cup_edit/thermion_dart/native/src/UnprojectTexture.cpp

#include <filament/Engine.h>
#include <filament/Camera.h>
#include <filament/Texture.h>
#include <filament/VertexBuffer.h>
#include <filament/IndexBuffer.h>
#include <filament/RenderableManager.h>
#include <filament/TransformManager.h>
#include <math/mat4.h>
#include <math/vec2.h>
#include <math/vec3.h>
#include <math/vec4.h>
#include <utils/EntityManager.h>
#include <backend/PixelBufferDescriptor.h>
#include "Log.hpp"
#include <vector>
#include <algorithm>

#include <iostream>

#include "CustomGeometry.hpp"
#include "UnprojectTexture.hpp"

namespace thermion_filament
{

    bool UnprojectTexture::isInsideTriangle(const math::float2 &p, const math::float2 &a, const math::float2 &b, const math::float2 &c)
    {
        float d1 = (p.x - b.x) * (a.y - b.y) - (a.x - b.x) * (p.y - b.y);
        float d2 = (p.x - c.x) * (b.y - c.y) - (b.x - c.x) * (p.y - c.y);
        float d3 = (p.x - a.x) * (c.y - a.y) - (c.x - a.x) * (p.y - a.y);
        return (d1 >= 0 && d2 >= 0 && d3 >= 0) || (d1 <= 0 && d2 <= 0 && d3 <= 0);
    }

    math::float3 UnprojectTexture::barycentric(const math::float2 &p, const math::float2 &a, const math::float2 &b, const math::float2 &c)
    {
        math::float2 v0 = b - a;
        math::float2 v1 = c - a;
        math::float2 v2 = p - a;

        float d00 = dot(v0, v0);
        float d01 = dot(v0, v1);
        float d11 = dot(v1, v1);
        float d20 = dot(v2, v0);
        float d21 = dot(v2, v1);

        float denom = d00 * d11 - d01 * d01;

        float v = (d11 * d20 - d01 * d21) / denom;
        float w = (d00 * d21 - d01 * d20) / denom;
        float u = 1.0f - v - w;

        return math::float3(u, v, w);
    }

    void UnprojectTexture::unproject(utils::Entity entity, const uint8_t *inputTexture, uint8_t *outputTexture,
                                     uint32_t inputWidth, uint32_t inputHeight,
                                     uint32_t outputWidth, uint32_t outputHeight)
    {

        auto &rm = _engine->getRenderableManager();

        auto &tm = _engine->getTransformManager();

        math::mat4 invViewProj = Camera::inverseProjection(_camera.getProjectionMatrix()) * _camera.getModelMatrix();

        auto ti = tm.getInstance(entity);
        math::mat4f worldTransform = tm.getWorldTransform(ti);
        auto inverseWorldTransform = inverse(worldTransform);

        const float *vertices = _geometry->vertices;
        const float *uvs = _geometry->uvs;
        const uint16_t *indices = _geometry->indices;
        uint32_t numIndices = _geometry->numIndices;

        // Create a depth buffer
        std::vector<float> depthBuffer(inputWidth * inputHeight, std::numeric_limits<float>::infinity());

        // Create a buffer to store the triangle index for each pixel
        std::vector<int> triangleIndexBuffer(inputWidth * inputHeight, -1);

        auto max = 0.0f;
        auto min = 99.0f;

        // Depth pre-pass
        for (size_t i = 0; i < numIndices; i += 3)
        {
            math::float3 v0(vertices[indices[i] * 3], vertices[indices[i] * 3 + 1], vertices[indices[i] * 3 + 2]);
            math::float3 v1(vertices[indices[i + 1] * 3], vertices[indices[i + 1] * 3 + 1], vertices[indices[i + 1] * 3 + 2]);
            math::float3 v2(vertices[indices[i + 2] * 3], vertices[indices[i + 2] * 3 + 1], vertices[indices[i + 2] * 3 + 2]);

            math::float2 uv0(uvs[(indices[i] * 2)], uvs[(indices[i] * 2) + 1]);
            math::float2 uv1(uvs[(indices[i + 1] * 2)], uvs[(indices[i + 1] * 2) + 1]);
            math::float2 uv2(uvs[(indices[i + 2] * 2)], uvs[(indices[i + 2] * 2) + 1]);

            // Transform vertices to world space
            v0 = (worldTransform * math::float4(v0, 1.0f)).xyz;
            v1 = (worldTransform * math::float4(v1, 1.0f)).xyz;
            v2 = (worldTransform * math::float4(v2, 1.0f)).xyz;

            // Project vertices to screen space
            math::float4 clipPos0 = _camera.getProjectionMatrix() * _camera.getViewMatrix() * math::float4(v0, 1.0f);
            math::float4 clipPos1 = _camera.getProjectionMatrix() * _camera.getViewMatrix() * math::float4(v1, 1.0f);
            math::float4 clipPos2 = _camera.getProjectionMatrix() * _camera.getViewMatrix() * math::float4(v2, 1.0f);

            math::float3 ndcPos0 = clipPos0.xyz / clipPos0.w;
            math::float3 ndcPos1 = clipPos1.xyz / clipPos1.w;
            math::float3 ndcPos2 = clipPos2.xyz / clipPos2.w;

            // Convert NDC to screen coordinates
            math::float2 screenPos0((ndcPos0.x * 0.5f + 0.5f) * inputWidth, (1.0f - (ndcPos0.y * 0.5f + 0.5f)) * inputHeight);
            math::float2 screenPos1((ndcPos1.x * 0.5f + 0.5f) * inputWidth, (1.0f - (ndcPos1.y * 0.5f + 0.5f)) * inputHeight);
            math::float2 screenPos2((ndcPos2.x * 0.5f + 0.5f) * inputWidth, (1.0f - (ndcPos2.y * 0.5f + 0.5f)) * inputHeight);

            // Compute bounding box of the triangle
            int minX = std::max(0, static_cast<int>(std::min({screenPos0.x, screenPos1.x, screenPos2.x})));
            int maxX = std::min(static_cast<int>(inputWidth) - 1, static_cast<int>(std::max({screenPos0.x, screenPos1.x, screenPos2.x})));
            int minY = std::max(0, static_cast<int>(std::min({screenPos0.y, screenPos1.y, screenPos2.y})));
            int maxY = std::min(static_cast<int>(inputHeight) - 1, static_cast<int>(std::max({screenPos0.y, screenPos1.y, screenPos2.y})));

            // Iterate over the bounding box
            for (int y = minY; y <= maxY; ++y)
            {
                for (int x = minX; x <= maxX; ++x)
                {
                    math::float2 pixelPos(x + 0.5f, y + 0.5f);

                    if (isInsideTriangle(pixelPos, screenPos0, screenPos1, screenPos2))
                    {
                        math::float3 bary = barycentric(pixelPos, screenPos0, screenPos1, screenPos2);

                        // Interpolate depth
                        float depth = bary.x * ndcPos0.z + bary.y * ndcPos1.z + bary.z * ndcPos2.z;

                        // Depth test
                        if (depth < depthBuffer[y * inputWidth + x])
                        {

                            if (depth > max)
                            {
                                max = depth;
                            }
                            if (depth < min)
                            {
                                min = depth;
                            }
                            depthBuffer[y * inputWidth + x] = depth;
                            triangleIndexBuffer[y * inputWidth + x] = i / 3; // Store triangle index
                        }
                    }
                }
            }
        }

        for (uint32_t y = 0; y < outputHeight; ++y)
        {
            for (uint32_t x = 0; x < outputWidth; ++x)
            {

                math::float2 uv(static_cast<float>(x) / outputWidth, static_cast<float>(y) / outputHeight);

                // Use the UV coordinates to get the corresponding 3D position on the renderable
                math::float3 objectPos;
                math::float2 interpolatedUV;
                bool found = false;

                // Iterate over triangles to find which one contains this UV coordinate
                for (size_t i = 0; i < numIndices; i += 3)
                {
                    math::float2 uv0 = *(math::float2 *)&uvs[indices[i] * 2];
                    math::float2 uv1 = *(math::float2 *)&uvs[indices[i + 1] * 2];
                    math::float2 uv2 = *(math::float2 *)&uvs[indices[i + 2] * 2];

                    if (isInsideTriangle(uv, uv0, uv1, uv2))
                    {
                        // Compute barycentric coordinates in UV space
                        math::float3 bary = barycentric(uv, uv0, uv1, uv2);

                        // Interpolate 3D position
                        math::float3 v0(vertices[indices[i] * 3], vertices[indices[i] * 3 + 1], vertices[indices[i] * 3 + 2]);
                        math::float3 v1(vertices[indices[i + 1] * 3], vertices[indices[i + 1] * 3 + 1], vertices[indices[i + 1] * 3 + 2]);
                        math::float3 v2(vertices[indices[i + 2] * 3], vertices[indices[i + 2] * 3 + 1], vertices[indices[i + 2] * 3 + 2]);

                        objectPos = v0 * bary.x + v1 * bary.y + v2 * bary.z;
                        interpolatedUV = uv;

                        // Find the screen coordinates on the input texture
                        math::float3 worldPos = (worldTransform * math::float4(objectPos, 1.0f)).xyz;
                        // Project the world position to screen space
                        math::float4 clipPos = _camera.getProjectionMatrix() * _camera.getViewMatrix() * math::float4(worldPos, 1.0f);
                        math::float3 ndcPos = clipPos.xyz / clipPos.w;
                        // Convert NDC to screen coordinates
                        uint32_t screenX = (ndcPos.x * 0.5f + 0.5f) * inputWidth;
                        uint32_t screenY = (1.0f - (ndcPos.y * 0.5f + 0.5f)) * inputHeight;

                        if (triangleIndexBuffer[(screenY * inputWidth) + screenX] == i / 3)
                        {
                            if (screenX >= 0 && screenX < inputWidth && screenY >= 0 && screenY < inputHeight)
                            {
                                int inputIndex = (screenY * inputWidth + screenX) * 4;
                                int outputIndex = (y * outputWidth + x) * 4;
                                std::copy_n(&inputTexture[inputIndex], 4, &outputTexture[outputIndex]);
                            }
                        }
                    }
                }
            }
        }
    }

} // namespace thermion_filament