Add some utility functions for manipulating the block data, including packing colors back into the 64-bit word.

2025-08-04 20:11:13 +00:00 · 2013-09-24 20:33:48 -04:00 · 2013-09-24 20:33:48 -04:00 · 8f4dcca4d7
parent 3de9abc908
commit 8f4dcca4d7
3 changed files with 229 additions and 0 deletions
--- a/PVRTCEncoder/src/Block.cpp
+++ b/PVRTCEncoder/src/Block.cpp
@ -83,6 +83,42 @@ namespace PVRTCC {
    return m_ColorA;
  }
  Pixel Block::SetColor(const Pixel &c, bool transparent,
                        const uint8 (&tbd)[4], const uint8 (&obd)[4]) {
    uint8 cDepth[4];
    c.GetBitDepth(cDepth);
    Pixel final = c;
    if(transparent) {
      final.ChangeBitDepth(tbd);
      // If we went effectively transparent, then just switch over to opaque...
      if(final.A() == 0x7) {
        return SetColor(c, false, tbd, obd);
      }
    } else {
      final.A() = 255;
      final.ChangeBitDepth(obd);
    }
    return final;
  }
  void Block::SetColorA(const Pixel &c, bool transparent) {
    const uint8 transparentBitDepth[4] = { 3, 4, 4, 4 };
    const uint8 opaqueBitDepth[4] = { 0, 5, 5, 5 };
    m_ColorA = SetColor(c, transparent, transparentBitDepth, opaqueBitDepth);
    m_ColorACached = true;
  }
  void Block::SetColorB(const Pixel &c, bool transparent) {
    const uint8 transparentBitDepth[4] = { 3, 4, 4, 3 };
    const uint8 opaqueBitDepth[4] = { 0, 5, 5, 4 };
    m_ColorB = SetColor(c, transparent, transparentBitDepth, opaqueBitDepth);
    m_ColorBCached = true;
  }
  Pixel Block::GetColorB() {
    if(m_ColorBCached) {
      return m_ColorB;
@ -109,6 +145,17 @@ namespace PVRTCC {
    return (m_LongData >> (texelIdx * 2)) & 0x3;
  }
  void Block::SetLerpValue(uint32 texelIdx, uint8 lerpVal) {
    assert(texelIdx >= 0);
    assert(texelIdx <= 15);
    assert(lerpVal >= 0);
    assert(lerpVal < 4);
    m_LongData &= ~(static_cast<uint64>(0x3) << (texelIdx * 2));
    m_LongData |= static_cast<uint64>(lerpVal & 0x3) << (texelIdx * 2);
  }
  Block::E2BPPSubMode Block::Get2BPPSubMode() const {
    uint8 first = GetLerpValue(0);
    if(!(first & 0x1)) {
@ -145,4 +192,65 @@ namespace PVRTCC {
    return ret;
  }
  uint64 Block::Pack() {
    assert(m_ColorACached);
    assert(m_ColorBCached);
 #ifndef NDEBUG
    uint8 bitDepthA[4];
    m_ColorA.GetBitDepth(bitDepthA);
    uint32 sumA = 0;
    for(int i = 0; i < 4; i++) {
      sumA += bitDepthA[i];
    }
    assert(sumA == 15);
 #endif
 #ifndef NDEBUG
    uint8 bitDepthB[4];
    m_ColorB.GetBitDepth(bitDepthB);
    uint32 sumB = 0;
    for(int i = 0; i < 4; i++) {
      sumB += bitDepthB[i];
    }
    assert(sumB == 14);
 #endif
    uint8 aBits[2], bBits[2];
    memset(aBits, 0, sizeof(aBits));
    memset(bBits, 0, sizeof(bBits));
    m_ColorA.ToBits(aBits, 2);
    m_ColorB.ToBits(bBits, 2, 1);
    if(m_ColorA.A() == 0xFF) {
      m_ByteData[7] |= 0x80;
    } else {
      m_ByteData[7] &= 0x7f;
    }
    m_ByteData[7] = aBits[1];
    m_ByteData[6] = aBits[0];
    bool modeBit = GetModeBit();
    m_ByteData[5] = bBits[1];
    m_ByteData[4] = bBits[0];
    if(m_ColorB.A() == 0xFF) {
      m_ByteData[5] |= 0x80;
    } else {
      m_ByteData[5] &= 0x7f;
    }
    if(modeBit) {
      m_ByteData[4] |= 0x1;
    } else {
      m_ByteData[4] &= 0xFE;
    }
    // Modulation data should have already been set...
    return m_LongData;
  }
 }  // namespace PVRTCC
--- a/PVRTCEncoder/src/Block.h
+++ b/PVRTCEncoder/src/Block.h
@ -61,15 +61,29 @@ namespace PVRTCC {
 class Block {
 public:
  Block(): m_LongData(0) { }
  explicit Block(const uint8 *data);
  // Accessors for the A and B colors of the block.
  Pixel GetColorA();
  void SetColorA(const Pixel &, bool transparent=false);
  Pixel GetColorB();
  void SetColorB(const Pixel &, bool transparent=false);
  bool GetModeBit() const {
    return static_cast<bool>((m_LongData >> 32) & 0x1);
  }
  void SetModeBit(bool flag) {
    const uint64 bit = 0x100000000L;
    if(flag) {
      m_LongData |= bit;
    } else {
      m_LongData &= ~bit;
    }
  }
  // For 2BPP PVRTC, if the mode bit is set, then we use the modulation data
  // as 2 bits for every other texel in the 8x4 block in a checkerboard pattern.
  // The interleaved texel data is decided by averaging nearby texel modulation
@ -101,6 +115,11 @@ class Block {
  // 12 13 14 15
  uint8 GetLerpValue(uint32 texelIdx) const;
  // Sets the values in the data for this block according to the texel and
  // modulation value passed. This happens immediately (i.e. a call to Pack()
  // will reflect these changes).
  void SetLerpValue(uint32 texelIdx, uint8 lerpVal);
  // This returns the modulation value for the texel in the block interpreted as
  // 2BPP. If the modulation bit is not set, then it expects a number from 0-31
  // and does the same operation as GetLerpValue. If the modulation bit is set,
@ -110,6 +129,12 @@ class Block {
  // global information.
  uint8 Get2BPPLerpValue(uint32 texelIdx) const;
  // Returns the 64-bit word that represents this block. This function packs the
  // A and B colors based on their bit depths and preserves the corresponding mode
  // bits. The color modes are determined by whether or not the alpha channel of
  // each block is fully opaque or not.
  uint64 Pack();
 private:
  union {
    uint8 m_ByteData[8];
@ -121,6 +146,11 @@ class Block {
  bool m_ColorBCached;
  Pixel m_ColorB;
  // tbd -- transparent bit depth
  // obd -- opaque bit depth
  static Pixel SetColor(const Pixel &c, bool transparent,
                        const uint8 (&tbd)[4], const uint8 (&obd)[4]);
 };
 }  // namespace PVRTCC
--- a/PVRTCEncoder/test/BlockTest.cpp
+++ b/PVRTCEncoder/test/BlockTest.cpp
@ -236,3 +236,94 @@ TEST(Block, Get2BPPSubMode) {
  b = PVRTCC::Block(data);
  EXPECT_EQ(b.Get2BPPSubMode(), PVRTCC::Block::e2BPPSubMode_Vertical);
 }
 TEST(Block, SetColorAandB) {
  PVRTCC::Block b;
  PVRTCC::Pixel color;
  color.A() = 212;
  color.R() = 200;
  color.G() = 100;
  color.B() = -120;
  b.SetColorA(color);
  PVRTCC::Pixel cA = b.GetColorA();
  uint8 bitDepth[4] = { 0, 5, 5, 5 };
  color.ChangeBitDepth(bitDepth);
  EXPECT_FALSE(memcmp(&color, &cA, sizeof(color)));
  memset(bitDepth, 8, sizeof(bitDepth));
  color.ChangeBitDepth(bitDepth);
  color.A() = 212;
  color.R() = 200;
  color.G() = 100;
  color.B() = -120;
  b.SetColorB(color, true);
  PVRTCC::Pixel cB = b.GetColorB();
  uint8 tBitDepth[4] = { 0, 5, 5, 4 };
  color.ChangeBitDepth(tBitDepth);
  EXPECT_FALSE(memcmp(&color, &cB, sizeof(color)));
  memset(bitDepth, 8, sizeof(bitDepth));
  color.ChangeBitDepth(bitDepth);
  color.A() = 100;
  color.R() = 200;
  color.G() = 100;
  color.B() = -120;
  b.SetColorB(color, true);
  PVRTCC::Pixel cC = b.GetColorB();
  uint8 uBitDepth[4] = { 3, 4, 4, 3 };
  color.ChangeBitDepth(uBitDepth);
  EXPECT_FALSE(memcmp(&color, &cC, sizeof(color)));
 }
 TEST(Block, SetLerpValue) {
  PVRTCC::Block b;
  for(int i = 0; i < 16; i++) {
    b.SetLerpValue(i, i%4);
  }
  for(int i = 0; i < 16; i++) {
    EXPECT_EQ(b.GetLerpValue(i), i % 4);
  }
 }
 TEST(Block, PackBlock) {
  PVRTCC::Block b;
  PVRTCC::Pixel cA, cB;
  cA.A() = 0xFF;
  cA.R() = 0xFF;
  cA.G() = 0x80;
  cA.B() = 0x00;
  cB.A() = 0x80;
  cB.R() = 0x7F;
  cB.G() = 0x00;
  cB.B() = 0xFF;
  b.SetColorA(cA);
  b.SetColorB(cB, true);
  for(int i = 0; i < 16; i++) {
    b.SetLerpValue(i, i%4);
  }
  b.SetModeBit(false);
  EXPECT_EQ(b.Pack(), 0xFE00480EE4E4E4E4UL);
  b.SetModeBit(true);
  EXPECT_EQ(b.Pack(), 0xFE00480FE4E4E4E4UL);
  b.SetColorB(cB);
  b.SetModeBit(false);
  EXPECT_EQ(b.Pack(), 0xFE00C01EE4E4E4E4UL);
 }