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-rw-r--r--src/im_convertcolor.cpp883
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diff --git a/src/im_convertcolor.cpp b/src/im_convertcolor.cpp
new file mode 100644
index 0000000..4068b94
--- /dev/null
+++ b/src/im_convertcolor.cpp
@@ -0,0 +1,883 @@
+/** \file
+ * \brief Image Conversion
+ *
+ * See Copyright Notice in im_lib.h
+ * $Id: im_convertcolor.cpp,v 1.1 2008/10/17 06:10:16 scuri Exp $
+ */
+
+#include "im.h"
+#include "im_util.h"
+#include "im_complex.h"
+#include "im_image.h"
+#include "im_convert.h"
+#include "im_color.h"
+#include "im_counter.h"
+
+#include <stdlib.h>
+#include <assert.h>
+#include <memory.h>
+
+void imConvertMapToRGB(unsigned char* data, int count, int depth, int packed, long* palette, int palette_count)
+{
+ int c, i, delta;
+ unsigned char r[256], g[256], b[256];
+ unsigned char *r_data, *g_data, *b_data;
+
+ unsigned char* src_data = data + count-1;
+ if (packed)
+ {
+ r_data = data + depth*(count-1);
+ g_data = r_data + 1;
+ b_data = r_data + 2;
+ delta = depth;
+ }
+ else
+ {
+ r_data = data + count - 1;
+ g_data = data + 2*count - 1;
+ b_data = data + 3*count - 1;
+ delta = 1;
+ }
+
+ for (c = 0; c < palette_count; c++)
+ imColorDecode(&r[c], &g[c], &b[c], palette[c]);
+
+ for (i = 0; i < count; i++)
+ {
+ int index = *src_data;
+ *r_data = r[index];
+ *g_data = g[index];
+ *b_data = b[index];
+
+ r_data -= delta;
+ g_data -= delta;
+ b_data -= delta;
+ src_data--;
+ }
+}
+
+// convert bin2gray and gray2bin
+inline void iConvertBinary(imbyte* map, int count, imbyte value)
+{
+ imbyte thres = (value == 255)? 1: 128;
+
+ // if gray2bin, check for invalid gray that already is binary
+ if (value != 255)
+ {
+ imbyte vmax = 0, *pmap = map;
+ for (int i = 0; i < count; i++)
+ {
+ if (*pmap > vmax)
+ vmax = *pmap;
+
+ pmap++;
+ }
+
+ if (vmax == 1)
+ thres = 1;
+ else
+ thres = vmax / 2;
+ }
+
+ for (int i = 0; i < count; i++)
+ {
+ if (*map >= thres)
+ *map = value;
+ else
+ *map = 0;
+
+ map++;
+ }
+}
+
+static void iConvertMap2Gray(const imbyte* src_map, imbyte* dst_map, int count, const long* palette, const int palette_count)
+{
+ imbyte r, g, b;
+ imbyte remap[256];
+
+ for (int c = 0; c < palette_count; c++)
+ {
+ imColorDecode(&r, &g, &b, palette[c]);
+ remap[c] = imColorRGB2Luma(r, g, b);
+ }
+
+ for (int i = 0; i < count; i++)
+ {
+ *dst_map++ = remap[*src_map++];
+ }
+}
+
+static void iConvertMapToRGB(const imbyte* src_map, imbyte* red, imbyte* green, imbyte* blue, int count, const long* palette, const int palette_count)
+{
+ imbyte r[256], g[256], b[256];
+ for (int c = 0; c < palette_count; c++)
+ imColorDecode(&r[c], &g[c], &b[c], palette[c]);
+
+ for (int i = 0; i < count; i++)
+ {
+ int index = *src_map++;
+ *red++ = r[index];
+ *green++ = g[index];
+ *blue++ = b[index];
+ }
+}
+
+template <class T>
+int iDoConvert2Gray(int count, int data_type,
+ const T** src_data, int src_color_space, T** dst_data, int counter)
+{
+ int i;
+ T max;
+
+ const T* src_map0 = src_data[0];
+ const T* src_map1 = src_data[1];
+ const T* src_map2 = src_data[2];
+ const T* src_map3 = (src_color_space == IM_CMYK)? src_data[3]: 0;
+ T* dst_map = dst_data[0];
+
+ imCounterTotal(counter, count, "Converting To Gray...");
+
+ switch(src_color_space)
+ {
+ case IM_XYZ:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // scale to 0-1
+ float c1 = imColorReconstruct(*src_map1++, max); // use only Y component
+
+ // do gamma correction then scale back to 0-max
+ *dst_map++ = imColorQuantize(imColorTransfer2Nonlinear(c1), max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_CMYK:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ T r, g, b;
+ // result is still 0-max
+ imColorCMYK2RGB(*src_map0++, *src_map1++, *src_map2++, *src_map3++, r, g, b, max);
+ *dst_map++ = imColorRGB2Luma(r, g, b);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_RGB:
+ for (i = 0; i < count; i++)
+ {
+ *dst_map++ = imColorRGB2Luma(*src_map0++, *src_map1++, *src_map2++);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_LUV:
+ case IM_LAB:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+
+ float c0 = imColorReconstruct(*src_map0++, max); // scale to 0-1
+ c0 = imColorLightness2Luminance(c0); // do the convertion
+
+ // do gamma correction then scale back to 0-max
+ *dst_map++ = imColorQuantize(imColorTransfer2Nonlinear(c0), max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ default:
+ return IM_ERR_DATA;
+ }
+
+ return IM_ERR_NONE;
+}
+
+template <class T>
+int iDoConvert2RGB(int count, int data_type,
+ const T** src_data, int src_color_space, T** dst_data, int counter)
+{
+ int i;
+ T max, zero;
+
+ const T* src_map0 = src_data[0];
+ const T* src_map1 = src_data[1];
+ const T* src_map2 = src_data[2];
+ const T* src_map3 = (src_color_space == IM_CMYK)? src_data[3]: 0;
+ T* dst_map0 = dst_data[0];
+ T* dst_map1 = dst_data[1];
+ T* dst_map2 = dst_data[2];
+
+ imCounterTotal(counter, count, "Converting To RGB...");
+
+ switch(src_color_space)
+ {
+ case IM_XYZ:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+
+ // scale to 0-1
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max);
+ float c2 = imColorReconstruct(*src_map2++, max);
+
+ // result is still 0-1
+ imColorXYZ2RGB(c0, c1, c2,
+ c0, c1, c2, 1.0f);
+
+ // do gamma correction then scale back to 0-max
+ *dst_map0++ = imColorQuantize(imColorTransfer2Nonlinear(c0), max);
+ *dst_map1++ = imColorQuantize(imColorTransfer2Nonlinear(c1), max);
+ *dst_map2++ = imColorQuantize(imColorTransfer2Nonlinear(c2), max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_YCBCR:
+ max = (T)imColorMax(data_type);
+ zero = (T)imColorZero(data_type);
+ for (i = 0; i < count; i++)
+ {
+ imColorYCbCr2RGB(*src_map0++, *src_map1++, *src_map2++,
+ *dst_map0++, *dst_map1++, *dst_map2++, zero, max);
+ }
+ break;
+ case IM_CMYK:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // result is still 0-max
+ imColorCMYK2RGB(*src_map0++, *src_map1++, *src_map2++, *src_map3++,
+ *dst_map0++, *dst_map1++, *dst_map2++, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_LUV:
+ case IM_LAB:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+
+ // scale to 0-1 and -0.5/+0.5
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max) - 0.5f;
+ float c2 = imColorReconstruct(*src_map2++, max) - 0.5f;
+
+ if (src_color_space == IM_LUV)
+ imColorLuv2XYZ(c0, c1, c2, // conversion in-place
+ c0, c1, c2);
+ else
+ imColorLab2XYZ(c0, c1, c2, // conversion in-place
+ c0, c1, c2);
+
+ imColorXYZ2RGB(c0, c1, c2, // conversion in-place
+ c0, c1, c2, 1.0f);
+
+ // do gamma correction then scale back to 0-max
+ *dst_map0++ = imColorQuantize(imColorTransfer2Nonlinear(c0), max);
+ *dst_map1++ = imColorQuantize(imColorTransfer2Nonlinear(c1), max);
+ *dst_map2++ = imColorQuantize(imColorTransfer2Nonlinear(c2), max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ default:
+ return IM_ERR_DATA;
+ }
+
+ return IM_ERR_NONE;
+}
+
+template <class T>
+int iDoConvert2YCbCr(int count, int data_type,
+ const T** src_data, int src_color_space, T** dst_data, int counter)
+{
+ int i;
+ T zero;
+
+ const T* src_map0 = src_data[0];
+ const T* src_map1 = src_data[1];
+ const T* src_map2 = src_data[2];
+ T* dst_map0 = dst_data[0];
+ T* dst_map1 = dst_data[1];
+ T* dst_map2 = dst_data[2];
+
+ imCounterTotal(counter, count, "Converting To YCbCr...");
+
+ switch(src_color_space)
+ {
+ case IM_RGB:
+ zero = (T)imColorZero(data_type);
+ for (i = 0; i < count; i++)
+ {
+ imColorRGB2YCbCr(*src_map0++, *src_map1++, *src_map2++,
+ *dst_map0++, *dst_map1++, *dst_map2++, zero);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ default:
+ return IM_ERR_DATA;
+ }
+
+ return IM_ERR_NONE;
+}
+
+template <class T>
+int iDoConvert2XYZ(int count, int data_type,
+ const T** src_data, int src_color_space, T** dst_data, int counter)
+{
+ int i;
+ T max;
+
+ const T* src_map0 = src_data[0];
+ const T* src_map1 = (src_color_space == IM_GRAY)? 0: src_data[1];
+ const T* src_map2 = (src_color_space == IM_GRAY)? 0: src_data[2];
+ T* dst_map0 = dst_data[0];
+ T* dst_map1 = dst_data[1];
+ T* dst_map2 = dst_data[2];
+
+ imCounterTotal(counter, count, "Converting To XYZ...");
+
+ switch(src_color_space)
+ {
+ case IM_GRAY:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // scale to 0-1
+ float c0 = imColorReconstruct(*src_map0++, max);
+
+ // do gamma correction
+ c0 = imColorTransfer2Linear(c0);
+
+ // then scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0*0.9505f, max); // Compensate D65 white point
+ *dst_map1++ = imColorQuantize(c0, max);
+ *dst_map2++ = imColorQuantize(c0*1.0890f, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_RGB:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+
+ // scale to 0-1
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max);
+ float c2 = imColorReconstruct(*src_map2++, max);
+
+ // do gamma correction
+ c0 = imColorTransfer2Linear(c0);
+ c1 = imColorTransfer2Linear(c1);
+ c2 = imColorTransfer2Linear(c2);
+
+ // result is still 0-1
+ imColorRGB2XYZ(c0, c1, c2,
+ c0, c1, c2);
+
+ // then scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max);
+ *dst_map1++ = imColorQuantize(c1, max);
+ *dst_map2++ = imColorQuantize(c2, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_LUV:
+ case IM_LAB:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+ // scale to 0-1 and -0.5/+0.5
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max) - 0.5f;
+ float c2 = imColorReconstruct(*src_map2++, max) - 0.5f;
+
+ if (src_color_space == IM_LUV)
+ imColorLuv2XYZ(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+ else
+ imColorLab2XYZ(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+
+ // scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max);
+ *dst_map1++ = imColorQuantize(c1, max);
+ *dst_map2++ = imColorQuantize(c2, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ default:
+ return IM_ERR_DATA;
+ }
+
+ return IM_ERR_NONE;
+}
+
+template <class T>
+int iDoConvert2Lab(int count, int data_type,
+ const T** src_data, int src_color_space, T** dst_data, int counter)
+{
+ int i;
+ T max;
+
+ const T* src_map0 = src_data[0];
+ const T* src_map1 = (src_color_space == IM_GRAY)? 0: src_data[1];
+ const T* src_map2 = (src_color_space == IM_GRAY)? 0: src_data[2];
+ T* dst_map0 = dst_data[0];
+ T* dst_map1 = dst_data[1];
+ T* dst_map2 = dst_data[2];
+
+ imCounterTotal(counter, count, "Converting To Lab...");
+
+ switch(src_color_space)
+ {
+ case IM_GRAY:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // scale to 0-1
+ float c0 = imColorReconstruct(*src_map0++, max);
+
+ // do gamma correction
+ c0 = imColorTransfer2Linear(c0);
+
+ // do conversion
+ c0 = imColorLuminance2Lightness(c0);
+
+ // then scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max); // update only the L component
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_RGB:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+
+ // scale to 0-1
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max);
+ float c2 = imColorReconstruct(*src_map2++, max);
+
+ // do gamma correction
+ c0 = imColorTransfer2Linear(c0);
+ c1 = imColorTransfer2Linear(c1);
+ c2 = imColorTransfer2Linear(c2);
+
+ imColorRGB2XYZ(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+
+ imColorXYZ2Lab(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+
+ // then scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max);
+ *dst_map1++ = imColorQuantize(c1 + 0.5f, max);
+ *dst_map2++ = imColorQuantize(c2 + 0.5f, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_XYZ:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+ // scale to 0-1 and -0.5/+0.5
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max);
+ float c2 = imColorReconstruct(*src_map2++, max);
+
+ imColorXYZ2Lab(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+
+ // scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max);
+ *dst_map1++ = imColorQuantize(c1 + 0.5f, max);
+ *dst_map2++ = imColorQuantize(c2 + 0.5f, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_LUV:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+ // scale to 0-1 and -0.5/+0.5
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max) - 0.5f;
+ float c2 = imColorReconstruct(*src_map2++, max) - 0.5f;
+
+ imColorLuv2XYZ(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+ imColorXYZ2Lab(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+
+ // scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max);
+ *dst_map1++ = imColorQuantize(c1 + 0.5f, max);
+ *dst_map2++ = imColorQuantize(c2 + 0.5f, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ default:
+ return IM_ERR_DATA;
+ }
+
+ return IM_ERR_NONE;
+}
+
+template <class T>
+int iDoConvert2Luv(int count, int data_type,
+ const T** src_data, int src_color_space, T** dst_data, int counter)
+{
+ int i;
+ T max;
+
+ const T* src_map0 = src_data[0];
+ const T* src_map1 = (src_color_space == IM_GRAY)? 0: src_data[1];
+ const T* src_map2 = (src_color_space == IM_GRAY)? 0: src_data[2];
+ T* dst_map0 = dst_data[0];
+ T* dst_map1 = dst_data[1];
+ T* dst_map2 = dst_data[2];
+
+ imCounterTotal(counter, count, "Converting To Luv...");
+
+ switch(src_color_space)
+ {
+ case IM_GRAY:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // scale to 0-1
+ float c0 = imColorReconstruct(*src_map0++, max);
+
+ // do gamma correction
+ c0 = imColorTransfer2Linear(c0);
+
+ // do conversion
+ c0 = imColorLuminance2Lightness(c0);
+
+ // then scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max); // update only the L component
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_RGB:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+
+ // scale to 0-1
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max);
+ float c2 = imColorReconstruct(*src_map2++, max);
+
+ // do gamma correction
+ c0 = imColorTransfer2Linear(c0);
+ c1 = imColorTransfer2Linear(c1);
+ c2 = imColorTransfer2Linear(c2);
+
+ imColorRGB2XYZ(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+
+ imColorXYZ2Luv(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+
+ // then scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max);
+ *dst_map1++ = imColorQuantize(c1 + 0.5f, max);
+ *dst_map2++ = imColorQuantize(c2 + 0.5f, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_XYZ:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+ // scale to 0-1 and -0.5/+0.5
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max);
+ float c2 = imColorReconstruct(*src_map2++, max);
+
+ imColorXYZ2Luv(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+
+ // scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max);
+ *dst_map1++ = imColorQuantize(c1 + 0.5f, max);
+ *dst_map2++ = imColorQuantize(c2 + 0.5f, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ case IM_LAB:
+ max = (T)imColorMax(data_type);
+ for (i = 0; i < count; i++)
+ {
+ // to increase precision do intermediate conversions in float
+ // scale to 0-1 and -0.5/+0.5
+ float c0 = imColorReconstruct(*src_map0++, max);
+ float c1 = imColorReconstruct(*src_map1++, max) - 0.5f;
+ float c2 = imColorReconstruct(*src_map2++, max) - 0.5f;
+
+ imColorLab2XYZ(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+ imColorXYZ2Luv(c0, c1, c2, // convertion in-place
+ c0, c1, c2);
+
+ // scale back to 0-max
+ *dst_map0++ = imColorQuantize(c0, max);
+ *dst_map1++ = imColorQuantize(c1 + 0.5f, max);
+ *dst_map2++ = imColorQuantize(c2 + 0.5f, max);
+
+ if (!imCounterInc(counter))
+ return IM_ERR_COUNTER;
+ }
+ break;
+ default:
+ return IM_ERR_DATA;
+ }
+
+ return IM_ERR_NONE;
+}
+
+template <class T>
+int iDoConvertColorSpace(int count, int data_type,
+ const T** src_data, int src_color_space,
+ T** dst_data, int dst_color_space)
+{
+ int ret = IM_ERR_DATA,
+ convert2rgb = 0;
+
+ if ((dst_color_space == IM_XYZ ||
+ dst_color_space == IM_LAB ||
+ dst_color_space == IM_LUV) &&
+ (src_color_space == IM_CMYK ||
+ src_color_space == IM_YCBCR))
+ {
+ convert2rgb = 1;
+ }
+
+ if (dst_color_space == IM_YCBCR && src_color_space != IM_RGB)
+ convert2rgb = 1;
+
+ int counter = imCounterBegin("Convert Color Space");
+
+ if (convert2rgb)
+ {
+ ret = iDoConvert2RGB(count, data_type, src_data, src_color_space, dst_data, counter);
+
+ if (ret != IM_ERR_NONE)
+ {
+ imCounterEnd(counter);
+ return ret;
+ }
+
+ src_data = (const T**)dst_data;
+ src_color_space = IM_RGB;
+ }
+
+ switch(dst_color_space)
+ {
+ case IM_GRAY:
+ ret = iDoConvert2Gray(count, data_type, src_data, src_color_space, dst_data, counter);
+ break;
+ case IM_RGB:
+ ret = iDoConvert2RGB(count, data_type, src_data, src_color_space, dst_data, counter);
+ break;
+ case IM_YCBCR:
+ ret = iDoConvert2YCbCr(count, data_type, src_data, src_color_space, dst_data, counter);
+ break;
+ case IM_XYZ:
+ ret = iDoConvert2XYZ(count, data_type, src_data, src_color_space, dst_data, counter);
+ break;
+ case IM_LAB:
+ ret = iDoConvert2Lab(count, data_type, src_data, src_color_space, dst_data, counter);
+ break;
+ case IM_LUV:
+ ret = iDoConvert2Luv(count, data_type, src_data, src_color_space, dst_data, counter);
+ break;
+ default:
+ ret = IM_ERR_DATA;
+ break;
+ }
+
+ imCounterEnd(counter);
+
+ return ret;
+}
+
+static int iConvertColorSpace(const imImage* src_image, imImage* dst_image)
+{
+ switch(src_image->data_type)
+ {
+ case IM_BYTE:
+ return iDoConvertColorSpace(src_image->count, src_image->data_type,
+ (const imbyte**)src_image->data, src_image->color_space,
+ (imbyte**)dst_image->data, dst_image->color_space);
+ case IM_USHORT:
+ return iDoConvertColorSpace(src_image->count, src_image->data_type,
+ (const imushort**)src_image->data, src_image->color_space,
+ (imushort**)dst_image->data, dst_image->color_space);
+ case IM_INT:
+ return iDoConvertColorSpace(src_image->count, src_image->data_type,
+ (const int**)src_image->data, src_image->color_space,
+ (int**)dst_image->data, dst_image->color_space);
+ case IM_FLOAT:
+ return iDoConvertColorSpace(src_image->count, src_image->data_type,
+ (const float**)src_image->data, src_image->color_space,
+ (float**)dst_image->data, dst_image->color_space);
+ case IM_CFLOAT:
+ /* treat complex as two real values */
+ return iDoConvertColorSpace(2*src_image->count, src_image->data_type,
+ (const float**)src_image->data, src_image->color_space,
+ (float**)dst_image->data, dst_image->color_space);
+ }
+
+ return IM_ERR_DATA;
+}
+
+int imConvertColorSpace(const imImage* src_image, imImage* dst_image)
+{
+ assert(src_image);
+ assert(dst_image);
+
+ if (!imImageMatchDataType(src_image, dst_image))
+ return IM_ERR_DATA;
+
+ if (src_image->color_space == dst_image->color_space)
+ return IM_ERR_DATA;
+
+ switch(dst_image->color_space)
+ {
+ case IM_RGB:
+ switch(src_image->color_space)
+ {
+ case IM_BINARY:
+ memcpy(dst_image->data[0], src_image->data[0], dst_image->plane_size);
+ iConvertBinary((imbyte*)dst_image->data[0], dst_image->count, 255);
+ memcpy(dst_image->data[1], dst_image->data[0], dst_image->plane_size);
+ memcpy(dst_image->data[2], dst_image->data[0], dst_image->plane_size);
+ return IM_ERR_NONE;
+ case IM_MAP:
+ iConvertMapToRGB((imbyte*)src_image->data[0], (imbyte*)dst_image->data[0], (imbyte*)dst_image->data[1], (imbyte*)dst_image->data[2], dst_image->count, src_image->palette, src_image->palette_count);
+ return IM_ERR_NONE;
+ case IM_GRAY:
+ memcpy(dst_image->data[0], src_image->data[0], dst_image->plane_size);
+ memcpy(dst_image->data[1], src_image->data[0], dst_image->plane_size);
+ memcpy(dst_image->data[2], src_image->data[0], dst_image->plane_size);
+ return IM_ERR_NONE;
+ default:
+ return iConvertColorSpace(src_image, dst_image);
+ }
+ case IM_GRAY:
+ switch(src_image->color_space)
+ {
+ case IM_BINARY:
+ memcpy(dst_image->data[0], src_image->data[0], dst_image->size);
+ iConvertBinary((imbyte*)dst_image->data[0], dst_image->count, 255);
+ return IM_ERR_NONE;
+ case IM_MAP:
+ iConvertMap2Gray((imbyte*)src_image->data[0], (imbyte*)dst_image->data[0], dst_image->count, src_image->palette, src_image->palette_count);
+ return IM_ERR_NONE;
+ case IM_YCBCR:
+ memcpy(dst_image->data[0], src_image->data[0], dst_image->plane_size);
+ return IM_ERR_NONE;
+ default:
+ return iConvertColorSpace(src_image, dst_image);
+ }
+ case IM_MAP:
+ switch(src_image->color_space)
+ {
+ case IM_BINARY: // no break, same procedure as gray
+ case IM_GRAY:
+ memcpy(dst_image->data[0], src_image->data[0], dst_image->size);
+ dst_image->palette_count = src_image->palette_count;
+ memcpy(dst_image->palette, src_image->palette, dst_image->palette_count*sizeof(long));
+ return IM_ERR_NONE;
+ case IM_RGB:
+ dst_image->palette_count = 256;
+ return imConvertRGB2Map(src_image->width, src_image->height,
+ (imbyte*)src_image->data[0], (imbyte*)src_image->data[1], (imbyte*)src_image->data[2],
+ (imbyte*)dst_image->data[0], dst_image->palette, &dst_image->palette_count);
+ default:
+ return IM_ERR_DATA;
+ }
+ case IM_BINARY:
+ switch(src_image->color_space)
+ {
+ case IM_GRAY:
+ memcpy(dst_image->data[0], src_image->data[0], dst_image->size);
+ iConvertBinary((imbyte*)dst_image->data[0], dst_image->count, 1);
+ return IM_ERR_NONE;
+ case IM_MAP: // convert to gray, then convert to binary
+ iConvertMap2Gray((imbyte*)src_image->data[0], (imbyte*)dst_image->data[0], dst_image->count, src_image->palette, src_image->palette_count);
+ iConvertBinary((imbyte*)dst_image->data[0], dst_image->count, 1);
+ return IM_ERR_NONE;
+ case IM_YCBCR: // convert to gray, then convert to binary
+ memcpy(dst_image->data[0], src_image->data[0], dst_image->plane_size);
+ iConvertBinary((imbyte*)dst_image->data[0], dst_image->count, 1);
+ return IM_ERR_NONE;
+ default: // convert to gray, then convert to binary
+ {
+ dst_image->color_space = IM_GRAY;
+ int ret = iConvertColorSpace(src_image, dst_image);
+ dst_image->color_space = IM_BINARY;
+ if (ret != IM_ERR_NONE) return ret;
+ iConvertBinary((imbyte*)dst_image->data[0], dst_image->count, 1);
+ return IM_ERR_NONE;
+ }
+ }
+ case IM_YCBCR:
+ switch(src_image->color_space)
+ {
+ case IM_GRAY:
+ memcpy(dst_image->data[0], src_image->data[0], dst_image->plane_size);
+ return IM_ERR_NONE;
+ default:
+ return iConvertColorSpace(src_image, dst_image);
+ }
+ default:
+ return iConvertColorSpace(src_image, dst_image);
+ }
+}