[babl] extensions: add single to/from half float extension
- From: Øyvind Kolås <ok src gnome org>
- To: commits-list gnome org
- Cc:
- Subject: [babl] extensions: add single to/from half float extension
- Date: Sat, 16 Jan 2016 11:16:36 +0000 (UTC)
commit 7c1d2df8ac4aa8022039189686de883599c18b84
Author: Øyvind Kolås <pippin gimp org>
Date: Sat Jan 16 12:07:21 2016 +0100
extensions: add single to/from half float extension
extensions/Makefile.am | 2 +
extensions/float-half.c | 356 +++++++++++++++++++++++++++++++++++++++++++++++
2 files changed, 358 insertions(+), 0 deletions(-)
---
diff --git a/extensions/Makefile.am b/extensions/Makefile.am
index c06aa8f..839e0d2 100644
--- a/extensions/Makefile.am
+++ b/extensions/Makefile.am
@@ -17,6 +17,7 @@ extdir = $(libdir)/babl- BABL_API_VERSION@
ext_LTLIBRARIES = \
cairo.la \
CIE.la \
+ float-half.la \
gegl-fixups.la \
gggl-lies.la \
gggl.la \
@@ -39,6 +40,7 @@ ext_LTLIBRARIES = \
cairo_la_SOURCES = cairo.c cairo-tables.h
CIE_la_SOURCES = CIE.c
simple_la_SOURCES = simple.c
+float_half_la_SOURCES = float-half.c
gegl_fixups_la_SOURCES = gegl-fixups.c
gggl_lies_la_SOURCES = gggl-lies.c
gggl_la_SOURCES = gggl.c
diff --git a/extensions/float-half.c b/extensions/float-half.c
new file mode 100644
index 0000000..ff37625
--- /dev/null
+++ b/extensions/float-half.c
@@ -0,0 +1,356 @@
+/* babl - dynamically extendable universal pixel conversion library.
+ * Copyright (C) 2015 Daniel Sabo
+ * 2016 Øyvind Kolås
+ *
+ * This library is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU Lesser General Public
+ * License as published by the Free Software Foundation; either
+ * version 3 of the License, or (at your option) any later version.
+ *
+ * This library is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ * Lesser General Public License for more details.
+ *
+ * You should have received a copy of the GNU Lesser General
+ * Public License along with this library; if not, see
+ * <http://www.gnu.org/licenses/>.
+ */
+
+/* Copyright: (c) 2009 by James Tursa, All Rights Reserved
+ *
+ * This code uses the BSD License:
+ *
+ * Redistribution and use in source and binary forms, with or without
+ * modification, are permitted provided that the following conditions are
+ * met:
+ *
+ * * Redistributions of source code must retain the above copyright
+ * notice, this list of conditions and the following disclaimer.
+ * * Redistributions in binary form must reproduce the above copyright
+ * notice, this list of conditions and the following disclaimer in
+ * the documentation and/or other materials provided with the distribution
+ *
+ * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
+ * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+ * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
+ * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
+ * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
+ * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
+ * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
+ * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
+ * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
+ * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
+ * POSSIBILITY OF SUCH DAMAGE.
+ *
+ * halfprecision converts the input argument to/from a half precision floating
+ * point bit pattern corresponding to IEEE 754r. The bit pattern is stored in a
+ * uint16 class variable. Please note that halfprecision is *not* a class. That
+ * is, you cannot do any arithmetic with the half precision bit patterns.
+ * halfprecision is simply a function that converts the IEEE 754r half precision
+ * bit pattern to/from other numeric MATLAB variables. You can, however, take
+ * the half precision bit patterns, convert them to single or double, do the
+ * operation, and then convert the result back manually.
+ *
+ * 1 bit sign bit
+ * 5 bits exponent, biased by 15
+ * 10 bits mantissa, hidden leading bit, normalized to 1.0
+ *
+ * Special floating point bit patterns recognized and supported:
+ *
+ * All exponent bits zero:
+ * - If all mantissa bits are zero, then number is zero (possibly signed)
+ * - Otherwise, number is a denormalized bit pattern
+ *
+ * All exponent bits set to 1:
+ * - If all mantissa bits are zero, then number is +Infinity or -Infinity
+ * - Otherwise, number is NaN (Not a Number)
+ */
+
+#include "config.h"
+
+#include <stdint.h>
+#include <stdlib.h>
+
+#include "babl.h"
+#include "extensions/util.h"
+
+static void halfp2singles(void *target, const void *source, long numel)
+{
+ uint16_t *hp = (uint16_t *) source; // Type pun input as an unsigned 16-bit int
+ uint32_t *xp = (uint32_t *) target; // Type pun output as an unsigned 32-bit int
+ uint16_t h, hs, he, hm;
+ uint32_t xs, xe, xm;
+ int32_t xes;
+ int e;
+
+ if( source == NULL || target == NULL ) // Nothing to convert (e.g., imag part of pure real)
+ return;
+ while( numel-- ) {
+ h = *hp++;
+ if( (h & 0x7FFFu) == 0 ) { // Signed zero
+ *xp++ = ((uint32_t) h) << 16; // Return the signed zero
+ } else { // Not zero
+ hs = h & 0x8000u; // Pick off sign bit
+ he = h & 0x7C00u; // Pick off exponent bits
+ hm = h & 0x03FFu; // Pick off mantissa bits
+ if( he == 0 ) { // Denormal will convert to normalized
+ e = -1; // The following loop figures out how much extra to adjust the exponent
+ do {
+ e++;
+ hm <<= 1;
+ } while( (hm & 0x0400u) == 0 ); // Shift until leading bit overflows into exponent bit
+ xs = ((uint32_t) hs) << 16; // Sign bit
+ xes = ((int32_t) (he >> 10)) - 15 + 127 - e; // Exponent unbias the halfp, then bias the
single
+ xe = (uint32_t) (xes << 23); // Exponent
+ xm = ((uint32_t) (hm & 0x03FFu)) << 13; // Mantissa
+ *xp++ = (xs | xe | xm); // Combine sign bit, exponent bits, and mantissa bits
+ } else if( he == 0x7C00u ) { // Inf or NaN (all the exponent bits are set)
+ if( hm == 0 ) { // If mantissa is zero ...
+ *xp++ = (((uint32_t) hs) << 16) | ((uint32_t) 0x7F800000u); // Signed Inf
+ } else {
+ *xp++ = (uint32_t) 0xFFC00000u; // NaN, only 1st mantissa bit set
+ }
+ } else { // Normalized number
+ xs = ((uint32_t) hs) << 16; // Sign bit
+ xes = ((int32_t) (he >> 10)) - 15 + 127; // Exponent unbias the halfp, then bias the single
+ xe = (uint32_t) (xes << 23); // Exponent
+ xm = ((uint32_t) hm) << 13; // Mantissa
+ *xp++ = (xs | xe | xm); // Combine sign bit, exponent bits, and mantissa bits
+ }
+ }
+ }
+}
+
+static void singles2halfp(void *target, const void *source, long numel)
+{
+ uint16_t *hp = (uint16_t *) target; // Type pun output as an unsigned 16-bit int
+ uint32_t *xp = (uint32_t *) source; // Type pun input as an unsigned 32-bit int
+ uint16_t hs, he, hm;
+ uint32_t x, xs, xe, xm;
+ int hes;
+
+ if( source == NULL || target == NULL ) { // Nothing to convert (e.g., imag part of pure real)
+ return;
+ }
+ while( numel-- ) {
+ x = *xp++;
+ if( (x & 0x7FFFFFFFu) == 0 ) { // Signed zero
+ *hp++ = (uint16_t) (x >> 16); // Return the signed zero
+ } else { // Not zero
+ xs = x & 0x80000000u; // Pick off sign bit
+ xe = x & 0x7F800000u; // Pick off exponent bits
+ xm = x & 0x007FFFFFu; // Pick off mantissa bits
+ if( xe == 0 ) { // Denormal will underflow, return a signed zero
+ *hp++ = (uint16_t) (xs >> 16);
+ } else if( xe == 0x7F800000u ) { // Inf or NaN (all the exponent bits are set)
+ if( xm == 0 ) { // If mantissa is zero ...
+ *hp++ = (uint16_t) ((xs >> 16) | 0x7C00u); // Signed Inf
+ } else {
+ *hp++ = (uint16_t) 0xFE00u; // NaN, only 1st mantissa bit set
+ }
+ } else { // Normalized number
+ hs = (uint16_t) (xs >> 16); // Sign bit
+ hes = ((int)(xe >> 23)) - 127 + 15; // Exponent unbias the single, then bias the halfp
+ if( hes >= 0x1F ) { // Overflow
+ *hp++ = (uint16_t) ((xs >> 16) | 0x7C00u); // Signed Inf
+ } else if( hes <= 0 ) { // Underflow
+ if( (14 - hes) > 24 ) { // Mantissa shifted all the way off & no rounding possibility
+ hm = (uint16_t) 0u; // Set mantissa to zero
+ } else {
+ xm |= 0x00800000u; // Add the hidden leading bit
+ hm = (uint16_t) (xm >> (14 - hes)); // Mantissa
+ if( (xm >> (13 - hes)) & 0x00000001u ) // Check for rounding
+ hm += (uint16_t) 1u; // Round, might overflow into exp bit, but this is OK
+ }
+ *hp++ = (hs | hm); // Combine sign bit and mantissa bits, biased exponent is zero
+ } else {
+ he = (uint16_t) (hes << 10); // Exponent
+ hm = (uint16_t) (xm >> 13); // Mantissa
+ if( xm & 0x00001000u ) // Check for rounding
+ *hp++ = (hs | he | hm) + (uint16_t) 1u; // Round, might overflow to inf, this is OK
+ else
+ *hp++ = (hs | he | hm); // No rounding
+ }
+ }
+ }
+ }
+}
+
+static inline long
+conv_yHalf_yF (const uint16_t *src, float *dst, long samples)
+{
+ halfp2singles(dst, src, samples);
+ return samples;
+}
+
+static long
+conv_yaHalf_yaF (const uint16_t *src, float *dst, long samples)
+{
+ return conv_yHalf_yF (src, dst, samples * 2) / 2;
+}
+
+static long
+conv_rgbHalf_rgbF (const uint16_t *src, float *dst, long samples)
+{
+ return conv_yHalf_yF (src, dst, samples * 3) / 3;
+}
+
+static long
+conv_rgbaHalf_rgbaF (const uint16_t *src, float *dst, long samples)
+{
+ return conv_yHalf_yF (src, dst, samples * 4) / 4;
+}
+
+static inline long
+conv_yF_yHalf (const float *src, uint16_t *dst, long samples)
+{
+ singles2halfp (dst, src, samples);
+ return samples;
+}
+
+static long
+conv_yaF_yaHalf (const float *src, uint16_t *dst, long samples)
+{
+ return conv_yF_yHalf (src, dst, samples * 2) / 2;
+}
+
+static long
+conv_rgbF_rgbHalf (const float *src, uint16_t *dst, long samples)
+{
+ return conv_yF_yHalf (src, dst, samples * 3) / 3;
+}
+
+static long
+conv_rgbaF_rgbaHalf (const float *src, uint16_t *dst, long samples)
+{
+ return conv_yF_yHalf (src, dst, samples * 4) / 4;
+}
+
+int init (void);
+
+int
+init (void)
+{
+ const Babl *rgbaF_linear = babl_format_new (
+ babl_model ("RGBA"),
+ babl_type ("float"),
+ babl_component ("R"),
+ babl_component ("G"),
+ babl_component ("B"),
+ babl_component ("A"),
+ NULL);
+ const Babl *rgbaHalf_linear = babl_format_new (
+ babl_model ("RGBA"),
+ babl_type ("half"),
+ babl_component ("R"),
+ babl_component ("G"),
+ babl_component ("B"),
+ babl_component ("A"),
+ NULL);
+ const Babl *rgbaF_gamma = babl_format_new (
+ babl_model ("R'G'B'A"),
+ babl_type ("float"),
+ babl_component ("R'"),
+ babl_component ("G'"),
+ babl_component ("B'"),
+ babl_component ("A"),
+ NULL);
+ const Babl *rgbaHalf_gamma = babl_format_new (
+ babl_model ("R'G'B'A"),
+ babl_type ("half"),
+ babl_component ("R'"),
+ babl_component ("G'"),
+ babl_component ("B'"),
+ babl_component ("A"),
+ NULL);
+ const Babl *rgbF_linear = babl_format_new (
+ babl_model ("RGB"),
+ babl_type ("float"),
+ babl_component ("R"),
+ babl_component ("G"),
+ babl_component ("B"),
+ NULL);
+ const Babl *rgbHalf_linear = babl_format_new (
+ babl_model ("RGB"),
+ babl_type ("half"),
+ babl_component ("R"),
+ babl_component ("G"),
+ babl_component ("B"),
+ NULL);
+ const Babl *rgbF_gamma = babl_format_new (
+ babl_model ("R'G'B'"),
+ babl_type ("float"),
+ babl_component ("R'"),
+ babl_component ("G'"),
+ babl_component ("B'"),
+ NULL);
+ const Babl *rgbHalf_gamma = babl_format_new (
+ babl_model ("R'G'B'"),
+ babl_type ("half"),
+ babl_component ("R'"),
+ babl_component ("G'"),
+ babl_component ("B'"),
+ NULL);
+ const Babl *yaF_linear = babl_format_new (
+ babl_model ("YA"),
+ babl_type ("float"),
+ babl_component ("Y"),
+ babl_component ("A"),
+ NULL);
+ const Babl *yaHalf_linear = babl_format_new (
+ babl_model ("YA"),
+ babl_type ("half"),
+ babl_component ("Y"),
+ babl_component ("A"),
+ NULL);
+ const Babl *yaF_gamma = babl_format_new (
+ babl_model ("Y'A"),
+ babl_type ("float"),
+ babl_component ("Y'"),
+ babl_component ("A"),
+ NULL);
+ const Babl *yaHalf_gamma = babl_format_new (
+ babl_model ("Y'A"),
+ babl_type ("half"),
+ babl_component ("Y'"),
+ babl_component ("A"),
+ NULL);
+ const Babl *yF_linear = babl_format_new (
+ babl_model ("Y"),
+ babl_type ("float"),
+ babl_component ("Y"),
+ NULL);
+ const Babl *yHalf_linear = babl_format_new (
+ babl_model ("Y"),
+ babl_type ("half"),
+ babl_component ("Y"),
+ NULL);
+ const Babl *yF_gamma = babl_format_new (
+ babl_model ("Y'"),
+ babl_type ("float"),
+ babl_component ("Y'"),
+ NULL);
+ const Babl *yHalf_gamma = babl_format_new (
+ babl_model ("Y'"),
+ babl_type ("half"),
+ babl_component ("Y'"),
+ NULL);
+
+#define CONV(src, dst) \
+{ \
+ babl_conversion_new (src ## _linear, dst ## _linear, "linear", conv_ ## src ## _ ## dst, NULL); \
+ babl_conversion_new (src ## _gamma, dst ## _gamma, "linear", conv_ ## src ## _ ## dst, NULL); \
+}
+
+ CONV(rgbaHalf, rgbaF);
+ CONV(rgbHalf, rgbF);
+ CONV(yaHalf, yaF);
+ CONV(yHalf, yF);
+ CONV(rgbaF, rgbaHalf);
+ CONV(rgbF, rgbHalf);
+ CONV(yaF, yaHalf);
+ CONV(yF, yHalf);
+
+ return 0;
+}
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