ogl_beamforming

das.glsl (8687B)

---

 /* See LICENSE for license details. */
 layout(std430, binding = 1) readonly restrict buffer buffer_1 {
 	vec2 rf_data[];
 };
 
 layout(rg32f, binding = 0) writeonly restrict uniform image3D  u_out_data_tex;
 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
 
 #define TX_ROWS 0
 #define TX_COLS 1
 
 #define TX_MODE_TX_COLS(a) (((a) & 2) != 0)
 #define TX_MODE_RX_COLS(a) (((a) & 1) != 0)
 
 /* NOTE: See: https://cubic.org/docs/hermite.htm */
 vec2 cubic(int ridx, float x)
 {
 	mat4 h = mat4(
 		 2, -3,  0, 1,
 		-2,  3,  0, 0,
 		 1, -2,  1, 0,
 		 1, -1,  0, 0
 	);
 
 	int   xk = int(floor(x));
 	float t  = (x  - float(xk));
 	vec4  S  = vec4(t * t * t, t * t, t, 1);
 
 	vec2 P1 = rf_data[ridx + xk];
 	vec2 P2 = rf_data[ridx + xk + 1];
 	vec2 T1 = C_SPLINE * (P2 - rf_data[ridx + xk - 1]);
 	vec2 T2 = C_SPLINE * (rf_data[ridx + xk + 2] - P1);
 
 	vec4 C1 = vec4(P1.x, P2.x, T1.x, T2.x);
 	vec4 C2 = vec4(P1.y, P2.y, T1.y, T2.y);
 	return vec2(dot(S, h * C1), dot(S, h * C2));
 }
 
 vec2 sample_rf(int ridx, float t)
 {
 	vec2 result;
 	if (interpolate) result = cubic(ridx, t);
 	else             result = rf_data[ridx + int(floor(t))];
 	return result;
 }
 
 vec3 calc_image_point(vec3 voxel)
 {
 	vec3 out_data_dim  = vec3(imageSize(u_out_data_tex));
 	vec4 output_size   = abs(output_max_coordinate - output_min_coordinate);
 	vec3 image_point   = output_min_coordinate.xyz + voxel * output_size.xyz / out_data_dim;
 
 	switch (das_shader_id) {
 	case DAS_ID_FORCES:
 	case DAS_ID_UFORCES:
 		/* TODO: fix the math so that the image plane can be aritrary */
 		image_point.y = 0;
 		break;
 	case DAS_ID_HERCULES:
 	case DAS_ID_RCA_TPW:
 	case DAS_ID_RCA_VLS:
 		/* TODO(rnp): this can be removed when we use an abitrary plane transform */
 		if (!all(greaterThan(out_data_dim, vec3(1, 1, 1))))
 			image_point.y = off_axis_pos;
 		break;
 	}
 
 	return image_point;
 }
 
 vec2 apodize(vec2 value, float apodization_arg, float distance)
 {
 	/* NOTE: apodization value for this transducer element */
 	float a  = cos(clamp(abs(apodization_arg * distance), 0, 0.25 * radians(360)));
 	return value * a * a;
 }
 
 vec3 orientation_projection(vec3 point, bool rows)
 {
 	return point * vec3(!rows, rows, 1);
 }
 
 vec3 world_space_to_rca_space(vec3 image_point, bool rx_rows)
 {
 	return orientation_projection((xdc_transform * vec4(image_point, 1)).xyz, rx_rows);
 }
 
 float sample_index(float distance)
 {
 	float  time = distance / speed_of_sound + time_offset;
 	return time * sampling_frequency;
 }
 
 float planewave_transmit_distance(vec3 point, float transmit_angle, bool tx_rows)
 {
 	return dot(orientation_projection(point, tx_rows),
 	           vec3(sin(transmit_angle), sin(transmit_angle), cos(transmit_angle)));
 }
 
 float cylindricalwave_transmit_distance(vec3 point, float focal_depth, float transmit_angle, bool tx_rows)
 {
 	vec3 f = focal_depth * vec3(sin(transmit_angle), sin(transmit_angle), cos(transmit_angle));
 	return length(orientation_projection(point - f, tx_rows));
 }
 
 vec2 RCA(vec3 image_point, vec3 delta, float apodization_arg)
 {
 	int ridx      = 0;
 	int direction = beamform_plane;
 	if (direction != TX_ROWS) image_point = image_point.yxz;
 
 	bool tx_col = TX_MODE_TX_COLS(transmit_mode);
 	bool rx_col = TX_MODE_RX_COLS(transmit_mode);
 
 	vec3 receive_point = world_space_to_rca_space(image_point, !rx_col);
 	delta = orientation_projection(delta, !rx_col);
 
 	vec2 sum = vec2(0);
 	/* NOTE: For Each Acquistion in Raw Data */
 	// uint i = (dec_data_dim.z - 1) * uint(clamp(u_cycle_t, 0, 1)); {
 	for (int i = 0; i < dec_data_dim.z; i++) {
 		float transmit_angle = radians(imageLoad(focal_vectors, i).x);
 		float focal_depth    = imageLoad(focal_vectors, i).y;
 
 		float transmit_distance;
 		if (isinf(focal_depth)) {
 			transmit_distance = planewave_transmit_distance(image_point, transmit_angle,
 			                                                !tx_col);
 		} else {
 			transmit_distance = cylindricalwave_transmit_distance(image_point, focal_depth,
 			                                                      transmit_angle,
 			                                                      !tx_col);
 		}
 
 		vec3 receive_distance = receive_point;
 		/* NOTE: For Each Receiver */
 		// uint j = (dec_data_dim.z - 1) * uint(clamp(u_cycle_t, 0, 1)); {
 		for (uint j = 0; j < dec_data_dim.y; j++) {
 			float sidx  = sample_index(transmit_distance + length(receive_distance));
 			vec2 valid  = vec2(sidx >= 0) * vec2(sidx < dec_data_dim.x);
 			sum        += apodize(sample_rf(ridx, sidx), apodization_arg, length(receive_distance.xy)) * valid;
 			receive_distance -= delta;
 			ridx             += int(dec_data_dim.x);
 		}
 	}
 	return sum;
 }
 
 vec2 HERCULES(vec3 image_point, vec3 delta, float apodization_arg)
 {
 	int uhercules  = int(das_shader_id == DAS_ID_UHERCULES);
 	int ridx       = int(dec_data_dim.y * dec_data_dim.x * uhercules);
 	int  direction = beamform_plane;
 	if (direction != TX_ROWS) image_point = image_point.yxz;
 
 	bool tx_col = TX_MODE_TX_COLS(transmit_mode);
 	bool rx_col = TX_MODE_RX_COLS(transmit_mode);
 	float transmit_angle = radians(imageLoad(focal_vectors, 0).x);
 	float focal_depth    = imageLoad(focal_vectors, 0).y;
 
 	vec3 receive_point = (xdc_transform * vec4(image_point, 1)).xyz;
 
 	float transmit_distance;
 	if (isinf(focal_depth)) {
 		transmit_distance = planewave_transmit_distance(image_point, transmit_angle,
 		                                                !tx_col);
 	} else {
 		transmit_distance = cylindricalwave_transmit_distance(image_point, focal_depth,
 		                                                      transmit_angle,
 		                                                      !tx_col);
 	}
 
 	vec2 sum = vec2(0);
 	/* NOTE: For Each Acquistion in Raw Data */
 	for (int i = uhercules; i < dec_data_dim.z; i++) {
 		int channel = imageLoad(sparse_elements, i - uhercules).x;
 		/* NOTE: For Each Virtual Source */
 		for (uint j = 0; j < dec_data_dim.y; j++) {
 			vec3 element_position;
 			if (rx_col) element_position = vec3(j, channel, 0) * delta;
 			else        element_position = vec3(channel, j, 0) * delta;
 			vec3 receive_distance = receive_point - element_position;
 			float sidx  = sample_index(transmit_distance + length(receive_distance));
 			vec2 valid  = vec2(sidx >= 0) * vec2(sidx < dec_data_dim.x);
 
 			/* NOTE: tribal knowledge */
 			if (i == 0) valid *= inversesqrt(dec_data_dim.z);
 
 			sum  += apodize(sample_rf(ridx, sidx), apodization_arg,
 			                length(receive_distance.xy)) * valid;
 			ridx += int(dec_data_dim.x);
 		}
 	}
 	return sum;
 }
 
 vec2 uFORCES(vec3 image_point, vec3 delta, float apodization_arg)
 {
 	/* NOTE: skip first acquisition in uforces since its garbage */
 	int uforces = int(das_shader_id == DAS_ID_UFORCES);
 	int ridx    = int(dec_data_dim.y * dec_data_dim.x * uforces);
 
 	image_point  = (xdc_transform * vec4(image_point, 1)).xyz;
 
 	vec2 sum = vec2(0);
 	for (int i = uforces; i < dec_data_dim.z; i++) {
 		int   channel        = imageLoad(sparse_elements, i - uforces).x;
 		vec2  recieve_point  = image_point.xz;
 		vec3  element_center = delta * vec3(channel, floor(dec_data_dim.y / 2), 0);
 		float transmit_dist  = distance(image_point, element_center);
 
 		for (uint j = 0; j < dec_data_dim.y; j++) {
 			float sidx  = sample_index(transmit_dist + length(recieve_point));
 			vec2 valid  = vec2(sidx >= 0) * vec2(sidx < dec_data_dim.x);
 			sum        += valid * apodize(sample_rf(ridx, sidx), apodization_arg,
 			                              recieve_point.x);
 			ridx       += int(dec_data_dim.x);
 			recieve_point.x -= delta.x;
 		}
 	}
 	return sum;
 }
 
 void main()
 {
 	/* NOTE: Convert voxel to physical coordinates */
 	ivec3 out_coord   = ivec3(gl_GlobalInvocationID) + u_voxel_offset;
 	vec3  image_point = calc_image_point(vec3(out_coord));
 
 	/* 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 apod_arg = f_number * radians(180) / abs(image_point.z);
 
 	/* NOTE: skip over channels corresponding to other arrays */
 	vec2 sum;
 	switch (das_shader_id) {
 	case DAS_ID_FORCES:
 	case DAS_ID_UFORCES:
 		sum = uFORCES(image_point, vec3(xdc_element_pitch, 0), apod_arg);
 		break;
 	case DAS_ID_HERCULES:
 	case DAS_ID_UHERCULES:
 		sum = HERCULES(image_point, vec3(xdc_element_pitch, 0), apod_arg);
 		break;
 	case DAS_ID_RCA_TPW:
 	case DAS_ID_RCA_VLS:
 		sum = RCA(image_point, vec3(xdc_element_pitch, 0), apod_arg);
 		break;
 	}
 
 	imageStore(u_out_data_tex, out_coord, vec4(sum, 0, 0));
 }