services/surfaceflinger/Transform.cpp - platform/frameworks/base - Gitiles

 /*
  * Copyright (C) 2007 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.
  */

 #include <math.h>

 #include <cutils/compiler.h>
 #include <utils/String8.h>
 #include <ui/Region.h>

 #include "Transform.h"

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

 namespace android {

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

 template <typename T> inline T min(T a, T b) {
     return a<b ? a : b;
 }
 template <typename T> inline T min(T a, T b, T c) {
     return min(a, min(b, c));
 }
 template <typename T> inline T min(T a, T b, T c, T d) {
     return min(a, b, min(c, d));
 }

 template <typename T> inline T max(T a, T b) {
     return a>b ? a : b;
 }
 template <typename T> inline T max(T a, T b, T c) {
     return max(a, max(b, c));
 }
 template <typename T> inline T max(T a, T b, T c, T d) {
     return max(a, b, max(c, d));
 }

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

 Transform::Transform() {
     reset();
 }

 Transform::Transform(const Transform&  other)
     : mMatrix(other.mMatrix), mType(other.mType) {
 }

 Transform::Transform(uint32_t orientation) {
     set(orientation, 0, 0);
 }

 Transform::~Transform() {
 }

 static const float EPSILON = 0.0f;

 bool Transform::isZero(float f) {
     return fabs(f) <= EPSILON;
 }

 bool Transform::absIsOne(float f) {
     return isZero(fabs(f) - 1.0f);
 }

 Transform Transform::operator * (const Transform& rhs) const
 {
     if (CC_LIKELY(mType == IDENTITY))
         return rhs;

     Transform r(*this);
     if (rhs.mType == IDENTITY)
         return r;

     // TODO: we could use mType to optimize the matrix multiply
     const mat33& A(mMatrix);
     const mat33& B(rhs.mMatrix);
           mat33& D(r.mMatrix);
     for (int i=0 ; i<3 ; i++) {
         const float v0 = A[0][i];
         const float v1 = A[1][i];
         const float v2 = A[2][i];
         D[0][i] = v0*B[0][0] + v1*B[0][1] + v2*B[0][2];
         D[1][i] = v0*B[1][0] + v1*B[1][1] + v2*B[1][2];
         D[2][i] = v0*B[2][0] + v1*B[2][1] + v2*B[2][2];
     }
     r.mType |= rhs.mType;

     // TODO: we could recompute this value from r and rhs
     r.mType &= 0xFF;
     r.mType |= UNKNOWN_TYPE;
     return r;
 }

 float const* Transform::operator [] (int i) const {
     return mMatrix[i].v;
 }

 bool Transform::transformed() const {
     return type() > TRANSLATE;
 }

 int Transform::tx() const {
     return floorf(mMatrix[2][0] + 0.5f);
 }

 int Transform::ty() const {
     return floorf(mMatrix[2][1] + 0.5f);
 }

 void Transform::reset() {
     mType = IDENTITY;
     for(int i=0 ; i<3 ; i++) {
         vec3& v(mMatrix[i]);
         for (int j=0 ; j<3 ; j++)
             v[j] = ((i==j) ? 1.0f : 0.0f);
     }
 }

 void Transform::set(float tx, float ty)
 {
     mMatrix[2][0] = tx;
     mMatrix[2][1] = ty;
     mMatrix[2][2] = 1.0f;

     if (isZero(tx) && isZero(ty)) {
         mType &= ~TRANSLATE;
     } else {
         mType |= TRANSLATE;
     }
 }

 void Transform::set(float a, float b, float c, float d)
 {
     mat33& M(mMatrix);
     M[0][0] = a;    M[1][0] = b;
     M[0][1] = c;    M[1][1] = d;
     M[0][2] = 0;    M[1][2] = 0;
     mType = UNKNOWN_TYPE;
 }

 status_t Transform::set(uint32_t flags, float w, float h)
 {
     if (flags & ROT_INVALID) {
         // that's not allowed!
         reset();
         return BAD_VALUE;
     }

     mType = flags << 8;
     float sx = (flags & FLIP_H) ? -1 : 1;
     float sy = (flags & FLIP_V) ? -1 : 1;
     float a=0, b=0, c=0, d=0, x=0, y=0;
     int xmask = 0;

     // computation of x,y
     // x y
     // 0 0  0
     // w 0  ROT90
     // w h  FLIPH|FLIPV
     // 0 h  FLIPH|FLIPV|ROT90

     if (flags & ROT_90) {
         mType |= ROTATE;
         b = -sy;
         c = sx;
         xmask = 1;
     } else {
         a = sx;
         d = sy;
     }

     if (flags & FLIP_H) {
         mType ^= SCALE;
         xmask ^= 1;
     }

     if (flags & FLIP_V) {
         mType ^= SCALE;
         y = h;
     }

     if ((flags & ROT_180) == ROT_180) {
         mType |= ROTATE;
     }

     if (xmask) {
         x = w;
     }

     if (!isZero(x) || !isZero(y)) {
         mType |= TRANSLATE;
     }

     mat33& M(mMatrix);
     M[0][0] = a;    M[1][0] = b;    M[2][0] = x;
     M[0][1] = c;    M[1][1] = d;    M[2][1] = y;
     M[0][2] = 0;    M[1][2] = 0;    M[2][2] = 1;

     return NO_ERROR;
 }

 Transform::vec2 Transform::transform(const vec2& v) const {
     vec2 r;
     const mat33& M(mMatrix);
     r[0] = M[0][0]*v[0] + M[1][0]*v[1] + M[2][0];
     r[1] = M[0][1]*v[0] + M[1][1]*v[1] + M[2][1];
     return r;
 }

 Transform::vec3 Transform::transform(const vec3& v) const {
     vec3 r;
     const mat33& M(mMatrix);
     r[0] = M[0][0]*v[0] + M[1][0]*v[1] + M[2][0]*v[2];
     r[1] = M[0][1]*v[0] + M[1][1]*v[1] + M[2][1]*v[2];
     r[2] = M[0][2]*v[0] + M[1][2]*v[1] + M[2][2]*v[2];
     return r;
 }

 void Transform::transform(float* point, int x, int y) const
 {
     const mat33& M(mMatrix);
     vec2 v(x, y);
     v = transform(v);
     point[0] = v[0];
     point[1] = v[1];
 }

 Rect Transform::makeBounds(int w, int h) const
 {
     return transform( Rect(w, h) );
 }

 Rect Transform::transform(const Rect& bounds) const
 {
     Rect r;
     vec2 lt( bounds.left,  bounds.top    );
     vec2 rt( bounds.right, bounds.top    );
     vec2 lb( bounds.left,  bounds.bottom );
     vec2 rb( bounds.right, bounds.bottom );

     lt = transform(lt);
     rt = transform(rt);
     lb = transform(lb);
     rb = transform(rb);

     r.left   = floorf(min(lt[0], rt[0], lb[0], rb[0]) + 0.5f);
     r.top    = floorf(min(lt[1], rt[1], lb[1], rb[1]) + 0.5f);
     r.right  = floorf(max(lt[0], rt[0], lb[0], rb[0]) + 0.5f);
     r.bottom = floorf(max(lt[1], rt[1], lb[1], rb[1]) + 0.5f);

     return r;
 }

 Region Transform::transform(const Region& reg) const
 {
     Region out;
     if (CC_UNLIKELY(transformed())) {
         if (CC_LIKELY(preserveRects())) {
             Region::const_iterator it = reg.begin();
             Region::const_iterator const end = reg.end();
             while (it != end) {
                 out.orSelf(transform(*it++));
             }
         } else {
             out.set(transform(reg.bounds()));
         }
     } else {
         out = reg.translate(tx(), ty());
     }
     return out;
 }

 uint32_t Transform::type() const
 {
     if (mType & UNKNOWN_TYPE) {
         // recompute what this transform is

         const mat33& M(mMatrix);
         const float a = M[0][0];
         const float b = M[1][0];
         const float c = M[0][1];
         const float d = M[1][1];
         const float x = M[2][0];
         const float y = M[2][1];

         bool scale = false;
         uint32_t flags = ROT_0;
         if (isZero(b) && isZero(c)) {
             if (a<0)    flags |= FLIP_H;
             if (d<0)    flags |= FLIP_V;
             if (!absIsOne(a) || !absIsOne(d)) {
                 scale = true;
             }
         } else if (isZero(a) && isZero(d)) {
             flags |= ROT_90;
             if (b>0)    flags |= FLIP_H;
             if (c<0)    flags |= FLIP_V;
             if (!absIsOne(b) || !absIsOne(c)) {
                 scale = true;
             }
         } else {
             flags = ROT_INVALID;
         }

         mType = flags << 8;
         if (flags & ROT_INVALID) {
             mType |= UNKNOWN;
         } else {
             if ((flags & ROT_90) || ((flags & ROT_180) == ROT_180))
                 mType |= ROTATE;
             if (flags & FLIP_H)
                 mType ^= SCALE;
             if (flags & FLIP_V)
                 mType ^= SCALE;
             if (scale)
                 mType |= SCALE;
         }

         if (!isZero(x) || !isZero(y))
             mType |= TRANSLATE;
     }
     return mType;
 }

 uint32_t Transform::getType() const {
     return type() & 0xFF;
 }

 uint32_t Transform::getOrientation() const
 {
     return (type() >> 8) & 0xFF;
 }

 bool Transform::preserveRects() const
 {
     return (type() & ROT_INVALID) ? false : true;
 }

 void Transform::dump(const char* name) const
 {
     type(); // updates the type

     String8 flags, type;
     const mat33& m(mMatrix);
     uint32_t orient = mType >> 8;

     if (orient&ROT_INVALID) {
         flags.append("ROT_INVALID ");
     } else {
         if (orient&ROT_90) {
             flags.append("ROT_90 ");
         } else {
             flags.append("ROT_0 ");
         }
         if (orient&FLIP_V)
             flags.append("FLIP_V ");
         if (orient&FLIP_H)
             flags.append("FLIP_H ");
     }

     if (!(mType&(SCALE|ROTATE|TRANSLATE)))
         type.append("IDENTITY ");
     if (mType&SCALE)
         type.append("SCALE ");
     if (mType&ROTATE)
         type.append("ROTATE ");
     if (mType&TRANSLATE)
         type.append("TRANSLATE ");

     LOGD("%s 0x%08x (%s, %s)", name, mType, flags.string(), type.string());
     LOGD("%.4f  %.4f  %.4f", m[0][0], m[1][0], m[2][0]);
     LOGD("%.4f  %.4f  %.4f", m[0][1], m[1][1], m[2][1]);
     LOGD("%.4f  %.4f  %.4f", m[0][2], m[1][2], m[2][2]);
 }

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

 }; // namespace android
	/*
	* Copyright (C) 2007 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.
	*/

	#include <math.h>

	#include <cutils/compiler.h>
	#include <utils/String8.h>
	#include <ui/Region.h>

	#include "Transform.h"

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

	namespace android {

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

	template <typename T> inline T min(T a, T b) {
	return a<b ? a : b;
	}
	template <typename T> inline T min(T a, T b, T c) {
	return min(a, min(b, c));
	}
	template <typename T> inline T min(T a, T b, T c, T d) {
	return min(a, b, min(c, d));
	}

	template <typename T> inline T max(T a, T b) {
	return a>b ? a : b;
	}
	template <typename T> inline T max(T a, T b, T c) {
	return max(a, max(b, c));
	}
	template <typename T> inline T max(T a, T b, T c, T d) {
	return max(a, b, max(c, d));
	}

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

	Transform::Transform() {
	reset();
	}

	Transform::Transform(const Transform& other)
	: mMatrix(other.mMatrix), mType(other.mType) {
	}

	Transform::Transform(uint32_t orientation) {
	set(orientation, 0, 0);
	}

	Transform::~Transform() {
	}

	static const float EPSILON = 0.0f;

	bool Transform::isZero(float f) {
	return fabs(f) <= EPSILON;
	}

	bool Transform::absIsOne(float f) {
	return isZero(fabs(f) - 1.0f);
	}

	Transform Transform::operator * (const Transform& rhs) const
	{
	if (CC_LIKELY(mType == IDENTITY))
	return rhs;

	Transform r(*this);
	if (rhs.mType == IDENTITY)
	return r;

	// TODO: we could use mType to optimize the matrix multiply
	const mat33& A(mMatrix);
	const mat33& B(rhs.mMatrix);
	mat33& D(r.mMatrix);
	for (int i=0 ; i<3 ; i++) {
	const float v0 = A[0][i];
	const float v1 = A[1][i];
	const float v2 = A[2][i];
	D[0][i] = v0B[0][0] + v1B[0][1] + v2*B[0][2];
	D[1][i] = v0B[1][0] + v1B[1][1] + v2*B[1][2];
	D[2][i] = v0B[2][0] + v1B[2][1] + v2*B[2][2];
	}
	r.mType \|= rhs.mType;

	// TODO: we could recompute this value from r and rhs
	r.mType &= 0xFF;
	r.mType \|= UNKNOWN_TYPE;
	return r;
	}

	float const* Transform::operator [] (int i) const {
	return mMatrix[i].v;
	}

	bool Transform::transformed() const {
	return type() > TRANSLATE;
	}

	int Transform::tx() const {
	return floorf(mMatrix[2][0] + 0.5f);
	}

	int Transform::ty() const {
	return floorf(mMatrix[2][1] + 0.5f);
	}

	void Transform::reset() {
	mType = IDENTITY;
	for(int i=0 ; i<3 ; i++) {
	vec3& v(mMatrix[i]);
	for (int j=0 ; j<3 ; j++)
	v[j] = ((i==j) ? 1.0f : 0.0f);
	}
	}

	void Transform::set(float tx, float ty)
	{
	mMatrix[2][0] = tx;
	mMatrix[2][1] = ty;
	mMatrix[2][2] = 1.0f;

	if (isZero(tx) && isZero(ty)) {
	mType &= ~TRANSLATE;
	} else {
	mType \|= TRANSLATE;
	}
	}

	void Transform::set(float a, float b, float c, float d)
	{
	mat33& M(mMatrix);
	M[0][0] = a; M[1][0] = b;
	M[0][1] = c; M[1][1] = d;
	M[0][2] = 0; M[1][2] = 0;
	mType = UNKNOWN_TYPE;
	}

	status_t Transform::set(uint32_t flags, float w, float h)
	{
	if (flags & ROT_INVALID) {
	// that's not allowed!
	reset();
	return BAD_VALUE;
	}

	mType = flags << 8;
	float sx = (flags & FLIP_H) ? -1 : 1;
	float sy = (flags & FLIP_V) ? -1 : 1;
	float a=0, b=0, c=0, d=0, x=0, y=0;
	int xmask = 0;

	// computation of x,y
	// x y
	// 0 0 0
	// w 0 ROT90
	// w h FLIPH\|FLIPV
	// 0 h FLIPH\|FLIPV\|ROT90

	if (flags & ROT_90) {
	mType \|= ROTATE;
	b = -sy;
	c = sx;
	xmask = 1;
	} else {
	a = sx;
	d = sy;
	}

	if (flags & FLIP_H) {
	mType ^= SCALE;
	xmask ^= 1;
	}

	if (flags & FLIP_V) {
	mType ^= SCALE;
	y = h;
	}

	if ((flags & ROT_180) == ROT_180) {
	mType \|= ROTATE;
	}

	if (xmask) {
	x = w;
	}

	if (!isZero(x) \|\| !isZero(y)) {
	mType \|= TRANSLATE;
	}

	mat33& M(mMatrix);
	M[0][0] = a; M[1][0] = b; M[2][0] = x;
	M[0][1] = c; M[1][1] = d; M[2][1] = y;
	M[0][2] = 0; M[1][2] = 0; M[2][2] = 1;

	return NO_ERROR;
	}

	Transform::vec2 Transform::transform(const vec2& v) const {
	vec2 r;
	const mat33& M(mMatrix);
	r[0] = M[0][0]v[0] + M[1][0]v[1] + M[2][0];
	r[1] = M[0][1]v[0] + M[1][1]v[1] + M[2][1];
	return r;
	}

	Transform::vec3 Transform::transform(const vec3& v) const {
	vec3 r;
	const mat33& M(mMatrix);
	r[0] = M[0][0]v[0] + M[1][0]v[1] + M[2][0]*v[2];
	r[1] = M[0][1]v[0] + M[1][1]v[1] + M[2][1]*v[2];
	r[2] = M[0][2]v[0] + M[1][2]v[1] + M[2][2]*v[2];
	return r;
	}

	void Transform::transform(float* point, int x, int y) const
	{
	const mat33& M(mMatrix);
	vec2 v(x, y);
	v = transform(v);
	point[0] = v[0];
	point[1] = v[1];
	}

	Rect Transform::makeBounds(int w, int h) const
	{
	return transform( Rect(w, h) );
	}

	Rect Transform::transform(const Rect& bounds) const
	{
	Rect r;
	vec2 lt( bounds.left, bounds.top );
	vec2 rt( bounds.right, bounds.top );
	vec2 lb( bounds.left, bounds.bottom );
	vec2 rb( bounds.right, bounds.bottom );

	lt = transform(lt);
	rt = transform(rt);
	lb = transform(lb);
	rb = transform(rb);

	r.left = floorf(min(lt[0], rt[0], lb[0], rb[0]) + 0.5f);
	r.top = floorf(min(lt[1], rt[1], lb[1], rb[1]) + 0.5f);
	r.right = floorf(max(lt[0], rt[0], lb[0], rb[0]) + 0.5f);
	r.bottom = floorf(max(lt[1], rt[1], lb[1], rb[1]) + 0.5f);

	return r;
	}

	Region Transform::transform(const Region& reg) const
	{
	Region out;
	if (CC_UNLIKELY(transformed())) {
	if (CC_LIKELY(preserveRects())) {
	Region::const_iterator it = reg.begin();
	Region::const_iterator const end = reg.end();
	while (it != end) {
	out.orSelf(transform(*it++));
	}
	} else {
	out.set(transform(reg.bounds()));
	}
	} else {
	out = reg.translate(tx(), ty());
	}
	return out;
	}

	uint32_t Transform::type() const
	{
	if (mType & UNKNOWN_TYPE) {
	// recompute what this transform is

	const mat33& M(mMatrix);
	const float a = M[0][0];
	const float b = M[1][0];
	const float c = M[0][1];
	const float d = M[1][1];
	const float x = M[2][0];
	const float y = M[2][1];

	bool scale = false;
	uint32_t flags = ROT_0;
	if (isZero(b) && isZero(c)) {
	if (a<0) flags \|= FLIP_H;
	if (d<0) flags \|= FLIP_V;
	if (!absIsOne(a) \|\| !absIsOne(d)) {
	scale = true;
	}
	} else if (isZero(a) && isZero(d)) {
	flags \|= ROT_90;
	if (b>0) flags \|= FLIP_H;
	if (c<0) flags \|= FLIP_V;
	if (!absIsOne(b) \|\| !absIsOne(c)) {
	scale = true;
	}
	} else {
	flags = ROT_INVALID;
	}

	mType = flags << 8;
	if (flags & ROT_INVALID) {
	mType \|= UNKNOWN;
	} else {
	if ((flags & ROT_90) \|\| ((flags & ROT_180) == ROT_180))
	mType \|= ROTATE;
	if (flags & FLIP_H)
	mType ^= SCALE;
	if (flags & FLIP_V)
	mType ^= SCALE;
	if (scale)
	mType \|= SCALE;
	}

	if (!isZero(x) \|\| !isZero(y))
	mType \|= TRANSLATE;
	}
	return mType;
	}

	uint32_t Transform::getType() const {
	return type() & 0xFF;
	}

	uint32_t Transform::getOrientation() const
	{
	return (type() >> 8) & 0xFF;
	}

	bool Transform::preserveRects() const
	{
	return (type() & ROT_INVALID) ? false : true;
	}

	void Transform::dump(const char* name) const
	{
	type(); // updates the type

	String8 flags, type;
	const mat33& m(mMatrix);
	uint32_t orient = mType >> 8;

	if (orient&ROT_INVALID) {
	flags.append("ROT_INVALID ");
	} else {
	if (orient&ROT_90) {
	flags.append("ROT_90 ");
	} else {
	flags.append("ROT_0 ");
	}
	if (orient&FLIP_V)
	flags.append("FLIP_V ");
	if (orient&FLIP_H)
	flags.append("FLIP_H ");
	}

	if (!(mType&(SCALE\|ROTATE\|TRANSLATE)))
	type.append("IDENTITY ");
	if (mType&SCALE)
	type.append("SCALE ");
	if (mType&ROTATE)
	type.append("ROTATE ");
	if (mType&TRANSLATE)
	type.append("TRANSLATE ");

	LOGD("%s 0x%08x (%s, %s)", name, mType, flags.string(), type.string());
	LOGD("%.4f %.4f %.4f", m[0][0], m[1][0], m[2][0]);
	LOGD("%.4f %.4f %.4f", m[0][1], m[1][1], m[2][1]);
	LOGD("%.4f %.4f %.4f", m[0][2], m[1][2], m[2][2]);
	}

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

	}; // namespace android