1 files changed, 78 insertions, 83 deletions

diff --git a/src/gallium/drivers/cell/ppu/cell_gen_fragment.c b/src/gallium/drivers/cell/ppu/cell_gen_fragment.c
index 1837b4c79b..3b166e446d 100644
--- a/src/gallium/drivers/cell/ppu/cell_gen_fragment.c
+++ b/src/gallium/drivers/cell/ppu/cell_gen_fragment.c
@@ -971,87 +971,6 @@ gen_logicop(const struct pipe_blend_state *blend,
 }
 
 
-static void
-gen_colormask(uint colormask,
-              struct spe_function *f,
-              int fragRGBA_reg, int fbRGBA_reg)
-{
-   /* We've got four 32-bit RGBA packed pixels in each of
-    * fragRGBA_reg and fbRGBA_reg, not sets of floating-point
-    * reds, greens, blues, and alphas.
-    * */
-
-   /* The color mask operation can prevent any set of color
-    * components in the incoming fragment from being written to the frame 
-    * buffer; we do this by replacing the masked components of the 
-    * fragment with the frame buffer values.
-    *
-    * There are only 16 possibilities, with a unique mask for
-    * each of the possibilities.  (Technically, there are only 15
-    * possibilities, since we shouldn't be called for the one mask
-    * that does nothing, but the complete implementation is here
-    * anyway to avoid confusion.)
-    *
-    * We implement this via a constant static array which we'll index 
-    * into to get the correct mask.
-    * 
-    * We're dependent on the mask values being low-order bits,
-    * with particular values for each bit; so we start with a
-    * few assertions, which will fail if any of the values were
-    * to change.
-    */
-   ASSERT(PIPE_MASK_R == 0x1);
-   ASSERT(PIPE_MASK_G == 0x2);
-   ASSERT(PIPE_MASK_B == 0x4);
-   ASSERT(PIPE_MASK_A == 0x8);
-
-   /* Here's the list of all possible colormasks, indexed by the
-    * value of the combined mask specifier.
-    */
-   static const unsigned int colormasks[16] = {
-      0x00000000, /* 0: all colors masked */
-      0xff000000, /* 1: PIPE_MASK_R */
-      0x00ff0000, /* 2: PIPE_MASK_G */
-      0xffff0000, /* 3: PIPE_MASK_R | PIPE_MASK_G */
-      0x0000ff00, /* 4: PIPE_MASK_B */
-      0xff00ff00, /* 5: PIPE_MASK_R | PIPE_MASK_B */
-      0x00ffff00, /* 6: PIPE_MASK_G | PIPE_MASK_B */
-      0xffffff00, /* 7: PIPE_MASK_R | PIPE_MASK_G | PIPE_MASK_B */
-      0x000000ff, /* 8: PIPE_MASK_A */
-      0xff0000ff, /* 9: PIPE_MASK_R | PIPE_MASK_A */
-      0x00ff00ff, /* 10: PIPE_MASK_G | PIPE_MASK_A */
-      0xffff00ff, /* 11: PIPE_MASK_R | PIPE_MASK_G | PIPE_MASK_A */
-      0x0000ffff, /* 12: PIPE_MASK_B | PIPE_MASK_A */
-      0xff00ffff, /* 13: PIPE_MASK_R | PIPE_MASK_B | PIPE_MASK_A */
-      0x00ffffff, /* 14: PIPE_MASK_G | PIPE_MASK_B | PIPE_MASK_A */
-      0xffffffff  /* 15: PIPE_MASK_R | PIPE_MASK_G | PIPE_MASK_B | PIPE_MASK_A */
-   };
-
-   /* Get a temporary register to hold the mask */
-   int colormask_reg = spe_allocate_available_register(f);
-
-   /* Look up the desired mask directly and load it into the mask register.
-    * This will load the same mask into each of the four words in the
-    * mask register.
-    */
-   spe_load_uint(f, colormask_reg, colormasks[colormask]);
-
-   /* Use the mask register to select between the fragment color
-    * values and the frame buffer color values.  Wherever the
-    * mask has a 0 bit, the current frame buffer color should override
-    * the fragment color.  Wherever the mask has a 1 bit, the 
-    * fragment color should persevere.  The Select Bits (selb rt, rA, rB, rM)
-    * instruction will select bits from its first operand rA wherever the
-    * the mask bits rM are 0, and from its second operand rB wherever the
-    * mask bits rM are 1.  That means that the frame buffer color is the
-    * first operand, and the fragment color the second.
-    */
-    spe_selb(f, fragRGBA_reg, fbRGBA_reg, fragRGBA_reg, colormask_reg);
-
-    /* Release the temporary register and we're done */
-    spe_release_register(f, colormask_reg);
-}
-
 /**
  * Generate code to pack a quad of float colors into four 32-bit integers.
  *
@@ -1118,8 +1037,85 @@ gen_pack_colors(struct spe_function *f,
    spe_release_register(f, ba_reg);
 }
 
+static void
+gen_colormask(struct spe_function *f,
+              uint colormask,
+              enum pipe_format color_format,
+              int fragRGBA_reg, int fbRGBA_reg)
+{
+   /* We've got four 32-bit RGBA packed pixels in each of
+    * fragRGBA_reg and fbRGBA_reg, not sets of floating-point
+    * reds, greens, blues, and alphas.  Further, the pixels
+    * are packed according to the given color format, not
+    * necessarily RGBA...
+    */
+   unsigned int r_mask;
+   unsigned int g_mask;
+   unsigned int b_mask;
+   unsigned int a_mask;
+
+   /* Calculate exactly where the bits for any particular color
+    * end up, so we can mask them correctly.
+    */
+   switch(color_format) {
+      case PIPE_FORMAT_A8R8G8B8_UNORM:
+         /* ARGB */
+         a_mask = 0xff000000;
+         r_mask = 0x00ff0000;
+         g_mask = 0x0000ff00;
+         b_mask = 0x000000ff;
+         break;
+      case PIPE_FORMAT_B8G8R8A8_UNORM:
+         /* BGRA */
+         b_mask = 0xff000000;
+         g_mask = 0x00ff0000;
+         r_mask = 0x0000ff00;
+         a_mask = 0x000000ff;
+         break;
+      default:
+         ASSERT(0);
+   }
 
+   /* For each R, G, B, and A component we're supposed to mask out, 
+    * clear its bits.   Then our mask operation later will work 
+    * as expected.
+    */
+   if (!(colormask & PIPE_MASK_R)) {
+      r_mask = 0;
+   }
+   if (!(colormask & PIPE_MASK_G)) {
+      g_mask = 0;
+   }
+   if (!(colormask & PIPE_MASK_B)) {
+      b_mask = 0;
+   }
+   if (!(colormask & PIPE_MASK_A)) {
+      a_mask = 0;
+   }
+
+   /* Get a temporary register to hold the mask that will be applied to the fragment */
+   int colormask_reg = spe_allocate_available_register(f);
 
+   /* The actual mask we're going to use is an OR of the remaining R, G, B, and A
+    * masks.  Load the result value into our temporary register.
+    */
+   spe_load_uint(f, colormask_reg, r_mask | g_mask | b_mask | a_mask);
+
+   /* Use the mask register to select between the fragment color
+    * values and the frame buffer color values.  Wherever the
+    * mask has a 0 bit, the current frame buffer color should override
+    * the fragment color.  Wherever the mask has a 1 bit, the 
+    * fragment color should persevere.  The Select Bits (selb rt, rA, rB, rM)
+    * instruction will select bits from its first operand rA wherever the
+    * the mask bits rM are 0, and from its second operand rB wherever the
+    * mask bits rM are 1.  That means that the frame buffer color is the
+    * first operand, and the fragment color the second.
+    */
+    spe_selb(f, fragRGBA_reg, fbRGBA_reg, fragRGBA_reg, colormask_reg);
+
+    /* Release the temporary register and we're done */
+    spe_release_register(f, colormask_reg);
+}
 
 /**
  * Generate SPE code to implement the fragment operations (alpha test,
@@ -1383,7 +1379,7 @@ cell_gen_fragment_function(struct cell_context *cell, struct spe_function *f)
       }
 
       if (blend->colormask != PIPE_MASK_RGBA) {
-         gen_colormask(blend->colormask, f, rgba_reg, fbRGBA_reg);
+         gen_colormask(f, blend->colormask, color_format, rgba_reg, fbRGBA_reg);
       }
 
 
@@ -1407,7 +1403,6 @@ cell_gen_fragment_function(struct cell_context *cell, struct spe_function *f)
 
    spe_bi(f, SPE_REG_RA, 0, 0);  /* return from function call */
 
-
    spe_release_register(f, fbRGBA_reg);
    spe_release_register(f, fbZS_reg);
    spe_release_register(f, quad_offset_reg);