////////////////////////////////////////////////////////////////////////////////
//
// The University of Illinois/NCSA
// Open Source License (NCSA)
//
// Copyright (c) 2014-2024, Advanced Micro Devices, Inc. All rights reserved.
//
// Developed by:
//
//                 AMD Research and AMD HSA Software Development
//
//                 Advanced Micro Devices, Inc.
//
//                 www.amd.com
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to
// deal with the Software without restriction, including without limitation
// the rights to use, copy, modify, merge, publish, distribute, sublicense,
// and/or sell copies of the Software, and to permit persons to whom the
// Software is furnished to do so, subject to the following conditions:
//
//  - Redistributions of source code must retain the above copyright notice,
//    this list of conditions and the following disclaimers.
//  - Redistributions in binary form must reproduce the above copyright
//    notice, this list of conditions and the following disclaimers in
//    the documentation and/or other materials provided with the distribution.
//  - Neither the names of Advanced Micro Devices, Inc,
//    nor the names of its contributors may be used to endorse or promote
//    products derived from this Software without specific prior written
//    permission.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
// THE CONTRIBUTORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR
// OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
// ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
// DEALINGS WITH THE SOFTWARE.
//
////////////////////////////////////////////////////////////////////////////////

#define NOMINMAX
#include "image_manager_gfx12.h"

#include <assert.h>

#include <algorithm>
#include <climits>

#include "core/inc/runtime.h"
#include "inc/hsa_ext_amd.h"
#include "core/inc/hsa_internal.h"
#include "core/util/utils.h"
#include "addrlib/src/core/addrlib.h"
#include "image_runtime.h"
#include "resource.h"
#include "resource_gfx12.h"
#include "util.h"
#include "device_info.h"

namespace rocr {
namespace image {

static_assert(sizeof(SQ_BUF_RSRC_WORD0) == sizeof(uint32_t));
static_assert(sizeof(SQ_BUF_RSRC_WORD1) == sizeof(uint32_t));
static_assert(sizeof(SQ_BUF_RSRC_WORD2) == sizeof(uint32_t));
static_assert(sizeof(SQ_BUF_RSRC_WORD3) == sizeof(uint32_t));

static_assert(sizeof(SQ_IMG_RSRC_WORD0) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_RSRC_WORD1) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_RSRC_WORD2) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_RSRC_WORD3) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_RSRC_WORD4) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_RSRC_WORD5) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_RSRC_WORD6) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_RSRC_WORD7) == sizeof(uint32_t));

static_assert(sizeof(SQ_IMG_SAMP_WORD0) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_SAMP_WORD1) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_SAMP_WORD2) == sizeof(uint32_t));
static_assert(sizeof(SQ_IMG_SAMP_WORD3) == sizeof(uint32_t));

//-----------------------------------------------------------------------------
// Workaround switch to combined format/type codes and missing gfx11
// specific look up table.  Only covers types used in image_lut_gfx11.cpp.
//-----------------------------------------------------------------------------
struct formatconverstion_t {
  FMT fmt;
  type type;
  FORMAT format;
};

// Format/Type to combined format code table.
// Sorted and indexed to allow fast searches.
static const formatconverstion_t FormatLUT[] = {
    {FMT_1_5_5_5, TYPE_UNORM, CFMT_1_5_5_5_UNORM},              // 0
    {FMT_10_10_10_2, TYPE_UNORM, CFMT_10_10_10_2_UNORM},        // 1
    {FMT_10_10_10_2, TYPE_SNORM, CFMT_10_10_10_2_SNORM},        // 2
    {FMT_10_10_10_2, TYPE_UINT, CFMT_10_10_10_2_UINT},          // 3
    {FMT_10_10_10_2, TYPE_SINT, CFMT_10_10_10_2_SINT},          // 4
    {FMT_16, TYPE_UNORM, CFMT_16_UNORM},                        // 5
    {FMT_16, TYPE_SNORM, CFMT_16_SNORM},                        // 6
    {FMT_16, TYPE_UINT, CFMT_16_UINT},                          // 7
    {FMT_16, TYPE_SINT, CFMT_16_SINT},                          // 8
    {FMT_16, TYPE_FLOAT, CFMT_16_FLOAT},                        // 9
    {FMT_16, TYPE_USCALED, CFMT_16_USCALED},                    // 10
    {FMT_16, TYPE_SSCALED, CFMT_16_SSCALED},                    // 11
    {FMT_16_16, TYPE_UNORM, CFMT_16_16_UNORM},                  // 12
    {FMT_16_16, TYPE_SNORM, CFMT_16_16_SNORM},                  // 13
    {FMT_16_16, TYPE_UINT, CFMT_16_16_UINT},                    // 14
    {FMT_16_16, TYPE_SINT, CFMT_16_16_SINT},                    // 15
    {FMT_16_16, TYPE_FLOAT, CFMT_16_16_FLOAT},                  // 16
    {FMT_16_16, TYPE_USCALED, CFMT_16_16_USCALED},              // 17
    {FMT_16_16, TYPE_SSCALED, CFMT_16_16_SSCALED},              // 18
    {FMT_16_16_16_16, TYPE_UNORM, CFMT_16_16_16_16_UNORM},      // 19
    {FMT_16_16_16_16, TYPE_SNORM, CFMT_16_16_16_16_SNORM},      // 20
    {FMT_16_16_16_16, TYPE_UINT, CFMT_16_16_16_16_UINT},        // 21
    {FMT_16_16_16_16, TYPE_SINT, CFMT_16_16_16_16_SINT},        // 22
    {FMT_16_16_16_16, TYPE_FLOAT, CFMT_16_16_16_16_FLOAT},      // 23
    {FMT_16_16_16_16, TYPE_USCALED, CFMT_16_16_16_16_USCALED},  // 24
    {FMT_16_16_16_16, TYPE_SSCALED, CFMT_16_16_16_16_SSCALED},  // 25
    {FMT_2_10_10_10, TYPE_UNORM, CFMT_2_10_10_10_UNORM},        // 26
    {FMT_2_10_10_10, TYPE_SNORM, CFMT_2_10_10_10_SNORM},        // 27
    {FMT_2_10_10_10, TYPE_UINT, CFMT_2_10_10_10_UINT},          // 28
    {FMT_2_10_10_10, TYPE_SINT, CFMT_2_10_10_10_SINT},          // 29
    {FMT_2_10_10_10, TYPE_USCALED, CFMT_2_10_10_10_USCALED},    // 30
    {FMT_2_10_10_10, TYPE_SSCALED, CFMT_2_10_10_10_SSCALED},    // 31
    {FMT_24_8, TYPE_UNORM, CFMT_24_8_UNORM},                    // 32
    {FMT_24_8, TYPE_UINT, CFMT_24_8_UINT},                      // 33
    {FMT_32, TYPE_UINT, CFMT_32_UINT},                          // 34
    {FMT_32, TYPE_SINT, CFMT_32_SINT},                          // 35
    {FMT_32, TYPE_FLOAT, CFMT_32_FLOAT},                        // 36
    {FMT_32_32, TYPE_UINT, CFMT_32_32_UINT},                    // 37
    {FMT_32_32, TYPE_SINT, CFMT_32_32_SINT},                    // 38
    {FMT_32_32, TYPE_FLOAT, CFMT_32_32_FLOAT},                  // 39
    {FMT_32_32_32, TYPE_UINT, CFMT_32_32_32_UINT},              // 40
    {FMT_32_32_32, TYPE_SINT, CFMT_32_32_32_SINT},              // 41
    {FMT_32_32_32, TYPE_FLOAT, CFMT_32_32_32_FLOAT},            // 42
    {FMT_32_32_32_32, TYPE_UINT, CFMT_32_32_32_32_UINT},        // 43
    {FMT_32_32_32_32, TYPE_SINT, CFMT_32_32_32_32_SINT},        // 44
    {FMT_32_32_32_32, TYPE_FLOAT, CFMT_32_32_32_32_FLOAT},      // 45
    {FMT_5_5_5_1, TYPE_UNORM, CFMT_5_5_5_1_UNORM},              // 46
    {FMT_5_6_5, TYPE_UNORM, CFMT_5_6_5_UNORM},                  // 47
    {FMT_8, TYPE_UNORM, CFMT_8_UNORM},                          // 48
    {FMT_8, TYPE_SNORM, CFMT_8_SNORM},                          // 49
    {FMT_8, TYPE_UINT, CFMT_8_UINT},                            // 50
    {FMT_8, TYPE_SINT, CFMT_8_SINT},                            // 51
    {FMT_8, TYPE_SRGB, CFMT_8_SRGB},                            // 52
    {FMT_8, TYPE_USCALED, CFMT_8_USCALED},                      // 53
    {FMT_8, TYPE_SSCALED, CFMT_8_SSCALED},                      // 54
    {FMT_8_24, TYPE_UNORM, CFMT_8_24_UNORM},                    // 55
    {FMT_8_24, TYPE_UINT, CFMT_8_24_UINT},                      // 56
    {FMT_8_8, TYPE_UNORM, CFMT_8_8_UNORM},                      // 57
    {FMT_8_8, TYPE_SNORM, CFMT_8_8_SNORM},                      // 58
    {FMT_8_8, TYPE_UINT, CFMT_8_8_UINT},                        // 59
    {FMT_8_8, TYPE_SINT, CFMT_8_8_SINT},                        // 60
    {FMT_8_8, TYPE_SRGB, CFMT_8_8_SRGB},                        // 61
    {FMT_8_8, TYPE_USCALED, CFMT_8_8_USCALED},                  // 62
    {FMT_8_8, TYPE_SSCALED, CFMT_8_8_SSCALED},                  // 63
    {FMT_8_8_8_8, TYPE_UNORM, CFMT_8_8_8_8_UNORM},              // 64
    {FMT_8_8_8_8, TYPE_SNORM, CFMT_8_8_8_8_SNORM},              // 65
    {FMT_8_8_8_8, TYPE_UINT, CFMT_8_8_8_8_UINT},                // 66
    {FMT_8_8_8_8, TYPE_SINT, CFMT_8_8_8_8_SINT},                // 67
    {FMT_8_8_8_8, TYPE_SRGB, CFMT_8_8_8_8_SRGB},                // 68
    {FMT_8_8_8_8, TYPE_USCALED, CFMT_8_8_8_8_USCALED},          // 69
    {FMT_8_8_8_8, TYPE_SSCALED, CFMT_8_8_8_8_SSCALED}           // 70
};
static const int FormatLUTSize = sizeof(FormatLUT)/sizeof(formatconverstion_t);

//Index in FormatLUT to start search, indexed by FMT enum.
static const int FormatEntryPoint[] = {
  71, // FMT_INVALID
  48, // FMT_8
  5,  // FMT_16
  57, // FMT_8_8
  34, // FMT_32
  12, // FMT_16_16
  71, // FMT_10_11_11
  71, // FMT_11_11_10
  1,  // FMT_10_10_10_2
  26, // FMT_2_10_10_10
  64, // FMT_8_8_8_8
  37, // FMT_32_32
  19, // FMT_16_16_16_16
  40, // FMT_32_32_32
  43, // FMT_32_32_32_32
  71, // RESERVED
  47, // FMT_5_6_5
  0,  // FMT_1_5_5_5
  46, // FMT_5_5_5_1
  71, // FMT_4_4_4_4
  55, // FMT_8_24
  32  // FMT_24_8
};

static FORMAT GetCombinedFormat(uint8_t fmt, uint8_t type) {
  assert(fmt < sizeof(FormatEntryPoint)/sizeof(int) && "FMT out of range.");
  int start = FormatEntryPoint[fmt];
  int stop = std::min(start + 6, FormatLUTSize); // Only 6 types are used in image_kv_lut.cpp

  for(int i=start; i<stop; i++) {
    if((FormatLUT[i].fmt == fmt) && (FormatLUT[i].type == type))
      return FormatLUT[i].format;
  }
  return CFMT_INVALID;
};
//-----------------------------------------------------------------------------
// End workaround
//-----------------------------------------------------------------------------

ImageManagerGfx12::ImageManagerGfx12() : ImageManagerKv() {}

ImageManagerGfx12::~ImageManagerGfx12() {}

// TODO(cfreehil) remove from class, make it a utility function
hsa_status_t ImageManagerGfx12::CalculateImageSizeAndAlignment(
    hsa_agent_t component, const hsa_ext_image_descriptor_t& desc,
    hsa_ext_image_data_layout_t image_data_layout,
    size_t image_data_row_pitch,
    size_t image_data_slice_pitch,
    hsa_ext_image_data_info_t& image_info) const {
  ADDR3_COMPUTE_SURFACE_INFO_OUTPUT out = {0};
  hsa_profile_t profile;

  hsa_status_t status = HSA::hsa_agent_get_info(component, HSA_AGENT_INFO_PROFILE, &profile);
  if (status != HSA_STATUS_SUCCESS) return status;

  Image::TileMode tileMode = Image::TileMode::LINEAR;
  if (image_data_layout == HSA_EXT_IMAGE_DATA_LAYOUT_OPAQUE) {
    tileMode = (profile == HSA_PROFILE_BASE &&
                desc.geometry != HSA_EXT_IMAGE_GEOMETRY_1DB)?
      Image::TileMode::TILED : Image::TileMode::LINEAR;
  }
  if (GetAddrlibSurfaceInfoNv(component, desc, tileMode,
        image_data_row_pitch, image_data_slice_pitch, out) ==
                                                             (uint32_t)(-1)) {
    return HSA_STATUS_ERROR;
  }

  size_t rowPitch   = (out.bpp >> 3) * out.pitch;
  size_t slicePitch = rowPitch * out.height;
  if (desc.geometry != HSA_EXT_IMAGE_GEOMETRY_1DB &&
      image_data_layout == HSA_EXT_IMAGE_DATA_LAYOUT_LINEAR &&
      ((image_data_row_pitch && (rowPitch != image_data_row_pitch)) ||
       (image_data_slice_pitch && (slicePitch != image_data_slice_pitch)))) {
    return static_cast<hsa_status_t>(
                                HSA_EXT_STATUS_ERROR_IMAGE_PITCH_UNSUPPORTED);
  }

  image_info.size = out.surfSize;
  assert(image_info.size != 0);
  image_info.alignment = out.baseAlign;
  assert(image_info.alignment != 0);

  return HSA_STATUS_SUCCESS;
}

bool ImageManagerGfx12::IsLocalMemory(const void* address) const {
  return true;
}

hsa_status_t ImageManagerGfx12::PopulateImageSrd(Image& image,
                                     const metadata_amd_t* descriptor) const {
  const metadata_amd_gfx12_t* desc = reinterpret_cast<const metadata_amd_gfx12_t*>(descriptor);
  const void* image_data_addr = image.data;

  ImageProperty image_prop = ImageLut().MapFormat(image.desc.format, image.desc.geometry);
  if ((image_prop.cap == HSA_EXT_IMAGE_CAPABILITY_NOT_SUPPORTED) ||
     (image_prop.element_size == 0))
    return (hsa_status_t)HSA_EXT_STATUS_ERROR_IMAGE_FORMAT_UNSUPPORTED;

  const Swizzle swizzle = ImageLut().MapSwizzle(image.desc.format.channel_order);

  if (IsLocalMemory(image.data)) {
    image_data_addr = reinterpret_cast<const void*>(
        reinterpret_cast<uintptr_t>(image.data) - local_memory_base_address_);
  }

  image.srd[0] = desc->word0.u32All;
  image.srd[1] = desc->word1.u32All;
  image.srd[2] = desc->word2.u32All;
  image.srd[3] = desc->word3.u32All;
  image.srd[4] = desc->word4.u32All;
  image.srd[5] = desc->word5.u32All;
  image.srd[6] = desc->word6.u32All;
  image.srd[7] = desc->word7.u32All;

  if (image.desc.geometry == HSA_EXT_IMAGE_GEOMETRY_1DB) {
    SQ_BUF_RSRC_WORD0 word0;
    SQ_BUF_RSRC_WORD1 word1;
    SQ_BUF_RSRC_WORD3 word3;

    word0.val = 0;
    word0.f.BASE_ADDRESS = PtrLow32(image_data_addr);

    word1.val = image.srd[1];
    word1.f.BASE_ADDRESS_HI = PtrHigh32(image_data_addr);
    word1.f.STRIDE = image_prop.element_size;

    word3.val = image.srd[3];
    word3.f.DST_SEL_X = swizzle.x;
    word3.f.DST_SEL_Y = swizzle.y;
    word3.f.DST_SEL_Z = swizzle.z;
    word3.f.DST_SEL_W = swizzle.w;

    word3.f.FORMAT = GetCombinedFormat(image_prop.data_format, image_prop.data_type);

    word3.f.INDEX_STRIDE = image_prop.element_size;

    // New to GFX12
    //word3.f.WRITE_COMPRESS_ENABLE = 0;
    //word3.f.COMPRESSION_EN = 0;
    //word3.f.COMPRESSION_ACCESS_MODE = 0;

    image.srd[0] = word0.val;
    image.srd[1] = word1.val;
    image.srd[3] = word3.val;
  } else {
    uint32_t hwPixelSize = ImageLut().GetPixelSize(image_prop.data_format, image_prop.data_type);

    if (image_prop.element_size != hwPixelSize) {
      return (hsa_status_t)HSA_EXT_STATUS_ERROR_IMAGE_FORMAT_UNSUPPORTED;
    }
    reinterpret_cast<SQ_IMG_RSRC_WORD0*>(&image.srd[0])->bits.BASE_ADDRESS =
        PtrLow40Shift8(image_data_addr);
    reinterpret_cast<SQ_IMG_RSRC_WORD1*>(&image.srd[1])->bits.BASE_ADDRESS_HI =
        PtrHigh64Shift40(image_data_addr);

    // New to GFX12...
    //reinterpret_cast<SQ_IMG_RSRC_WORD1*>(&image.srd[1])->bits.MAX_MIP = 0;

    reinterpret_cast<SQ_IMG_RSRC_WORD1*>(&image.srd[1])->bits.FORMAT = GetCombinedFormat(image_prop.data_format, image_prop.data_type);
    reinterpret_cast<SQ_IMG_RSRC_WORD3*>(&image.srd[3])->bits.DST_SEL_X =
                                                                    swizzle.x;
    reinterpret_cast<SQ_IMG_RSRC_WORD3*>(&image.srd[3])->bits.DST_SEL_Y =
                                                                    swizzle.y;
    reinterpret_cast<SQ_IMG_RSRC_WORD3*>(&image.srd[3])->bits.DST_SEL_Z =
                                                                    swizzle.z;
    reinterpret_cast<SQ_IMG_RSRC_WORD3*>(&image.srd[3])->bits.DST_SEL_W =
                                                                    swizzle.w;
    if (image.desc.geometry == HSA_EXT_IMAGE_GEOMETRY_1DA ||
        image.desc.geometry == HSA_EXT_IMAGE_GEOMETRY_1D) {
      reinterpret_cast<SQ_IMG_RSRC_WORD3*>(&image.srd[3])->bits.TYPE =
          ImageLut().MapGeometry(image.desc.geometry);
    }
  }

  // Looks like this is only used for CPU copies.
  image.row_pitch = 0;
  image.slice_pitch = 0;

  // Used by HSAIL shader ABI
  image.srd[8] = image.desc.format.channel_type;
  image.srd[9] = image.desc.format.channel_order;
  image.srd[10] = static_cast<uint32_t>(image.desc.width);

  return HSA_STATUS_SUCCESS;
}

static TEX_BC_SWIZZLE GetBcSwizzle(const Swizzle& swizzle) {
    SEL r = (SEL)swizzle.x;
    SEL g = (SEL)swizzle.y;
    SEL b = (SEL)swizzle.z;
    SEL a = (SEL)swizzle.w;

    TEX_BC_SWIZZLE bcSwizzle = TEX_BC_Swizzle_XYZW;

    if (a == SEL_X) {
        // Have to use either TEX_BC_Swizzle_WZYX or TEX_BC_Swizzle_WXYZ
        //
        // For the pre-defined border color values (white, opaque black,
        // transparent black), the only thing that matters is that the alpha
        // channel winds up in the correct place (because the RGB channels are
        // all the same) so either of these TEX_BC_Swizzle enumerations will
        // work.  Not sure what happens with border color palettes.
        if (b == SEL_Y) {
            // ABGR
            bcSwizzle = TEX_BC_Swizzle_WZYX;
        } else if ((r == SEL_X) && (g == SEL_X) && (b == SEL_X)) {
            // RGBA
            bcSwizzle = TEX_BC_Swizzle_XYZW;
        } else {
            // ARGB
            bcSwizzle = TEX_BC_Swizzle_WXYZ;
        }
    } else if (r == SEL_X) {
        // Have to use either TEX_BC_Swizzle_XYZW or TEX_BC_Swizzle_XWYZ
        if (g == SEL_Y) {
            // RGBA
            bcSwizzle = TEX_BC_Swizzle_XYZW;
        } else if ((g == SEL_X) && (b == SEL_X) && (a == SEL_W)) {
            // RGBA
            bcSwizzle = TEX_BC_Swizzle_XYZW;
        } else {
            // RAGB
            bcSwizzle = TEX_BC_Swizzle_XWYZ;
        }
    } else if (g == SEL_X) {
        // GRAB, have to use TEX_BC_Swizzle_YXWZ
        bcSwizzle = TEX_BC_Swizzle_YXWZ;
    } else if (b == SEL_X) {
        // BGRA, have to use TEX_BC_Swizzle_ZYXW
        bcSwizzle = TEX_BC_Swizzle_ZYXW;
    }

    return bcSwizzle;
}


hsa_status_t ImageManagerGfx12::PopulateImageSrd(Image& image) const {
  ImageProperty image_prop = ImageLut().MapFormat(image.desc.format, image.desc.geometry);
  assert(image_prop.cap != HSA_EXT_IMAGE_CAPABILITY_NOT_SUPPORTED);
  assert(image_prop.element_size != 0);

  const void* image_data_addr = image.data;

  if (IsLocalMemory(image.data))
    image_data_addr = reinterpret_cast<const void*>(
        reinterpret_cast<uintptr_t>(image.data) - local_memory_base_address_);

  if (image.desc.geometry == HSA_EXT_IMAGE_GEOMETRY_1DB) {
    SQ_BUF_RSRC_WORD0 word0;
    SQ_BUF_RSRC_WORD1 word1;
    SQ_BUF_RSRC_WORD2 word2;
    SQ_BUF_RSRC_WORD3 word3;

    word0.val = 0;
    word0.f.BASE_ADDRESS = PtrLow32(image_data_addr);

    word1.val = 0;
    word1.f.BASE_ADDRESS_HI = PtrHigh32(image_data_addr);
    word1.f.STRIDE = image_prop.element_size;

    word1.f.SWIZZLE_ENABLE = 0;

    word2.f.NUM_RECORDS = image.desc.width * image_prop.element_size;

    const Swizzle swizzle = ImageLut().MapSwizzle(image.desc.format.channel_order);
    word3.val = 0;
    word3.f.DST_SEL_X = swizzle.x;
    word3.f.DST_SEL_Y = swizzle.y;
    word3.f.DST_SEL_Z = swizzle.z;
    word3.f.DST_SEL_W = swizzle.w;
    word3.f.FORMAT = GetCombinedFormat(image_prop.data_format, image_prop.data_type);

    word3.f.INDEX_STRIDE = image_prop.element_size;

    // New to GFX12
    //word3.f.WRITE_COMPRESS_ENABLE = 0;
    //word3.f.COMPRESSION_EN = 0;
    //word3.f.COMPRESSION_ACCESS_MODE = 0;

    word3.f.TYPE = ImageLut().MapGeometry(image.desc.geometry);

    image.srd[0] = word0.val;
    image.srd[1] = word1.val;
    image.srd[2] = word2.val;
    image.srd[3] = word3.val;

    image.row_pitch = image.desc.width * image_prop.element_size;
    image.slice_pitch = image.row_pitch;
  } else {
    SQ_IMG_RSRC_WORD0 word0;
    SQ_IMG_RSRC_WORD1 word1;
    SQ_IMG_RSRC_WORD2 word2;
    SQ_IMG_RSRC_WORD3 word3;
    SQ_IMG_RSRC_WORD4 word4;
    SQ_IMG_RSRC_WORD5 word5;
    SQ_IMG_RSRC_WORD5 word6;
    SQ_IMG_RSRC_WORD5 word7;

    ADDR3_COMPUTE_SURFACE_INFO_OUTPUT out = {0};

    uint32_t swizzleMode = GetAddrlibSurfaceInfoNv(
         image.component, image.desc, image.tile_mode,
                                     image.row_pitch, image.slice_pitch, out);
    if (swizzleMode == (uint32_t)(-1)) {
      return HSA_STATUS_ERROR;
    }

    assert((out.bpp / 8) == image_prop.element_size);

    const size_t row_pitch_size = out.pitch * image_prop.element_size;

    word0.f.BASE_ADDRESS = PtrLow40Shift8(image_data_addr);

    word1.val = 0;
    word1.f.BASE_ADDRESS_HI = PtrHigh64Shift40(image_data_addr);

    // New to GFX12
    //word1.f.MAX_MIP = 0;
    //word1.f.BASE_LEVEL = 0;

    word1.f.FORMAT = GetCombinedFormat(image_prop.data_format, image_prop.data_type);
    // Only take the lowest 2 bits of (image.desc.width - 1)
    word1.f.WIDTH = BitSelect<0, 1>(image.desc.width - 1);

    word2.val = 0;
    // Take the high 14 bits of (image.desc.width - 1)
    word2.f.WIDTH_HI = BitSelect<2, 15>(image.desc.width - 1);
    word2.f.HEIGHT = image.desc.height ? image.desc.height - 1 : 0;

    const Swizzle swizzle = ImageLut().MapSwizzle(image.desc.format.channel_order);
    word3.val = 0;
    word3.f.DST_SEL_X = swizzle.x;
    word3.f.DST_SEL_Y = swizzle.y;
    word3.f.DST_SEL_Z = swizzle.z;
    word3.f.DST_SEL_W = swizzle.w;
    //word3.f.NO_EDGE_CLAMP = 0;  // New to GFX12
    //word3.f.LAST_LEVEL = 0;     // New to GFX12
    word3.f.SW_MODE = swizzleMode;
    word3.f.BC_SWIZZLE = GetBcSwizzle(swizzle);
    word3.f.TYPE = ImageLut().MapGeometry(image.desc.geometry);

    const bool image_array =
        (image.desc.geometry == HSA_EXT_IMAGE_GEOMETRY_1DA ||
         image.desc.geometry == HSA_EXT_IMAGE_GEOMETRY_2DA ||
         image.desc.geometry == HSA_EXT_IMAGE_GEOMETRY_2DADEPTH);
    const bool image_3d = (image.desc.geometry == HSA_EXT_IMAGE_GEOMETRY_3D);

    word4.val = 0;

    // For 1d, 2d and 2d-msaa, fields DEPTH+PITCH_MSB encode pitch-1
    if (!image_array && !image_3d) {
      uint32_t encPitch = out.pitch - 1;
      word4.f.DEPTH = encPitch & 0x3fff;           // first 14 bits
      word4.f.PITCH_MSB = (encPitch >> 14) & 0x3;  // last 2 bits
    } else {
      word4.f.DEPTH =
        (image_array) // Doesn't hurt but isn't array_size already >0?
            ? std::max(image.desc.array_size, static_cast<size_t>(1)) - 1
            : (image_3d) ? image.desc.depth - 1 : 0;
    }

    word5.val = 0;
    word6.val = 0;
    word7.val = 0;

    image.srd[0] = word0.val;
    image.srd[1] = word1.val;
    image.srd[2] = word2.val;
    image.srd[3] = word3.val;
    image.srd[4] = word4.val;
    image.srd[5] = word5.val;
    image.srd[6] = word6.val;
    image.srd[7] = word7.val;

    image.row_pitch = row_pitch_size;
    image.slice_pitch = out.sliceSize;
  }

  image.srd[8] = image.desc.format.channel_type;
  image.srd[9] = image.desc.format.channel_order;
  image.srd[10] = static_cast<uint32_t>(image.desc.width);

  return HSA_STATUS_SUCCESS;
}

hsa_status_t ImageManagerGfx12::ModifyImageSrd(
    Image& image, hsa_ext_image_format_t& new_format) const {
  image.desc.format = new_format;

  ImageProperty image_prop = ImageLut().MapFormat(image.desc.format, image.desc.geometry);
  assert(image_prop.cap != HSA_EXT_IMAGE_CAPABILITY_NOT_SUPPORTED);
  assert(image_prop.element_size != 0);

  if (image.desc.geometry == HSA_EXT_IMAGE_GEOMETRY_1DB) {
    const Swizzle swizzle = ImageLut().MapSwizzle(image.desc.format.channel_order);
    SQ_BUF_RSRC_WORD3* word3 =
        reinterpret_cast<SQ_BUF_RSRC_WORD3*>(&image.srd[3]);
    word3->bits.DST_SEL_X = swizzle.x;
    word3->bits.DST_SEL_Y = swizzle.y;
    word3->bits.DST_SEL_Z = swizzle.z;
    word3->bits.DST_SEL_W = swizzle.w;
    word3->bits.FORMAT = GetCombinedFormat(image_prop.data_format, image_prop.data_type);
  } else {
    SQ_IMG_RSRC_WORD1* word1 =
        reinterpret_cast<SQ_IMG_RSRC_WORD1*>(&image.srd[1]);
    word1->bits.FORMAT = GetCombinedFormat(image_prop.data_format, image_prop.data_type);

    const Swizzle swizzle = ImageLut().MapSwizzle(image.desc.format.channel_order);
    SQ_IMG_RSRC_WORD3* word3 =
        reinterpret_cast<SQ_IMG_RSRC_WORD3*>(&image.srd[3]);
    word3->bits.DST_SEL_X = swizzle.x;
    word3->bits.DST_SEL_Y = swizzle.y;
    word3->bits.DST_SEL_Z = swizzle.z;
    word3->bits.DST_SEL_W = swizzle.w;
  }

  image.srd[8] = image.desc.format.channel_type;
  image.srd[9] = image.desc.format.channel_order;
  image.srd[10] = static_cast<uint32_t>(image.desc.width);

  return HSA_STATUS_SUCCESS;
}

hsa_status_t ImageManagerGfx12::PopulateSamplerSrd(Sampler& sampler) const {
  const hsa_ext_sampler_descriptor_v2_t &sampler_descriptor = sampler.desc;

  SQ_IMG_SAMP_WORD0 word0;
  SQ_IMG_SAMP_WORD1 word1;
  SQ_IMG_SAMP_WORD2 word2;
  SQ_IMG_SAMP_WORD3 word3;

  word0.u32All = 0;
  hsa_status_t status = convertAddressMode<SQ_IMG_SAMP_WORD0, SQ_TEX_CLAMP>
                                       (word0, sampler_descriptor.address_modes);
  if (status != HSA_STATUS_SUCCESS) return status;
  word0.bits.FORCE_UNNORMALIZED = (sampler_descriptor.coordinate_mode ==
                                  HSA_EXT_SAMPLER_COORDINATE_MODE_UNNORMALIZED);

  word1.u32All = 0;
  word1.bits.MAX_LOD = 4095;

  word2.u32All = 0;
  switch (sampler_descriptor.filter_mode) {
    case HSA_EXT_SAMPLER_FILTER_MODE_NEAREST:
      word2.bits.XY_MAG_FILTER = static_cast<int>(SQ_TEX_XY_FILTER_POINT);
      break;
    case HSA_EXT_SAMPLER_FILTER_MODE_LINEAR:
      word2.bits.XY_MAG_FILTER = static_cast<int>(SQ_TEX_XY_FILTER_BILINEAR);
      break;
    default:
      return HSA_STATUS_ERROR_INVALID_ARGUMENT;
  }
  word2.bits.XY_MIN_FILTER = word2.bits.XY_MAG_FILTER;
  word2.bits.Z_FILTER = SQ_TEX_Z_FILTER_NONE;
  word2.bits.MIP_FILTER = SQ_TEX_MIP_FILTER_NONE;

  word3.u32All = 0;

  // TODO: check this bit with HSAIL spec.
  word3.bits.BORDER_COLOR_TYPE = SQ_TEX_BORDER_COLOR_TRANS_BLACK;

  sampler.srd[0] = word0.u32All;
  sampler.srd[1] = word1.u32All;
  sampler.srd[2] = word2.u32All;
  sampler.srd[3] = word3.u32All;

  return HSA_STATUS_SUCCESS;
}

uint32_t ImageManagerGfx12::GetAddrlibSurfaceInfoNv(
    hsa_agent_t component, const hsa_ext_image_descriptor_t& desc,
    Image::TileMode tileMode,
    size_t image_data_row_pitch,
    size_t image_data_slice_pitch,
    ADDR3_COMPUTE_SURFACE_INFO_OUTPUT& out) const {
  const ImageProperty image_prop =
      GetImageProperty(component, desc.format, desc.geometry);

  const AddrFormat addrlib_format = GetAddrlibFormat(image_prop);

  const uint32_t width = static_cast<uint32_t>(desc.width);
  const uint32_t height = static_cast<uint32_t>(desc.height);
  static const size_t kMinNumSlice = 1;
  const uint32_t num_slice = static_cast<uint32_t>(
      std::max(kMinNumSlice, std::max(desc.array_size, desc.depth)));

  ADDR3_COMPUTE_SURFACE_INFO_INPUT in = {0};
  in.size = sizeof(ADDR3_COMPUTE_SURFACE_INFO_INPUT);
  in.format = addrlib_format;
  in.bpp = static_cast<unsigned int>(image_prop.element_size) * 8;
  in.width = width;
  in.height = height;
  in.numSlices = num_slice;
  in.pitchInElement = image_data_row_pitch / image_prop.element_size;

  switch (desc.geometry) {
    case HSA_EXT_IMAGE_GEOMETRY_1D:
    case HSA_EXT_IMAGE_GEOMETRY_1DB:
    case HSA_EXT_IMAGE_GEOMETRY_1DA:
      in.resourceType = ADDR_RSRC_TEX_1D;
      break;

    case HSA_EXT_IMAGE_GEOMETRY_2D:
    case HSA_EXT_IMAGE_GEOMETRY_2DDEPTH:
    case HSA_EXT_IMAGE_GEOMETRY_2DA:
    case HSA_EXT_IMAGE_GEOMETRY_2DADEPTH:
      in.resourceType = ADDR_RSRC_TEX_2D;
      break;

    case HSA_EXT_IMAGE_GEOMETRY_3D:
      {
	in.resourceType = ADDR_RSRC_TEX_3D;
	/*
	 * 3D swizzle modes on GFX12 enforces alignment
	 * of the number of slices  to the block depth.
	 * If numSlices = 3 then the 3 slices are
	 * interleaved for 3D locality among the 8 slices
	 * that make up each block. This causes the memory
	 * footprint to jump from an ideal size of ~12 GB
	 * to ~32 GB.
	 * 'enable3DSwizzleMode' flag tests for env variable
	 * HSA_IMAGE_ENABLE_3D_SWIZZLE_DEBUG to enable or disable
	 * 3D swizzle:
	 * true: Keep view3dAs2dArray = 0 for real 3D interleaving.
	 * false: Use view3dAs2dArray = 1 to avoid the alignment
	 *       expansion.
	 * 2D swizzle modes can lower size overhead but may yield
	 * suboptimal cache behavior for fully 3D volumetric
	 * operations.
	 */
	bool enable3DSwizzleMode = core::Runtime::runtime_singleton_->flag().enable_3d_swizzle();
	if (enable3DSwizzleMode)
	{
		in.flags.view3dAs2dArray = 0;
	}
	else
	{
		in.flags.view3dAs2dArray = 1;
	}
	break;
      }
  }

  in.flags.texture = 1;

  if (tileMode == Image::TileMode::LINEAR)
  {
    in.swizzleMode = ADDR3_LINEAR;
  } else {

    /*
     * AddrLib3 does not provide the best swizzle mode (unlike AddrLib2).
     * Instead, client has to request the list of possible swizzle mode and
     * then pick the best one for its needs (i.e. performance/space tradeoffs).
     *
     */
    ADDR3_GET_POSSIBLE_SWIZZLE_MODE_OUTPUT swOut = { 0 };
    swOut.size = sizeof(ADDR3_GET_POSSIBLE_SWIZZLE_MODE_OUTPUT);

    ADDR3_GET_POSSIBLE_SWIZZLE_MODE_INPUT swIn = { 0 };
    swIn.size = sizeof(ADDR3_GET_POSSIBLE_SWIZZLE_MODE_INPUT);
    swIn.flags = in.flags;
    swIn.resourceType = in.resourceType;
    swIn.bpp = in.bpp;
    swIn.width = in.width;
    swIn.height = in.height;
    swIn.numSlices = in.numSlices;
    swIn.numMipLevels = in.numMipLevels;
    swIn.numSamples = in.numSamples;
    /*
     * Cannot leave it to 0 like GFX11 Addr2GetPreferredSurfaceSetting method
     * as it triggers an ASSERT in AddrLib3 code.
     *
     * Setting it to 256K to allow for maximum number of swizzle mode in set
     * returned (similar behaviour as GFX11).
     *
     */
    swIn.maxAlign = 256 * 1024;


    if (ADDR_OK != Addr3GetPossibleSwizzleModes(addr_lib_, &swIn, &swOut)) {
      debug_print("Addr3GetPossibleSwizzleModes failed!\n");
      return (uint32_t) -1;
    }

    /*
     * Remove any modes that the client does not want (if any).
     */
    //swOut.validModes.sw***** = 0;


    /*
     * Pick the "best" swizzle mode.
     *
     * This algorithm is based on behaviour in GFX11 AddrLib and on
     * GFX12 code in PAL (that is also based on the GFX11 behaviour).
     *
     * Ratio variables control the extra space that can be used to get a larger
     * swizzle mode.
     *
     * ratioLow:ratioHi meanings:
     *
     *   2:1 ratio - same behaviour as GFX11.
     *   3:2 ratio - would be equivalent if flag opt4space in GFX11 (not used in ROCr)
     *   1:1 ratio - minimum size, not necessary best for performance
     *
     */
    const UINT_32 ratioLow = 2;
    const UINT_32 ratioHigh = 1;

    // Same behaviour as GFX11, remove linear if height is 1.
    if (in.height > 1) {
      swOut.validModes.swLinear = 0;
    }

    UINT_64 minSize = 0;
    Addr3SwizzleMode bestSwizzle = ADDR3_MAX_TYPE;

    for (uint32_t i = ADDR3_LINEAR; i < ADDR3_MAX_TYPE; i++) {

      if (swOut.validModes.value & (1 << i)) {
        ADDR3_COMPUTE_SURFACE_INFO_OUTPUT localOut = {0};
        localOut.size = sizeof(ADDR3_COMPUTE_SURFACE_INFO_OUTPUT);

        in.swizzleMode = (Addr3SwizzleMode) i;

        if (ADDR_OK != Addr3ComputeSurfaceInfo(addr_lib_, &in, &localOut)) {
          // Should not happen, if it does, ignore this swizzle mode.
          debug_print("Addr3ComputeSurfaceInfo failed!\n");
          continue;
        }

        UINT_64 surfaceSize = localOut.surfSize;

        if (bestSwizzle == ADDR3_MAX_TYPE) {
          minSize = surfaceSize;
          bestSwizzle = (Addr3SwizzleMode) i;
        } else if ((surfaceSize * ratioHigh) <= (minSize * ratioLow)) {
          minSize = surfaceSize;
          bestSwizzle = (Addr3SwizzleMode) i;
        }
      }
    }

    if (bestSwizzle < ADDR3_MAX_TYPE) {
      in.swizzleMode = (Addr3SwizzleMode) bestSwizzle;
    } else {
      debug_print("Unable to find a valid swizzleMode for the surface!\n");
      return (uint32_t) -1;
    }
  }


  out.size = sizeof(ADDR3_COMPUTE_SURFACE_INFO_OUTPUT);

  if (ADDR_OK != Addr3ComputeSurfaceInfo(addr_lib_, &in, &out)) {
    return (uint32_t)(-1);
  }
  if (out.surfSize == 0) {
    return (uint32_t)(-1);
  }

  return in.swizzleMode;
}

hsa_status_t ImageManagerGfx12::FillImage(const Image& image, const void* pattern,
                                       const hsa_ext_image_region_t& region) {
  if (BlitQueueInit().queue_ == NULL) {
    return HSA_STATUS_ERROR_OUT_OF_RESOURCES;
  }

  Image* image_view = const_cast<Image*>(&image);

  SQ_BUF_RSRC_WORD3* word3_buff = NULL;
  SQ_IMG_RSRC_WORD3* word3_image = NULL;
  uint32_t dst_sel_w_original = 0;
  if (image_view->desc.format.channel_type ==
      HSA_EXT_IMAGE_CHANNEL_TYPE_UNORM_SHORT_101010) {
    // Force GPU to ignore the last two bits (alpha bits).
    if (image_view->desc.geometry == HSA_EXT_IMAGE_GEOMETRY_1DB) {
      word3_buff = reinterpret_cast<SQ_BUF_RSRC_WORD3*>(&image_view->srd[3]);
      dst_sel_w_original = word3_buff->bits.DST_SEL_W;
      word3_buff->bits.DST_SEL_W = SEL_0;
    } else {
      word3_image = reinterpret_cast<SQ_IMG_RSRC_WORD3*>(&image_view->srd[3]);
      dst_sel_w_original = word3_image->bits.DST_SEL_W;
      word3_image->bits.DST_SEL_W = SEL_0;
    }
  }

  SQ_IMG_RSRC_WORD1* word1 = NULL;
  uint32_t num_format_original = 0;
  const void* new_pattern = pattern;
  float fill_value[4] = {0};
  switch (image_view->desc.format.channel_order) {
    case HSA_EXT_IMAGE_CHANNEL_ORDER_SRGBA:
    case HSA_EXT_IMAGE_CHANNEL_ORDER_SRGB:
    case HSA_EXT_IMAGE_CHANNEL_ORDER_SRGBX:
    case HSA_EXT_IMAGE_CHANNEL_ORDER_SBGRA: {
      // We do not have write support for SRGBA image, so convert pattern
      // to standard form and treat the image as RGBA image.
      const float* pattern_f = reinterpret_cast<const float*>(pattern);
      fill_value[0] = LinearToStandardRGB(pattern_f[0]);
      fill_value[1] = LinearToStandardRGB(pattern_f[1]);
      fill_value[2] = LinearToStandardRGB(pattern_f[2]);
      fill_value[3] = pattern_f[3];
      new_pattern = fill_value;

      ImageProperty image_prop = ImageLut().MapFormat(image.desc.format, image.desc.geometry);

      word1 = reinterpret_cast<SQ_IMG_RSRC_WORD1*>(&image_view->srd[1]);
      num_format_original = word1->bits.FORMAT;
      word1->bits.FORMAT = GetCombinedFormat(image_prop.data_format, TYPE_UNORM);
    } break;
    default:
      break;
  }

  hsa_status_t status = ImageRuntime::instance()->blit_kernel().FillImage(
      blit_queue_, blit_code_catalog_, *image_view, new_pattern, region);

  // Revert back original configuration.
  if (word3_buff != NULL) {
    word3_buff->bits.DST_SEL_W = dst_sel_w_original;
  }

  if (word3_image != NULL) {
    word3_image->bits.DST_SEL_W = dst_sel_w_original;
  }

  if (word1 != NULL) {
    word1->bits.FORMAT = num_format_original;
  }

  return status;
}

}  // namespace image
}  // namespace rocr