ogl_beamforming

beamformer.c (58303B)

---

 /* See LICENSE for license details. */
 /* TODO(rnp):
  * [ ]: measure performance of doing channel mapping in a separate shader
  * [ ]: BeamformWorkQueue -> BeamformerWorkQueue
  * [ ]: need to keep track of gpu memory in some way
  *      - want to be able to store more than 16 2D frames but limit 3D frames
  *      - maybe keep track of how much gpu memory is committed for beamformed images
  *        and use that to determine when to loop back over existing textures
  *      - to do this maybe use a circular linked list instead of a flat array
  *      - then have a way of querying how many frames are available for a specific point count
  * [ ]: bug: reinit cuda on hot-reload
  */
 
 #include "beamformer.h"
 
 global f32 dt_for_frame;
 global u32 cycle_t;
 
 #ifndef _DEBUG
 #define start_renderdoc_capture(...)
 #define end_renderdoc_capture(...)
 #else
 global renderdoc_start_frame_capture_fn *start_frame_capture;
 global renderdoc_end_frame_capture_fn   *end_frame_capture;
 #define start_renderdoc_capture(gl) if (start_frame_capture) start_frame_capture(gl, 0)
 #define end_renderdoc_capture(gl)   if (end_frame_capture)   end_frame_capture(gl, 0)
 #endif
 
 typedef struct {
 	BeamformerFrame *frames;
 	u32 capacity;
 	u32 offset;
 	u32 cursor;
 	u32 needed_frames;
 } ComputeFrameIterator;
 
 function void
 beamformer_compute_plan_release(BeamformerComputeContext *cc, u32 block)
 {
 	assert(block < countof(cc->compute_plans));
 	BeamformerComputePlan *cp = cc->compute_plans[block];
 	if (cp) {
 		glDeleteBuffers(countof(cp->ubos), cp->ubos);
 		glDeleteTextures(countof(cp->textures), cp->textures);
 		for (u32 i = 0; i < countof(cp->filters); i++)
 			glDeleteTextures(1, &cp->filters[i].texture);
 		cc->compute_plans[block] = 0;
 		SLLPushFreelist(cp, cc->compute_plan_freelist);
 	}
 }
 
 function BeamformerComputePlan *
 beamformer_compute_plan_for_block(BeamformerComputeContext *cc, u32 block, Arena *arena)
 {
 	assert(block < countof(cc->compute_plans));
 	BeamformerComputePlan *result = cc->compute_plans[block];
 	if (!result) {
 		result = SLLPopFreelist(cc->compute_plan_freelist);
 		if (result) zero_struct(result);
 		else        result = push_struct(arena, BeamformerComputePlan);
 		cc->compute_plans[block] = result;
 
 		glCreateBuffers(countof(result->ubos), result->ubos);
 
 		Stream label = arena_stream(*arena);
 		#define X(k, t, ...) \
 			glNamedBufferStorage(result->ubos[BeamformerComputeUBOKind_##k], sizeof(t), \
 			                     0, GL_DYNAMIC_STORAGE_BIT); \
 			stream_append_s8(&label, s8(#t "[")); \
 			stream_append_u64(&label, block);     \
 			stream_append_byte(&label, ']');      \
 			glObjectLabel(GL_BUFFER, result->ubos[BeamformerComputeUBOKind_##k], \
 			              label.widx, (c8 *)label.data); \
 			label.widx = 0;
 		BEAMFORMER_COMPUTE_UBO_LIST
 		#undef X
 
 		#define X(_k, t, ...) t,
 		GLenum gl_kind[] = {BEAMFORMER_COMPUTE_TEXTURE_LIST};
 		#undef X
 		read_only local_persist s8 tex_prefix[] = {
 			#define X(k, ...) s8_comp(#k "["),
 			BEAMFORMER_COMPUTE_TEXTURE_LIST
 			#undef X
 		};
 		glCreateTextures(GL_TEXTURE_1D, BeamformerComputeTextureKind_Count - 1, result->textures);
 		for (u32 i = 0; i < BeamformerComputeTextureKind_Count - 1; i++) {
 			/* TODO(rnp): this could be predicated on channel count for this compute plan */
 			glTextureStorage1D(result->textures[i], 1, gl_kind[i], BeamformerMaxChannelCount);
 			stream_append_s8(&label, tex_prefix[i]);
 			stream_append_u64(&label, block);
 			stream_append_byte(&label, ']');
 			glObjectLabel(GL_TEXTURE, result->textures[i], label.widx, (c8 *)label.data);
 			label.widx = 0;
 		}
 	}
 	return result;
 }
 
 function void
 beamformer_filter_update(BeamformerFilter *f, BeamformerFilterKind kind,
                          BeamformerFilterParameters fp, u32 block, u32 slot, Arena arena)
 {
 	#define X(k, ...) s8_comp(#k "Filter"),
 	read_only local_persist s8 filter_kinds[] = {BEAMFORMER_FILTER_KIND_LIST(,)};
 	#undef X
 
 	Stream sb = arena_stream(arena);
 	stream_append_s8s(&sb, filter_kinds[kind % countof(filter_kinds)], s8("["));
 	stream_append_u64(&sb, block);
 	stream_append_s8(&sb, s8("]["));
 	stream_append_u64(&sb, slot);
 	stream_append_byte(&sb, ']');
 	s8 label = arena_stream_commit(&arena, &sb);
 
 	void *filter = 0;
 	switch (kind) {
 	case BeamformerFilterKind_Kaiser:{
 		/* TODO(rnp): this should also support complex */
 		/* TODO(rnp): implement this as an IFIR filter instead to reduce computation */
 		filter = kaiser_low_pass_filter(&arena, fp.Kaiser.cutoff_frequency, fp.sampling_frequency,
 		                                fp.Kaiser.beta, (i32)fp.Kaiser.length);
 		f->length     = (i32)fp.Kaiser.length;
 		f->time_delay = (f32)f->length / 2.0f / fp.sampling_frequency;
 	}break;
 	case BeamformerFilterKind_MatchedChirp:{
 		typeof(fp.MatchedChirp) *mc = &fp.MatchedChirp;
 		f32 fs    = fp.sampling_frequency;
 		f->length = (i32)(mc->duration * fs);
 		if (fp.complex) {
 			filter = baseband_chirp(&arena, mc->min_frequency, mc->max_frequency, fs, f->length, 1, 0.5f);
 			f->time_delay = complex_filter_first_moment(filter, f->length, fs);
 		} else {
 			filter = rf_chirp(&arena, mc->min_frequency, mc->max_frequency, fs, f->length, 1);
 			f->time_delay = real_filter_first_moment(filter, f->length, fs);
 		}
 	}break;
 	InvalidDefaultCase;
 	}
 
 	f->kind       = kind;
 	f->parameters = fp;
 
 	glDeleteTextures(1, &f->texture);
 	glCreateTextures(GL_TEXTURE_1D, 1, &f->texture);
 	glTextureStorage1D(f->texture, 1, fp.complex? GL_RG32F : GL_R32F, f->length);
 	glTextureSubImage1D(f->texture, 0, 0, f->length, fp.complex? GL_RG : GL_RED, GL_FLOAT, filter);
 	glObjectLabel(GL_TEXTURE, f->texture, (i32)label.len, (c8 *)label.data);
 }
 
 function ComputeFrameIterator
 compute_frame_iterator(BeamformerCtx *ctx, u32 start_index, u32 needed_frames)
 {
 	start_index = start_index % ARRAY_COUNT(ctx->beamform_frames);
 
 	ComputeFrameIterator result;
 	result.frames        = ctx->beamform_frames;
 	result.offset        = start_index;
 	result.capacity      = ARRAY_COUNT(ctx->beamform_frames);
 	result.cursor        = 0;
 	result.needed_frames = needed_frames;
 	return result;
 }
 
 function BeamformerFrame *
 frame_next(ComputeFrameIterator *bfi)
 {
 	BeamformerFrame *result = 0;
 	if (bfi->cursor != bfi->needed_frames) {
 		u32 index = (bfi->offset + bfi->cursor++) % bfi->capacity;
 		result    = bfi->frames + index;
 	}
 	return result;
 }
 
 function b32
 beamformer_frame_compatible(BeamformerFrame *f, iv3 dim, GLenum gl_kind)
 {
 	b32 result = gl_kind == f->gl_kind && iv3_equal(dim, f->dim);
 	return result;
 }
 
 function void
 alloc_beamform_frame(GLParams *gp, BeamformerFrame *out, iv3 out_dim, GLenum gl_kind, s8 name, Arena arena)
 {
 	out->dim.x = MAX(1, out_dim.x);
 	out->dim.y = MAX(1, out_dim.y);
 	out->dim.z = MAX(1, out_dim.z);
 
 	if (gp) {
 		out->dim.x = MIN(out->dim.x, gp->max_3d_texture_dim);
 		out->dim.y = MIN(out->dim.y, gp->max_3d_texture_dim);
 		out->dim.z = MIN(out->dim.z, gp->max_3d_texture_dim);
 	}
 
 	/* NOTE: allocate storage for beamformed output data;
 	 * this is shared between compute and fragment shaders */
 	u32 max_dim = (u32)MAX(out->dim.x, MAX(out->dim.y, out->dim.z));
 	out->mips   = (i32)ctz_u32(round_up_power_of_2(max_dim)) + 1;
 
 	out->gl_kind = gl_kind;
 
 	Stream label = arena_stream(arena);
 	stream_append_s8(&label, name);
 	stream_append_byte(&label, '[');
 	stream_append_hex_u64(&label, out->id);
 	stream_append_byte(&label, ']');
 
 	glDeleteTextures(1, &out->texture);
 	glCreateTextures(GL_TEXTURE_3D, 1, &out->texture);
 	glTextureStorage3D(out->texture, out->mips, gl_kind, out->dim.x, out->dim.y, out->dim.z);
 
 	glTextureParameteri(out->texture, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
 	glTextureParameteri(out->texture, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
 
 	LABEL_GL_OBJECT(GL_TEXTURE, out->texture, stream_to_s8(&label));
 }
 
 function void
 update_hadamard_texture(BeamformerComputePlan *cp, i32 order, Arena arena)
 {
 	i32 *hadamard = make_hadamard_transpose(&arena, order);
 	if (hadamard) {
 		cp->hadamard_order = order;
 		u32 *texture = cp->textures + BeamformerComputeTextureKind_Hadamard;
 		glDeleteTextures(1, texture);
 		glCreateTextures(GL_TEXTURE_2D, 1, texture);
 		glTextureStorage2D(*texture, 1, GL_R8I, order, order);
 		glTextureSubImage2D(*texture, 0, 0, 0,  order, order, GL_RED_INTEGER, GL_INT, hadamard);
 
 		Stream label = arena_stream(arena);
 		stream_append_s8(&label, s8("Hadamard"));
 		stream_append_i64(&label, order);
 		LABEL_GL_OBJECT(GL_TEXTURE, *texture, stream_to_s8(&label));
 	}
 }
 
 function void
 alloc_shader_storage(BeamformerCtx *ctx, u32 decoded_data_size, Arena arena)
 {
 	BeamformerComputeContext *cc = &ctx->compute_context;
 	glDeleteBuffers(countof(cc->ping_pong_ssbos), cc->ping_pong_ssbos);
 	glCreateBuffers(countof(cc->ping_pong_ssbos), cc->ping_pong_ssbos);
 
 	cc->ping_pong_ssbo_size = decoded_data_size;
 
 	Stream label = arena_stream(arena);
 	stream_append_s8(&label, s8("PingPongSSBO["));
 	i32 s_widx = label.widx;
 	for (i32 i = 0; i < countof(cc->ping_pong_ssbos); i++) {
 		glNamedBufferStorage(cc->ping_pong_ssbos[i], (iz)decoded_data_size, 0, 0);
 		stream_append_i64(&label, i);
 		stream_append_byte(&label, ']');
 		LABEL_GL_OBJECT(GL_BUFFER, cc->ping_pong_ssbos[i], stream_to_s8(&label));
 		stream_reset(&label, s_widx);
 	}
 
 	/* TODO(rnp): (25.08.04) cuda lib is heavily broken atm. First there are multiple RF
 	 * buffers and cuda decode shouldn't assume that the data is coming from the rf_buffer
 	 * ssbo. Second each parameter block may need a different hadamard matrix so ideally
 	 * decode should just take the texture as a parameter. Third, none of these dimensions
 	 * need to be pre-known by the library unless its allocating GPU memory which it shouldn't
 	 * need to do. For now grab out of parameter block 0 but it is not correct */
 	BeamformerParameterBlock *pb = beamformer_parameter_block(ctx->shared_memory.region, 0);
 	/* NOTE(rnp): these are stubs when CUDA isn't supported */
 	cuda_register_buffers(cc->ping_pong_ssbos, countof(cc->ping_pong_ssbos), cc->rf_buffer.ssbo);
 	u32 decoded_data_dimension[3] = {pb->parameters.sample_count, pb->parameters.channel_count, pb->parameters.acquisition_count};
 	cuda_init(pb->parameters.raw_data_dimensions, decoded_data_dimension);
 }
 
 function void
 push_compute_timing_info(ComputeTimingTable *t, ComputeTimingInfo info)
 {
 	u32 index = atomic_add_u32(&t->write_index, 1) % countof(t->buffer);
 	t->buffer[index] = info;
 }
 
 function b32
 fill_frame_compute_work(BeamformerCtx *ctx, BeamformWork *work, BeamformerViewPlaneTag plane,
                         u32 parameter_block, b32 indirect)
 {
 	b32 result = 0;
 	if (work) {
 		result = 1;
 		u32 frame_id    = atomic_add_u32(&ctx->next_render_frame_index, 1);
 		u32 frame_index = frame_id % countof(ctx->beamform_frames);
 		work->kind      = indirect? BeamformerWorkKind_ComputeIndirect : BeamformerWorkKind_Compute;
 		work->lock      = BeamformerSharedMemoryLockKind_DispatchCompute;
 		work->compute_context.parameter_block = parameter_block;
 		work->compute_context.frame = ctx->beamform_frames + frame_index;
 		work->compute_context.frame->ready_to_present = 0;
 		work->compute_context.frame->view_plane_tag   = plane;
 		work->compute_context.frame->id               = frame_id;
 	}
 	return result;
 }
 
 function void
 do_sum_shader(BeamformerComputeContext *cc, u32 *in_textures, u32 in_texture_count, f32 in_scale,
               u32 out_texture, iv3 out_data_dim)
 {
 	/* NOTE: zero output before summing */
 	glClearTexImage(out_texture, 0, GL_RED, GL_FLOAT, 0);
 	glMemoryBarrier(GL_TEXTURE_UPDATE_BARRIER_BIT);
 
 	glBindImageTexture(0, out_texture, 0, GL_TRUE, 0, GL_READ_WRITE, GL_RG32F);
 	glProgramUniform1f(cc->programs[BeamformerShaderKind_Sum], SUM_PRESCALE_UNIFORM_LOC, in_scale);
 	for (u32 i = 0; i < in_texture_count; i++) {
 		glBindImageTexture(1, in_textures[i], 0, GL_TRUE, 0, GL_READ_ONLY, GL_RG32F);
 		glDispatchCompute(ORONE((u32)out_data_dim.x / 32u),
 		                  ORONE((u32)out_data_dim.y),
 		                  ORONE((u32)out_data_dim.z / 32u));
 		glMemoryBarrier(GL_SHADER_IMAGE_ACCESS_BARRIER_BIT);
 	}
 }
 
 struct compute_cursor {
 	iv3 cursor;
 	uv3 dispatch;
 	iv3 target;
 	u32 points_per_dispatch;
 	u32 completed_points;
 	u32 total_points;
 };
 
 function struct compute_cursor
 start_compute_cursor(iv3 dim, u32 max_points)
 {
 	struct compute_cursor result = {0};
 	u32 invocations_per_dispatch = DAS_LOCAL_SIZE_X * DAS_LOCAL_SIZE_Y * DAS_LOCAL_SIZE_Z;
 
 	result.dispatch.y = MIN(max_points / invocations_per_dispatch, (u32)ceil_f32((f32)dim.y / DAS_LOCAL_SIZE_Y));
 
 	u32 remaining     = max_points / result.dispatch.y;
 	result.dispatch.x = MIN(remaining / invocations_per_dispatch, (u32)ceil_f32((f32)dim.x / DAS_LOCAL_SIZE_X));
 	result.dispatch.z = MIN(remaining / (invocations_per_dispatch * result.dispatch.x),
 	                        (u32)ceil_f32((f32)dim.z / DAS_LOCAL_SIZE_Z));
 
 	result.target.x = MAX(dim.x / (i32)result.dispatch.x / DAS_LOCAL_SIZE_X, 1);
 	result.target.y = MAX(dim.y / (i32)result.dispatch.y / DAS_LOCAL_SIZE_Y, 1);
 	result.target.z = MAX(dim.z / (i32)result.dispatch.z / DAS_LOCAL_SIZE_Z, 1);
 
 	result.points_per_dispatch = 1;
 	result.points_per_dispatch *= result.dispatch.x * DAS_LOCAL_SIZE_X;
 	result.points_per_dispatch *= result.dispatch.y * DAS_LOCAL_SIZE_Y;
 	result.points_per_dispatch *= result.dispatch.z * DAS_LOCAL_SIZE_Z;
 
 	result.total_points = (u32)(dim.x * dim.y * dim.z);
 
 	return result;
 }
 
 function iv3
 step_compute_cursor(struct compute_cursor *cursor)
 {
 	cursor->cursor.x += 1;
 	if (cursor->cursor.x >= cursor->target.x) {
 		cursor->cursor.x  = 0;
 		cursor->cursor.y += 1;
 		if (cursor->cursor.y >= cursor->target.y) {
 			cursor->cursor.y  = 0;
 			cursor->cursor.z += 1;
 		}
 	}
 
 	cursor->completed_points += cursor->points_per_dispatch;
 
 	iv3 result = cursor->cursor;
 	result.x *= (i32)cursor->dispatch.x * DAS_LOCAL_SIZE_X;
 	result.y *= (i32)cursor->dispatch.y * DAS_LOCAL_SIZE_Y;
 	result.z *= (i32)cursor->dispatch.z * DAS_LOCAL_SIZE_Z;
 
 	return result;
 }
 
 function b32
 compute_cursor_finished(struct compute_cursor *cursor)
 {
 	b32 result = cursor->completed_points >= cursor->total_points;
 	return result;
 }
 
 function m4
 das_voxel_transform_matrix(BeamformerParameters *bp)
 {
 	v3 min = v3_from_f32_array(bp->output_min_coordinate);
 	v3 max = v3_from_f32_array(bp->output_max_coordinate);
 	v3 extent = v3_abs(v3_sub(max, min));
 	v3 points = {{(f32)bp->output_points[0], (f32)bp->output_points[1], (f32)bp->output_points[2]}};
 
 	m4 T1 = m4_translation(v3_scale(v3_sub(points, (v3){{1.0f, 1.0f, 1.0f}}), -0.5f));
 	m4 T2 = m4_translation(v3_add(min, v3_scale(extent, 0.5f)));
 	m4 S  = m4_scale(v3_div(extent, points));
 
 	m4 R;
 	switch (bp->das_shader_id) {
 	case BeamformerDASKind_FORCES:
 	case BeamformerDASKind_UFORCES:
 	case BeamformerDASKind_Flash:
 	{
 		R = m4_identity();
 		S.c[1].E[1]  = 0;
 		T2.c[3].E[1] = 0;
 	}break;
 	case BeamformerDASKind_HERCULES:
 	case BeamformerDASKind_UHERCULES:
 	case BeamformerDASKind_RCA_TPW:
 	case BeamformerDASKind_RCA_VLS:
 	{
 		R = m4_rotation_about_z(bp->beamform_plane ? 0.0f : 0.25f);
 		if (!(points.x > 1 && points.y > 1 && points.z > 1))
 			T2.c[3].E[1] = bp->off_axis_pos;
 	}break;
 	default:{ R = m4_identity(); }break;
 	}
 	m4 result = m4_mul(R, m4_mul(T2, m4_mul(S, T1)));
 	return result;
 }
 
 function void
 das_ubo_from_beamformer_parameters(BeamformerDASUBO *du, BeamformerParameters *bp)
 {
 	du->voxel_transform = das_voxel_transform_matrix(bp);
 	mem_copy(du->xdc_transform.E,     bp->xdc_transform,     sizeof(du->xdc_transform));
 	mem_copy(du->xdc_element_pitch.E, bp->xdc_element_pitch, sizeof(du->xdc_element_pitch));
 	du->sampling_frequency     = bp->sampling_frequency;
 	du->demodulation_frequency = bp->demodulation_frequency;
 	du->speed_of_sound         = bp->speed_of_sound;
 	du->time_offset            = bp->time_offset;
 	du->f_number               = bp->f_number;
 	du->shader_kind            = bp->das_shader_id;
 	du->sample_count           = bp->sample_count;
 	du->channel_count          = bp->channel_count;
 	du->acquisition_count      = bp->acquisition_count;
 
 	du->shader_flags = 0;
 	if (bp->coherency_weighting) du->shader_flags |= BeamformerShaderDASFlags_CoherencyWeighting;
 	if (bp->transmit_mode == BeamformerRCAOrientation_Columns)
 		du->shader_flags |= BeamformerShaderDASFlags_TxColumns;
 	if (bp->receive_mode == BeamformerRCAOrientation_Columns)
 		du->shader_flags |= BeamformerShaderDASFlags_RxColumns;
 }
 
 function void
 plan_compute_pipeline(BeamformerComputePlan *cp, BeamformerParameterBlock *pb)
 {
 	BeamformerDASUBO *bp = &cp->das_ubo_data;
 
 	das_ubo_from_beamformer_parameters(bp, &pb->parameters);
 
 	b32 decode_first = pb->pipeline.shaders[0] == BeamformerShaderKind_Decode;
 	b32 run_cuda_hilbert = 0;
 	b32 demodulate       = 0;
 
 	for (u32 i = 0; i < pb->pipeline.shader_count; i++) {
 		switch (pb->pipeline.shaders[i]) {
 		case BeamformerShaderKind_CudaHilbert:{ run_cuda_hilbert = 1; }break;
 		case BeamformerShaderKind_Demodulate:{  demodulate = 1;       }break;
 		default:{}break;
 		}
 	}
 
 	if (demodulate) run_cuda_hilbert = 0;
 
 	if (demodulate || run_cuda_hilbert) cp->iq_pipeline = 1;
 
 	BeamformerDataKind data_kind = pb->pipeline.data_kind;
 	cp->pipeline.shader_count = 0;
 	for (u32 i = 0; i < pb->pipeline.shader_count; i++) {
 		BeamformerShaderParameters *sp = pb->pipeline.parameters + i;
 		u32 shader = pb->pipeline.shaders[i];
 		b32 commit = 0;
 
 		iz match = 0;
 		switch (shader) {
 		case BeamformerShaderKind_CudaHilbert:{ commit = run_cuda_hilbert; }break;
 		case BeamformerShaderKind_Decode:{
 			/* TODO(rnp): rework decode first and demodulate after */
 			BeamformerDataKind decode_data_kind = data_kind;
 			if (!decode_first) {
 				if (data_kind == BeamformerDataKind_Int16) {
 					decode_data_kind = BeamformerDataKind_Int16Complex;
 				} else {
 					decode_data_kind = BeamformerDataKind_Float32Complex;
 				}
 			}
 			i32 local_flags = 0;
 			if (run_cuda_hilbert) local_flags |= BeamformerShaderDecodeFlags_DilateOutput;
 			match = beamformer_shader_decode_match(decode_data_kind, local_flags);
 			commit = 1;
 		}break;
 		case BeamformerShaderKind_Demodulate:{
 			BeamformerFilter *f = cp->filters + sp->filter_slot;
 			i32 local_flags = BeamformerShaderFilterFlags_Demodulate;
 			if (f->parameters.complex) local_flags |= BeamformerShaderFilterFlags_ComplexFilter;
 			if (!decode_first)         local_flags |= BeamformerShaderFilterFlags_MapChannels;
 
 			BeamformerDataKind filter_data_kind = data_kind;
 			if (decode_first)
 				filter_data_kind = BeamformerDataKind_Float32;
 
 			match = beamformer_shader_demodulate_match(filter_data_kind, pb->parameters.sampling_mode, local_flags);
 
 			bp->time_offset += f->time_delay;
 			commit = 1;
 		}break;
 		case BeamformerShaderKind_Filter:{
 			BeamformerFilter *f = cp->filters + sp->filter_slot;
 			i32 local_flags = 0;
 			if (f->parameters.complex) local_flags |= BeamformerShaderFilterFlags_ComplexFilter;
 
 			BeamformerDataKind filter_data_kind = data_kind;
 			if (decode_first)
 				filter_data_kind = BeamformerDataKind_Float32;
 
 			match = beamformer_shader_filter_match(filter_data_kind, local_flags);
 			bp->time_offset += f->time_delay;
 			commit = 1;
 		}break;
 		case BeamformerShaderKind_DAS:{
 			BeamformerDataKind das_data_kind = BeamformerDataKind_Float32;
 			if (demodulate || run_cuda_hilbert)
 				das_data_kind = BeamformerDataKind_Float32Complex;
 
 			i32 local_flags = 0;
 			if ((bp->shader_flags & BeamformerShaderDASFlags_CoherencyWeighting) == 0)
 				local_flags |= BeamformerShaderDASFlags_Fast;
 			if (bp->shader_kind == BeamformerDASKind_UFORCES || bp->shader_kind == BeamformerDASKind_UHERCULES)
 				local_flags |= BeamformerShaderDASFlags_Sparse;
 			if (pb->parameters.interpolate)
 				local_flags |= BeamformerShaderDASFlags_Interpolate;
 
 			match = beamformer_shader_das_match(das_data_kind, local_flags);
 			commit = 1;
 		}break;
 		default:{
 			match  = beamformer_shader_descriptors[shader].first_match_vector_index;
 			commit = 1;
 		}break;
 		}
 
 		if (commit) {
 			u32 index = cp->pipeline.shader_count++;
 			cp->pipeline.shaders[index]         = shader;
 			cp->pipeline.program_indices[index] = (u32)match;
 			cp->pipeline.parameters[index]      = *sp;
 		}
 	}
 	cp->pipeline.data_kind = data_kind;
 
 	u32 das_sample_stride   = 1;
 	u32 das_transmit_stride = bp->sample_count;
 	u32 das_channel_stride  = bp->acquisition_count * bp->sample_count;
 
 	u32 decimation_rate = MAX(pb->parameters.decimation_rate, 1);
 	if (demodulate) {
 		das_channel_stride  /= (2 * decimation_rate);
 		das_transmit_stride /= (2 * decimation_rate);
 	}
 
 	u32 input_sample_stride   = 1;
 	u32 input_transmit_stride = bp->sample_count;
 	u32 input_channel_stride  = pb->parameters.raw_data_dimensions[0];
 
 	BeamformerDecodeUBO *dp = &cp->decode_ubo_data;
 	dp->decode_mode    = pb->parameters.decode;
 	dp->transmit_count = bp->acquisition_count;
 
 	dp->input_sample_stride    = decode_first? input_sample_stride   : bp->acquisition_count;
 	dp->input_channel_stride   = decode_first? input_channel_stride  : das_channel_stride;
 	dp->input_transmit_stride  = decode_first? input_transmit_stride : 1;
 	dp->output_sample_stride   = das_sample_stride;
 	dp->output_channel_stride  = das_channel_stride;
 	dp->output_transmit_stride = das_transmit_stride;
 	if (decode_first) {
 		dp->output_channel_stride  *= decimation_rate;
 		dp->output_transmit_stride *= decimation_rate;
 	}
 
 	cp->decode_dispatch.x = (u32)ceil_f32((f32)bp->sample_count      / DECODE_LOCAL_SIZE_X);
 	cp->decode_dispatch.y = (u32)ceil_f32((f32)bp->channel_count     / DECODE_LOCAL_SIZE_Y);
 	cp->decode_dispatch.z = (u32)ceil_f32((f32)bp->acquisition_count / DECODE_LOCAL_SIZE_Z);
 
 	/* NOTE(rnp): decode 2 samples per dispatch when data is i16 */
 	if (decode_first && data_kind == BeamformerDataKind_Int16)
 		cp->decode_dispatch.x = (u32)ceil_f32((f32)cp->decode_dispatch.x / 2);
 
 	/* NOTE(rnp): when we are demodulating we pretend that the sampler was alternating
 	 * between sampling the I portion and the Q portion of an IQ signal. Therefore there
 	 * is an implicit decimation factor of 2 which must always be included. All code here
 	 * assumes that the signal was sampled in such a way that supports this operation.
 	 * To recover IQ[n] from the sampled data (RF[n]) we do the following:
 	 *   I[n]  = RF[n]
 	 *   Q[n]  = RF[n + 1]
 	 *   IQ[n] = I[n] - j*Q[n]
 	 */
 	if (demodulate) {
 		BeamformerFilterUBO *mp    = &cp->demod_ubo_data;
 		mp->demodulation_frequency = bp->demodulation_frequency;
 		mp->sampling_frequency     = bp->sampling_frequency / 2;
 		mp->decimation_rate        = decimation_rate;
 
 		bp->sampling_frequency /= 2 * (f32)mp->decimation_rate;
 		bp->sample_count       /= 2 * mp->decimation_rate;
 
 		if (decode_first) {
 			mp->input_channel_stride  = dp->output_channel_stride;
 			mp->input_sample_stride   = dp->output_sample_stride;
 			mp->input_transmit_stride = dp->output_transmit_stride;
 
 			mp->output_channel_stride  = das_channel_stride;
 			mp->output_sample_stride   = das_sample_stride;
 			mp->output_transmit_stride = das_transmit_stride;
 		} else {
 			mp->input_channel_stride  = input_channel_stride  / 2;
 			mp->input_sample_stride   = input_sample_stride;
 			mp->input_transmit_stride = input_transmit_stride / 2;
 
 			/* NOTE(rnp): output optimized layout for decoding */
 			mp->output_channel_stride  = dp->input_channel_stride;
 			mp->output_sample_stride   = dp->input_sample_stride;
 			mp->output_transmit_stride = dp->input_transmit_stride;
 
 			cp->decode_dispatch.x = (u32)ceil_f32((f32)bp->sample_count / DECODE_LOCAL_SIZE_X);
 		}
 	}
 
 	/* TODO(rnp): filter may need a different dispatch layout */
 	cp->demod_dispatch.x = (u32)ceil_f32((f32)bp->sample_count      / FILTER_LOCAL_SIZE_X);
 	cp->demod_dispatch.y = (u32)ceil_f32((f32)bp->channel_count     / FILTER_LOCAL_SIZE_Y);
 	cp->demod_dispatch.z = (u32)ceil_f32((f32)bp->acquisition_count / FILTER_LOCAL_SIZE_Z);
 
 	cp->rf_size = bp->sample_count * bp->channel_count * bp->acquisition_count;
 	if (demodulate || run_cuda_hilbert) cp->rf_size *= 8;
 	else                                cp->rf_size *= 4;
 
 	/* TODO(rnp): UBO per filter stage */
 	BeamformerFilterUBO *flt = &cp->filter_ubo_data;
 	flt->demodulation_frequency = bp->demodulation_frequency;
 	flt->sampling_frequency     = bp->sampling_frequency;
 	flt->decimation_rate        = 1;
 	flt->output_channel_stride  = bp->sample_count * bp->acquisition_count;
 	flt->output_sample_stride   = 1;
 	flt->output_transmit_stride = bp->sample_count;
 	flt->input_channel_stride   = bp->sample_count * bp->acquisition_count;
 	flt->input_sample_stride    = 1;
 	flt->input_transmit_stride  = bp->sample_count;
 }
 
 function void
 beamformer_commit_parameter_block(BeamformerCtx *ctx, BeamformerComputePlan *cp, u32 block, Arena arena)
 {
 	BeamformerParameterBlock *pb = beamformer_parameter_block_lock(&ctx->shared_memory, block, -1);
 	for (u32 region = ctz_u32(pb->dirty_regions);
 	     region != 32;
 	     region = ctz_u32(pb->dirty_regions))
 	{
 		mark_parameter_block_region_clean(ctx->shared_memory.region, block, region);
 		switch (region) {
 		case BeamformerParameterBlockRegion_ComputePipeline:
 		case BeamformerParameterBlockRegion_Parameters:
 		{
 			plan_compute_pipeline(cp, pb);
 
 			/* NOTE(rnp): these are both handled by plan_compute_pipeline() */
 			u32 mask = 1 << BeamformerParameterBlockRegion_ComputePipeline |
 			           1 << BeamformerParameterBlockRegion_Parameters;
 			pb->dirty_regions &= ~mask;
 
 			#define X(k, t, v) glNamedBufferSubData(cp->ubos[BeamformerComputeUBOKind_##k], \
 			                                        0, sizeof(t), &cp->v ## _ubo_data);
 			BEAMFORMER_COMPUTE_UBO_LIST
 			#undef X
 
 			u32 decoded_data_size = cp->rf_size;
 			if (ctx->compute_context.ping_pong_ssbo_size < decoded_data_size)
 				alloc_shader_storage(ctx, decoded_data_size, arena);
 
 			if (cp->hadamard_order != (i32)cp->das_ubo_data.acquisition_count)
 				update_hadamard_texture(cp, (i32)cp->das_ubo_data.acquisition_count, arena);
 
 			cp->min_coordinate = v3_from_f32_array(pb->parameters.output_min_coordinate);
 			cp->max_coordinate = v3_from_f32_array(pb->parameters.output_max_coordinate);
 
 			cp->output_points.E[0] = MAX(pb->parameters.output_points[0], 1);
 			cp->output_points.E[1] = MAX(pb->parameters.output_points[1], 1);
 			cp->output_points.E[2] = MAX(pb->parameters.output_points[2], 1);
 			cp->average_frames     = pb->parameters.output_points[3];
 
 			GLenum gl_kind = cp->iq_pipeline ? GL_RG32F : GL_R32F;
 			if (cp->average_frames > 1 && !beamformer_frame_compatible(ctx->averaged_frames + 0, cp->output_points, gl_kind)) {
 				alloc_beamform_frame(&ctx->gl, ctx->averaged_frames + 0, cp->output_points, gl_kind, s8("Averaged Frame"), arena);
 				alloc_beamform_frame(&ctx->gl, ctx->averaged_frames + 1, cp->output_points, gl_kind, s8("Averaged Frame"), arena);
 			}
 		}break;
 		case BeamformerParameterBlockRegion_ChannelMapping:
 		case BeamformerParameterBlockRegion_FocalVectors:
 		case BeamformerParameterBlockRegion_SparseElements:
 		{
 			BeamformerComputeTextureKind texture_kind = 0;
 			u32 texture_type = 0, texture_format = 0;
 			/* TODO(rnp): this whole thing could be a table */
 			switch (region) {
 			case BeamformerParameterBlockRegion_ChannelMapping:{
 				texture_kind   = BeamformerComputeTextureKind_ChannelMapping;
 				texture_type   = GL_SHORT;
 				texture_format = GL_RED_INTEGER;
 				/* TODO(rnp): cuda lib */
 				cuda_set_channel_mapping(pb->channel_mapping);
 			}break;
 			case BeamformerParameterBlockRegion_FocalVectors:{
 				texture_kind   = BeamformerComputeTextureKind_FocalVectors;
 				texture_type   = GL_FLOAT;
 				texture_format = GL_RG;
 			}break;
 			case BeamformerParameterBlockRegion_SparseElements:{
 				texture_kind   = BeamformerComputeTextureKind_SparseElements;
 				texture_type   = GL_SHORT;
 				texture_format = GL_RED_INTEGER;
 			}break;
 			InvalidDefaultCase;
 			}
 			glTextureSubImage1D(cp->textures[texture_kind], 0, 0, BeamformerMaxChannelCount,
 			                    texture_format, texture_type,
 			                    (u8 *)pb + BeamformerParameterBlockRegionOffsets[region]);
 		}break;
 		}
 	}
 	beamformer_parameter_block_unlock(&ctx->shared_memory, block);
 }
 
 function void
 do_compute_shader(BeamformerCtx *ctx, BeamformerComputePlan *cp, BeamformerFrame *frame,
                   BeamformerShaderKind shader, u32 program_index, BeamformerShaderParameters *sp, Arena arena)
 {
 	BeamformerComputeContext *cc = &ctx->compute_context;
 
 	i32 *match_vector = beamformer_shader_match_vectors[program_index];
 	BeamformerShaderDescriptor *shader_descriptor = beamformer_shader_descriptors + shader;
 
 	u32 program = cc->programs[program_index];
 	glUseProgram(program);
 
 	u32 output_ssbo_idx = !cc->last_output_ssbo_index;
 	u32 input_ssbo_idx  = cc->last_output_ssbo_index;
 
 	switch (shader) {
 	case BeamformerShaderKind_Decode:{
 		glBindBufferBase(GL_UNIFORM_BUFFER, 0, cp->ubos[BeamformerComputeUBOKind_Decode]);
 		glBindImageTexture(0, cp->textures[BeamformerComputeTextureKind_Hadamard], 0, 0, 0, GL_READ_ONLY, GL_R8I);
 
 		if (shader == cp->pipeline.shaders[0]) {
 			glBindBufferBase(GL_SHADER_STORAGE_BUFFER, 2, cc->ping_pong_ssbos[input_ssbo_idx]);
 			glBindImageTexture(1, cp->textures[BeamformerComputeTextureKind_ChannelMapping], 0, 0, 0, GL_READ_ONLY, GL_R16I);
 			glProgramUniform1ui(program, DECODE_FIRST_PASS_UNIFORM_LOC, 1);
 
 			glDispatchCompute(cp->decode_dispatch.x, cp->decode_dispatch.y, cp->decode_dispatch.z);
 			glMemoryBarrier(GL_SHADER_STORAGE_BARRIER_BIT);
 		}
 
 		glBindBufferBase(GL_SHADER_STORAGE_BUFFER, 1, cc->ping_pong_ssbos[input_ssbo_idx]);
 		glBindBufferBase(GL_SHADER_STORAGE_BUFFER, 3, cc->ping_pong_ssbos[output_ssbo_idx]);
 
 		glProgramUniform1ui(program, DECODE_FIRST_PASS_UNIFORM_LOC, 0);
 
 		glDispatchCompute(cp->decode_dispatch.x, cp->decode_dispatch.y, cp->decode_dispatch.z);
 		glMemoryBarrier(GL_SHADER_STORAGE_BARRIER_BIT);
 
 		cc->last_output_ssbo_index = !cc->last_output_ssbo_index;
 	}break;
 	case BeamformerShaderKind_CudaDecode:{
 		cuda_decode(0, output_ssbo_idx, 0);
 		cc->last_output_ssbo_index = !cc->last_output_ssbo_index;
 	}break;
 	case BeamformerShaderKind_CudaHilbert:{
 		cuda_hilbert(input_ssbo_idx, output_ssbo_idx);
 		cc->last_output_ssbo_index = !cc->last_output_ssbo_index;
 	}break;
 	case BeamformerShaderKind_Filter:
 	case BeamformerShaderKind_Demodulate:
 	{
 		i32 local_flags  = match_vector[shader_descriptor->match_vector_length];
 		b32 map_channels = (local_flags & BeamformerShaderFilterFlags_MapChannels) != 0;
 
 		u32 index = shader == BeamformerShaderKind_Filter ? BeamformerComputeUBOKind_Filter
 		                                                  : BeamformerComputeUBOKind_Demodulate;
 		glBindBufferBase(GL_UNIFORM_BUFFER,        0, cp->ubos[index]);
 		glBindBufferBase(GL_SHADER_STORAGE_BUFFER, 2, cc->ping_pong_ssbos[output_ssbo_idx]);
 
 		if (!map_channels)
 			glBindBufferBase(GL_SHADER_STORAGE_BUFFER, 1, cc->ping_pong_ssbos[input_ssbo_idx]);
 
 		GLenum kind = cp->filters[sp->filter_slot].parameters.complex? GL_RG32F : GL_R32F;
 		glBindImageTexture(0, cp->filters[sp->filter_slot].texture, 0, 0, 0, GL_READ_ONLY, kind);
 
 		if (map_channels)
 			glBindImageTexture(1, cp->textures[BeamformerComputeTextureKind_ChannelMapping], 0, 0, 0, GL_READ_ONLY, GL_R16I);
 
 		glDispatchCompute(cp->demod_dispatch.x, cp->demod_dispatch.y, cp->demod_dispatch.z);
 		glMemoryBarrier(GL_SHADER_STORAGE_BARRIER_BIT);
 
 		cc->last_output_ssbo_index = !cc->last_output_ssbo_index;
 	}break;
 	case BeamformerShaderKind_MinMax:{
 		for (i32 i = 1; i < frame->mips; i++) {
 			glBindImageTexture(0, frame->texture, i - 1, GL_TRUE, 0, GL_READ_ONLY,  GL_RG32F);
 			glBindImageTexture(1, frame->texture, i - 0, GL_TRUE, 0, GL_WRITE_ONLY, GL_RG32F);
 			glProgramUniform1i(cc->programs[shader], MIN_MAX_MIPS_LEVEL_UNIFORM_LOC, i);
 
 			u32 width  = (u32)frame->dim.x >> i;
 			u32 height = (u32)frame->dim.y >> i;
 			u32 depth  = (u32)frame->dim.z >> i;
 			glDispatchCompute(ORONE(width / 32), ORONE(height), ORONE(depth / 32));
 			glMemoryBarrier(GL_SHADER_IMAGE_ACCESS_BARRIER_BIT);
 		}
 	}break;
 	case BeamformerShaderKind_DAS:{
 		BeamformerDASUBO *ubo = &cp->das_ubo_data;
 
 		i32 local_flags = match_vector[shader_descriptor->match_vector_length];
 		b32 fast        = (local_flags & BeamformerShaderDASFlags_Fast)   != 0;
 		b32 sparse      = (local_flags & BeamformerShaderDASFlags_Sparse) != 0;
 
 		if (fast) {
 			glClearTexImage(frame->texture, 0, GL_RED, GL_FLOAT, 0);
 			glMemoryBarrier(GL_TEXTURE_UPDATE_BARRIER_BIT);
 			glBindImageTexture(0, frame->texture, 0, GL_TRUE, 0, GL_READ_WRITE, cp->iq_pipeline ? GL_RG32F : GL_R32F);
 		} else {
 			glBindImageTexture(0, frame->texture, 0, GL_TRUE, 0, GL_WRITE_ONLY, cp->iq_pipeline ? GL_RG32F : GL_R32F);
 		}
 
 		u32 sparse_texture = cp->textures[BeamformerComputeTextureKind_SparseElements];
 		if (!sparse) sparse_texture = 0;
 
 		glBindBufferBase(GL_UNIFORM_BUFFER, 0, cp->ubos[BeamformerComputeUBOKind_DAS]);
 		glBindBufferRange(GL_SHADER_STORAGE_BUFFER, 1, cc->ping_pong_ssbos[input_ssbo_idx], 0, cp->rf_size);
 		glBindImageTexture(1, sparse_texture, 0, 0, 0, GL_READ_ONLY, GL_R16I);
 		glBindImageTexture(2, cp->textures[BeamformerComputeTextureKind_FocalVectors], 0, 0, 0, GL_READ_ONLY, GL_RG32F);
 
 		glProgramUniform1ui(program, DAS_CYCLE_T_UNIFORM_LOC, cycle_t++);
 
 		if (fast) {
 			i32 loop_end;
 			if (ubo->shader_kind == BeamformerDASKind_RCA_VLS ||
 			    ubo->shader_kind == BeamformerDASKind_RCA_TPW)
 			{
 				/* NOTE(rnp): to avoid repeatedly sampling the whole focal vectors
 				 * texture we loop over transmits for VLS/TPW */
 				loop_end = (i32)ubo->acquisition_count;
 			} else {
 				loop_end = (i32)ubo->channel_count;
 			}
 			f32 percent_per_step = 1.0f / (f32)loop_end;
 			cc->processing_progress = -percent_per_step;
 			for (i32 index = 0; index < loop_end; index++) {
 				cc->processing_progress += percent_per_step;
 				/* IMPORTANT(rnp): prevents OS from coalescing and killing our shader */
 				glFinish();
 				glProgramUniform1i(program, DAS_FAST_CHANNEL_UNIFORM_LOC, index);
 				glDispatchCompute((u32)ceil_f32((f32)frame->dim.x / DAS_LOCAL_SIZE_X),
 				                  (u32)ceil_f32((f32)frame->dim.y / DAS_LOCAL_SIZE_Y),
 				                  (u32)ceil_f32((f32)frame->dim.z / DAS_LOCAL_SIZE_Z));
 				glMemoryBarrier(GL_SHADER_IMAGE_ACCESS_BARRIER_BIT);
 			}
 		} else {
 			#if 1
 			/* TODO(rnp): compute max_points_per_dispatch based on something like a
 			 * transmit_count * channel_count product */
 			u32 max_points_per_dispatch = KB(64);
 			struct compute_cursor cursor = start_compute_cursor(frame->dim, max_points_per_dispatch);
 			f32 percent_per_step = (f32)cursor.points_per_dispatch / (f32)cursor.total_points;
 			cc->processing_progress = -percent_per_step;
 			for (iv3 offset = {0};
 			     !compute_cursor_finished(&cursor);
 			     offset = step_compute_cursor(&cursor))
 			{
 				cc->processing_progress += percent_per_step;
 				/* IMPORTANT(rnp): prevents OS from coalescing and killing our shader */
 				glFinish();
 				glProgramUniform3iv(program, DAS_VOXEL_OFFSET_UNIFORM_LOC, 1, offset.E);
 				glDispatchCompute(cursor.dispatch.x, cursor.dispatch.y, cursor.dispatch.z);
 			}
 			#else
 			/* NOTE(rnp): use this for testing tiling code. The performance of the above path
 			 * should be the same as this path if everything is working correctly */
 			iv3 compute_dim_offset = {0};
 			glProgramUniform3iv(program, DAS_VOXEL_OFFSET_UNIFORM_LOC, 1, compute_dim_offset.E);
 			glDispatchCompute((u32)ceil_f32((f32)dim.x / DAS_LOCAL_SIZE_X),
 			                  (u32)ceil_f32((f32)dim.y / DAS_LOCAL_SIZE_Y),
 			                  (u32)ceil_f32((f32)dim.z / DAS_LOCAL_SIZE_Z));
 			#endif
 		}
 		glMemoryBarrier(GL_TEXTURE_UPDATE_BARRIER_BIT|GL_SHADER_IMAGE_ACCESS_BARRIER_BIT);
 	}break;
 	case BeamformerShaderKind_Sum:{
 		u32 aframe_index = ctx->averaged_frame_index % ARRAY_COUNT(ctx->averaged_frames);
 		BeamformerFrame *aframe = ctx->averaged_frames + aframe_index;
 		aframe->id              = ctx->averaged_frame_index;
 		atomic_store_u32(&aframe->ready_to_present, 0);
 		/* TODO(rnp): hack we need a better way of specifying which frames to sum;
 		 * this is fine for rolling averaging but what if we want to do something else */
 		assert(frame >= ctx->beamform_frames);
 		assert(frame < ctx->beamform_frames + countof(ctx->beamform_frames));
 		u32 base_index   = (u32)(frame - ctx->beamform_frames);
 		u32 to_average   = (u32)cp->average_frames;
 		u32 frame_count  = 0;
 		u32 *in_textures = push_array(&arena, u32, BeamformerMaxSavedFrames);
 		ComputeFrameIterator cfi = compute_frame_iterator(ctx, 1 + base_index - to_average, to_average);
 		for (BeamformerFrame *it = frame_next(&cfi); it; it = frame_next(&cfi))
 			in_textures[frame_count++] = it->texture;
 
 		assert(to_average == frame_count);
 
 		do_sum_shader(cc, in_textures, frame_count, 1 / (f32)frame_count, aframe->texture, aframe->dim);
 		aframe->min_coordinate  = frame->min_coordinate;
 		aframe->max_coordinate  = frame->max_coordinate;
 		aframe->compound_count  = frame->compound_count;
 		aframe->das_kind        = frame->das_kind;
 	}break;
 	InvalidDefaultCase;
 	}
 }
 
 function void
 stream_push_shader_header(Stream *s, ShaderReloadContext *ctx)
 {
 	BeamformerReloadableShaderInfo *rsi = beamformer_reloadable_shader_infos + ctx->reloadable_info_index;
 
 	stream_append_s8s(s, s8("#version 460 core\n\n"), ctx->header);
 
 	switch (rsi->kind) {
 	case BeamformerShaderKind_Filter:{
 		stream_append_s8(s, s8(""
 		"layout(local_size_x = " str(FILTER_LOCAL_SIZE_X) ", "
 		       "local_size_y = " str(FILTER_LOCAL_SIZE_Y) ", "
 		       "local_size_z = " str(FILTER_LOCAL_SIZE_Z) ") in;\n\n"
 		));
 	}break;
 	case BeamformerShaderKind_DAS:{
 		stream_append_s8(s, s8(""
 		"layout(local_size_x = " str(DAS_LOCAL_SIZE_X) ", "
 		       "local_size_y = " str(DAS_LOCAL_SIZE_Y) ", "
 		       "local_size_z = " str(DAS_LOCAL_SIZE_Z) ") in;\n\n"
 		"layout(location = " str(DAS_VOXEL_OFFSET_UNIFORM_LOC) ") uniform ivec3 u_voxel_offset;\n"
 		"layout(location = " str(DAS_CYCLE_T_UNIFORM_LOC)      ") uniform uint  u_cycle_t;\n"
 		"layout(location = " str(DAS_FAST_CHANNEL_UNIFORM_LOC) ") uniform int   u_channel;\n\n"
 		));
 
 		#define X(k, id, ...) "#define ShaderKind_" #k " " #id "\n"
 		stream_append_s8s(s, s8(DAS_SHADER_KIND_LIST), s8("\n"));
 		#undef X
 	}break;
 	case BeamformerShaderKind_Decode:{
 		stream_append_s8s(s, s8(""
 		"layout(local_size_x = " str(DECODE_LOCAL_SIZE_X) ", "
 		       "local_size_y = " str(DECODE_LOCAL_SIZE_Y) ", "
 		       "local_size_z = " str(DECODE_LOCAL_SIZE_Z) ") in;\n\n"
 		"layout(location = " str(DECODE_FIRST_PASS_UNIFORM_LOC) ") uniform bool u_first_pass;\n\n"
 		));
 	}break;
 	case BeamformerShaderKind_MinMax:{
 		stream_append_s8(s, s8("layout(location = " str(MIN_MAX_MIPS_LEVEL_UNIFORM_LOC)
 		                       ") uniform int u_mip_map;\n\n"));
 	}break;
 	case BeamformerShaderKind_Sum:{
 		stream_append_s8(s, s8("layout(location = " str(SUM_PRESCALE_UNIFORM_LOC)
 		                       ") uniform float u_sum_prescale = 1.0;\n\n"));
 	}break;
 	default:{}break;
 	}
 }
 
 function s8
 shader_text_with_header(ShaderReloadContext *ctx, s8 filepath, Arena *arena)
 {
 	Stream sb = arena_stream(*arena);
 	stream_push_shader_header(&sb, ctx);
 	stream_append_s8(&sb, s8("\n#line 1\n"));
 
 	s8 result = arena_stream_commit(arena, &sb);
 	if (filepath.len > 0) {
 		s8 file = os_read_whole_file(arena, (c8 *)filepath.data);
 		assert(file.data == result.data + result.len);
 		result.len += file.len;
 	}
 
 	return result;
 }
 
 /* NOTE(rnp): currently this function is only handling rendering shaders.
  * look at reload_compute_shader for compute shaders */
 DEBUG_EXPORT BEAMFORMER_RELOAD_SHADER_FN(beamformer_reload_shader)
 {
 	BeamformerCtx *ctx = src->beamformer_context;
 
 	i32 shader_count = 1;
 	ShaderReloadContext *link = src->link;
 	while (link != src) { shader_count++; link = link->link; }
 
 	s8  *shader_texts = push_array(&arena, s8,  shader_count);
 	u32 *shader_types = push_array(&arena, u32, shader_count);
 
 	i32 index = 0;
 	do {
 		s8 filepath = {0};
 		if (link->reloadable_info_index >= 0) filepath = path;
 		shader_texts[index] = shader_text_with_header(link, filepath, &arena);
 		shader_types[index] = link->gl_type;
 		index++;
 		link = link->link;
 	} while (link != src);
 
 	BeamformerReloadableShaderInfo *rsi = beamformer_reloadable_shader_infos + src->reloadable_info_index;
 	assert(rsi->kind == BeamformerShaderKind_Render3D);
 
 	u32 *shader = &ctx->frame_view_render_context.shader;
 	glDeleteProgram(*shader);
 	*shader = load_shader(&ctx->os, arena, shader_texts, shader_types, shader_count, shader_name);
 	ctx->frame_view_render_context.updated = 1;
 
 	return 1;
 }
 
 function void
 reload_compute_shader(BeamformerCtx *ctx, ShaderReloadContext *src, Arena arena)
 {
 	BeamformerComputeContext       *cc  = &ctx->compute_context;
 	BeamformerReloadableShaderInfo *rsi = beamformer_reloadable_shader_infos + src->reloadable_info_index;
 	BeamformerShaderDescriptor     *sd  = beamformer_shader_descriptors + rsi->kind;
 
 	Stream status = stream_alloc(&arena, 128);
 	u32 completed     = 0;
 	u32 total_shaders = (u32)(sd->one_past_last_match_vector_index - sd->first_match_vector_index);
 	for (i32 i = 0; i < rsi->sub_shader_descriptor_index_count; i++) {
 		BeamformerShaderDescriptor *ssd  = beamformer_shader_descriptors + rsi->sub_shader_descriptor_indices[i];
 		total_shaders += (u32)(ssd->one_past_last_match_vector_index - ssd->first_match_vector_index);
 	}
 
 	s8 path = push_s8_from_parts(&arena, ctx->os.path_separator, s8("shaders"),
 	                             beamformer_reloadable_shader_files[src->reloadable_info_index]);
 	s8 file_text  = os_read_whole_file(&arena, (c8 *)path.data);
 	Stream shader = arena_stream(arena);
 
 	stream_push_shader_header(&shader, src);
 
 	stream_append_s8(&shader, beamformer_shader_local_header_strings[src->reloadable_info_index]);
 
 	i32 save_point = shader.widx;
 	for (i32 sub_index = -1; sub_index < rsi->sub_shader_descriptor_index_count; sub_index++) {
 		shader.widx = save_point;
 
 		if (sub_index != -1)
 			sd = beamformer_shader_descriptors + rsi->sub_shader_descriptor_indices[sub_index];
 
 		i32 *hvector = beamformer_shader_header_vectors[sd - beamformer_shader_descriptors];
 		for (i32 index = 0; index < sd->header_vector_length; index++)
 			stream_append_s8s(&shader, beamformer_shader_global_header_strings[hvector[index]], s8("\n"));
 
 		i32 instance_save_point = shader.widx;
 		arena_commit(&arena, instance_save_point);
 		TempArena arena_save = begin_temp_arena(&arena);
 
 		for (i32 instance = sd->first_match_vector_index;
 		     instance < sd->one_past_last_match_vector_index;
 		     instance++)
 		{
 			shader.widx = instance_save_point;
 			end_temp_arena(arena_save);
 
 			i32 *match_vector = beamformer_shader_match_vectors[instance];
 			for (i32 index = 0; index < sd->match_vector_length; index++) {
 				stream_append_s8s(&shader, s8("#define "), beamformer_shader_descriptor_header_strings[hvector[index]], s8(" ("));
 				stream_append_i64(&shader, match_vector[index]);
 				stream_append_s8(&shader, s8(")\n"));
 			}
 
 			if (sd->has_local_flags) {
 				stream_append_s8(&shader, s8("#define ShaderFlags (0x"));
 				stream_append_hex_u64(&shader, (u64)match_vector[sd->match_vector_length]);
 				stream_append_s8(&shader, s8(")\n"));
 			}
 
 			stream_append_s8s(&shader, s8("\n#line 1\n"), file_text);
 
 			arena_commit(&arena, shader.widx - instance_save_point);
 
 			s8 shader_text = stream_to_s8(&shader);
 			/* TODO(rnp): instance name */
 			s8 shader_name = beamformer_shader_names[rsi->kind];
 			glDeleteProgram(cc->programs[instance]);
 			cc->programs[instance] = load_shader(&ctx->os, arena, &shader_text, &src->gl_type, 1, shader_name);
 
 			status.widx = 0;
 			stream_append_s8s(&status, s8("\r\x1b[2Kloaded shader "), shader_name, s8(": ["));
 			stream_append_u64(&status, ++completed);
 			stream_append_s8s(&status, s8("/"));
 			stream_append_u64(&status, total_shaders);
 			stream_append_s8s(&status, s8("]"));
 			os_write_file(ctx->os.error_handle, stream_to_s8(&status));
 		}
 	}
 	os_write_file(ctx->os.error_handle, s8("\n"));
 }
 
 function void
 complete_queue(BeamformerCtx *ctx, BeamformWorkQueue *q, Arena *arena, iptr gl_context)
 {
 	BeamformerComputeContext *cs = &ctx->compute_context;
 	BeamformerSharedMemory   *sm = ctx->shared_memory.region;
 
 	BeamformWork *work = beamform_work_queue_pop(q);
 	while (work) {
 		b32 can_commit = 1;
 		switch (work->kind) {
 		case BeamformerWorkKind_ReloadShader:{
 			reload_compute_shader(ctx, work->shader_reload_context, *arena);
 			if (ctx->latest_frame && !sm->live_imaging_parameters.active) {
 				fill_frame_compute_work(ctx, work, ctx->latest_frame->view_plane_tag, 0, 0);
 				can_commit = 0;
 			}
 		}break;
 		case BeamformerWorkKind_ExportBuffer:{
 			/* TODO(rnp): better way of handling DispatchCompute barrier */
 			post_sync_barrier(&ctx->shared_memory, BeamformerSharedMemoryLockKind_DispatchCompute, sm->locks);
 			os_shared_memory_region_lock(&ctx->shared_memory, sm->locks, (i32)work->lock, (u32)-1);
 			BeamformerExportContext *ec = &work->export_context;
 			switch (ec->kind) {
 			case BeamformerExportKind_BeamformedData:{
 				BeamformerFrame *frame = ctx->latest_frame;
 				if (frame) {
 					assert(frame->ready_to_present);
 					u32 texture  = frame->texture;
 					iv3 dim      = frame->dim;
 					u32 out_size = (u32)dim.x * (u32)dim.y * (u32)dim.z * 2 * sizeof(f32);
 					if (out_size <= ec->size) {
 						glGetTextureImage(texture, 0, GL_RG, GL_FLOAT, (i32)out_size,
 						                  beamformer_shared_memory_scratch_arena(sm).beg);
 					}
 				}
 			}break;
 			case BeamformerExportKind_Stats:{
 				ComputeTimingTable *table = ctx->compute_timing_table;
 				/* NOTE(rnp): do a little spin to let this finish updating */
 				while (table->write_index != atomic_load_u32(&table->read_index));
 				ComputeShaderStats *stats = ctx->compute_shader_stats;
 				if (sizeof(stats->table) <= ec->size)
 					mem_copy(beamformer_shared_memory_scratch_arena(sm).beg, &stats->table, sizeof(stats->table));
 			}break;
 			InvalidDefaultCase;
 			}
 			os_shared_memory_region_unlock(&ctx->shared_memory, sm->locks, (i32)work->lock);
 			post_sync_barrier(&ctx->shared_memory, BeamformerSharedMemoryLockKind_ExportSync, sm->locks);
 		}break;
 		case BeamformerWorkKind_CreateFilter:{
 			/* TODO(rnp): this should probably get deleted and moved to lazy loading */
 			BeamformerCreateFilterContext *fctx = &work->create_filter_context;
 			u32 block = fctx->parameter_block;
 			u32 slot  = fctx->filter_slot;
 			BeamformerComputePlan *cp = beamformer_compute_plan_for_block(cs, block, arena);
 			beamformer_filter_update(cp->filters + slot, fctx->kind, fctx->parameters, block, slot, *arena);
 		}break;
 		case BeamformerWorkKind_ComputeIndirect:{
 			fill_frame_compute_work(ctx, work, work->compute_indirect_context.view_plane,
 			                        work->compute_indirect_context.parameter_block, 1);
 		} /* FALLTHROUGH */
 		case BeamformerWorkKind_Compute:{
 			DEBUG_DECL(glClearNamedBufferData(cs->ping_pong_ssbos[0], GL_RG32F, GL_RG, GL_FLOAT, 0);)
 			DEBUG_DECL(glClearNamedBufferData(cs->ping_pong_ssbos[1], GL_RG32F, GL_RG, GL_FLOAT, 0);)
 			DEBUG_DECL(glMemoryBarrier(GL_SHADER_STORAGE_BARRIER_BIT);)
 
 			push_compute_timing_info(ctx->compute_timing_table,
 			                         (ComputeTimingInfo){.kind = ComputeTimingInfoKind_ComputeFrameBegin});
 
 			BeamformerComputePlan *cp = beamformer_compute_plan_for_block(cs, work->compute_context.parameter_block, arena);
 			if (beamformer_parameter_block_dirty(sm, work->compute_context.parameter_block)) {
 				u32 block = work->compute_context.parameter_block;
 				beamformer_commit_parameter_block(ctx, cp, block, *arena);
 				atomic_store_u32(&ctx->ui_dirty_parameter_blocks, (u32)(ctx->beamform_work_queue != q) << block);
 			}
 
 			post_sync_barrier(&ctx->shared_memory, work->lock, sm->locks);
 
 			atomic_store_u32(&cs->processing_compute, 1);
 			start_renderdoc_capture(gl_context);
 
 			BeamformerFrame *frame = work->compute_context.frame;
 
 			GLenum gl_kind = cp->iq_pipeline ? GL_RG32F : GL_R32F;
 			if (!beamformer_frame_compatible(frame, cp->output_points, gl_kind))
 				alloc_beamform_frame(&ctx->gl, frame, cp->output_points, gl_kind, s8("Beamformed_Data"), *arena);
 
 			frame->min_coordinate  = cp->min_coordinate;
 			frame->max_coordinate  = cp->max_coordinate;
 			frame->das_kind        = cp->das_ubo_data.shader_kind;
 			frame->compound_count  = cp->das_ubo_data.acquisition_count;
 
 			BeamformerComputeContext  *cc       = &ctx->compute_context;
 			BeamformerComputePipeline *pipeline = &cp->pipeline;
 			/* NOTE(rnp): first stage requires access to raw data buffer directly so we break
 			 * it out into a separate step. This way data can get released as soon as possible */
 			if (pipeline->shader_count > 0) {
 				BeamformerRFBuffer *rf = &cs->rf_buffer;
 				u32 slot = rf->compute_index % countof(rf->compute_syncs);
 
 				/* NOTE(rnp): compute indirect is used when uploading data. in this case the thread
 				 * must wait on an upload fence. if the fence doesn't yet exist the thread must wait */
 				if (work->kind == BeamformerWorkKind_ComputeIndirect)
 					spin_wait(!atomic_load_u64(rf->upload_syncs + slot));
 
 				if (rf->upload_syncs[slot]) {
 					rf->compute_index++;
 					glWaitSync(rf->upload_syncs[slot], 0, GL_TIMEOUT_IGNORED);
 					glDeleteSync(rf->upload_syncs[slot]);
 				} else {
 					slot = (rf->compute_index - 1) % countof(rf->compute_syncs);
 				}
 
 				glBindBufferRange(GL_SHADER_STORAGE_BUFFER, 1, rf->ssbo, slot * rf->active_rf_size, rf->active_rf_size);
 
 				glBeginQuery(GL_TIME_ELAPSED, cc->shader_timer_ids[0]);
 				do_compute_shader(ctx, cp, frame, pipeline->shaders[0], pipeline->program_indices[0],
 				                  pipeline->parameters + 0, *arena);
 				glEndQuery(GL_TIME_ELAPSED);
 
 				if (work->kind == BeamformerWorkKind_ComputeIndirect) {
 					rf->compute_syncs[slot] = glFenceSync(GL_SYNC_GPU_COMMANDS_COMPLETE, 0);
 					rf->upload_syncs[slot]  = 0;
 					memory_write_barrier();
 				}
 			}
 
 			b32 did_sum_shader = 0;
 			for (u32 i = 1; i < pipeline->shader_count; i++) {
 				did_sum_shader |= pipeline->shaders[i] == BeamformerShaderKind_Sum;
 				glBeginQuery(GL_TIME_ELAPSED, cc->shader_timer_ids[i]);
 				do_compute_shader(ctx, cp, frame, pipeline->shaders[i], pipeline->program_indices[i],
 				                  pipeline->parameters + i, *arena);
 				glEndQuery(GL_TIME_ELAPSED);
 			}
 
 			/* NOTE(rnp): the first of these blocks until work completes */
 			for (u32 i = 0; i < pipeline->shader_count; i++) {
 				ComputeTimingInfo info = {0};
 				info.kind   = ComputeTimingInfoKind_Shader;
 				info.shader = pipeline->shaders[i];
 				glGetQueryObjectui64v(cc->shader_timer_ids[i], GL_QUERY_RESULT, &info.timer_count);
 				push_compute_timing_info(ctx->compute_timing_table, info);
 			}
 			cs->processing_progress = 1;
 
 			frame->ready_to_present = 1;
 			if (did_sum_shader) {
 				u32 aframe_index = (ctx->averaged_frame_index % countof(ctx->averaged_frames));
 				ctx->averaged_frames[aframe_index].view_plane_tag  = frame->view_plane_tag;
 				ctx->averaged_frames[aframe_index].ready_to_present = 1;
 				atomic_add_u32(&ctx->averaged_frame_index, 1);
 				atomic_store_u64((u64 *)&ctx->latest_frame, (u64)(ctx->averaged_frames + aframe_index));
 			} else {
 				atomic_store_u64((u64 *)&ctx->latest_frame, (u64)frame);
 			}
 			cs->processing_compute  = 0;
 
 			push_compute_timing_info(ctx->compute_timing_table,
 			                         (ComputeTimingInfo){.kind = ComputeTimingInfoKind_ComputeFrameEnd});
 
 			end_renderdoc_capture(gl_context);
 		}break;
 		InvalidDefaultCase;
 		}
 
 		if (can_commit) {
 			beamform_work_queue_pop_commit(q);
 			work = beamform_work_queue_pop(q);
 		}
 	}
 }
 
 function void
 coalesce_timing_table(ComputeTimingTable *t, ComputeShaderStats *stats)
 {
 	/* TODO(rnp): we do not currently do anything to handle the potential for a half written
 	 * info item. this could result in garbage entries but they shouldn't really matter */
 
 	u32 target = atomic_load_u32(&t->write_index);
 	u32 stats_index = (stats->latest_frame_index + 1) % countof(stats->table.times);
 
 	static_assert(BeamformerShaderKind_Count + 1 <= 32, "timing coalescence bitfield test");
 	u32 seen_info_test = 0;
 
 	while (t->read_index != target) {
 		ComputeTimingInfo info = t->buffer[t->read_index % countof(t->buffer)];
 		switch (info.kind) {
 		case ComputeTimingInfoKind_ComputeFrameBegin:{
 			assert(t->compute_frame_active == 0);
 			t->compute_frame_active = 1;
 			/* NOTE(rnp): allow multiple instances of same shader to accumulate */
 			mem_clear(stats->table.times[stats_index], 0, sizeof(stats->table.times[stats_index]));
 		}break;
 		case ComputeTimingInfoKind_ComputeFrameEnd:{
 			assert(t->compute_frame_active == 1);
 			t->compute_frame_active = 0;
 			stats->latest_frame_index = stats_index;
 			stats_index = (stats_index + 1) % countof(stats->table.times);
 		}break;
 		case ComputeTimingInfoKind_Shader:{
 			stats->table.times[stats_index][info.shader] += (f32)info.timer_count / 1.0e9f;
 			seen_info_test |= (1u << info.shader);
 		}break;
 		case ComputeTimingInfoKind_RF_Data:{
 			stats->latest_rf_index = (stats->latest_rf_index + 1) % countof(stats->table.rf_time_deltas);
 			f32 delta = (f32)(info.timer_count - stats->last_rf_timer_count) / 1.0e9f;
 			stats->table.rf_time_deltas[stats->latest_rf_index] = delta;
 			stats->last_rf_timer_count = info.timer_count;
 			seen_info_test |= (1 << BeamformerShaderKind_Count);
 		}break;
 		}
 		/* NOTE(rnp): do this at the end so that stats table is always in a consistent state */
 		atomic_add_u32(&t->read_index, 1);
 	}
 
 	if (seen_info_test) {
 		for EachEnumValue(BeamformerShaderKind, shader) {
 			if (seen_info_test & (1 << shader)) {
 				f32 sum = 0;
 				for EachElement(stats->table.times, i)
 					sum += stats->table.times[i][shader];
 				stats->average_times[shader] = sum / countof(stats->table.times);
 			}
 		}
 
 		if (seen_info_test & (1 << BeamformerShaderKind_Count)) {
 			f32 sum = 0;
 			for EachElement(stats->table.rf_time_deltas, i)
 				sum += stats->table.rf_time_deltas[i];
 			stats->rf_time_delta_average = sum / countof(stats->table.rf_time_deltas);
 		}
 	}
 }
 
 DEBUG_EXPORT BEAMFORMER_COMPLETE_COMPUTE_FN(beamformer_complete_compute)
 {
 	BeamformerCtx *ctx         = (BeamformerCtx *)user_context;
 	BeamformerSharedMemory *sm = ctx->shared_memory.region;
 	complete_queue(ctx, &sm->external_work_queue, arena, gl_context);
 	complete_queue(ctx, ctx->beamform_work_queue, arena, gl_context);
 }
 
 function void
 beamformer_rf_buffer_allocate(BeamformerRFBuffer *rf, u32 rf_size, Arena arena)
 {
 	assert((rf_size % 64) == 0);
 	glUnmapNamedBuffer(rf->ssbo);
 	glDeleteBuffers(1, &rf->ssbo);
 	glCreateBuffers(1, &rf->ssbo);
 
 	glNamedBufferStorage(rf->ssbo, countof(rf->compute_syncs) * rf_size, 0,
 	                     GL_DYNAMIC_STORAGE_BIT|GL_MAP_WRITE_BIT);
 	LABEL_GL_OBJECT(GL_BUFFER, rf->ssbo, s8("Raw_RF_SSBO"));
 	rf->size = rf_size;
 }
 
 DEBUG_EXPORT BEAMFORMER_RF_UPLOAD_FN(beamformer_rf_upload)
 {
 	BeamformerSharedMemory *sm = ctx->shared_memory->region;
 
 	BeamformerSharedMemoryLockKind scratch_lock = BeamformerSharedMemoryLockKind_ScratchSpace;
 	BeamformerSharedMemoryLockKind upload_lock  = BeamformerSharedMemoryLockKind_UploadRF;
 	if (sm->locks[upload_lock] &&
 	    os_shared_memory_region_lock(ctx->shared_memory, sm->locks, (i32)scratch_lock, (u32)-1))
 	{
 		BeamformerRFBuffer *rf = ctx->rf_buffer;
 		rf->active_rf_size = (u32)round_up_to(sm->scratch_rf_size, 64);
 		if (rf->size < rf->active_rf_size)
 			beamformer_rf_buffer_allocate(rf, rf->active_rf_size, arena);
 
 		u32 slot = rf->insertion_index++ % countof(rf->compute_syncs);
 
 		/* NOTE(rnp): if the rest of the code is functioning then the first
 		 * time the compute thread processes an upload it must have gone
 		 * through this path. therefore it is safe to spin until it gets processed */
 		spin_wait(atomic_load_u64(rf->upload_syncs + slot));
 
 		if (rf->compute_syncs[slot]) {
 			GLenum sync_result = glClientWaitSync(rf->compute_syncs[slot], 0, 1000000000);
 			if (sync_result == GL_TIMEOUT_EXPIRED || sync_result == GL_WAIT_FAILED) {
 				// TODO(rnp): what do?
 			}
 			glDeleteSync(rf->compute_syncs[slot]);
 		}
 
 		/* NOTE(rnp): nVidia's drivers really don't play nice with persistant mapping,
 		 * at least when it is a big as this one wants to be. mapping and unmapping the
 		 * desired range each time doesn't seem to introduce any performance hit */
 		u32 access = GL_MAP_WRITE_BIT|GL_MAP_FLUSH_EXPLICIT_BIT|GL_MAP_UNSYNCHRONIZED_BIT;
 		u8 *buffer = glMapNamedBufferRange(rf->ssbo, slot * rf->active_rf_size, (i32)rf->active_rf_size, access);
 
 		mem_copy(buffer, beamformer_shared_memory_scratch_arena(sm).beg, rf->active_rf_size);
 		os_shared_memory_region_unlock(ctx->shared_memory, sm->locks, (i32)scratch_lock);
 		post_sync_barrier(ctx->shared_memory, upload_lock, sm->locks);
 
 		glFlushMappedNamedBufferRange(rf->ssbo, 0, (i32)rf->active_rf_size);
 		glUnmapNamedBuffer(rf->ssbo);
 
 		rf->upload_syncs[slot]  = glFenceSync(GL_SYNC_GPU_COMMANDS_COMPLETE, 0);
 		rf->compute_syncs[slot] = 0;
 		memory_write_barrier();
 
 		os_wake_waiters(ctx->compute_worker_sync);
 
 		ComputeTimingInfo info = {.kind = ComputeTimingInfoKind_RF_Data};
 		glGetQueryObjectui64v(rf->data_timestamp_query, GL_QUERY_RESULT, &info.timer_count);
 		glQueryCounter(rf->data_timestamp_query, GL_TIMESTAMP);
 		push_compute_timing_info(ctx->compute_timing_table, info);
 	}
 }
 
 #include "ui.c"
 
 DEBUG_EXPORT BEAMFORMER_FRAME_STEP_FN(beamformer_frame_step)
 {
 	dt_for_frame = input->dt;
 
 	if (IsWindowResized()) {
 		ctx->window_size.h = GetScreenHeight();
 		ctx->window_size.w = GetScreenWidth();
 	}
 
 	coalesce_timing_table(ctx->compute_timing_table, ctx->compute_shader_stats);
 
 	if (input->executable_reloaded) {
 		ui_init(ctx, ctx->ui_backing_store);
 		DEBUG_DECL(start_frame_capture = ctx->os.start_frame_capture);
 		DEBUG_DECL(end_frame_capture   = ctx->os.end_frame_capture);
 	}
 
 	BeamformerSharedMemory *sm = ctx->shared_memory.region;
 	if (sm->locks[BeamformerSharedMemoryLockKind_UploadRF] != 0)
 		os_wake_waiters(&ctx->os.upload_worker.sync_variable);
 
 	BeamformerFrame        *frame = ctx->latest_frame;
 	BeamformerViewPlaneTag  tag   = frame? frame->view_plane_tag : 0;
 	draw_ui(ctx, input, frame, tag);
 
 	ctx->frame_view_render_context.updated = 0;
 
 	if (WindowShouldClose())
 		ctx->should_exit = 1;
 }
 
 /* NOTE(rnp): functions defined in these shouldn't be visible to the whole program */
 #if _DEBUG
   #if OS_LINUX
     #include "os_linux.c"
   #elif OS_WINDOWS
     #include "os_win32.c"
   #endif
 #endif