include/core/SkYUVAInfo.h - skia - Git at Google

 /*
  * Copyright 2020 Google LLC
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkYUVAInfo_DEFINED
 #define SkYUVAInfo_DEFINED

 #include "include/codec/SkEncodedOrigin.h"
 #include "include/core/SkImageInfo.h"
 #include "include/core/SkSize.h"

 #include <array>
 #include <tuple>

 /**
  * Specifies the structure of planes for a YUV image with optional alpha. The actual planar data
  * is not part of this structure and depending on usage is in external textures or pixmaps.
  */
 class SK_API SkYUVAInfo {
 public:
     enum YUVAChannels { kY, kU, kV, kA, kLast = kA };
     static constexpr int kYUVAChannelCount = static_cast<int>(YUVAChannels::kLast + 1);

     struct YUVALocation;  // For internal use.
     using YUVALocations = std::array<YUVALocation, kYUVAChannelCount>;

     /**
      * Specifies how YUV (and optionally A) are divided among planes. Planes are separated by
      * underscores in the enum value names. Within each plane the pixmap/texture channels are
      * mapped to the YUVA channels in the order specified, e.g. for kY_UV Y is in channel 0 of plane
      * 0, U is in channel 0 of plane 1, and V is in channel 1 of plane 1. Channel ordering
      * within a pixmap/texture given the channels it contains:
      * A:                       0:A
      * Luminance/Gray:          0:Gray
      * Luminance/Gray + Alpha:  0:Gray, 1:A
      * RG                       0:R,    1:G
      * RGB                      0:R,    1:G, 2:B
      * RGBA                     0:R,    1:G, 2:B, 3:A
      */
     enum class PlaneConfig {
         kUnknown,

         kY_U_V,    ///< Plane 0: Y, Plane 1: U,  Plane 2: V
         kY_V_U,    ///< Plane 0: Y, Plane 1: V,  Plane 2: U
         kY_UV,     ///< Plane 0: Y, Plane 1: UV
         kY_VU,     ///< Plane 0: Y, Plane 1: VU
         kYUV,      ///< Plane 0: YUV
         kUYV,      ///< Plane 0: UYV

         kY_U_V_A,  ///< Plane 0: Y, Plane 1: U,  Plane 2: V, Plane 3: A
         kY_V_U_A,  ///< Plane 0: Y, Plane 1: V,  Plane 2: U, Plane 3: A
         kY_UV_A,   ///< Plane 0: Y, Plane 1: UV, Plane 2: A
         kY_VU_A,   ///< Plane 0: Y, Plane 1: VU, Plane 2: A
         kYUVA,     ///< Plane 0: YUVA
         kUYVA,     ///< Plane 0: UYVA

         kLast = kUYVA
     };

     /**
      * UV subsampling is also specified in the enum value names using J:a:b notation (e.g. 4:2:0 is
      * 1/2 horizontal and 1/2 vertical resolution for U and V). If alpha is present it is not sub-
      * sampled. Note that Subsampling values other than k444 are only valid with PlaneConfig values
      * that have U and V in different planes than Y (and A, if present).
      */
     enum class Subsampling {
         kUnknown,

         k444,    ///< No subsampling. UV values for each Y.
         k422,    ///< 1 set of UV values for each 2x1 block of Y values.
         k420,    ///< 1 set of UV values for each 2x2 block of Y values.
         k440,    ///< 1 set of UV values for each 1x2 block of Y values.
         k411,    ///< 1 set of UV values for each 4x1 block of Y values.
         k410,    ///< 1 set of UV values for each 4x2 block of Y values.

         kLast = k410
     };

     /**
      * Describes how subsampled chroma values are sited relative to luma values.
      *
      * Currently only centered siting is supported but will expand to support additional sitings.
      */
     enum class Siting {
         /**
          * Subsampled chroma value is sited at the center of the block of corresponding luma values.
          */
         kCentered,
     };

     static constexpr int kMaxPlanes = 4;

     /** ratio of Y/A values to U/V values in x and y. */
     static std::tuple<int, int> SubsamplingFactors(Subsampling);

     /**
      * SubsamplingFactors(Subsampling) if planedIdx refers to a U/V plane and otherwise {1, 1} if
      * inputs are valid. Invalid inputs consist of incompatible PlaneConfig/Subsampling/planeIdx
      * combinations. {0, 0} is returned for invalid inputs.
      */
     static std::tuple<int, int> PlaneSubsamplingFactors(PlaneConfig, Subsampling, int planeIdx);

     /**
      * Given image dimensions, a planer configuration, subsampling, and origin, determine the
      * expected size of each plane. Returns the number of expected planes. planeDimensions[0]
      * through planeDimensions[<ret>] are written. The input image dimensions are as displayed
      * (after the planes have been transformed to the intended display orientation). The plane
      * dimensions are output as the planes are stored in memory (may be rotated from image
      * dimensions).
      */
     static int PlaneDimensions(SkISize imageDimensions,
                                PlaneConfig,
                                Subsampling,
                                SkEncodedOrigin,
                                SkISize planeDimensions[kMaxPlanes]);

     /** Number of planes for a given PlaneConfig. */
     static constexpr int NumPlanes(PlaneConfig);

     /**
      * Number of Y, U, V, A channels in the ith plane for a given PlaneConfig (or 0 if i is
      * invalid).
      */
     static constexpr int NumChannelsInPlane(PlaneConfig, int i);

     /**
      * Given a PlaneConfig and a set of channel flags for each plane, convert to YUVALocations
      * representation. Fails if channel flags aren't valid for the PlaneConfig (i.e. don't have
      * enough channels in a plane) by returning an invalid set of locations (plane indices are -1).
      */
     static YUVALocations GetYUVALocations(PlaneConfig, const uint32_t* planeChannelFlags);

     /** Does the PlaneConfig have alpha values? */
     static bool HasAlpha(PlaneConfig);

     SkYUVAInfo() = default;
     SkYUVAInfo(const SkYUVAInfo&) = default;

     /**
      * 'dimensions' should specify the size of the full resolution image (after planes have been
      * oriented to how the image is displayed as indicated by 'origin').
      */
     SkYUVAInfo(SkISize dimensions,
                PlaneConfig,
                Subsampling,
                SkYUVColorSpace,
                SkEncodedOrigin origin = kTopLeft_SkEncodedOrigin,
                Siting sitingX = Siting::kCentered,
                Siting sitingY = Siting::kCentered);

     SkYUVAInfo& operator=(const SkYUVAInfo& that) = default;

     PlaneConfig planeConfig() const { return fPlaneConfig; }
     Subsampling subsampling() const { return fSubsampling; }

     std::tuple<int, int> planeSubsamplingFactors(int planeIdx) const {
         return PlaneSubsamplingFactors(fPlaneConfig, fSubsampling, planeIdx);
     }

     /**
      * Dimensions of the full resolution image (after planes have been oriented to how the image
      * is displayed as indicated by fOrigin).
      */
     SkISize dimensions() const { return fDimensions; }
     int width() const { return fDimensions.width(); }
     int height() const { return fDimensions.height(); }

     SkYUVColorSpace yuvColorSpace() const { return fYUVColorSpace; }
     Siting sitingX() const { return fSitingX; }
     Siting sitingY() const { return fSitingY; }

     SkEncodedOrigin origin() const { return fOrigin; }

     SkMatrix originMatrix() const {
         return SkEncodedOriginToMatrix(fOrigin, this->width(), this->height());
     }

     bool hasAlpha() const { return HasAlpha(fPlaneConfig); }

     /**
      * Returns the number of planes and initializes planeDimensions[0]..planeDimensions[<ret>] to
      * the expected dimensions for each plane. Dimensions are as stored in memory, before
      * transformation to image display space as indicated by origin().
      */
     int planeDimensions(SkISize planeDimensions[kMaxPlanes]) const {
         return PlaneDimensions(fDimensions, fPlaneConfig, fSubsampling, fOrigin, planeDimensions);
     }

     /**
      * Given a per-plane row bytes, determine size to allocate for all planes. Optionally retrieves
      * the per-plane byte sizes in planeSizes if not null. If total size overflows will return
      * SIZE_MAX and set all planeSizes to SIZE_MAX.
      */
     size_t computeTotalBytes(const size_t rowBytes[kMaxPlanes],
                              size_t planeSizes[kMaxPlanes] = nullptr) const;

     int numPlanes() const { return NumPlanes(fPlaneConfig); }

     int numChannelsInPlane(int i) const { return NumChannelsInPlane(fPlaneConfig, i); }

     /**
      * Given a set of channel flags for each plane, converts this->planeConfig() to YUVALocations
      * representation. Fails if the channel flags aren't valid for the PlaneConfig (i.e. don't have
      * enough channels in a plane) by returning default initialized locations (all plane indices are
      * -1).
      */
     YUVALocations toYUVALocations(const uint32_t* channelFlags) const;

     /**
      * Makes a SkYUVAInfo that is identical to this one but with the passed Subsampling. If the
      * passed Subsampling is not k444 and this info's PlaneConfig is not compatible with chroma
      * subsampling (because Y is in the same plane as UV) then the result will be an invalid
      * SkYUVAInfo.
      */
     SkYUVAInfo makeSubsampling(SkYUVAInfo::Subsampling) const;

     /**
      * Makes a SkYUVAInfo that is identical to this one but with the passed dimensions. If the
      * passed dimensions is empty then the result will be an invalid SkYUVAInfo.
      */
     SkYUVAInfo makeDimensions(SkISize) const;

     bool operator==(const SkYUVAInfo& that) const;
     bool operator!=(const SkYUVAInfo& that) const { return !(*this == that); }

     bool isValid() const { return fPlaneConfig != PlaneConfig::kUnknown; }

 private:
     SkISize fDimensions = {0, 0};

     PlaneConfig fPlaneConfig = PlaneConfig::kUnknown;
     Subsampling fSubsampling = Subsampling::kUnknown;

     SkYUVColorSpace fYUVColorSpace = SkYUVColorSpace::kIdentity_SkYUVColorSpace;

     /**
      * YUVA data often comes from formats like JPEG that support EXIF orientation.
      * Code that operates on the raw YUV data often needs to know that orientation.
      */
     SkEncodedOrigin fOrigin = kTopLeft_SkEncodedOrigin;

     Siting fSitingX = Siting::kCentered;
     Siting fSitingY = Siting::kCentered;
 };

 constexpr int SkYUVAInfo::NumPlanes(PlaneConfig planeConfig) {
     switch (planeConfig) {
         case PlaneConfig::kUnknown: return 0;
         case PlaneConfig::kY_U_V:   return 3;
         case PlaneConfig::kY_V_U:   return 3;
         case PlaneConfig::kY_UV:    return 2;
         case PlaneConfig::kY_VU:    return 2;
         case PlaneConfig::kYUV:     return 1;
         case PlaneConfig::kUYV:     return 1;
         case PlaneConfig::kY_U_V_A: return 4;
         case PlaneConfig::kY_V_U_A: return 4;
         case PlaneConfig::kY_UV_A:  return 3;
         case PlaneConfig::kY_VU_A:  return 3;
         case PlaneConfig::kYUVA:    return 1;
         case PlaneConfig::kUYVA:    return 1;
     }
     SkUNREACHABLE;
 }

 constexpr int SkYUVAInfo::NumChannelsInPlane(PlaneConfig config, int i) {
     switch (config) {
         case PlaneConfig::kUnknown:
             return 0;

         case SkYUVAInfo::PlaneConfig::kY_U_V:
         case SkYUVAInfo::PlaneConfig::kY_V_U:
             return i >= 0 && i < 3 ? 1 : 0;
         case SkYUVAInfo::PlaneConfig::kY_UV:
         case SkYUVAInfo::PlaneConfig::kY_VU:
             switch (i) {
                 case 0:  return 1;
                 case 1:  return 2;
                 default: return 0;
             }
         case SkYUVAInfo::PlaneConfig::kYUV:
         case SkYUVAInfo::PlaneConfig::kUYV:
             return i == 0 ? 3 : 0;
         case SkYUVAInfo::PlaneConfig::kY_U_V_A:
         case SkYUVAInfo::PlaneConfig::kY_V_U_A:
             return i >= 0 && i < 4 ? 1 : 0;
         case SkYUVAInfo::PlaneConfig::kY_UV_A:
         case SkYUVAInfo::PlaneConfig::kY_VU_A:
             switch (i) {
                 case 0:  return 1;
                 case 1:  return 2;
                 case 2:  return 1;
                 default: return 0;
             }
         case SkYUVAInfo::PlaneConfig::kYUVA:
         case SkYUVAInfo::PlaneConfig::kUYVA:
             return i == 0 ? 4 : 0;
     }
     return 0;
 }

 #endif
	/*
	* Copyright 2020 Google LLC
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkYUVAInfo_DEFINED
	#define SkYUVAInfo_DEFINED

	#include "include/codec/SkEncodedOrigin.h"
	#include "include/core/SkImageInfo.h"
	#include "include/core/SkSize.h"

	#include <array>
	#include <tuple>

	/**
	* Specifies the structure of planes for a YUV image with optional alpha. The actual planar data
	* is not part of this structure and depending on usage is in external textures or pixmaps.
	*/
	class SK_API SkYUVAInfo {
	public:
	enum YUVAChannels { kY, kU, kV, kA, kLast = kA };
	static constexpr int kYUVAChannelCount = static_cast<int>(YUVAChannels::kLast + 1);

	struct YUVALocation; // For internal use.
	using YUVALocations = std::array<YUVALocation, kYUVAChannelCount>;

	/**
	* Specifies how YUV (and optionally A) are divided among planes. Planes are separated by
	* underscores in the enum value names. Within each plane the pixmap/texture channels are
	* mapped to the YUVA channels in the order specified, e.g. for kY_UV Y is in channel 0 of plane
	* 0, U is in channel 0 of plane 1, and V is in channel 1 of plane 1. Channel ordering
	* within a pixmap/texture given the channels it contains:
	* A: 0:A
	* Luminance/Gray: 0:Gray
	* Luminance/Gray + Alpha: 0:Gray, 1:A
	* RG 0:R, 1:G
	* RGB 0:R, 1:G, 2:B
	* RGBA 0:R, 1:G, 2:B, 3:A
	*/
	enum class PlaneConfig {
	kUnknown,

	kY_U_V, ///< Plane 0: Y, Plane 1: U, Plane 2: V
	kY_V_U, ///< Plane 0: Y, Plane 1: V, Plane 2: U
	kY_UV, ///< Plane 0: Y, Plane 1: UV
	kY_VU, ///< Plane 0: Y, Plane 1: VU
	kYUV, ///< Plane 0: YUV
	kUYV, ///< Plane 0: UYV

	kY_U_V_A, ///< Plane 0: Y, Plane 1: U, Plane 2: V, Plane 3: A
	kY_V_U_A, ///< Plane 0: Y, Plane 1: V, Plane 2: U, Plane 3: A
	kY_UV_A, ///< Plane 0: Y, Plane 1: UV, Plane 2: A
	kY_VU_A, ///< Plane 0: Y, Plane 1: VU, Plane 2: A
	kYUVA, ///< Plane 0: YUVA
	kUYVA, ///< Plane 0: UYVA

	kLast = kUYVA
	};

	/**
	* UV subsampling is also specified in the enum value names using J:a:b notation (e.g. 4:2:0 is
	* 1/2 horizontal and 1/2 vertical resolution for U and V). If alpha is present it is not sub-
	* sampled. Note that Subsampling values other than k444 are only valid with PlaneConfig values
	* that have U and V in different planes than Y (and A, if present).
	*/
	enum class Subsampling {
	kUnknown,

	k444, ///< No subsampling. UV values for each Y.
	k422, ///< 1 set of UV values for each 2x1 block of Y values.
	k420, ///< 1 set of UV values for each 2x2 block of Y values.
	k440, ///< 1 set of UV values for each 1x2 block of Y values.
	k411, ///< 1 set of UV values for each 4x1 block of Y values.
	k410, ///< 1 set of UV values for each 4x2 block of Y values.

	kLast = k410
	};

	/**
	* Describes how subsampled chroma values are sited relative to luma values.
	*
	* Currently only centered siting is supported but will expand to support additional sitings.
	*/
	enum class Siting {
	/**
	* Subsampled chroma value is sited at the center of the block of corresponding luma values.
	*/
	kCentered,
	};

	static constexpr int kMaxPlanes = 4;

	/** ratio of Y/A values to U/V values in x and y. */
	static std::tuple<int, int> SubsamplingFactors(Subsampling);

	/**
	* SubsamplingFactors(Subsampling) if planedIdx refers to a U/V plane and otherwise {1, 1} if
	* inputs are valid. Invalid inputs consist of incompatible PlaneConfig/Subsampling/planeIdx
	* combinations. {0, 0} is returned for invalid inputs.
	*/
	static std::tuple<int, int> PlaneSubsamplingFactors(PlaneConfig, Subsampling, int planeIdx);

	/**
	* Given image dimensions, a planer configuration, subsampling, and origin, determine the
	* expected size of each plane. Returns the number of expected planes. planeDimensions[0]
	* through planeDimensions[<ret>] are written. The input image dimensions are as displayed
	* (after the planes have been transformed to the intended display orientation). The plane
	* dimensions are output as the planes are stored in memory (may be rotated from image
	* dimensions).
	*/
	static int PlaneDimensions(SkISize imageDimensions,
	PlaneConfig,
	Subsampling,
	SkEncodedOrigin,
	SkISize planeDimensions[kMaxPlanes]);

	/** Number of planes for a given PlaneConfig. */
	static constexpr int NumPlanes(PlaneConfig);

	/**
	* Number of Y, U, V, A channels in the ith plane for a given PlaneConfig (or 0 if i is
	* invalid).
	*/
	static constexpr int NumChannelsInPlane(PlaneConfig, int i);

	/**
	* Given a PlaneConfig and a set of channel flags for each plane, convert to YUVALocations
	* representation. Fails if channel flags aren't valid for the PlaneConfig (i.e. don't have
	* enough channels in a plane) by returning an invalid set of locations (plane indices are -1).
	*/
	static YUVALocations GetYUVALocations(PlaneConfig, const uint32_t* planeChannelFlags);

	/** Does the PlaneConfig have alpha values? */
	static bool HasAlpha(PlaneConfig);

	SkYUVAInfo() = default;
	SkYUVAInfo(const SkYUVAInfo&) = default;

	/**
	* 'dimensions' should specify the size of the full resolution image (after planes have been
	* oriented to how the image is displayed as indicated by 'origin').
	*/
	SkYUVAInfo(SkISize dimensions,
	PlaneConfig,
	Subsampling,
	SkYUVColorSpace,
	SkEncodedOrigin origin = kTopLeft_SkEncodedOrigin,
	Siting sitingX = Siting::kCentered,
	Siting sitingY = Siting::kCentered);

	SkYUVAInfo& operator=(const SkYUVAInfo& that) = default;

	PlaneConfig planeConfig() const { return fPlaneConfig; }
	Subsampling subsampling() const { return fSubsampling; }

	std::tuple<int, int> planeSubsamplingFactors(int planeIdx) const {
	return PlaneSubsamplingFactors(fPlaneConfig, fSubsampling, planeIdx);
	}

	/**
	* Dimensions of the full resolution image (after planes have been oriented to how the image
	* is displayed as indicated by fOrigin).
	*/
	SkISize dimensions() const { return fDimensions; }
	int width() const { return fDimensions.width(); }
	int height() const { return fDimensions.height(); }

	SkYUVColorSpace yuvColorSpace() const { return fYUVColorSpace; }
	Siting sitingX() const { return fSitingX; }
	Siting sitingY() const { return fSitingY; }

	SkEncodedOrigin origin() const { return fOrigin; }

	SkMatrix originMatrix() const {
	return SkEncodedOriginToMatrix(fOrigin, this->width(), this->height());
	}

	bool hasAlpha() const { return HasAlpha(fPlaneConfig); }

	/**
	* Returns the number of planes and initializes planeDimensions[0]..planeDimensions[<ret>] to
	* the expected dimensions for each plane. Dimensions are as stored in memory, before
	* transformation to image display space as indicated by origin().
	*/
	int planeDimensions(SkISize planeDimensions[kMaxPlanes]) const {
	return PlaneDimensions(fDimensions, fPlaneConfig, fSubsampling, fOrigin, planeDimensions);
	}

	/**
	* Given a per-plane row bytes, determine size to allocate for all planes. Optionally retrieves
	* the per-plane byte sizes in planeSizes if not null. If total size overflows will return
	* SIZE_MAX and set all planeSizes to SIZE_MAX.
	*/
	size_t computeTotalBytes(const size_t rowBytes[kMaxPlanes],
	size_t planeSizes[kMaxPlanes] = nullptr) const;

	int numPlanes() const { return NumPlanes(fPlaneConfig); }

	int numChannelsInPlane(int i) const { return NumChannelsInPlane(fPlaneConfig, i); }

	/**
	* Given a set of channel flags for each plane, converts this->planeConfig() to YUVALocations
	* representation. Fails if the channel flags aren't valid for the PlaneConfig (i.e. don't have
	* enough channels in a plane) by returning default initialized locations (all plane indices are
	* -1).
	*/
	YUVALocations toYUVALocations(const uint32_t* channelFlags) const;

	/**
	* Makes a SkYUVAInfo that is identical to this one but with the passed Subsampling. If the
	* passed Subsampling is not k444 and this info's PlaneConfig is not compatible with chroma
	* subsampling (because Y is in the same plane as UV) then the result will be an invalid
	* SkYUVAInfo.
	*/
	SkYUVAInfo makeSubsampling(SkYUVAInfo::Subsampling) const;

	/**
	* Makes a SkYUVAInfo that is identical to this one but with the passed dimensions. If the
	* passed dimensions is empty then the result will be an invalid SkYUVAInfo.
	*/
	SkYUVAInfo makeDimensions(SkISize) const;

	bool operator==(const SkYUVAInfo& that) const;
	bool operator!=(const SkYUVAInfo& that) const { return !(*this == that); }

	bool isValid() const { return fPlaneConfig != PlaneConfig::kUnknown; }

	private:
	SkISize fDimensions = {0, 0};

	PlaneConfig fPlaneConfig = PlaneConfig::kUnknown;
	Subsampling fSubsampling = Subsampling::kUnknown;

	SkYUVColorSpace fYUVColorSpace = SkYUVColorSpace::kIdentity_SkYUVColorSpace;

	/**
	* YUVA data often comes from formats like JPEG that support EXIF orientation.
	* Code that operates on the raw YUV data often needs to know that orientation.
	*/
	SkEncodedOrigin fOrigin = kTopLeft_SkEncodedOrigin;

	Siting fSitingX = Siting::kCentered;
	Siting fSitingY = Siting::kCentered;
	};

	constexpr int SkYUVAInfo::NumPlanes(PlaneConfig planeConfig) {
	switch (planeConfig) {
	case PlaneConfig::kUnknown: return 0;
	case PlaneConfig::kY_U_V: return 3;
	case PlaneConfig::kY_V_U: return 3;
	case PlaneConfig::kY_UV: return 2;
	case PlaneConfig::kY_VU: return 2;
	case PlaneConfig::kYUV: return 1;
	case PlaneConfig::kUYV: return 1;
	case PlaneConfig::kY_U_V_A: return 4;
	case PlaneConfig::kY_V_U_A: return 4;
	case PlaneConfig::kY_UV_A: return 3;
	case PlaneConfig::kY_VU_A: return 3;
	case PlaneConfig::kYUVA: return 1;
	case PlaneConfig::kUYVA: return 1;
	}
	SkUNREACHABLE;
	}

	constexpr int SkYUVAInfo::NumChannelsInPlane(PlaneConfig config, int i) {
	switch (config) {
	case PlaneConfig::kUnknown:
	return 0;

	case SkYUVAInfo::PlaneConfig::kY_U_V:
	case SkYUVAInfo::PlaneConfig::kY_V_U:
	return i >= 0 && i < 3 ? 1 : 0;
	case SkYUVAInfo::PlaneConfig::kY_UV:
	case SkYUVAInfo::PlaneConfig::kY_VU:
	switch (i) {
	case 0: return 1;
	case 1: return 2;
	default: return 0;
	}
	case SkYUVAInfo::PlaneConfig::kYUV:
	case SkYUVAInfo::PlaneConfig::kUYV:
	return i == 0 ? 3 : 0;
	case SkYUVAInfo::PlaneConfig::kY_U_V_A:
	case SkYUVAInfo::PlaneConfig::kY_V_U_A:
	return i >= 0 && i < 4 ? 1 : 0;
	case SkYUVAInfo::PlaneConfig::kY_UV_A:
	case SkYUVAInfo::PlaneConfig::kY_VU_A:
	switch (i) {
	case 0: return 1;
	case 1: return 2;
	case 2: return 1;
	default: return 0;
	}
	case SkYUVAInfo::PlaneConfig::kYUVA:
	case SkYUVAInfo::PlaneConfig::kUYVA:
	return i == 0 ? 4 : 0;
	}
	return 0;
	}

	#endif