internal App_Init_Desc incenter_get_init_desc() { App_Init_Desc result = {}; result.assembly_cap = 4; return result; } #define INCENTER_METER 1.0f #define INCENTER_FOOT 0.3048f #define INCENTER_METERS(count) (count) * INCENTER_METER #define INCENTER_FEET(count) (count) * INCENTER_FOOT #define INCENTER_PER_METER(count) INCENTER_METER / (r32)(count) internal void incenter_init(App_State* state) { // create a fake sculpture Assembly_Handle ah = assembly_add(&state->assemblies, lit_str("test"), 5043, 41); //Assembly_Handle ah = assembly_add(&state->assemblies, lit_str("test"), 20000, 150); scratch_get(scratch); Allocator* s = scratch.a; v3 start_p = (v3){0, 0, 0}; Assembly_Strip* vertical_strip = assembly_add_strip(&state->assemblies, ah, 123); assembly_strip_create_leds( &state->assemblies, ah, vertical_strip, start_p, (v3){0, INCENTER_FEET(-4.5f), 0}, 123 ); r32 radius = INCENTER_FEET(10); Random_Series rand = random_series_create(hash_djb2_cstr_to_u32("slfsaassdjf")); u32 i = 0; while (i < 40) //for (u32 i = 0; i < 40; i++) { r32 theta = random_series_next_unilateral(&rand) * r32_tau; r32 phi = random_series_next_unilateral(&rand) * r32_tau; // spherical to cartesian conversion v3 end_p = { radius * sinf(phi) * cosf(theta), radius * sinf(phi) * sinf(theta), radius * cosf(phi) }; r32 down = HMM_DotVec3(HMM_NormalizeVec3(end_p), (v3){0, -1, 0}); if (down > 0.7f || down < -0.9f) continue; Assembly_Strip* strip = assembly_add_strip(&state->assemblies, ah, 123); strip->output_kind = OutputData_NetworkSACN; strip->sacn_universe = i; assembly_strip_create_leds(&state->assemblies, ah, strip, start_p, end_p, 123); i++; } r32 rad = 0.05f; sculpture_updated(state, 5, rad); scratch_release(scratch); } internal void incenter_frame_prepare(App_State* state) { } internal void incenter_frame(App_State* state) { } internal void incenter_cleanup(App_State* state) { }