ADataSpace should be aligned with the AIDL Dataspace.
Bug: 200309580
Test: build pass
Change-Id: Ibe184ca6edcbd61677d2cdf5d45e0ad24161ee30
diff --git a/libs/nativewindow/ANativeWindow.cpp b/libs/nativewindow/ANativeWindow.cpp
index 75f2385..2db9992 100644
--- a/libs/nativewindow/ANativeWindow.cpp
+++ b/libs/nativewindow/ANativeWindow.cpp
@@ -133,12 +133,41 @@
int32_t ANativeWindow_setBuffersDataSpace(ANativeWindow* window, int32_t dataSpace) {
static_assert(static_cast<int>(ADATASPACE_UNKNOWN) == static_cast<int>(HAL_DATASPACE_UNKNOWN));
- static_assert(static_cast<int>(ADATASPACE_SCRGB_LINEAR) == static_cast<int>(HAL_DATASPACE_V0_SCRGB_LINEAR));
+ static_assert(static_cast<int>(STANDARD_SHIFT) == static_cast<int>(HAL_DATASPACE_STANDARD_SHIFT));
+ static_assert(static_cast<int>(STANDARD_MASK) == static_cast<int>(HAL_DATASPACE_STANDARD_MASK));
+ static_assert(static_cast<int>(STANDARD_UNSPECIFIED) == static_cast<int>(HAL_DATASPACE_STANDARD_UNSPECIFIED));
+ static_assert(static_cast<int>(STANDARD_BT709) == static_cast<int>(HAL_DATASPACE_STANDARD_BT709));
+ static_assert(static_cast<int>(STANDARD_BT601_625) == static_cast<int>(HAL_DATASPACE_STANDARD_BT601_625));
+ static_assert(static_cast<int>(STANDARD_BT601_625_UNADJUSTED) == static_cast<int>(HAL_DATASPACE_STANDARD_BT601_625_UNADJUSTED));
+ static_assert(static_cast<int>(STANDARD_BT601_525) == static_cast<int>(HAL_DATASPACE_STANDARD_BT601_525));
+ static_assert(static_cast<int>(STANDARD_BT601_525_UNADJUSTED) == static_cast<int>(HAL_DATASPACE_STANDARD_BT601_525_UNADJUSTED));
+ static_assert(static_cast<int>(STANDARD_BT470M) == static_cast<int>(HAL_DATASPACE_STANDARD_BT470M));
+ static_assert(static_cast<int>(STANDARD_FILM) == static_cast<int>(HAL_DATASPACE_STANDARD_FILM));
+ static_assert(static_cast<int>(STANDARD_DCI_P3) == static_cast<int>(HAL_DATASPACE_STANDARD_DCI_P3));
+ static_assert(static_cast<int>(STANDARD_ADOBE_RGB) == static_cast<int>(HAL_DATASPACE_STANDARD_ADOBE_RGB));
+ static_assert(static_cast<int>(TRANSFER_SHIFT) == static_cast<int>(HAL_DATASPACE_TRANSFER_SHIFT));
+ static_assert(static_cast<int>(TRANSFER_MASK) == static_cast<int>(HAL_DATASPACE_TRANSFER_MASK));
+ static_assert(static_cast<int>(TRANSFER_UNSPECIFIED) == static_cast<int>(HAL_DATASPACE_TRANSFER_UNSPECIFIED));
+ static_assert(static_cast<int>(TRANSFER_LINEAR) == static_cast<int>(HAL_DATASPACE_TRANSFER_LINEAR));
+ static_assert(static_cast<int>(TRANSFER_SMPTE_170M) == static_cast<int>(HAL_DATASPACE_TRANSFER_SMPTE_170M));
+ static_assert(static_cast<int>(TRANSFER_GAMMA2_2) == static_cast<int>(HAL_DATASPACE_TRANSFER_GAMMA2_2));
+ static_assert(static_cast<int>(TRANSFER_GAMMA2_6) == static_cast<int>(HAL_DATASPACE_TRANSFER_GAMMA2_6));
+ static_assert(static_cast<int>(TRANSFER_GAMMA2_8) == static_cast<int>(HAL_DATASPACE_TRANSFER_GAMMA2_8));
+ static_assert(static_cast<int>(TRANSFER_ST2084) == static_cast<int>(HAL_DATASPACE_TRANSFER_ST2084));
+ static_assert(static_cast<int>(TRANSFER_HLG) == static_cast<int>(HAL_DATASPACE_TRANSFER_HLG));
+ static_assert(static_cast<int>(RANGE_MASK) == static_cast<int>(HAL_DATASPACE_RANGE_MASK));
+ static_assert(static_cast<int>(RANGE_UNSPECIFIED) == static_cast<int>(HAL_DATASPACE_RANGE_UNSPECIFIED));
+ static_assert(static_cast<int>(RANGE_FULL) == static_cast<int>(HAL_DATASPACE_RANGE_FULL));
+ static_assert(static_cast<int>(RANGE_LIMITED) == static_cast<int>(HAL_DATASPACE_RANGE_LIMITED));
+ static_assert(static_cast<int>(RANGE_EXTENDED) == static_cast<int>(HAL_DATASPACE_RANGE_EXTENDED));
static_assert(static_cast<int>(ADATASPACE_SRGB) == static_cast<int>(HAL_DATASPACE_V0_SRGB));
static_assert(static_cast<int>(ADATASPACE_SCRGB) == static_cast<int>(HAL_DATASPACE_V0_SCRGB));
static_assert(static_cast<int>(ADATASPACE_DISPLAY_P3) == static_cast<int>(HAL_DATASPACE_DISPLAY_P3));
static_assert(static_cast<int>(ADATASPACE_BT2020_PQ) == static_cast<int>(HAL_DATASPACE_BT2020_PQ));
static_assert(static_cast<int>(ADATASPACE_ADOBE_RGB) == static_cast<int>(HAL_DATASPACE_ADOBE_RGB));
+ static_assert(static_cast<int>(ADATASPACE_JFIF) == static_cast<int>(HAL_DATASPACE_V0_JFIF));
+ static_assert(static_cast<int>(ADATASPACE_BT601_625) == static_cast<int>(HAL_DATASPACE_V0_BT601_625));
+ static_assert(static_cast<int>(ADATASPACE_BT601_525) == static_cast<int>(HAL_DATASPACE_V0_BT601_525));
static_assert(static_cast<int>(ADATASPACE_BT2020) == static_cast<int>(HAL_DATASPACE_BT2020));
static_assert(static_cast<int>(ADATASPACE_BT709) == static_cast<int>(HAL_DATASPACE_V0_BT709));
static_assert(static_cast<int>(ADATASPACE_DCI_P3) == static_cast<int>(HAL_DATASPACE_DCI_P3));
diff --git a/libs/nativewindow/include/android/data_space.h b/libs/nativewindow/include/android/data_space.h
index e759513..612fb39 100644
--- a/libs/nativewindow/include/android/data_space.h
+++ b/libs/nativewindow/include/android/data_space.h
@@ -43,6 +43,346 @@
ADATASPACE_UNKNOWN = 0,
/**
+ * Color-description aspects
+ *
+ * The following aspects define various characteristics of the color
+ * specification. These represent bitfields, so that a data space value
+ * can specify each of them independently.
+ */
+
+ /**
+ * Standard aspect
+ *
+ * Defines the chromaticity coordinates of the source primaries in terms of
+ * the CIE 1931 definition of x and y specified in ISO 11664-1.
+ */
+ STANDARD_SHIFT = 16,
+
+ STANDARD_MASK = 63 << 16, // 63 << STANDARD_SHIFT = 0x3F
+
+ /**
+ * Chromacity coordinates are unknown or are determined by the application.
+ * Implementations shall use the following suggested standards:
+ *
+ * All YCbCr formats: BT709 if size is 720p or larger (since most video
+ * content is letterboxed this corresponds to width is
+ * 1280 or greater, or height is 720 or greater).
+ * BT601_625 if size is smaller than 720p or is JPEG.
+ * All RGB formats: BT709.
+ *
+ * For all other formats standard is undefined, and implementations should use
+ * an appropriate standard for the data represented.
+ */
+ STANDARD_UNSPECIFIED = 0 << 16, // STANDARD_SHIFT
+
+ /**
+ * Primaries: x y
+ * green 0.300 0.600
+ * blue 0.150 0.060
+ * red 0.640 0.330
+ * white (D65) 0.3127 0.3290
+ *
+ * Use the unadjusted KR = 0.2126, KB = 0.0722 luminance interpretation
+ * for RGB conversion.
+ */
+ STANDARD_BT709 = 1 << 16, // 1 << STANDARD_SHIFT
+
+ /**
+ * Primaries: x y
+ * green 0.290 0.600
+ * blue 0.150 0.060
+ * red 0.640 0.330
+ * white (D65) 0.3127 0.3290
+ *
+ * KR = 0.299, KB = 0.114. This adjusts the luminance interpretation
+ * for RGB conversion from the one purely determined by the primaries
+ * to minimize the color shift into RGB space that uses BT.709
+ * primaries.
+ */
+ STANDARD_BT601_625 = 2 << 16, // 2 << STANDARD_SHIFT,
+
+ /**
+ * Primaries: x y
+ * green 0.290 0.600
+ * blue 0.150 0.060
+ * red 0.640 0.330
+ * white (D65) 0.3127 0.3290
+ *
+ * Use the unadjusted KR = 0.222, KB = 0.071 luminance interpretation
+ * for RGB conversion.
+ */
+ STANDARD_BT601_625_UNADJUSTED = 3 << 16, // 3 << STANDARD_SHIFT
+
+ /**
+ * Primaries: x y
+ * green 0.310 0.595
+ * blue 0.155 0.070
+ * red 0.630 0.340
+ * white (D65) 0.3127 0.3290
+ *
+ * KR = 0.299, KB = 0.114. This adjusts the luminance interpretation
+ * for RGB conversion from the one purely determined by the primaries
+ * to minimize the color shift into RGB space that uses BT.709
+ * primaries.
+ */
+ STANDARD_BT601_525 = 4 << 16, // 4 << STANDARD_SHIFT
+
+ /**
+ * Primaries: x y
+ * green 0.310 0.595
+ * blue 0.155 0.070
+ * red 0.630 0.340
+ * white (D65) 0.3127 0.3290
+ *
+ * Use the unadjusted KR = 0.212, KB = 0.087 luminance interpretation
+ * for RGB conversion (as in SMPTE 240M).
+ */
+ STANDARD_BT601_525_UNADJUSTED = 5 << 16, // 5 << STANDARD_SHIFT
+
+ /**
+ * Primaries: x y
+ * green 0.170 0.797
+ * blue 0.131 0.046
+ * red 0.708 0.292
+ * white (D65) 0.3127 0.3290
+ *
+ * Use the unadjusted KR = 0.2627, KB = 0.0593 luminance interpretation
+ * for RGB conversion.
+ */
+ STANDARD_BT2020 = 6 << 16, // 6 << STANDARD_SHIFT
+
+ /**
+ * Primaries: x y
+ * green 0.170 0.797
+ * blue 0.131 0.046
+ * red 0.708 0.292
+ * white (D65) 0.3127 0.3290
+ *
+ * Use the unadjusted KR = 0.2627, KB = 0.0593 luminance interpretation
+ * for RGB conversion using the linear domain.
+ */
+ STANDARD_BT2020_CONSTANT_LUMINANCE = 7 << 16, // 7 << STANDARD_SHIFT
+
+ /**
+ * Primaries: x y
+ * green 0.21 0.71
+ * blue 0.14 0.08
+ * red 0.67 0.33
+ * white (C) 0.310 0.316
+ *
+ * Use the unadjusted KR = 0.30, KB = 0.11 luminance interpretation
+ * for RGB conversion.
+ */
+ STANDARD_BT470M = 8 << 16, // 8 << STANDARD_SHIFT
+
+ /**
+ * Primaries: x y
+ * green 0.243 0.692
+ * blue 0.145 0.049
+ * red 0.681 0.319
+ * white (C) 0.310 0.316
+ *
+ * Use the unadjusted KR = 0.254, KB = 0.068 luminance interpretation
+ * for RGB conversion.
+ */
+ STANDARD_FILM = 9 << 16, // 9 << STANDARD_SHIFT
+
+ /**
+ * SMPTE EG 432-1 and SMPTE RP 431-2. (DCI-P3)
+ * Primaries: x y
+ * green 0.265 0.690
+ * blue 0.150 0.060
+ * red 0.680 0.320
+ * white (D65) 0.3127 0.3290
+ */
+ STANDARD_DCI_P3 = 10 << 16, // 10 << STANDARD_SHIFT
+
+ /**
+ * Adobe RGB
+ * Primaries: x y
+ * green 0.210 0.710
+ * blue 0.150 0.060
+ * red 0.640 0.330
+ * white (D65) 0.3127 0.3290
+ */
+ STANDARD_ADOBE_RGB = 11 << 16, // 11 << STANDARD_SHIFT
+
+ /**
+ * Transfer aspect
+ *
+ * Transfer characteristics are the opto-electronic transfer characteristic
+ * at the source as a function of linear optical intensity (luminance).
+ *
+ * For digital signals, E corresponds to the recorded value. Normally, the
+ * transfer function is applied in RGB space to each of the R, G and B
+ * components independently. This may result in color shift that can be
+ * minized by applying the transfer function in Lab space only for the L
+ * component. Implementation may apply the transfer function in RGB space
+ * for all pixel formats if desired.
+ */
+ TRANSFER_SHIFT = 22,
+
+ TRANSFER_MASK = 31 << 22, // 31 << TRANSFER_SHIFT = 0x1F
+
+ /**
+ * Transfer characteristics are unknown or are determined by the
+ * application.
+ *
+ * Implementations should use the following transfer functions:
+ *
+ * For YCbCr formats: use TRANSFER_SMPTE_170M
+ * For RGB formats: use TRANSFER_SRGB
+ *
+ * For all other formats transfer function is undefined, and implementations
+ * should use an appropriate standard for the data represented.
+ */
+ TRANSFER_UNSPECIFIED = 0 << 22, // 0 << TRANSFER_SHIFT
+
+ /**
+ * Transfer characteristic curve:
+ * E = L
+ * L - luminance of image 0 <= L <= 1 for conventional colorimetry
+ * E - corresponding electrical signal
+ */
+ TRANSFER_LINEAR = 1 << 22, // 1 << TRANSFER_SHIFT
+
+ /**
+ * Transfer characteristic curve:
+ *
+ * E = 1.055 * L^(1/2.4) - 0.055 for 0.0031308 <= L <= 1
+ * = 12.92 * L for 0 <= L < 0.0031308
+ * L - luminance of image 0 <= L <= 1 for conventional colorimetry
+ * E - corresponding electrical signal
+ */
+ TRANSFER_SRGB = 2 << 22, // 2 << TRANSFER_SHIFT
+
+ /**
+ * BT.601 525, BT.601 625, BT.709, BT.2020
+ *
+ * Transfer characteristic curve:
+ * E = 1.099 * L ^ 0.45 - 0.099 for 0.018 <= L <= 1
+ * = 4.500 * L for 0 <= L < 0.018
+ * L - luminance of image 0 <= L <= 1 for conventional colorimetry
+ * E - corresponding electrical signal
+ */
+ TRANSFER_SMPTE_170M = 3 << 22, // 3 << TRANSFER_SHIFT
+
+ /**
+ * Assumed display gamma 2.2.
+ *
+ * Transfer characteristic curve:
+ * E = L ^ (1/2.2)
+ * L - luminance of image 0 <= L <= 1 for conventional colorimetry
+ * E - corresponding electrical signal
+ */
+ TRANSFER_GAMMA2_2 = 4 << 22, // 4 << TRANSFER_SHIFT
+
+ /**
+ * display gamma 2.6.
+ *
+ * Transfer characteristic curve:
+ * E = L ^ (1/2.6)
+ * L - luminance of image 0 <= L <= 1 for conventional colorimetry
+ * E - corresponding electrical signal
+ */
+ TRANSFER_GAMMA2_6 = 5 << 22, // 5 << TRANSFER_SHIFT
+
+ /**
+ * display gamma 2.8.
+ *
+ * Transfer characteristic curve:
+ * E = L ^ (1/2.8)
+ * L - luminance of image 0 <= L <= 1 for conventional colorimetry
+ * E - corresponding electrical signal
+ */
+ TRANSFER_GAMMA2_8 = 6 << 22, // 6 << TRANSFER_SHIFT
+
+ /**
+ * SMPTE ST 2084 (Dolby Perceptual Quantizer)
+ *
+ * Transfer characteristic curve:
+ * E = ((c1 + c2 * L^n) / (1 + c3 * L^n)) ^ m
+ * c1 = c3 - c2 + 1 = 3424 / 4096 = 0.8359375
+ * c2 = 32 * 2413 / 4096 = 18.8515625
+ * c3 = 32 * 2392 / 4096 = 18.6875
+ * m = 128 * 2523 / 4096 = 78.84375
+ * n = 0.25 * 2610 / 4096 = 0.1593017578125
+ * L - luminance of image 0 <= L <= 1 for HDR colorimetry.
+ * L = 1 corresponds to 10000 cd/m2
+ * E - corresponding electrical signal
+ */
+ TRANSFER_ST2084 = 7 << 22, // 7 << TRANSFER_SHIFT
+
+ /**
+ * ARIB STD-B67 Hybrid Log Gamma
+ *
+ * Transfer characteristic curve:
+ * E = r * L^0.5 for 0 <= L <= 1
+ * = a * ln(L - b) + c for 1 < L
+ * a = 0.17883277
+ * b = 0.28466892
+ * c = 0.55991073
+ * r = 0.5
+ * L - luminance of image 0 <= L for HDR colorimetry. L = 1 corresponds
+ * to reference white level of 100 cd/m2
+ * E - corresponding electrical signal
+ */
+ TRANSFER_HLG = 8 << 22, // 8 << TRANSFER_SHIFT
+
+ /**
+ * Range aspect
+ *
+ * Defines the range of values corresponding to the unit range of 0-1.
+ * This is defined for YCbCr only, but can be expanded to RGB space.
+ */
+ RANGE_SHIFT = 27,
+
+ RANGE_MASK = 7 << 27, // 7 << RANGE_SHIFT = 0x7
+
+ /**
+ * Range is unknown or are determined by the application. Implementations
+ * shall use the following suggested ranges:
+ *
+ * All YCbCr formats: limited range.
+ * All RGB or RGBA formats (including RAW and Bayer): full range.
+ * All Y formats: full range
+ *
+ * For all other formats range is undefined, and implementations should use
+ * an appropriate range for the data represented.
+ */
+ RANGE_UNSPECIFIED = 0 << 27, // 0 << RANGE_SHIFT = 0x0
+
+ /**
+ * Full range uses all values for Y, Cb and Cr from
+ * 0 to 2^b-1, where b is the bit depth of the color format.
+ */
+ RANGE_FULL = 1 << 27, // 1 << RANGE_SHIFT = 0x8000000
+
+ /**
+ * Limited range uses values 16/256*2^b to 235/256*2^b for Y, and
+ * 1/16*2^b to 15/16*2^b for Cb, Cr, R, G and B, where b is the bit depth of
+ * the color format.
+ *
+ * E.g. For 8-bit-depth formats:
+ * Luma (Y) samples should range from 16 to 235, inclusive
+ * Chroma (Cb, Cr) samples should range from 16 to 240, inclusive
+ *
+ * For 10-bit-depth formats:
+ * Luma (Y) samples should range from 64 to 940, inclusive
+ * Chroma (Cb, Cr) samples should range from 64 to 960, inclusive
+ */
+ RANGE_LIMITED = 2 << 27, // 2 << RANGE_SHIFT = 0x10000000
+
+ /**
+ * Extended range is used for scRGB. Intended for use with
+ * floating point pixel formats. [0.0 - 1.0] is the standard
+ * sRGB space. Values outside the range 0.0 - 1.0 can encode
+ * color outside the sRGB gamut.
+ * Used to blend / merge multiple dataspaces on a single display.
+ */
+ RANGE_EXTENDED = 3 << 27, // 3 << RANGE_SHIFT = 0x18000000
+
+ /**
* scRGB linear encoding:
*
* The red, green, and blue components are stored in extended sRGB space,
@@ -112,6 +452,33 @@
ADATASPACE_ADOBE_RGB = 151715840, // STANDARD_ADOBE_RGB | TRANSFER_GAMMA2_2 | RANGE_FULL
/**
+ * JPEG File Interchange Format (JFIF)
+ *
+ * Same model as BT.601-625, but all values (Y, Cb, Cr) range from 0 to 255
+ *
+ * Use full range, SMPTE 170M transfer and BT.601_625 standard.
+ */
+ ADATASPACE_JFIF = 146931712, // STANDARD_BT601_625 | TRANSFER_SMPTE_170M | RANGE_FULL
+
+ /**
+ * ITU-R Recommendation 601 (BT.601) - 525-line
+ *
+ * Standard-definition television, 525 Lines (NTSC)
+ *
+ * Use limited range, SMPTE 170M transfer and BT.601_525 standard.
+ */
+ ADATASPACE_BT601_625 = 281149440, // STANDARD_BT601_625 | TRANSFER_SMPTE_170M | RANGE_LIMITED
+
+ /**
+ * ITU-R Recommendation 709 (BT.709)
+ *
+ * High-definition television
+ *
+ * Use limited range, SMPTE 170M transfer and BT.709 standard.
+ */
+ ADATASPACE_BT601_525 = 281280512, // STANDARD_BT601_525 | TRANSFER_SMPTE_170M | RANGE_LIMITED
+
+ /**
* ITU-R Recommendation 2020 (BT.2020)
*
* Ultra High-definition television