ogl_beamforming

das.glsl (13703B)

---

 /* See LICENSE for license details. */
 #if   DataKind == DataKind_Float32
   #define SAMPLE_TYPE           float
   #define TEXTURE_KIND          r32f
   #define RESULT_TYPE_CAST(a)   (a).x
   #define OUTPUT_TYPE_CAST(a)   vec4((a).x, 0, 0, 0)
   #if (ShaderFlags & ShaderFlags_Fast)
     #define RESULT_TYPE         SAMPLE_TYPE
   #else
     #define RESULT_TYPE         vec2
     #define RESULT_LAST_INDEX   1
   #endif
 #elif DataKind == DataKind_Float32Complex
   #define SAMPLE_TYPE           vec2
   #define TEXTURE_KIND          rg32f
   #define RESULT_TYPE_CAST(a)   (a).xy
   #define OUTPUT_TYPE_CAST(a)   vec4((a).xy, 0, 0)
   #if (ShaderFlags & ShaderFlags_Fast)
     #define RESULT_TYPE         SAMPLE_TYPE
   #else
     #define RESULT_TYPE         vec3
     #define RESULT_LAST_INDEX   2
   #endif
 #else
   #error DataKind unsupported for DAS
 #endif
 
 layout(std430, binding = 1) readonly restrict buffer buffer_1 {
 	SAMPLE_TYPE rf_data[];
 };
 
 const bool sparse      = bool(ShaderFlags & ShaderFlags_Sparse);
 const bool interpolate = bool(ShaderFlags & ShaderFlags_Interpolate);
 
 #if (ShaderFlags & ShaderFlags_Fast)
 layout(TEXTURE_KIND, binding = 0)           restrict uniform image3D  u_out_data_tex;
 #else
 layout(TEXTURE_KIND, binding = 0) writeonly restrict uniform image3D  u_out_data_tex;
 #endif
 
 layout(r16i,  binding = 1) readonly  restrict uniform iimage1D sparse_elements;
 layout(rg32f, binding = 2) readonly  restrict uniform image1D  focal_vectors;
 
 #define C_SPLINE 0.5
 
 #if DataKind == DataKind_Float32Complex
 vec2 rotate_iq(vec2 iq, float time)
 {
 	float arg    = radians(360) * demodulation_frequency * time;
 	mat2  phasor = mat2( cos(arg), sin(arg),
 	                    -sin(arg), cos(arg));
 	vec2 result = phasor * iq;
 	return result;
 }
 #else
   #define rotate_iq(a, b) (a)
 #endif
 
 /* NOTE: See: https://cubic.org/docs/hermite.htm */
 SAMPLE_TYPE cubic(int base_index, float index)
 {
 	const mat4 h = mat4(
 		 2, -3,  0, 1,
 		-2,  3,  0, 0,
 		 1, -2,  1, 0,
 		 1, -1,  0, 0
 	);
 
 	float tk, t = modf(index, tk);
 	SAMPLE_TYPE samples[4] = {
 		rf_data[base_index + int(tk) - 1],
 		rf_data[base_index + int(tk) + 0],
 		rf_data[base_index + int(tk) + 1],
 		rf_data[base_index + int(tk) + 2],
 	};
 
 	vec4        S  = vec4(t * t * t, t * t, t, 1);
 	SAMPLE_TYPE P1 = samples[1];
 	SAMPLE_TYPE P2 = samples[2];
 	SAMPLE_TYPE T1 = C_SPLINE * (P2 - samples[0]);
 	SAMPLE_TYPE T2 = C_SPLINE * (samples[3] - P1);
 
 #if   DataKind == DataKind_Float32
 	vec4 C = vec4(P1.x, P2.x, T1.x, T2.x);
 	float result = dot(S, h * C);
 #elif DataKind == DataKind_Float32Complex
 	mat2x4 C = mat2x4(vec4(P1.x, P2.x, T1.x, T2.x), vec4(P1.y, P2.y, T1.y, T2.y));
 	vec2 result = S * h * C;
 #endif
 	return result;
 }
 
 SAMPLE_TYPE sample_rf(int channel, int transmit, float index)
 {
 	SAMPLE_TYPE result = SAMPLE_TYPE(index >= 0.0f) * SAMPLE_TYPE((int(index) + 1 + int(interpolate)) < sample_count);
 	int base_index = int(channel * sample_count * acquisition_count + transmit * sample_count);
 	if (interpolate) result *= cubic(base_index, index);
 	else             result *= rf_data[base_index + int(round(index))];
 	result = rotate_iq(result, index / sampling_frequency);
 	return result;
 }
 
 float sample_index(float distance)
 {
 	float  time = distance / speed_of_sound + time_offset;
 	return time * sampling_frequency;
 }
 
 float apodize(float arg)
 {
 	/* NOTE: used for constant F# dynamic receive apodization. This is implemented as:
 	 *
 	 *                  /        |x_e - x_i|\
 	 *    a(x, z) = cos(F# * π * ----------- ) ^ 2
 	 *                  \        |z_e - z_i|/
 	 *
 	 * where x,z_e are transducer element positions and x,z_i are image positions. */
 	float a = cos(clamp(abs(arg), 0, 0.25 * radians(360)));
 	return a * a;
 }
 
 vec2 rca_plane_projection(vec3 point, bool rows)
 {
 	vec2 result = vec2(point[int(rows)], point[2]);
 	return result;
 }
 
 float plane_wave_transmit_distance(vec3 point, float transmit_angle, bool tx_rows)
 {
 	return dot(rca_plane_projection(point, tx_rows), vec2(sin(transmit_angle), cos(transmit_angle)));
 }
 
 float cylindrical_wave_transmit_distance(vec3 point, float focal_depth, float transmit_angle, bool tx_rows)
 {
 	vec2 f = focal_depth * vec2(sin(transmit_angle), cos(transmit_angle));
 	return distance(rca_plane_projection(point, tx_rows), f);
 }
 
 #if (ShaderFlags & ShaderFlags_Fast)
 RESULT_TYPE RCA(vec3 world_point)
 {
 	bool  tx_rows         = bool((shader_flags & ShaderFlags_TxColumns) == 0);
 	bool  rx_rows         = bool((shader_flags & ShaderFlags_RxColumns) == 0);
 	vec2  xdc_world_point = rca_plane_projection((xdc_transform * vec4(world_point, 1)).xyz, rx_rows);
 	vec2  focal_vector    = imageLoad(focal_vectors, u_channel).xy;
 	float transmit_angle  = radians(focal_vector.x);
 	float focal_depth     = focal_vector.y;
 
 	float transmit_distance;
 	if (isinf(focal_depth)) {
 		transmit_distance = plane_wave_transmit_distance(world_point, transmit_angle, tx_rows);
 	} else {
 		transmit_distance = cylindrical_wave_transmit_distance(world_point, focal_depth,
 		                                                       transmit_angle, tx_rows);
 	}
 
 	RESULT_TYPE result = RESULT_TYPE(0);
 	for (int channel = 0; channel < channel_count; channel++) {
 		vec2  receive_vector   = xdc_world_point - rca_plane_projection(vec3(channel * xdc_element_pitch, 0), rx_rows);
 		float receive_distance = length(receive_vector);
 		float apodization      = apodize(f_number * radians(180) / abs(xdc_world_point.y) * receive_vector.x);
 
 		if (apodization > 0) {
 			float sidx  = sample_index(transmit_distance + receive_distance);
 			result     += apodization * sample_rf(channel, u_channel, sidx);
 		}
 	}
 	return result;
 }
 #else
 RESULT_TYPE RCA(vec3 world_point)
 {
 	bool tx_rows         = bool((shader_flags & ShaderFlags_TxColumns) == 0);
 	bool rx_rows         = bool((shader_flags & ShaderFlags_RxColumns) == 0);
 	vec2 xdc_world_point = rca_plane_projection((xdc_transform * vec4(world_point, 1)).xyz, rx_rows);
 
 	RESULT_TYPE result = RESULT_TYPE(0);
 	for (int transmit = 0; transmit < acquisition_count; transmit++) {
 		vec2  focal_vector   = imageLoad(focal_vectors, transmit).xy;
 		float transmit_angle = radians(focal_vector.x);
 		float focal_depth    = focal_vector.y;
 
 		float transmit_distance;
 		if (isinf(focal_depth)) {
 			transmit_distance = plane_wave_transmit_distance(world_point, transmit_angle, tx_rows);
 		} else {
 			transmit_distance = cylindrical_wave_transmit_distance(world_point, focal_depth,
 			                                                       transmit_angle, tx_rows);
 		}
 
 		for (int rx_channel = 0; rx_channel < channel_count; rx_channel++) {
 			vec3  rx_center      = vec3(rx_channel * xdc_element_pitch, 0);
 			vec2  receive_vector = xdc_world_point - rca_plane_projection(rx_center, rx_rows);
 			float apodization    = apodize(f_number * radians(180) / abs(xdc_world_point.y) * receive_vector.x);
 
 			if (apodization > 0) {
 				float       sidx  = sample_index(transmit_distance + length(receive_vector));
 				SAMPLE_TYPE value = apodization * sample_rf(rx_channel, transmit, sidx);
 				result += RESULT_TYPE(value, length(value));
 			}
 		}
 	}
 	return result;
 }
 #endif
 
 #if (ShaderFlags & ShaderFlags_Fast)
 RESULT_TYPE HERCULES(vec3 world_point)
 {
 	vec3  xdc_world_point = (xdc_transform * vec4(world_point, 1)).xyz;
 	bool  tx_rows         = bool((shader_flags & ShaderFlags_TxColumns) == 0);
 	bool  rx_cols         = bool((shader_flags & ShaderFlags_RxColumns));
 	vec2  focal_vector    = imageLoad(focal_vectors, 0).xy;
 	float transmit_angle  = radians(focal_vector.x);
 	float focal_depth     = focal_vector.y;
 
 	float transmit_distance;
 	if (isinf(focal_depth)) {
 		transmit_distance = plane_wave_transmit_distance(world_point, transmit_angle, tx_rows);
 	} else {
 		transmit_distance = cylindrical_wave_transmit_distance(world_point, focal_depth,
 		                                                       transmit_angle, tx_rows);
 	}
 
 	RESULT_TYPE result = RESULT_TYPE(0);
 	for (int transmit = int(sparse); transmit < acquisition_count; transmit++) {
 		int tx_channel = sparse ? imageLoad(sparse_elements, transmit - int(sparse)).x : transmit;
 		vec3 element_position;
 		if (rx_cols) element_position = vec3(u_channel,  tx_channel, 0) * vec3(xdc_element_pitch, 0);
 		else         element_position = vec3(tx_channel, u_channel,  0) * vec3(xdc_element_pitch, 0);
 
 		float apodization = apodize(f_number * radians(180) / abs(xdc_world_point.z) *
 		                            distance(xdc_world_point.xy, element_position.xy));
 		if (apodization > 0) {
 			/* NOTE: tribal knowledge */
 			if (transmit == 0) apodization *= inversesqrt(acquisition_count);
 
 			float sidx  = sample_index(transmit_distance + distance(xdc_world_point, element_position));
 			result     += apodization * sample_rf(u_channel, transmit, sidx);
 		}
 	}
 	return result;
 }
 #else
 RESULT_TYPE HERCULES(vec3 world_point)
 {
 	vec3  xdc_world_point = (xdc_transform * vec4(world_point, 1)).xyz;
 	bool  tx_rows         = bool((shader_flags & ShaderFlags_TxColumns) == 0);
 	bool  rx_cols         = bool((shader_flags & ShaderFlags_RxColumns));
 	vec2  focal_vector    = imageLoad(focal_vectors, 0).xy;
 	float transmit_angle  = radians(focal_vector.x);
 	float focal_depth     = focal_vector.y;
 
 	float transmit_distance;
 	if (isinf(focal_depth)) {
 		transmit_distance = plane_wave_transmit_distance(world_point, transmit_angle, tx_rows);
 	} else {
 		transmit_distance = cylindrical_wave_transmit_distance(world_point, focal_depth,
 		                                                       transmit_angle, tx_rows);
 	}
 
 	RESULT_TYPE result = RESULT_TYPE(0);
 	for (int transmit = int(sparse); transmit < acquisition_count; transmit++) {
 		int tx_channel = sparse ? imageLoad(sparse_elements, transmit - int(sparse)).x : transmit;
 		for (int rx_channel = 0; rx_channel < channel_count; rx_channel++) {
 			vec3 element_position;
 			if (rx_cols) element_position = vec3(rx_channel, tx_channel, 0) * vec3(xdc_element_pitch, 0);
 			else         element_position = vec3(tx_channel, rx_channel, 0) * vec3(xdc_element_pitch, 0);
 
 			float apodization = apodize(f_number * radians(180) / abs(xdc_world_point.z) *
 			                            distance(xdc_world_point.xy, element_position.xy));
 			if (apodization > 0) {
 				/* NOTE: tribal knowledge */
 				if (transmit == 0) apodization *= inversesqrt(acquisition_count);
 
 				float       sidx  = sample_index(transmit_distance + distance(xdc_world_point, element_position));
 				SAMPLE_TYPE value = apodization * sample_rf(rx_channel, transmit, sidx);
 				result += RESULT_TYPE(value, length(value));
 			}
 		}
 	}
 	return result;
 }
 #endif
 
 #if (ShaderFlags & ShaderFlags_Fast)
 RESULT_TYPE FORCES(vec3 world_point)
 {
 	vec3  xdc_world_point  = (xdc_transform * vec4(world_point, 1)).xyz;
 	float receive_distance = distance(xdc_world_point.xz, vec2(u_channel * xdc_element_pitch.x, 0));
 	float apodization      = apodize(f_number * radians(180) / abs(xdc_world_point.z) *
 	                                 (xdc_world_point.x - u_channel * xdc_element_pitch.x));
 
 	RESULT_TYPE result = RESULT_TYPE(0);
 	if (apodization > 0) {
 		for (int transmit = int(sparse); transmit < acquisition_count; transmit++) {
 			int   tx_channel      = sparse ? imageLoad(sparse_elements, transmit - int(sparse)).x : transmit;
 			vec3  transmit_center = vec3(xdc_element_pitch * vec2(tx_channel, floor(channel_count / 2)), 0);
 
 			float sidx  = sample_index(distance(xdc_world_point, transmit_center) + receive_distance);
 			result     += apodization * sample_rf(u_channel, transmit, sidx);
 		}
 	}
 	return result;
 }
 #else
 RESULT_TYPE FORCES(vec3 world_point)
 {
 	vec3 xdc_world_point = (xdc_transform * vec4(world_point, 1)).xyz;
 
 	RESULT_TYPE result = RESULT_TYPE(0);
 	for (int rx_channel = 0; rx_channel < channel_count; rx_channel++) {
 		float receive_distance = distance(xdc_world_point.xz, vec2(rx_channel * xdc_element_pitch.x, 0));
 		float apodization      = apodize(f_number * radians(180) / abs(xdc_world_point.z) *
 		                                 (xdc_world_point.x - rx_channel * xdc_element_pitch.x));
 		if (apodization > 0) {
 			for (int transmit = int(sparse); transmit < acquisition_count; transmit++) {
 				int   tx_channel      = sparse ? imageLoad(sparse_elements, transmit - int(sparse)).x : transmit;
 				vec3  transmit_center = vec3(xdc_element_pitch * vec2(tx_channel, floor(channel_count / 2)), 0);
 
 				float       sidx  = sample_index(distance(xdc_world_point, transmit_center) + receive_distance);
 				SAMPLE_TYPE value = apodization * sample_rf(rx_channel, transmit, sidx);
 				result += RESULT_TYPE(value, length(value));
 			}
 		}
 	}
 	return result;
 }
 #endif
 
 void main()
 {
 	ivec3 out_voxel = ivec3(gl_GlobalInvocationID);
 	if (!all(lessThan(out_voxel, imageSize(u_out_data_tex))))
 		return;
 
 #if (ShaderFlags & ShaderFlags_Fast)
 	RESULT_TYPE sum = RESULT_TYPE_CAST(imageLoad(u_out_data_tex, out_voxel));
 #else
 	RESULT_TYPE sum = RESULT_TYPE(0);
 	out_voxel += u_voxel_offset;
 #endif
 
 	vec3 world_point = (voxel_transform * vec4(out_voxel, 1)).xyz;
 
 	switch (shader_kind) {
 	case ShaderKind_FORCES:
 	case ShaderKind_UFORCES:
 	{
 		sum += FORCES(world_point);
 	}break;
 	case ShaderKind_HERCULES:
 	case ShaderKind_UHERCULES:
 	{
 		sum += HERCULES(world_point);
 	}break;
 	case ShaderKind_Flash:
 	case ShaderKind_RCA_TPW:
 	case ShaderKind_RCA_VLS:
 	{
 		sum += RCA(world_point);
 	}break;
 	}
 
 	#if (ShaderFlags & ShaderFlags_Fast) == 0
 	/* TODO(rnp): scale such that brightness remains ~constant */
 	if (bool(shader_flags & ShaderFlags_CoherencyWeighting)) {
 		float denominator = sum[RESULT_LAST_INDEX] + float(sum[RESULT_LAST_INDEX] == 0);
 		RESULT_TYPE_CAST(sum) *= RESULT_TYPE_CAST(sum) / denominator;
 	}
 	#endif
 
 	imageStore(u_out_data_tex, out_voxel, OUTPUT_TYPE_CAST(sum));
 }