ogl_beamforming

beamformer.c (21396B)

---

 /* See LICENSE for license details. */
 
 #include "beamformer_internal.h"
 
 /* NOTE(rnp): magic variables to force discrete GPU usage on laptops with multiple devices */
 EXPORT i32 NvOptimusEnablement = 1;
 EXPORT i32 AmdPowerXpressRequestHighPerformance = 1;
 
 #if !BEAMFORMER_DEBUG
 #include "beamformer_core.c"
 #else
 
 typedef void beamformer_frame_step_fn(BeamformerInput *);
 
 #define BEAMFORMER_DEBUG_ENTRY_POINTS \
 	X(beamformer_debug_ui_deinit)  \
 	X(beamformer_complete_compute) \
 	X(beamformer_frame_step)       \
 	X(beamformer_rf_upload)        \
 
 #define X(name) global name ##_fn *name;
 BEAMFORMER_DEBUG_ENTRY_POINTS
 #undef X
 
 BEAMFORMER_EXPORT void
 beamformer_debug_hot_reload(OSLibrary library, BeamformerInput *input)
 {
 	BeamformerCtx *ctx = BeamformerContextMemory(input->memory);
 
 	// TODO(rnp): this will deadlock if live imaging is active
 	/* NOTE(rnp): spin until compute thread finishes its work (we will probably
 	 * never reload while compute is in progress but just incase). */
 	spin_wait(atomic_load_u32(&ctx->upload_worker.awake));
 	spin_wait(atomic_load_u32(&ctx->compute_worker.awake));
 
 	#define X(name) name = os_lookup_symbol(library, #name);
 	BEAMFORMER_DEBUG_ENTRY_POINTS
 	#undef X
 
 	s8 info = beamformer_info("reloaded main executable");
 	os_console_log(info.data, info.len);
 }
 
 #endif /* BEAMFORMER_DEBUG */
 
 function no_return void
 fatal(s8 message)
 {
 	os_fatal(message.data, message.len);
 	unreachable();
 }
 
 // TODO(rnp): none of this belongs here, but will be removed
 // once vulkan migration is complete
 #define GLFW_VISIBLE 0x00020004
 void   glfwWindowHint(i32, i32);
 iptr   glfwCreateWindow(i32, i32, char *, iptr, iptr);
 void   glfwMakeContextCurrent(iptr);
 iptr   glfwGetGLXContext(iptr);
 iptr   glfwGetWGLContext(iptr);
 void * glfwGetProcAddress(char *);
 
 #if OS_WINDOWS
 function iptr
 os_get_native_gl_context(iptr window)
 {
 	return glfwGetWGLContext(window);
 }
 #else
 function iptr
 os_get_native_gl_context(iptr window)
 {
 	return glfwGetGLXContext(window);
 }
 #endif
 
 function void
 gl_debug_logger(u32 src, u32 type, u32 id, u32 lvl, i32 len, const char *msg, const void *userctx)
 {
 	Stream *e = (Stream *)userctx;
 	stream_append_s8s(e, s8("[OpenGL] "), (s8){.len = len, .data = (u8 *)msg}, s8("\n"));
 	os_console_log(e->data, e->widx);
 	stream_reset(e, 0);
 }
 
 function void
 load_gl(Stream *err)
 {
 	#define X(name, ret, params) name = (name##_fn *)glfwGetProcAddress(#name);
 	OGLProcedureList
 	#undef X
 
 	/* NOTE: Gather information about the GPU */
 	{
 		char *vendor = (char *)glGetString(GL_VENDOR);
 		if (!vendor) {
 			stream_append_s8(err, s8("Failed to determine GL Vendor\n"));
 			fatal(stream_to_s8(err));
 		}
 		/* TODO(rnp): str prefix of */
 		switch (vendor[0]) {
 		case 'A': gl_parameters.vendor_id = GLVendor_AMD;    break;
 		case 'I': gl_parameters.vendor_id = GLVendor_Intel;  break;
 		case 'N': gl_parameters.vendor_id = GLVendor_NVIDIA; break;
 		/* NOTE(rnp): freedreno */
 		case 'f': gl_parameters.vendor_id = GLVendor_ARM;    break;
 		/* NOTE(rnp): Microsoft Corporation - weird win32 thing (microsoft is just using mesa for the driver) */
 		case 'M': gl_parameters.vendor_id = GLVendor_ARM;    break;
 		default:
 			stream_append_s8s(err, s8("Unknown GL Vendor: "), c_str_to_s8(vendor), s8("\n"));
 			fatal(stream_to_s8(err));
 		}
 
 		#define X(glname, name, suffix) glGetIntegerv(GL_##glname, &gl_parameters.name);
 		GL_PARAMETERS
 		#undef X
 	}
 
 #ifdef _DEBUG
 	{
 		s8 vendor = s8("vendor:");
 		i32 max_width = (i32)vendor.len;
 		#define X(glname, name, suffix) if (s8(#name).len > max_width) max_width = (i32)s8(#name ":").len;
 		GL_PARAMETERS
 		#undef X
 		max_width++;
 
 		stream_append_s8s(err, s8("---- GL Parameters ----\n"), vendor);
 		stream_pad(err, ' ', max_width - (i32)vendor.len);
 		switch (gl_parameters.vendor_id) {
 		case GLVendor_AMD:    stream_append_s8(err, s8("AMD"));    break;
 		case GLVendor_ARM:    stream_append_s8(err, s8("ARM"));    break;
 		case GLVendor_Intel:  stream_append_s8(err, s8("Intel"));  break;
 		case GLVendor_NVIDIA: stream_append_s8(err, s8("nVidia")); break;
 		}
 		stream_append_byte(err, '\n');
 
 		#define X(glname, name, suffix) \
 			stream_append_s8(err, s8(#name ":"));                     \
 			stream_pad(err, ' ', max_width - (i32)s8(#name ":").len); \
 			stream_append_i64(err, gl_parameters.name);               \
 			stream_append_s8(err, s8(suffix "\n"));
 		GL_PARAMETERS
 		#undef X
 		stream_append_s8(err, s8("-----------------------\n"));
 		os_console_log(err->data, err->widx);
 	}
 #endif
 
 	{
 		stream_reset(err, 0);
 		if (gl_parameters.max_ubo_size < (i32)sizeof(BeamformerParameters)) {
 			stream_append_s8(err, s8("GPU must support UBOs of at least "));
 			stream_append_i64(err, sizeof(BeamformerParameters));
 			stream_append_s8(err, s8(" bytes!\n"));
 		}
 
 		#define X(name, ret, params) if (!name) stream_append_s8(err, s8("missing required GL function: " #name "\n"));
 		OGLProcedureList
 		#undef X
 
 		if (err->widx) fatal(stream_to_s8(err));
 	}
 }
 
 function void
 beamformer_load_cuda_library(BeamformerCtx *ctx, OSLibrary cuda, Arena arena)
 {
 	/* TODO(rnp): (25.10.30) registering the rf buffer with CUDA is currently
 	 * causing a major performance regression. for now we are disabling its use
 	 * altogether. it will be reenabled once the issue can be fixed */
 	b32 result = 0 && gl_parameters.vendor_id == GLVendor_NVIDIA && ValidHandle(cuda);
 	if (result) {
 		Stream err = arena_stream(arena);
 
 		stream_append_s8(&err, beamformer_info("loading CUDA library functions"));
 		#define X(name, symname) cuda_## name = os_lookup_symbol(cuda, symname);
 		CUDALibraryProcedureList
 		#undef X
 
 		os_console_log(err.data, err.widx);
 	}
 
 	#define X(name, symname) if (!cuda_## name) cuda_## name = cuda_ ## name ## _stub;
 	CUDALibraryProcedureList
 	#undef X
 }
 
 function BeamformerRenderModel
 render_model_from_arrays(f32 *vertices, f32 *normals, i32 vertices_size, u16 *indices, i32 index_count)
 {
 	BeamformerRenderModel result = {0};
 
 	i32 buffer_size    = vertices_size * 2 + index_count * (i32)sizeof(u16);
 	i32 indices_offset = vertices_size * 2;
 	i32 indices_size   = index_count * (i32)sizeof(u16);
 
 	result.elements        = index_count;
 	result.elements_offset = indices_offset;
 
 	glCreateBuffers(1, &result.buffer);
 	glNamedBufferStorage(result.buffer, buffer_size, 0, GL_DYNAMIC_STORAGE_BIT);
 	glNamedBufferSubData(result.buffer, 0,              vertices_size, vertices);
 	glNamedBufferSubData(result.buffer, vertices_size,  vertices_size, normals);
 	glNamedBufferSubData(result.buffer, indices_offset, indices_size,  indices);
 
 	glCreateVertexArrays(1, &result.vao);
 	glVertexArrayVertexBuffer(result.vao, 0, result.buffer, 0,             3 * sizeof(f32));
 	glVertexArrayVertexBuffer(result.vao, 1, result.buffer, vertices_size, 3 * sizeof(f32));
 	glVertexArrayElementBuffer(result.vao, result.buffer);
 
 	glEnableVertexArrayAttrib(result.vao, 0);
 	glEnableVertexArrayAttrib(result.vao, 1);
 
 	glVertexArrayAttribFormat(result.vao, 0, 3, GL_FLOAT, 0, 0);
 	glVertexArrayAttribFormat(result.vao, 1, 3, GL_FLOAT, 0, (u32)vertices_size);
 
 	glVertexArrayAttribBinding(result.vao, 0, 0);
 	glVertexArrayAttribBinding(result.vao, 1, 0);
 
 	return result;
 }
 
 function void
 worker_thread_sleep(GLWorkerThreadContext *ctx, BeamformerSharedMemory *sm)
 {
 	for (;;) {
 		i32 expected = 0;
 		if (atomic_cas_u32(&ctx->sync_variable, &expected, 1) ||
 		    atomic_load_u32(&sm->live_imaging_parameters.active))
 		{
 			break;
 		}
 
 		/* TODO(rnp): clean this crap up; we shouldn't need two values to communicate this */
 		atomic_store_u32(&ctx->awake, 0);
 		os_wait_on_address(&ctx->sync_variable, 1, (u32)-1);
 		atomic_store_u32(&ctx->awake, 1);
 	}
 }
 
 function OS_THREAD_ENTRY_POINT_FN(compute_worker_thread_entry_point)
 {
 	GLWorkerThreadContext *ctx = user_context;
 
 	glfwMakeContextCurrent(ctx->window_handle);
 	ctx->gl_context = os_get_native_gl_context(ctx->window_handle);
 
 	BeamformerCtx *beamformer = (BeamformerCtx *)ctx->user_context;
 	glCreateQueries(GL_TIME_ELAPSED, countof(beamformer->compute_context.shader_timer_ids),
 	                beamformer->compute_context.shader_timer_ids);
 
 	for (;;) {
 		worker_thread_sleep(ctx, beamformer->shared_memory);
 		asan_poison_region(ctx->arena.beg, ctx->arena.end - ctx->arena.beg);
 		beamformer_complete_compute(ctx->user_context, &ctx->arena, ctx->gl_context);
 	}
 
 	unreachable();
 
 	return 0;
 }
 
 function OS_THREAD_ENTRY_POINT_FN(beamformer_upload_entry_point)
 {
 	GLWorkerThreadContext *ctx = user_context;
 	glfwMakeContextCurrent(ctx->window_handle);
 	ctx->gl_context = os_get_native_gl_context(ctx->window_handle);
 
 	BeamformerUploadThreadContext *up = (typeof(up))ctx->user_context;
 	glCreateQueries(GL_TIMESTAMP, 1, &up->rf_buffer->data_timestamp_query);
 	/* NOTE(rnp): start this here so we don't have to worry about it being started or not */
 	glQueryCounter(up->rf_buffer->data_timestamp_query, GL_TIMESTAMP);
 
 	for (;;) {
 		worker_thread_sleep(ctx, up->shared_memory);
 		beamformer_rf_upload(up);
 	}
 
 	unreachable();
 
 	return 0;
 }
 
 BEAMFORMER_EXPORT void
 beamformer_init(BeamformerInput *input)
 {
 	Arena  memory        = arena_from_memory(input->memory, input->memory_size);
 	Arena  compute_arena = sub_arena_end(&memory, MB(2), KB(4));
 	Arena  upload_arena  = sub_arena_end(&memory, KB(4), KB(4));
 	Arena  ui_arena      = sub_arena_end(&memory, MB(2), KB(4));
 	Stream error         = arena_stream(sub_arena_end(&memory, MB(1), 1));
 	BeamformerCtx *ctx   = push_struct(&memory, BeamformerCtx);
 
 	Arena scratch = {.beg = memory.end - 4096L, .end = memory.end};
 	memory.end = scratch.beg;
 
 	ctx->window_size = (iv2){{1280, 840}};
 	ctx->error_stream = error;
 	ctx->ui_backing_store = ui_arena;
 
 	ctx->compute_worker.arena  = compute_arena;
 	ctx->upload_worker.arena   = upload_arena;
 
 	beamformer_load_cuda_library(ctx, input->cuda_library_handle, memory);
 
 	SetConfigFlags(FLAG_VSYNC_HINT|FLAG_WINDOW_ALWAYS_RUN);
 	InitWindow(ctx->window_size.w, ctx->window_size.h, "OGL Beamformer");
 	/* NOTE: do this after initing so that the window starts out floating in tiling wm */
 	SetWindowState(FLAG_WINDOW_RESIZABLE);
 	SetWindowMinSize(840, ctx->window_size.h);
 
 	glfwWindowHint(GLFW_VISIBLE, 0);
 	iptr raylib_window_handle = (iptr)GetPlatformWindowHandle();
 
 	load_gl(&ctx->error_stream);
 
 	ctx->beamform_work_queue  = push_struct(&memory, BeamformWorkQueue);
 	ctx->compute_shader_stats = push_struct(&memory, ComputeShaderStats);
 	ctx->compute_timing_table = push_struct(&memory, ComputeTimingTable);
 
 	ctx->shared_memory = input->shared_memory;
 	if (!ctx->shared_memory) fatal(s8("Get more ram lol\n"));
 	zero_struct(ctx->shared_memory);
 
 	ctx->shared_memory->version = BEAMFORMER_SHARED_MEMORY_VERSION;
 	ctx->shared_memory->reserved_parameter_blocks = 1;
 
 	/* TODO(rnp): I'm not sure if its a good idea to pre-reserve a bunch of semaphores
 	 * on w32 but thats what we are doing for now */
 	#if OS_WINDOWS
 	{
 		Stream sb = arena_stream(memory);
 		stream_append(&sb, input->shared_memory_name, input->shared_memory_name_length);
 		stream_append_s8(&sb, s8("_lock_"));
 		i32 start_index = sb.widx;
 		for EachElement(os_w32_shared_memory_semaphores, it) {
 			stream_reset(&sb, start_index);
 			stream_append_u64(&sb, it);
 			stream_append_byte(&sb, 0);
 			os_w32_shared_memory_semaphores[it] = os_w32_create_semaphore((c8 *)sb.data, 1, 1);
 			if InvalidHandle(os_w32_shared_memory_semaphores[it])
 				fatal(beamformer_info("init: failed to create w32 shared memory semaphore\n"));
 
 			/* NOTE(rnp): hacky garbage because CreateSemaphore will just open an existing
 			 * semaphore without any indication. Sometimes the other side of the shared memory
 			 * will provide incorrect parameters or will otherwise fail and its faster to
 			 * restart this program than to get that application to release the semaphores */
 			/* TODO(rnp): figure out something more robust */
 			os_w32_semaphore_release(os_w32_shared_memory_semaphores[it], 1);
 		}
 	}
 	#endif
 
 	BeamformerComputeContext *cs = &ctx->compute_context;
 
 	GLWorkerThreadContext *worker = &ctx->compute_worker;
 	/* TODO(rnp): we should lock this down after we have something working */
 	worker->user_context  = (iptr)ctx;
 	worker->window_handle = glfwCreateWindow(1, 1, "", 0, raylib_window_handle);
 	worker->handle        = os_create_thread("[compute]", worker, compute_worker_thread_entry_point);
 
 	GLWorkerThreadContext         *upload = &ctx->upload_worker;
 	BeamformerUploadThreadContext *upctx  = push_struct(&memory, typeof(*upctx));
 	upload->user_context = (iptr)upctx;
 	upctx->rf_buffer     = &cs->rf_buffer;
 	upctx->shared_memory = ctx->shared_memory;
 	upctx->compute_timing_table = ctx->compute_timing_table;
 	upctx->compute_worker_sync  = &ctx->compute_worker.sync_variable;
 	upload->window_handle = glfwCreateWindow(1, 1, "", 0, raylib_window_handle);
 	upload->handle        = os_create_thread("[upload]", upload, beamformer_upload_entry_point);
 
 	glfwMakeContextCurrent(raylib_window_handle);
 
 	/* NOTE: set up OpenGL debug logging */
 	Stream *gl_error_stream = push_struct(&memory, Stream);
 	*gl_error_stream        = stream_alloc(&memory, 1024);
 	glDebugMessageCallback(gl_debug_logger, gl_error_stream);
 #ifdef _DEBUG
 	glEnable(GL_DEBUG_OUTPUT);
 #endif
 
 	if (!BakeShaders)
 	{
 		for EachElement(beamformer_reloadable_compute_shader_info_indices, it) {
 			i32   index = beamformer_reloadable_compute_shader_info_indices[it];
 			Arena temp  = scratch;
 			s8 file = push_s8_from_parts(&temp, os_path_separator(), s8("shaders"),
 			                             beamformer_reloadable_shader_files[index]);
 			BeamformerFileReloadContext *frc = push_struct(&memory, typeof(*frc));
 			frc->kind                = BeamformerFileReloadKind_ComputeShader;
 			frc->compute_shader_kind = beamformer_reloadable_shader_kinds[index];
 			os_add_file_watch((char *)file.data, file.len, frc);
 		}
 	}
 
 	FrameViewRenderContext *fvr = &ctx->frame_view_render_context;
 	glCreateFramebuffers(countof(fvr->framebuffers), fvr->framebuffers);
 	LABEL_GL_OBJECT(GL_FRAMEBUFFER, fvr->framebuffers[0], s8("Frame View Framebuffer"));
 	LABEL_GL_OBJECT(GL_FRAMEBUFFER, fvr->framebuffers[1], s8("Frame View Resolving Framebuffer"));
 
 	glCreateRenderbuffers(countof(fvr->renderbuffers), fvr->renderbuffers);
 	i32 msaa_samples = gl_parameters.vendor_id == GLVendor_ARM? 4 : 8;
 	glNamedRenderbufferStorageMultisample(fvr->renderbuffers[0], msaa_samples, GL_RGBA8,
 	                                      FRAME_VIEW_RENDER_TARGET_SIZE);
 	glNamedRenderbufferStorageMultisample(fvr->renderbuffers[1], msaa_samples, GL_DEPTH_COMPONENT24,
 	                                      FRAME_VIEW_RENDER_TARGET_SIZE);
 
 	static_assert(countof(beamformer_reloadable_render_shader_info_indices) == 1,
 	              "only a single render shader is currently handled");
 	i32 render_rsi_index = beamformer_reloadable_render_shader_info_indices[0];
 
 	// TODO(rnp): leaks when BakeShaders is true
 	Arena *arena = &memory;
 	BeamformerShaderReloadContext *render_3d = push_struct(arena, typeof(*render_3d));
 	render_3d->reloadable_info_index = render_rsi_index;
 	render_3d->gl_type = GL_FRAGMENT_SHADER;
 	render_3d->header  = s8(""
 	"layout(location = 0) in  vec3 normal;\n"
 	"layout(location = 1) in  vec3 texture_coordinate;\n\n"
 	"layout(location = 2) in  vec3 test_texture_coordinate;\n\n"
 	"layout(location = 0) out vec4 out_colour;\n\n"
 	"layout(location = " str(FRAME_VIEW_DYNAMIC_RANGE_LOC) ") uniform float u_db_cutoff = 60;\n"
 	"layout(location = " str(FRAME_VIEW_THRESHOLD_LOC)     ") uniform float u_threshold = 40;\n"
 	"layout(location = " str(FRAME_VIEW_GAMMA_LOC)         ") uniform float u_gamma     = 1;\n"
 	"layout(location = " str(FRAME_VIEW_LOG_SCALE_LOC)     ") uniform bool  u_log_scale;\n"
 	"layout(location = " str(FRAME_VIEW_BB_COLOUR_LOC)     ") uniform vec4  u_bb_colour   = vec4(" str(FRAME_VIEW_BB_COLOUR) ");\n"
 	"layout(location = " str(FRAME_VIEW_BB_FRACTION_LOC)   ") uniform float u_bb_fraction = " str(FRAME_VIEW_BB_FRACTION) ";\n"
 	"layout(location = " str(FRAME_VIEW_SOLID_BB_LOC)      ") uniform bool  u_solid_bb;\n"
 	"\n"
 	"layout(binding = 0) uniform sampler3D u_texture;\n");
 
 	render_3d->link = push_struct(arena, typeof(*render_3d));
 	render_3d->link->reloadable_info_index = -1;
 	render_3d->link->gl_type = GL_VERTEX_SHADER;
 	render_3d->link->link    = render_3d;
 	render_3d->link->header  = s8(""
 	"layout(location = 0) in vec3 v_position;\n"
 	"layout(location = 1) in vec3 v_normal;\n"
 	"\n"
 	"layout(location = 0) out vec3 f_normal;\n"
 	"layout(location = 1) out vec3 f_texture_coordinate;\n"
 	"layout(location = 2) out vec3 f_orig_texture_coordinate;\n"
 	"\n"
 	"layout(location = " str(FRAME_VIEW_MODEL_MATRIX_LOC)  ") uniform mat4  u_model;\n"
 	"layout(location = " str(FRAME_VIEW_VIEW_MATRIX_LOC)   ") uniform mat4  u_view;\n"
 	"layout(location = " str(FRAME_VIEW_PROJ_MATRIX_LOC)   ") uniform mat4  u_projection;\n"
 	"\n"
 	"\n"
 	"void main()\n"
 	"{\n"
 	"\tvec3 pos = v_position;\n"
 	"\tf_orig_texture_coordinate = (2 * v_position + 1) / 2;\n"
 	//"\tif (v_position.y == -1) pos.x = clamp(v_position.x, -u_clip_fraction, u_clip_fraction);\n"
 	"\tvec3 tex_coord = (2 * pos + 1) / 2;\n"
 	"\tf_texture_coordinate = tex_coord.xzy;\n"
 	//"\tf_texture_coordinate = u_swizzle? tex_coord.xzy : tex_coord;\n"
 	//"\tf_normal    = normalize(mat3(u_model) * v_normal);\n"
 	"\tf_normal    = v_normal;\n"
 	"\tgl_Position = u_projection * u_view * u_model * vec4(pos, 1);\n"
 	"}\n");
 
 	// TODO(rnp): this is probably not expected by the platform, refactor so that all
 	// needed context (eg. headers) are available outside of here and push initial load
 	// into ui_init
 	{
 		BeamformerFileReloadContext *frc = push_struct(&memory, typeof(*frc));
 		frc->kind                  = BeamformerFileReloadKind_Shader;
 		frc->shader_reload_context = render_3d;
 		input->event_queue[input->event_count++] = (BeamformerInputEvent){
 			.kind = BeamformerInputEventKind_FileEvent,
 			.file_watch_user_context = frc,
 		};
 
 		s8 render_file = {0};
 		if (!BakeShaders) {
 			render_file = push_s8_from_parts(&scratch, os_path_separator(), s8("shaders"),
 			                                 beamformer_reloadable_shader_files[render_rsi_index]);
 			os_add_file_watch((char *)render_file.data, render_file.len, frc);
 		}
 	}
 
 	f32 unit_cube_vertices[] = {
 		 0.5f,  0.5f, -0.5f,
 		 0.5f,  0.5f, -0.5f,
 		 0.5f,  0.5f, -0.5f,
 		 0.5f, -0.5f, -0.5f,
 		 0.5f, -0.5f, -0.5f,
 		 0.5f, -0.5f, -0.5f,
 		 0.5f,  0.5f,  0.5f,
 		 0.5f,  0.5f,  0.5f,
 		 0.5f,  0.5f,  0.5f,
 		 0.5f, -0.5f,  0.5f,
 		 0.5f, -0.5f,  0.5f,
 		 0.5f, -0.5f,  0.5f,
 		-0.5f,  0.5f, -0.5f,
 		-0.5f,  0.5f, -0.5f,
 		-0.5f,  0.5f, -0.5f,
 		-0.5f, -0.5f, -0.5f,
 		-0.5f, -0.5f, -0.5f,
 		-0.5f, -0.5f, -0.5f,
 		-0.5f,  0.5f,  0.5f,
 		-0.5f,  0.5f,  0.5f,
 		-0.5f,  0.5f,  0.5f,
 		-0.5f, -0.5f,  0.5f,
 		-0.5f, -0.5f,  0.5f,
 		-0.5f, -0.5f,  0.5f
 	};
 	f32 unit_cube_normals[] = {
 		 0.0f,  0.0f, -1.0f,
 		 0.0f,  1.0f,  0.0f,
 		 1.0f,  0.0f,  0.0f,
 		 0.0f,  0.0f, -1.0f,
 		 0.0f, -1.0f,  0.0f,
 		 1.0f,  0.0f,  0.0f,
 		 0.0f,  0.0f,  1.0f,
 		 0.0f,  1.0f,  0.0f,
 		 1.0f,  0.0f,  0.0f,
 		 0.0f,  0.0f,  1.0f,
 		 0.0f, -1.0f,  0.0f,
 		 1.0f,  0.0f,  0.0f,
 		 0.0f,  0.0f, -1.0f,
 		 0.0f,  1.0f,  0.0f,
 		-1.0f,  0.0f,  0.0f,
 		 0.0f,  0.0f, -1.0f,
 		 0.0f, -1.0f,  0.0f,
 		-1.0f,  0.0f,  0.0f,
 		 0.0f,  0.0f,  1.0f,
 		 0.0f,  1.0f,  0.0f,
 		-1.0f,  0.0f,  0.0f,
 		 0.0f,  0.0f,  1.0f,
 		 0.0f, -1.0f,  0.0f,
 		-1.0f,  0.0f,  0.0f
 	};
 	u16 unit_cube_indices[] = {
 		1,  13, 19,
 		1,  19, 7,
 		9,  6,  18,
 		9,  18, 21,
 		23, 20, 14,
 		23, 14, 17,
 		16, 4,  10,
 		16, 10, 22,
 		5,  2,  8,
 		5,  8,  11,
 		15, 12, 0,
 		15, 0,  3
 	};
 
 	cs->unit_cube_model = render_model_from_arrays(unit_cube_vertices, unit_cube_normals,
 	                                               sizeof(unit_cube_vertices),
 	                                               unit_cube_indices, countof(unit_cube_indices));
 
 	memory.end = scratch.end;
 	ctx->arena = memory;
 	ctx->state = BeamformerState_Running;
 }
 
 BEAMFORMER_EXPORT void
 beamformer_terminate(BeamformerInput *input)
 {
 	/* NOTE(rnp): work around pebkac when the beamformer is closed while we are doing live
 	 * imaging. if the verasonics is blocked in an external function (calling the library
 	 * to start compute) it is impossible for us to get it to properly shut down which
 	 * will sometimes result in us needing to power cycle the system. set the shared memory
 	 * into an error state and release dispatch lock so that future calls will error instead
 	 * of blocking.
 	 */
 	BeamformerCtx *          ctx = BeamformerContextMemory(input->memory);
 	BeamformerSharedMemory * sm  = input->shared_memory;
 	if (ctx->state != BeamformerState_Terminated) {
 		if (sm) {
 			BeamformerSharedMemoryLockKind lock = BeamformerSharedMemoryLockKind_DispatchCompute;
 			atomic_store_u32(&sm->invalid, 1);
 			atomic_store_u32(&sm->external_work_queue.ridx, sm->external_work_queue.widx);
 			DEBUG_DECL(if (sm->locks[lock])) {
 				beamformer_shared_memory_release_lock(sm, (i32)lock);
 			}
 
 			atomic_or_u32(&sm->live_imaging_dirty_flags, BeamformerLiveImagingDirtyFlags_StopImaging);
 		}
 
 		beamformer_debug_ui_deinit(ctx);
 
 		ctx->state = BeamformerState_Terminated;
 	}
 }
 
 BEAMFORMER_EXPORT u32
 beamformer_should_close(BeamformerInput *input)
 {
 	BeamformerCtx * ctx = BeamformerContextMemory(input->memory);
 	if (ctx->state == BeamformerState_ShouldClose)
 		beamformer_terminate(input);
 	return ctx->state == BeamformerState_Terminated;
 }