOAT_3; } public static Element F32_4(RenderScript rs) { if(rs.mElement_FLOAT_4 == null) { rs.mElement_FLOAT_4 = createVector(rs, DataType.FLOAT_32, 4); } return rs.mElement_FLOAT_4; } public static Element F64_2(RenderScript rs) { if(rs.mElement_DOUBLE_2 == null) { rs.mElement_DOUBLE_2 = createVector(rs, DataType.FLOAT_64, 2); } return rs.mElement_DOUBLE_2; } public static Element F64_3(RenderScript rs) { if(rs.mElement_DOUBLE_3 == null) { rs.mElement_DOUBLE_3 = createVector(rs, DataType.FLOAT_64, 3); } return rs.mElement_DOUBLE_3; } public static Element F64_4(RenderScript rs) { if(rs.mElement_DOUBLE_4 == null) { rs.mElement_DOUBLE_4 = createVector(rs, DataType.FLOAT_64, 4); } return rs.mElement_DOUBLE_4; } public static Element U8_2(RenderScript rs) { if(rs.mElement_UCHAR_2 == null) { rs.mElement_UCHAR_2 = createVector(rs, DataType.UNSIGNED_8, 2); } return rs.mElement_UCHAR_2; } public static Element U8_3(RenderScript rs) { if(rs.mElement_UCHAR_3 == null) { rs.mElement_UCHAR_3 = createVector(rs, DataType.UNSIGNED_8, 3); } return rs.mElement_UCHAR_3; } public static Element U8_4(RenderScript rs) { if(rs.mElement_UCHAR_4 == null) { rs.mElement_UCHAR_4 = createVector(rs, DataType.UNSIGNED_8, 4); } return rs.mElement_UCHAR_4; } public static Element I8_2(RenderScript rs) { if(rs.mElement_CHAR_2 == null) { rs.mElement_CHAR_2 = createVector(rs, DataType.SIGNED_8, 2); } return rs.mElement_CHAR_2; } public static Element I8_3(RenderScript rs) { if(rs.mElement_CHAR_3 == null) { rs.mElement_CHAR_3 = createVector(rs, DataType.SIGNED_8, 3); } return rs.mElement_CHAR_3; } public static Element I8_4(RenderScript rs) { if(rs.mElement_CHAR_4 == null) { rs.mElement_CHAR_4 = createVector(rs, DataType.SIGNED_8, 4); } return rs.mElement_CHAR_4; } public static Element U16_2(RenderScript rs) { if(rs.mElement_USHORT_2 == null) { rs.mElement_USHORT_2 = createVector(rs, DataType.UNSIGNED_16, 2); } return rs.mElement_USHORT_2; } public static Element U16_3(RenderScript rs) { if(rs.mElement_USHORT_3 == null) { rs.mElement_USHORT_3 = createVector(rs, DataType.UNSIGNED_16, 3); } return rs.mElement_USHORT_3; } public static Element U16_4(RenderScript rs) { if(rs.mElement_USHORT_4 == null) { rs.mElement_USHORT_4 = createVector(rs, DataType.UNSIGNED_16, 4); } return rs.mElement_USHORT_4; } public static Element I16_2(RenderScript rs) { if(rs.mElement_SHORT_2 == null) { rs.mElement_SHORT_2 = createVector(rs, DataType.SIGNED_16, 2); } return rs.mElement_SHORT_2; } public static Element I16_3(RenderScript rs) { if(rs.mElement_SHORT_3 == null) { rs.mElement_SHORT_3 = createVector(rs, DataType.SIGNED_16, 3); } return rs.mElement_SHORT_3; } public static Element I16_4(RenderScript rs) { if(rs.mElement_SHORT_4 == null) { rs.mElement_SHORT_4 = createVector(rs, DataType.SIGNED_16, 4); } return rs.mElement_SHORT_4; } public static Element U32_2(RenderScript rs) { if(rs.mElement_UINT_2 == null) { rs.mElement_UINT_2 = createVector(rs, DataType.UNSIGNED_32, 2); } return rs.mElement_UINT_2; } public static Element U32_3(RenderScript rs) { if(rs.mElement_UINT_3 == null) { rs.mElement_UINT_3 = createVector(rs, DataType.UNSIGNED_32, 3); } return rs.mElement_UINT_3; } public static Element U32_4(RenderScript rs) { if(rs.mElement_UINT_4 == null) { rs.mElement_UINT_4 = createVector(rs, DataType.UNSIGNED_32, 4); } return rs.mElement_UINT_4; } public static Element I32_2(RenderScript rs) { if(rs.mElement_INT_2 == null) { rs.mElement_INT_2 = createVector(rs, DataType.SIGNED_32, 2); } return rs.mElement_INT_2; } public static Element I32_3(RenderScript rs) { if(rs.mElement_INT_3 == null) { rs.mElement_INT_3 = createVector(rs, DataType.SIGNED_32, 3); } return rs.mElement_INT_3; } public static Element I32_4(RenderScript rs) { if(rs.mElement_INT_4 == null) { rs.mElement_INT_4 = createVector(rs, DataType.SIGNED_32, 4); } return rs.mElement_INT_4; } public static Element U64_2(RenderScript rs) { if(rs.mElement_ULONG_2 == null) { rs.mElement_ULONG_2 = createVector(rs, DataType.UNSIGNED_64, 2); } return rs.mElement_ULONG_2; } public static Element U64_3(RenderScript rs) { if(rs.mElement_ULONG_3 == null) { rs.mElement_ULONG_3 = createVector(rs, DataType.UNSIGNED_64, 3); } return rs.mElement_ULONG_3; } public static Element U64_4(RenderScript rs) { if(rs.mElement_ULONG_4 == null) { rs.mElement_ULONG_4 = createVector(rs, DataType.UNSIGNED_64, 4); } return rs.mElement_ULONG_4; } public static Element I64_2(RenderScript rs) { if(rs.mElement_LONG_2 == null) { rs.mElement_LONG_2 = createVector(rs, DataType.SIGNED_64, 2); } return rs.mElement_LONG_2; } public static Element I64_3(RenderScript rs) { if(rs.mElement_LONG_3 == null) { rs.mElement_LONG_3 = createVector(rs, DataType.SIGNED_64, 3); } return rs.mElement_LONG_3; } public static Element I64_4(RenderScript rs) { if(rs.mElement_LONG_4 == null) { rs.mElement_LONG_4 = createVector(rs, DataType.SIGNED_64, 4); } return rs.mElement_LONG_4; } public static Element MATRIX_4X4(RenderScript rs) { if(rs.mElement_MATRIX_4X4 == null) { rs.mElement_MATRIX_4X4 = createUser(rs, DataType.MATRIX_4X4); } return rs.mElement_MATRIX_4X4; } public static Element MATRIX_3X3(RenderScript rs) { if(rs.mElement_MATRIX_3X3 == null) { rs.mElement_MATRIX_3X3 = createUser(rs, DataType.MATRIX_3X3); } return rs.mElement_MATRIX_3X3; } public static Element MATRIX_2X2(RenderScript rs) { if(rs.mElement_MATRIX_2X2 == null) { rs.mElement_MATRIX_2X2 = createUser(rs, DataType.MATRIX_2X2); } return rs.mElement_MATRIX_2X2; } Element(int id, RenderScript rs, Element[] e, String[] n, int[] as) { super(id, rs); mSize = 0; mVectorSize = 1; mElements = e; mElementNames = n; mArraySizes = as; mType = DataType.NONE; mKind = DataKind.USER; mOffsetInBytes = new int[mElements.length]; for (int ct = 0; ct < mElements.length; ct++ ) { mOffsetInBytes[ct] = mSize; mSize += mElements[ct].mSize * mArraySizes[ct]; } updateVisibleSubElements(); } Element(int id, RenderScript rs, DataType dt, DataKind dk, boolean norm, int size) { super(id, rs); if ((dt != DataType.UNSIGNED_5_6_5) && (dt != DataType.UNSIGNED_4_4_4_4) && (dt != DataType.UNSIGNED_5_5_5_1)) { if (size == 3) { mSize = dt.mSize * 4; } else { mSize = dt.mSize * size; } } else { mSize = dt.mSize; } mType = dt; mKind = dk; mNormalized = norm; mVectorSize = size; } Element(int id, RenderScript rs) { super(id, rs); } /** * Create a custom Element of the specified DataType. The DataKind will be * set to USER and the vector size to 1 indicating non-vector. * * @param rs The context associated with the new Element. * @param dt The DataType for the new element. * @return Element */ static Element createUser(RenderScript rs, DataType dt) { if (rs.isNative) { RenderScriptThunker rst = (RenderScriptThunker)rs; return ElementThunker.create(rst, dt); } DataKind dk = DataKind.USER; boolean norm = false; int vecSize = 1; int id = rs.nElementCreate(dt.mID, dk.mID, norm, vecSize); return new Element(id, rs, dt, dk, norm, vecSize); } /** * Create a custom vector element of the specified DataType and vector size. * DataKind will be set to USER. Only primitive types (FLOAT_32, FLOAT_64, * SIGNED_8, SIGNED_16, SIGNED_32, SIGNED_64, UNSIGNED_8, UNSIGNED_16, * UNSIGNED_32, UNSIGNED_64, BOOLEAN) are supported. * * @param rs The context associated with the new Element. * @param dt The DataType for the new Element. * @param size Vector size for the new Element. Range 2-4 inclusive * supported. * * @return Element */ public static Element createVector(RenderScript rs, DataType dt, int size) { if (rs.isNative) { RenderScriptThunker rst = (RenderScriptThunker)rs; return ElementThunker.createVector(rst, dt, size); } if (size < 2 || size > 4) { throw new RSIllegalArgumentException("Vector size out of range 2-4."); } switch (dt) { // Support only primitive integer/float/boolean types as vectors. case FLOAT_32: case FLOAT_64: case SIGNED_8: case SIGNED_16: case SIGNED_32: case SIGNED_64: case UNSIGNED_8: case UNSIGNED_16: case UNSIGNED_32: case UNSIGNED_64: case BOOLEAN: { DataKind dk = DataKind.USER; boolean norm = false; int id = rs.nElementCreate(dt.mID, dk.mID, norm, size); return new Element(id, rs, dt, dk, norm, size); } default: { throw new RSIllegalArgumentException("Cannot create vector of " + "non-primitive type."); } } } /** * Create a new pixel Element type. A matching DataType and DataKind must * be provided. The DataType and DataKind must contain the same number of * components. Vector size will be set to 1. * * @param rs The context associated with the new Element. * @param dt The DataType for the new element. * @param dk The DataKind to specify the mapping of each component in the * DataType. * * @return Element */ public static Element createPixel(RenderScript rs, DataType dt, DataKind dk) { if (rs.isNative) { RenderScriptThunker rst = (RenderScriptThunker)rs; return ElementThunker.createPixel(rst, dt, dk); } if (!(dk == DataKind.PIXEL_L || dk == DataKind.PIXEL_A || dk == DataKind.PIXEL_LA || dk == DataKind.PIXEL_RGB || dk == DataKind.PIXEL_RGBA || dk == DataKind.PIXEL_DEPTH || dk == DataKind.PIXEL_YUV)) { throw new RSIllegalArgumentException("Unsupported DataKind"); } if (!(dt == DataType.UNSIGNED_8 || dt == DataType.UNSIGNED_16 || dt == DataType.UNSIGNED_5_6_5 || dt == DataType.UNSIGNED_4_4_4_4 || dt == DataType.UNSIGNED_5_5_5_1)) { throw new RSIllegalArgumentException("Unsupported DataType"); } if (dt == DataType.UNSIGNED_5_6_5 && dk != DataKind.PIXEL_RGB) { throw new RSIllegalArgumentException("Bad kind and type combo"); } if (dt == DataType.UNSIGNED_5_5_5_1 && dk != DataKind.PIXEL_RGBA) { throw new RSIllegalArgumentException("Bad kind and type combo"); } if (dt == DataType.UNSIGNED_4_4_4_4 && dk != DataKind.PIXEL_RGBA) { throw new RSIllegalArgumentException("Bad kind and type combo"); } if (dt == DataType.UNSIGNED_16 && dk != DataKind.PIXEL_DEPTH) { throw new RSIllegalArgumentException("Bad kind and type combo"); } int size = 1; switch (dk) { case PIXEL_LA: size = 2; break; case PIXEL_RGB: size = 3; break; case PIXEL_RGBA: size = 4; break; } boolean norm = true; int id = rs.nElementCreate(dt.mID, dk.mID, norm, size); return new Element(id, rs, dt, dk, norm, size); } /** * Check if the current Element is compatible with another Element. * Primitive Elements are compatible if they share the same underlying * size and type (i.e. U8 is compatible with A_8). User-defined Elements * must be equal in order to be compatible. This requires strict name * equivalence for all sub-Elements (in addition to structural equivalence). * * @param e The Element to check compatibility with. * * @return boolean true if the Elements are compatible, otherwise false. */ public boolean isCompatible(Element e) { // Try strict BaseObj equality to start with. if (this.equals(e)) { return true; } // Ignore mKind because it is allowed to be different (user vs. pixel). // We also ignore mNormalized because it can be different. The mType // field must not be NONE since we require name equivalence for // all user-created Elements. return ((mSize == e.mSize) && (mType != DataType.NONE) && (mType == e.mType) && (mVectorSize == e.mVectorSize)); } /** * Builder class for producing complex elements with matching field and name * pairs. The builder starts empty. The order in which elements are added * is retained for the layout in memory. * */ public static class Builder { ElementThunker.BuilderThunker mT; RenderScript mRS; Element[] mElements; String[] mElementNames; int[] mArraySizes; int mCount; int mSkipPadding; /** * Create a builder object. * * @param rs */ public Builder(RenderScript rs) { if (rs.isNative) { RenderScriptThunker rst = (RenderScriptThunker)rs; mT = new ElementThunker.BuilderThunker(rs); } mRS = rs; mCount = 0; mElements = new Element[8]; mElementNames = new String[8]; mArraySizes = new int[8]; } /** * Add an array of elements to this element. * * @param element * @param name * @param arraySize */ public Builder add(Element element, String name, int arraySize) { if (mT != null) { mT.add(element, name, arraySize); return this; } if (arraySize < 1) { throw new RSIllegalArgumentException("Array size cannot be less than 1."); } // Skip padding fields after a vector 3 type. if (mSkipPadding != 0) { if (name.startsWith("#padding_")) { mSkipPadding = 0; return this; } } if (element.mVectorSize == 3) { mSkipPadding = 1; } else { mSkipPadding = 0; } if(mCount == mElements.length) { Element[] e = new Element[mCount + 8]; String[] s = new String[mCount + 8]; int[] as = new int[mCount + 8]; System.arraycopy(mElements, 0, e, 0, mCount); System.arraycopy(mElementNames, 0, s, 0, mCount); System.arraycopy(mArraySizes, 0, as, 0, mCount); mElements = e; mElementNames = s; mArraySizes = as; } mElements[mCount] = element; mElementNames[mCount] = name; mArraySizes[mCount] = arraySize; mCount++; return this; } /** * Add a single element to this Element. * * @param element * @param name */ public Builder add(Element element, String name) { return add(element, name, 1); } /** * Create the element from this builder. * * * @return Element */ public Element create() { if (mT != null) { return mT.create(mRS); } mRS.validate(); Element[] ein = new Element[mCount]; String[] sin = new String[mCount]; int[] asin = new int[mCount]; java.lang.System.arraycopy(mElements, 0, ein, 0, mCount); java.lang.System.arraycopy(mElementNames, 0, sin, 0, mCount); java.lang.System.arraycopy(mArraySizes, 0, asin, 0, mCount); int[] ids = new int[ein.length]; for (int ct = 0; ct < ein.length; ct++ ) { ids[ct] = ein[ct].getID(mRS); } int id = mRS.nElementCreate2(ids, sin, asin); return new Element(id, mRS, ein, sin, asin); } } }