Stable-Dreamfusion / raymarching /src /raymarching.cu

fix https://github.com/ashawkey/stable-dreamfusion/issues/17

69fbfd2 almost 2 years ago

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31.3 kB

	#include <cuda.h>
	#include <cuda_fp16.h>
	#include <cuda_runtime.h>

	#include <ATen/cuda/CUDAContext.h>
	#include <torch/torch.h>

	#include <cstdio>
	#include <stdint.h>
	#include <stdexcept>
	#include <limits>

	#define CHECK_CUDA(x) TORCH_CHECK(x.device().is_cuda(), #x " must be a CUDA tensor")
	#define CHECK_CONTIGUOUS(x) TORCH_CHECK(x.is_contiguous(), #x " must be a contiguous tensor")
	#define CHECK_IS_INT(x) TORCH_CHECK(x.scalar_type() == at::ScalarType::Int, #x " must be an int tensor")
	#define CHECK_IS_FLOATING(x) TORCH_CHECK(x.scalar_type() == at::ScalarType::Float \|\| x.scalar_type() == at::ScalarType::Half \|\| x.scalar_type() == at::ScalarType::Double, #x " must be a floating tensor")


	inline constexpr __device__ float SQRT3() { return 1.7320508075688772f; }
	inline constexpr __device__ float RSQRT3() { return 0.5773502691896258f; }
	inline constexpr __device__ float PI() { return 3.141592653589793f; }
	inline constexpr __device__ float RPI() { return 0.3183098861837907f; }


	template <typename T>
	inline __host__ __device__ T div_round_up(T val, T divisor) {
	return (val + divisor - 1) / divisor;
	}

	inline __host__ __device__ float signf(const float x) {
	return copysignf(1.0, x);
	}

	inline __host__ __device__ float clamp(const float x, const float min, const float max) {
	return fminf(max, fmaxf(min, x));
	}

	inline __host__ __device__ void swapf(float& a, float& b) {
	float c = a; a = b; b = c;
	}

	inline __device__ int mip_from_pos(const float x, const float y, const float z, const float max_cascade) {
	const float mx = fmaxf(fabsf(x), fmaxf(fabs(y), fabs(z)));
	int exponent;
	frexpf(mx, &exponent); // [0, 0.5) --> -1, [0.5, 1) --> 0, [1, 2) --> 1, [2, 4) --> 2, ...
	return fminf(max_cascade - 1, fmaxf(0, exponent));
	}

	inline __device__ int mip_from_dt(const float dt, const float H, const float max_cascade) {
	const float mx = dt * H * 0.5;
	int exponent;
	frexpf(mx, &exponent);
	return fminf(max_cascade - 1, fmaxf(0, exponent));
	}

	inline __host__ __device__ uint32_t __expand_bits(uint32_t v)
	{
	v = (v * 0x00010001u) & 0xFF0000FFu;
	v = (v * 0x00000101u) & 0x0F00F00Fu;
	v = (v * 0x00000011u) & 0xC30C30C3u;
	v = (v * 0x00000005u) & 0x49249249u;
	return v;
	}

	inline __host__ __device__ uint32_t __morton3D(uint32_t x, uint32_t y, uint32_t z)
	{
	uint32_t xx = __expand_bits(x);
	uint32_t yy = __expand_bits(y);
	uint32_t zz = __expand_bits(z);
	return xx \| (yy << 1) \| (zz << 2);
	}

	inline __host__ __device__ uint32_t __morton3D_invert(uint32_t x)
	{
	x = x & 0x49249249;
	x = (x \| (x >> 2)) & 0xc30c30c3;
	x = (x \| (x >> 4)) & 0x0f00f00f;
	x = (x \| (x >> 8)) & 0xff0000ff;
	x = (x \| (x >> 16)) & 0x0000ffff;
	return x;
	}


	////////////////////////////////////////////////////
	///////////// utils /////////////
	////////////////////////////////////////////////////

	// rays_o/d: [N, 3]
	// nears/fars: [N]
	// scalar_t should always be float in use.
	template <typename scalar_t>
	__global__ void kernel_near_far_from_aabb(
	const scalar_t * __restrict__ rays_o,
	const scalar_t * __restrict__ rays_d,
	const scalar_t * __restrict__ aabb,
	const uint32_t N,
	const float min_near,
	scalar_t * nears, scalar_t * fars
	) {
	// parallel per ray
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= N) return;

	// locate
	rays_o += n * 3;
	rays_d += n * 3;

	const float ox = rays_o[0], oy = rays_o[1], oz = rays_o[2];
	const float dx = rays_d[0], dy = rays_d[1], dz = rays_d[2];
	const float rdx = 1 / dx, rdy = 1 / dy, rdz = 1 / dz;

	// get near far (assume cube scene)
	float near = (aabb[0] - ox) * rdx;
	float far = (aabb[3] - ox) * rdx;
	if (near > far) swapf(near, far);

	float near_y = (aabb[1] - oy) * rdy;
	float far_y = (aabb[4] - oy) * rdy;
	if (near_y > far_y) swapf(near_y, far_y);

	if (near > far_y \|\| near_y > far) {
	nears[n] = fars[n] = std::numeric_limits<scalar_t>::max();
	return;
	}

	if (near_y > near) near = near_y;
	if (far_y < far) far = far_y;

	float near_z = (aabb[2] - oz) * rdz;
	float far_z = (aabb[5] - oz) * rdz;
	if (near_z > far_z) swapf(near_z, far_z);

	if (near > far_z \|\| near_z > far) {
	nears[n] = fars[n] = std::numeric_limits<scalar_t>::max();
	return;
	}

	if (near_z > near) near = near_z;
	if (far_z < far) far = far_z;

	if (near < min_near) near = min_near;

	nears[n] = near;
	fars[n] = far;
	}


	void near_far_from_aabb(const at::Tensor rays_o, const at::Tensor rays_d, const at::Tensor aabb, const uint32_t N, const float min_near, at::Tensor nears, at::Tensor fars) {

	static constexpr uint32_t N_THREAD = 128;

	AT_DISPATCH_FLOATING_TYPES_AND_HALF(
	rays_o.scalar_type(), "near_far_from_aabb", ([&] {
	kernel_near_far_from_aabb<<<div_round_up(N, N_THREAD), N_THREAD>>>(rays_o.data_ptr<scalar_t>(), rays_d.data_ptr<scalar_t>(), aabb.data_ptr<scalar_t>(), N, min_near, nears.data_ptr<scalar_t>(), fars.data_ptr<scalar_t>());
	}));
	}


	// rays_o/d: [N, 3]
	// radius: float
	// coords: [N, 2]
	template <typename scalar_t>
	__global__ void kernel_sph_from_ray(
	const scalar_t * __restrict__ rays_o,
	const scalar_t * __restrict__ rays_d,
	const float radius,
	const uint32_t N,
	scalar_t * coords
	) {
	// parallel per ray
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= N) return;

	// locate
	rays_o += n * 3;
	rays_d += n * 3;
	coords += n * 2;

	const float ox = rays_o[0], oy = rays_o[1], oz = rays_o[2];
	const float dx = rays_d[0], dy = rays_d[1], dz = rays_d[2];
	const float rdx = 1 / dx, rdy = 1 / dy, rdz = 1 / dz;

	// solve t from \|\| o + td \|\| = radius
	const float A = dx * dx + dy * dy + dz * dz;
	const float B = ox * dx + oy * dy + oz * dz; // in fact B / 2
	const float C = ox * ox + oy * oy + oz * oz - radius * radius;

	const float t = (- B + sqrtf(B * B - A * C)) / A; // always use the larger solution (positive)

	// solve theta, phi (assume y is the up axis)
	const float x = ox + t * dx, y = oy + t * dy, z = oz + t * dz;
	const float theta = atan2(sqrtf(x * x + z * z), y); // [0, PI)
	const float phi = atan2(z, x); // [-PI, PI)

	// normalize to [-1, 1]
	coords[0] = 2 * theta * RPI() - 1;
	coords[1] = phi * RPI();
	}


	void sph_from_ray(const at::Tensor rays_o, const at::Tensor rays_d, const float radius, const uint32_t N, at::Tensor coords) {

	static constexpr uint32_t N_THREAD = 128;

	AT_DISPATCH_FLOATING_TYPES_AND_HALF(
	rays_o.scalar_type(), "sph_from_ray", ([&] {
	kernel_sph_from_ray<<<div_round_up(N, N_THREAD), N_THREAD>>>(rays_o.data_ptr<scalar_t>(), rays_d.data_ptr<scalar_t>(), radius, N, coords.data_ptr<scalar_t>());
	}));
	}


	// coords: int32, [N, 3]
	// indices: int32, [N]
	__global__ void kernel_morton3D(
	const int * __restrict__ coords,
	const uint32_t N,
	int * indices
	) {
	// parallel
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= N) return;

	// locate
	coords += n * 3;
	indices[n] = __morton3D(coords[0], coords[1], coords[2]);
	}


	void morton3D(const at::Tensor coords, const uint32_t N, at::Tensor indices) {
	static constexpr uint32_t N_THREAD = 128;
	kernel_morton3D<<<div_round_up(N, N_THREAD), N_THREAD>>>(coords.data_ptr<int>(), N, indices.data_ptr<int>());
	}


	// indices: int32, [N]
	// coords: int32, [N, 3]
	__global__ void kernel_morton3D_invert(
	const int * __restrict__ indices,
	const uint32_t N,
	int * coords
	) {
	// parallel
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= N) return;

	// locate
	coords += n * 3;

	const int ind = indices[n];

	coords[0] = __morton3D_invert(ind >> 0);
	coords[1] = __morton3D_invert(ind >> 1);
	coords[2] = __morton3D_invert(ind >> 2);
	}


	void morton3D_invert(const at::Tensor indices, const uint32_t N, at::Tensor coords) {
	static constexpr uint32_t N_THREAD = 128;
	kernel_morton3D_invert<<<div_round_up(N, N_THREAD), N_THREAD>>>(indices.data_ptr<int>(), N, coords.data_ptr<int>());
	}


	// grid: float, [C, H, H, H]
	// N: int, C * H * H * H / 8
	// density_thresh: float
	// bitfield: uint8, [N]
	template <typename scalar_t>
	__global__ void kernel_packbits(
	const scalar_t * __restrict__ grid,
	const uint32_t N,
	const float density_thresh,
	uint8_t * bitfield
	) {
	// parallel per byte
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= N) return;

	// locate
	grid += n * 8;

	uint8_t bits = 0;

	#pragma unroll
	for (uint8_t i = 0; i < 8; i++) {
	bits \|= (grid[i] > density_thresh) ? ((uint8_t)1 << i) : 0;
	}

	bitfield[n] = bits;
	}


	void packbits(const at::Tensor grid, const uint32_t N, const float density_thresh, at::Tensor bitfield) {

	static constexpr uint32_t N_THREAD = 128;

	AT_DISPATCH_FLOATING_TYPES_AND_HALF(
	grid.scalar_type(), "packbits", ([&] {
	kernel_packbits<<<div_round_up(N, N_THREAD), N_THREAD>>>(grid.data_ptr<scalar_t>(), N, density_thresh, bitfield.data_ptr<uint8_t>());
	}));
	}

	////////////////////////////////////////////////////
	///////////// training /////////////
	////////////////////////////////////////////////////

	// rays_o/d: [N, 3]
	// grid: [CHHH / 8]
	// xyzs, dirs, deltas: [M, 3], [M, 3], [M, 2]
	// dirs: [M, 3]
	// rays: [N, 3], idx, offset, num_steps
	template <typename scalar_t>
	__global__ void kernel_march_rays_train(
	const scalar_t * __restrict__ rays_o,
	const scalar_t * __restrict__ rays_d,
	const uint8_t * __restrict__ grid,
	const float bound,
	const float dt_gamma, const uint32_t max_steps,
	const uint32_t N, const uint32_t C, const uint32_t H, const uint32_t M,
	const scalar_t* __restrict__ nears,
	const scalar_t* __restrict__ fars,
	scalar_t * xyzs, scalar_t * dirs, scalar_t * deltas,
	int * rays,
	int * counter,
	const scalar_t* __restrict__ noises
	) {
	// parallel per ray
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= N) return;

	// locate
	rays_o += n * 3;
	rays_d += n * 3;

	// ray marching
	const float ox = rays_o[0], oy = rays_o[1], oz = rays_o[2];
	const float dx = rays_d[0], dy = rays_d[1], dz = rays_d[2];
	const float rdx = 1 / dx, rdy = 1 / dy, rdz = 1 / dz;
	const float rH = 1 / (float)H;
	const float H3 = H * H * H;

	const float near = nears[n];
	const float far = fars[n];
	const float noise = noises[n];

	const float dt_min = 2 * SQRT3() / max_steps;
	const float dt_max = 2 * SQRT3() * (1 << (C - 1)) / H;

	float t0 = near;

	// perturb
	t0 += clamp(t0 * dt_gamma, dt_min, dt_max) * noise;

	// first pass: estimation of num_steps
	float t = t0;
	uint32_t num_steps = 0;

	//if (t < far) printf("valid ray %d t=%f near=%f far=%f \n", n, t, near, far);

	while (t < far && num_steps < max_steps) {
	// current point
	const float x = clamp(ox + t * dx, -bound, bound);
	const float y = clamp(oy + t * dy, -bound, bound);
	const float z = clamp(oz + t * dz, -bound, bound);

	const float dt = clamp(t * dt_gamma, dt_min, dt_max);

	// get mip level
	const int level = max(mip_from_pos(x, y, z, C), mip_from_dt(dt, H, C)); // range in [0, C - 1]

	const float mip_bound = fminf(scalbnf(1.0f, level), bound);
	const float mip_rbound = 1 / mip_bound;

	// convert to nearest grid position
	const int nx = clamp(0.5 * (x * mip_rbound + 1) * H, 0.0f, (float)(H - 1));
	const int ny = clamp(0.5 * (y * mip_rbound + 1) * H, 0.0f, (float)(H - 1));
	const int nz = clamp(0.5 * (z * mip_rbound + 1) * H, 0.0f, (float)(H - 1));

	const uint32_t index = level * H3 + __morton3D(nx, ny, nz);
	const bool occ = grid[index / 8] & (1 << (index % 8));

	// if occpuied, advance a small step, and write to output
	//if (n == 0) printf("t=%f density=%f vs thresh=%f step=%d\n", t, density, density_thresh, num_steps);

	if (occ) {
	num_steps++;
	t += dt;
	// else, skip a large step (basically skip a voxel grid)
	} else {
	// calc distance to next voxel
	const float tx = (((nx + 0.5f + 0.5f * signf(dx)) * rH * 2 - 1) * mip_bound - x) * rdx;
	const float ty = (((ny + 0.5f + 0.5f * signf(dy)) * rH * 2 - 1) * mip_bound - y) * rdy;
	const float tz = (((nz + 0.5f + 0.5f * signf(dz)) * rH * 2 - 1) * mip_bound - z) * rdz;

	const float tt = t + fmaxf(0.0f, fminf(tx, fminf(ty, tz)));
	// step until next voxel
	do {
	t += clamp(t * dt_gamma, dt_min, dt_max);
	} while (t < tt);
	}
	}

	//printf("[n=%d] num_steps=%d, near=%f, far=%f, dt=%f, max_steps=%f\n", n, num_steps, near, far, dt_min, (far - near) / dt_min);

	// second pass: really locate and write points & dirs
	uint32_t point_index = atomicAdd(counter, num_steps);
	uint32_t ray_index = atomicAdd(counter + 1, 1);

	//printf("[n=%d] num_steps=%d, point_index=%d, ray_index=%d\n", n, num_steps, point_index, ray_index);

	// write rays
	rays[ray_index * 3] = n;
	rays[ray_index * 3 + 1] = point_index;
	rays[ray_index * 3 + 2] = num_steps;

	if (num_steps == 0) return;
	if (point_index + num_steps > M) return;

	xyzs += point_index * 3;
	dirs += point_index * 3;
	deltas += point_index * 2;

	t = t0;
	uint32_t step = 0;

	float last_t = t;

	while (t < far && step < num_steps) {
	// current point
	const float x = clamp(ox + t * dx, -bound, bound);
	const float y = clamp(oy + t * dy, -bound, bound);
	const float z = clamp(oz + t * dz, -bound, bound);

	const float dt = clamp(t * dt_gamma, dt_min, dt_max);

	// get mip level
	const int level = max(mip_from_pos(x, y, z, C), mip_from_dt(dt, H, C)); // range in [0, C - 1]

	const float mip_bound = fminf(scalbnf(1.0f, level), bound);
	const float mip_rbound = 1 / mip_bound;

	// convert to nearest grid position
	const int nx = clamp(0.5 * (x * mip_rbound + 1) * H, 0.0f, (float)(H - 1));
	const int ny = clamp(0.5 * (y * mip_rbound + 1) * H, 0.0f, (float)(H - 1));
	const int nz = clamp(0.5 * (z * mip_rbound + 1) * H, 0.0f, (float)(H - 1));

	// query grid
	const uint32_t index = level * H3 + __morton3D(nx, ny, nz);
	const bool occ = grid[index / 8] & (1 << (index % 8));

	// if occpuied, advance a small step, and write to output
	if (occ) {
	// write step
	xyzs[0] = x;
	xyzs[1] = y;
	xyzs[2] = z;
	dirs[0] = dx;
	dirs[1] = dy;
	dirs[2] = dz;
	t += dt;
	deltas[0] = dt;
	deltas[1] = t - last_t; // used to calc depth
	last_t = t;
	xyzs += 3;
	dirs += 3;
	deltas += 2;
	step++;
	// else, skip a large step (basically skip a voxel grid)
	} else {
	// calc distance to next voxel
	const float tx = (((nx + 0.5f + 0.5f * signf(dx)) * rH * 2 - 1) * mip_bound - x) * rdx;
	const float ty = (((ny + 0.5f + 0.5f * signf(dy)) * rH * 2 - 1) * mip_bound - y) * rdy;
	const float tz = (((nz + 0.5f + 0.5f * signf(dz)) * rH * 2 - 1) * mip_bound - z) * rdz;
	const float tt = t + fmaxf(0.0f, fminf(tx, fminf(ty, tz)));
	// step until next voxel
	do {
	t += clamp(t * dt_gamma, dt_min, dt_max);
	} while (t < tt);
	}
	}
	}

	void march_rays_train(const at::Tensor rays_o, const at::Tensor rays_d, const at::Tensor grid, const float bound, const float dt_gamma, const uint32_t max_steps, const uint32_t N, const uint32_t C, const uint32_t H, const uint32_t M, const at::Tensor nears, const at::Tensor fars, at::Tensor xyzs, at::Tensor dirs, at::Tensor deltas, at::Tensor rays, at::Tensor counter, at::Tensor noises) {

	static constexpr uint32_t N_THREAD = 128;

	AT_DISPATCH_FLOATING_TYPES_AND_HALF(
	rays_o.scalar_type(), "march_rays_train", ([&] {
	kernel_march_rays_train<<<div_round_up(N, N_THREAD), N_THREAD>>>(rays_o.data_ptr<scalar_t>(), rays_d.data_ptr<scalar_t>(), grid.data_ptr<uint8_t>(), bound, dt_gamma, max_steps, N, C, H, M, nears.data_ptr<scalar_t>(), fars.data_ptr<scalar_t>(), xyzs.data_ptr<scalar_t>(), dirs.data_ptr<scalar_t>(), deltas.data_ptr<scalar_t>(), rays.data_ptr<int>(), counter.data_ptr<int>(), noises.data_ptr<scalar_t>());
	}));
	}


	// sigmas: [M]
	// rgbs: [M, 3]
	// deltas: [M, 2]
	// rays: [N, 3], idx, offset, num_steps
	// weights_sum: [N], final pixel alpha
	// depth: [N,]
	// image: [N, 3]
	template <typename scalar_t>
	__global__ void kernel_composite_rays_train_forward(
	const scalar_t * __restrict__ sigmas,
	const scalar_t * __restrict__ rgbs,
	const scalar_t * __restrict__ deltas,
	const int * __restrict__ rays,
	const uint32_t M, const uint32_t N, const float T_thresh,
	scalar_t * weights_sum,
	scalar_t * depth,
	scalar_t * image
	) {
	// parallel per ray
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= N) return;

	// locate
	uint32_t index = rays[n * 3];
	uint32_t offset = rays[n * 3 + 1];
	uint32_t num_steps = rays[n * 3 + 2];

	// empty ray, or ray that exceed max step count.
	if (num_steps == 0 \|\| offset + num_steps > M) {
	weights_sum[index] = 0;
	depth[index] = 0;
	image[index * 3] = 0;
	image[index * 3 + 1] = 0;
	image[index * 3 + 2] = 0;
	return;
	}

	sigmas += offset;
	rgbs += offset * 3;
	deltas += offset * 2;

	// accumulate
	uint32_t step = 0;

	scalar_t T = 1.0f;
	scalar_t r = 0, g = 0, b = 0, ws = 0, t = 0, d = 0;

	while (step < num_steps) {

	const scalar_t alpha = 1.0f - __expf(- sigmas[0] * deltas[0]);
	const scalar_t weight = alpha * T;

	r += weight * rgbs[0];
	g += weight * rgbs[1];
	b += weight * rgbs[2];

	t += deltas[1]; // real delta
	d += weight * t;

	ws += weight;

	T *= 1.0f - alpha;

	// minimal remained transmittence
	if (T < T_thresh) break;

	//printf("[n=%d] num_steps=%d, alpha=%f, w=%f, T=%f, sum_dt=%f, d=%f\n", n, step, alpha, weight, T, sum_delta, d);

	// locate
	sigmas++;
	rgbs += 3;
	deltas += 2;

	step++;
	}

	//printf("[n=%d] rgb=(%f, %f, %f), d=%f\n", n, r, g, b, d);

	// write
	weights_sum[index] = ws; // weights_sum
	depth[index] = d;
	image[index * 3] = r;
	image[index * 3 + 1] = g;
	image[index * 3 + 2] = b;
	}


	void composite_rays_train_forward(const at::Tensor sigmas, const at::Tensor rgbs, const at::Tensor deltas, const at::Tensor rays, const uint32_t M, const uint32_t N, const float T_thresh, at::Tensor weights_sum, at::Tensor depth, at::Tensor image) {

	static constexpr uint32_t N_THREAD = 128;

	AT_DISPATCH_FLOATING_TYPES_AND_HALF(
	sigmas.scalar_type(), "composite_rays_train_forward", ([&] {
	kernel_composite_rays_train_forward<<<div_round_up(N, N_THREAD), N_THREAD>>>(sigmas.data_ptr<scalar_t>(), rgbs.data_ptr<scalar_t>(), deltas.data_ptr<scalar_t>(), rays.data_ptr<int>(), M, N, T_thresh, weights_sum.data_ptr<scalar_t>(), depth.data_ptr<scalar_t>(), image.data_ptr<scalar_t>());
	}));
	}


	// grad_weights_sum: [N,]
	// grad: [N, 3]
	// sigmas: [M]
	// rgbs: [M, 3]
	// deltas: [M, 2]
	// rays: [N, 3], idx, offset, num_steps
	// weights_sum: [N,], weights_sum here
	// image: [N, 3]
	// grad_sigmas: [M]
	// grad_rgbs: [M, 3]
	template <typename scalar_t>
	__global__ void kernel_composite_rays_train_backward(
	const scalar_t * __restrict__ grad_weights_sum,
	const scalar_t * __restrict__ grad_image,
	const scalar_t * __restrict__ sigmas,
	const scalar_t * __restrict__ rgbs,
	const scalar_t * __restrict__ deltas,
	const int * __restrict__ rays,
	const scalar_t * __restrict__ weights_sum,
	const scalar_t * __restrict__ image,
	const uint32_t M, const uint32_t N, const float T_thresh,
	scalar_t * grad_sigmas,
	scalar_t * grad_rgbs
	) {
	// parallel per ray
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= N) return;

	// locate
	uint32_t index = rays[n * 3];
	uint32_t offset = rays[n * 3 + 1];
	uint32_t num_steps = rays[n * 3 + 2];

	if (num_steps == 0 \|\| offset + num_steps > M) return;

	grad_weights_sum += index;
	grad_image += index * 3;
	weights_sum += index;
	image += index * 3;
	sigmas += offset;
	rgbs += offset * 3;
	deltas += offset * 2;
	grad_sigmas += offset;
	grad_rgbs += offset * 3;

	// accumulate
	uint32_t step = 0;

	scalar_t T = 1.0f;
	const scalar_t r_final = image[0], g_final = image[1], b_final = image[2], ws_final = weights_sum[0];
	scalar_t r = 0, g = 0, b = 0, ws = 0;

	while (step < num_steps) {

	const scalar_t alpha = 1.0f - __expf(- sigmas[0] * deltas[0]);
	const scalar_t weight = alpha * T;

	r += weight * rgbs[0];
	g += weight * rgbs[1];
	b += weight * rgbs[2];
	ws += weight;

	T *= 1.0f - alpha;

	// check https://note.kiui.moe/others/nerf_gradient/ for the gradient calculation.
	// write grad_rgbs
	grad_rgbs[0] = grad_image[0] * weight;
	grad_rgbs[1] = grad_image[1] * weight;
	grad_rgbs[2] = grad_image[2] * weight;

	// write grad_sigmas
	grad_sigmas[0] = deltas[0] * (
	grad_image[0] * (T * rgbs[0] - (r_final - r)) +
	grad_image[1] * (T * rgbs[1] - (g_final - g)) +
	grad_image[2] * (T * rgbs[2] - (b_final - b)) +
	grad_weights_sum[0] * (1 - ws_final)
	);

	//printf("[n=%d] num_steps=%d, T=%f, grad_sigmas=%f, r_final=%f, r=%f\n", n, step, T, grad_sigmas[0], r_final, r);
	// minimal remained transmittence
	if (T < T_thresh) break;

	// locate
	sigmas++;
	rgbs += 3;
	deltas += 2;
	grad_sigmas++;
	grad_rgbs += 3;

	step++;
	}
	}


	void composite_rays_train_backward(const at::Tensor grad_weights_sum, const at::Tensor grad_image, const at::Tensor sigmas, const at::Tensor rgbs, const at::Tensor deltas, const at::Tensor rays, const at::Tensor weights_sum, const at::Tensor image, const uint32_t M, const uint32_t N, const float T_thresh, at::Tensor grad_sigmas, at::Tensor grad_rgbs) {

	static constexpr uint32_t N_THREAD = 128;

	AT_DISPATCH_FLOATING_TYPES_AND_HALF(
	grad_image.scalar_type(), "composite_rays_train_backward", ([&] {
	kernel_composite_rays_train_backward<<<div_round_up(N, N_THREAD), N_THREAD>>>(grad_weights_sum.data_ptr<scalar_t>(), grad_image.data_ptr<scalar_t>(), sigmas.data_ptr<scalar_t>(), rgbs.data_ptr<scalar_t>(), deltas.data_ptr<scalar_t>(), rays.data_ptr<int>(), weights_sum.data_ptr<scalar_t>(), image.data_ptr<scalar_t>(), M, N, T_thresh, grad_sigmas.data_ptr<scalar_t>(), grad_rgbs.data_ptr<scalar_t>());
	}));
	}


	////////////////////////////////////////////////////
	///////////// infernce /////////////
	////////////////////////////////////////////////////

	template <typename scalar_t>
	__global__ void kernel_march_rays(
	const uint32_t n_alive,
	const uint32_t n_step,
	const int* __restrict__ rays_alive,
	const scalar_t* __restrict__ rays_t,
	const scalar_t* __restrict__ rays_o,
	const scalar_t* __restrict__ rays_d,
	const float bound,
	const float dt_gamma, const uint32_t max_steps,
	const uint32_t C, const uint32_t H,
	const uint8_t * __restrict__ grid,
	const scalar_t* __restrict__ nears,
	const scalar_t* __restrict__ fars,
	scalar_t* xyzs, scalar_t* dirs, scalar_t* deltas,
	const scalar_t* __restrict__ noises
	) {
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= n_alive) return;

	const int index = rays_alive[n]; // ray id
	const float noise = noises[n];

	// locate
	rays_o += index * 3;
	rays_d += index * 3;
	xyzs += n * n_step * 3;
	dirs += n * n_step * 3;
	deltas += n * n_step * 2;

	const float ox = rays_o[0], oy = rays_o[1], oz = rays_o[2];
	const float dx = rays_d[0], dy = rays_d[1], dz = rays_d[2];
	const float rdx = 1 / dx, rdy = 1 / dy, rdz = 1 / dz;
	const float rH = 1 / (float)H;
	const float H3 = H * H * H;

	float t = rays_t[index]; // current ray's t
	const float near = nears[index], far = fars[index];

	const float dt_min = 2 * SQRT3() / max_steps;
	const float dt_max = 2 * SQRT3() * (1 << (C - 1)) / H;

	// march for n_step steps, record points
	uint32_t step = 0;

	// introduce some randomness
	t += clamp(t * dt_gamma, dt_min, dt_max) * noise;

	float last_t = t;

	while (t < far && step < n_step) {
	// current point
	const float x = clamp(ox + t * dx, -bound, bound);
	const float y = clamp(oy + t * dy, -bound, bound);
	const float z = clamp(oz + t * dz, -bound, bound);

	const float dt = clamp(t * dt_gamma, dt_min, dt_max);

	// get mip level
	const int level = max(mip_from_pos(x, y, z, C), mip_from_dt(dt, H, C)); // range in [0, C - 1]

	const float mip_bound = fminf(scalbnf(1, level), bound);
	const float mip_rbound = 1 / mip_bound;

	// convert to nearest grid position
	const int nx = clamp(0.5 * (x * mip_rbound + 1) * H, 0.0f, (float)(H - 1));
	const int ny = clamp(0.5 * (y * mip_rbound + 1) * H, 0.0f, (float)(H - 1));
	const int nz = clamp(0.5 * (z * mip_rbound + 1) * H, 0.0f, (float)(H - 1));

	const uint32_t index = level * H3 + __morton3D(nx, ny, nz);
	const bool occ = grid[index / 8] & (1 << (index % 8));

	// if occpuied, advance a small step, and write to output
	if (occ) {
	// write step
	xyzs[0] = x;
	xyzs[1] = y;
	xyzs[2] = z;
	dirs[0] = dx;
	dirs[1] = dy;
	dirs[2] = dz;
	// calc dt
	t += dt;
	deltas[0] = dt;
	deltas[1] = t - last_t; // used to calc depth
	last_t = t;
	// step
	xyzs += 3;
	dirs += 3;
	deltas += 2;
	step++;

	// else, skip a large step (basically skip a voxel grid)
	} else {
	// calc distance to next voxel
	const float tx = (((nx + 0.5f + 0.5f * signf(dx)) * rH * 2 - 1) * mip_bound - x) * rdx;
	const float ty = (((ny + 0.5f + 0.5f * signf(dy)) * rH * 2 - 1) * mip_bound - y) * rdy;
	const float tz = (((nz + 0.5f + 0.5f * signf(dz)) * rH * 2 - 1) * mip_bound - z) * rdz;
	const float tt = t + fmaxf(0.0f, fminf(tx, fminf(ty, tz)));
	// step until next voxel
	do {
	t += clamp(t * dt_gamma, dt_min, dt_max);
	} while (t < tt);
	}
	}
	}


	void march_rays(const uint32_t n_alive, const uint32_t n_step, const at::Tensor rays_alive, const at::Tensor rays_t, const at::Tensor rays_o, const at::Tensor rays_d, const float bound, const float dt_gamma, const uint32_t max_steps, const uint32_t C, const uint32_t H, const at::Tensor grid, const at::Tensor near, const at::Tensor far, at::Tensor xyzs, at::Tensor dirs, at::Tensor deltas, at::Tensor noises) {
	static constexpr uint32_t N_THREAD = 128;

	AT_DISPATCH_FLOATING_TYPES_AND_HALF(
	rays_o.scalar_type(), "march_rays", ([&] {
	kernel_march_rays<<<div_round_up(n_alive, N_THREAD), N_THREAD>>>(n_alive, n_step, rays_alive.data_ptr<int>(), rays_t.data_ptr<scalar_t>(), rays_o.data_ptr<scalar_t>(), rays_d.data_ptr<scalar_t>(), bound, dt_gamma, max_steps, C, H, grid.data_ptr<uint8_t>(), near.data_ptr<scalar_t>(), far.data_ptr<scalar_t>(), xyzs.data_ptr<scalar_t>(), dirs.data_ptr<scalar_t>(), deltas.data_ptr<scalar_t>(), noises.data_ptr<scalar_t>());
	}));
	}


	template <typename scalar_t>
	__global__ void kernel_composite_rays(
	const uint32_t n_alive,
	const uint32_t n_step,
	const float T_thresh,
	int* rays_alive,
	scalar_t* rays_t,
	const scalar_t* __restrict__ sigmas,
	const scalar_t* __restrict__ rgbs,
	const scalar_t* __restrict__ deltas,
	scalar_t* weights_sum, scalar_t* depth, scalar_t* image
	) {
	const uint32_t n = threadIdx.x + blockIdx.x * blockDim.x;
	if (n >= n_alive) return;

	const int index = rays_alive[n]; // ray id

	// locate
	sigmas += n * n_step;
	rgbs += n * n_step * 3;
	deltas += n * n_step * 2;

	rays_t += index;
	weights_sum += index;
	depth += index;
	image += index * 3;

	scalar_t t = rays_t[0]; // current ray's t

	scalar_t weight_sum = weights_sum[0];
	scalar_t d = depth[0];
	scalar_t r = image[0];
	scalar_t g = image[1];
	scalar_t b = image[2];

	// accumulate
	uint32_t step = 0;
	while (step < n_step) {

	// ray is terminated if delta == 0
	if (deltas[0] == 0) break;

	const scalar_t alpha = 1.0f - __expf(- sigmas[0] * deltas[0]);

	/*
	T_0 = 1; T_i = \prod_{j=0}^{i-1} (1 - alpha_j)
	w_i = alpha_i * T_i
	-->
	T_i = 1 - \sum_{j=0}^{i-1} w_j
	*/
	const scalar_t T = 1 - weight_sum;
	const scalar_t weight = alpha * T;
	weight_sum += weight;

	t += deltas[1]; // real delta
	d += weight * t;
	r += weight * rgbs[0];
	g += weight * rgbs[1];
	b += weight * rgbs[2];

	//printf("[n=%d] num_steps=%d, alpha=%f, w=%f, T=%f, sum_dt=%f, d=%f\n", n, step, alpha, weight, T, sum_delta, d);

	// ray is terminated if T is too small
	// use a larger bound to further accelerate inference
	if (T < T_thresh) break;

	// locate
	sigmas++;
	rgbs += 3;
	deltas += 2;
	step++;
	}

	//printf("[n=%d] rgb=(%f, %f, %f), d=%f\n", n, r, g, b, d);

	// rays_alive = -1 means ray is terminated early.
	if (step < n_step) {
	rays_alive[n] = -1;
	} else {
	rays_t[0] = t;
	}

	weights_sum[0] = weight_sum; // this is the thing I needed!
	depth[0] = d;
	image[0] = r;
	image[1] = g;
	image[2] = b;
	}


	void composite_rays(const uint32_t n_alive, const uint32_t n_step, const float T_thresh, at::Tensor rays_alive, at::Tensor rays_t, at::Tensor sigmas, at::Tensor rgbs, at::Tensor deltas, at::Tensor weights, at::Tensor depth, at::Tensor image) {
	static constexpr uint32_t N_THREAD = 128;
	AT_DISPATCH_FLOATING_TYPES_AND_HALF(
	image.scalar_type(), "composite_rays", ([&] {
	kernel_composite_rays<<<div_round_up(n_alive, N_THREAD), N_THREAD>>>(n_alive, n_step, T_thresh, rays_alive.data_ptr<int>(), rays_t.data_ptr<scalar_t>(), sigmas.data_ptr<scalar_t>(), rgbs.data_ptr<scalar_t>(), deltas.data_ptr<scalar_t>(), weights.data_ptr<scalar_t>(), depth.data_ptr<scalar_t>(), image.data_ptr<scalar_t>());
	}));
	}