#pragma clang diagnostic ignored "-Wmissing-prototypes" #pragma clang diagnostic ignored "-Wmissing-braces" #include #include using namespace metal; template struct spvUnsafeArray { T elements[Num ? Num : 1]; thread T& operator [] (size_t pos) thread { return elements[pos]; } constexpr const thread T& operator [] (size_t pos) const thread { return elements[pos]; } device T& operator [] (size_t pos) device { return elements[pos]; } constexpr const device T& operator [] (size_t pos) const device { return elements[pos]; } constexpr const constant T& operator [] (size_t pos) const constant { return elements[pos]; } threadgroup T& operator [] (size_t pos) threadgroup { return elements[pos]; } constexpr const threadgroup T& operator [] (size_t pos) const threadgroup { return elements[pos]; } }; struct Alloc { uint offset; }; struct CmdStrokeRef { uint offset; }; struct CmdStroke { uint tile_ref; float half_width; }; struct CmdFillRef { uint offset; }; struct CmdFill { uint tile_ref; int backdrop; }; struct CmdColorRef { uint offset; }; struct CmdColor { uint rgba_color; }; struct CmdLinGradRef { uint offset; }; struct CmdLinGrad { uint index; float line_x; float line_y; float line_c; }; struct CmdImageRef { uint offset; }; struct CmdImage { uint index; int2 offset; }; struct CmdAlphaRef { uint offset; }; struct CmdAlpha { float alpha; }; struct CmdEndClipRef { uint offset; }; struct CmdEndClip { uint blend; }; struct CmdJumpRef { uint offset; }; struct CmdJump { uint new_ref; }; struct CmdRef { uint offset; }; struct CmdTag { uint tag; uint flags; }; struct TileSegRef { uint offset; }; struct TileSeg { float2 origin; float2 vector; float y_edge; TileSegRef next; }; struct Memory { uint mem_offset; uint mem_error; uint memory[1]; }; struct Alloc_1 { uint offset; }; struct Config { uint n_elements; uint n_pathseg; uint width_in_tiles; uint height_in_tiles; Alloc_1 tile_alloc; Alloc_1 bin_alloc; Alloc_1 ptcl_alloc; Alloc_1 pathseg_alloc; Alloc_1 anno_alloc; Alloc_1 trans_alloc; Alloc_1 bbox_alloc; Alloc_1 drawmonoid_alloc; Alloc_1 clip_alloc; Alloc_1 clip_bic_alloc; Alloc_1 clip_stack_alloc; Alloc_1 clip_bbox_alloc; uint n_trans; uint n_path; uint n_clip; uint trans_offset; uint linewidth_offset; uint pathtag_offset; uint pathseg_offset; }; struct ConfigBuf { Config conf; }; constant uint3 gl_WorkGroupSize [[maybe_unused]] = uint3(8u, 4u, 1u); static inline __attribute__((always_inline)) Alloc slice_mem(thread const Alloc& a, thread const uint& offset, thread const uint& size) { return Alloc{ a.offset + offset }; } static inline __attribute__((always_inline)) bool touch_mem(thread const Alloc& alloc, thread const uint& offset) { return true; } static inline __attribute__((always_inline)) uint read_mem(thread const Alloc& alloc, thread const uint& offset, device Memory& v_278) { Alloc param = alloc; uint param_1 = offset; if (!touch_mem(param, param_1)) { return 0u; } uint v = v_278.memory[offset]; return v; } static inline __attribute__((always_inline)) CmdTag Cmd_tag(thread const Alloc& a, thread const CmdRef& ref, device Memory& v_278) { Alloc param = a; uint param_1 = ref.offset >> uint(2); uint tag_and_flags = read_mem(param, param_1, v_278); return CmdTag{ tag_and_flags & 65535u, tag_and_flags >> uint(16) }; } static inline __attribute__((always_inline)) CmdStroke CmdStroke_read(thread const Alloc& a, thread const CmdStrokeRef& ref, device Memory& v_278) { uint ix = ref.offset >> uint(2); Alloc param = a; uint param_1 = ix + 0u; uint raw0 = read_mem(param, param_1, v_278); Alloc param_2 = a; uint param_3 = ix + 1u; uint raw1 = read_mem(param_2, param_3, v_278); CmdStroke s; s.tile_ref = raw0; s.half_width = as_type(raw1); return s; } static inline __attribute__((always_inline)) CmdStroke Cmd_Stroke_read(thread const Alloc& a, thread const CmdRef& ref, device Memory& v_278) { Alloc param = a; CmdStrokeRef param_1 = CmdStrokeRef{ ref.offset + 4u }; return CmdStroke_read(param, param_1, v_278); } static inline __attribute__((always_inline)) Alloc new_alloc(thread const uint& offset, thread const uint& size, thread const bool& mem_ok) { Alloc a; a.offset = offset; return a; } static inline __attribute__((always_inline)) TileSeg TileSeg_read(thread const Alloc& a, thread const TileSegRef& ref, device Memory& v_278) { uint ix = ref.offset >> uint(2); Alloc param = a; uint param_1 = ix + 0u; uint raw0 = read_mem(param, param_1, v_278); Alloc param_2 = a; uint param_3 = ix + 1u; uint raw1 = read_mem(param_2, param_3, v_278); Alloc param_4 = a; uint param_5 = ix + 2u; uint raw2 = read_mem(param_4, param_5, v_278); Alloc param_6 = a; uint param_7 = ix + 3u; uint raw3 = read_mem(param_6, param_7, v_278); Alloc param_8 = a; uint param_9 = ix + 4u; uint raw4 = read_mem(param_8, param_9, v_278); Alloc param_10 = a; uint param_11 = ix + 5u; uint raw5 = read_mem(param_10, param_11, v_278); TileSeg s; s.origin = float2(as_type(raw0), as_type(raw1)); s.vector = float2(as_type(raw2), as_type(raw3)); s.y_edge = as_type(raw4); s.next = TileSegRef{ raw5 }; return s; } static inline __attribute__((always_inline)) uint2 chunk_offset(thread const uint& i) { return uint2((i % 2u) * 8u, (i / 2u) * 4u); } static inline __attribute__((always_inline)) CmdFill CmdFill_read(thread const Alloc& a, thread const CmdFillRef& ref, device Memory& v_278) { uint ix = ref.offset >> uint(2); Alloc param = a; uint param_1 = ix + 0u; uint raw0 = read_mem(param, param_1, v_278); Alloc param_2 = a; uint param_3 = ix + 1u; uint raw1 = read_mem(param_2, param_3, v_278); CmdFill s; s.tile_ref = raw0; s.backdrop = int(raw1); return s; } static inline __attribute__((always_inline)) CmdFill Cmd_Fill_read(thread const Alloc& a, thread const CmdRef& ref, device Memory& v_278) { Alloc param = a; CmdFillRef param_1 = CmdFillRef{ ref.offset + 4u }; return CmdFill_read(param, param_1, v_278); } static inline __attribute__((always_inline)) CmdAlpha CmdAlpha_read(thread const Alloc& a, thread const CmdAlphaRef& ref, device Memory& v_278) { uint ix = ref.offset >> uint(2); Alloc param = a; uint param_1 = ix + 0u; uint raw0 = read_mem(param, param_1, v_278); CmdAlpha s; s.alpha = as_type(raw0); return s; } static inline __attribute__((always_inline)) CmdAlpha Cmd_Alpha_read(thread const Alloc& a, thread const CmdRef& ref, device Memory& v_278) { Alloc param = a; CmdAlphaRef param_1 = CmdAlphaRef{ ref.offset + 4u }; return CmdAlpha_read(param, param_1, v_278); } static inline __attribute__((always_inline)) CmdColor CmdColor_read(thread const Alloc& a, thread const CmdColorRef& ref, device Memory& v_278) { uint ix = ref.offset >> uint(2); Alloc param = a; uint param_1 = ix + 0u; uint raw0 = read_mem(param, param_1, v_278); CmdColor s; s.rgba_color = raw0; return s; } static inline __attribute__((always_inline)) CmdColor Cmd_Color_read(thread const Alloc& a, thread const CmdRef& ref, device Memory& v_278) { Alloc param = a; CmdColorRef param_1 = CmdColorRef{ ref.offset + 4u }; return CmdColor_read(param, param_1, v_278); } static inline __attribute__((always_inline)) float3 fromsRGB(thread const float3& srgb) { bool3 cutoff = srgb >= float3(0.040449999272823333740234375); float3 below = srgb / float3(12.9200000762939453125); float3 above = pow((srgb + float3(0.054999999701976776123046875)) / float3(1.05499994754791259765625), float3(2.400000095367431640625)); return select(below, above, cutoff); } static inline __attribute__((always_inline)) float4 unpacksRGB(thread const uint& srgba) { float4 color = unpack_unorm4x8_to_float(srgba).wzyx; float3 param = color.xyz; return float4(fromsRGB(param), color.w); } static inline __attribute__((always_inline)) CmdLinGrad CmdLinGrad_read(thread const Alloc& a, thread const CmdLinGradRef& ref, device Memory& v_278) { uint ix = ref.offset >> uint(2); Alloc param = a; uint param_1 = ix + 0u; uint raw0 = read_mem(param, param_1, v_278); Alloc param_2 = a; uint param_3 = ix + 1u; uint raw1 = read_mem(param_2, param_3, v_278); Alloc param_4 = a; uint param_5 = ix + 2u; uint raw2 = read_mem(param_4, param_5, v_278); Alloc param_6 = a; uint param_7 = ix + 3u; uint raw3 = read_mem(param_6, param_7, v_278); CmdLinGrad s; s.index = raw0; s.line_x = as_type(raw1); s.line_y = as_type(raw2); s.line_c = as_type(raw3); return s; } static inline __attribute__((always_inline)) CmdLinGrad Cmd_LinGrad_read(thread const Alloc& a, thread const CmdRef& ref, device Memory& v_278) { Alloc param = a; CmdLinGradRef param_1 = CmdLinGradRef{ ref.offset + 4u }; return CmdLinGrad_read(param, param_1, v_278); } static inline __attribute__((always_inline)) CmdImage CmdImage_read(thread const Alloc& a, thread const CmdImageRef& ref, device Memory& v_278) { uint ix = ref.offset >> uint(2); Alloc param = a; uint param_1 = ix + 0u; uint raw0 = read_mem(param, param_1, v_278); Alloc param_2 = a; uint param_3 = ix + 1u; uint raw1 = read_mem(param_2, param_3, v_278); CmdImage s; s.index = raw0; s.offset = int2(int(raw1 << uint(16)) >> 16, int(raw1) >> 16); return s; } static inline __attribute__((always_inline)) CmdImage Cmd_Image_read(thread const Alloc& a, thread const CmdRef& ref, device Memory& v_278) { Alloc param = a; CmdImageRef param_1 = CmdImageRef{ ref.offset + 4u }; return CmdImage_read(param, param_1, v_278); } static inline __attribute__((always_inline)) spvUnsafeArray fillImage(thread const uint2& xy, thread const CmdImage& cmd_img, thread texture2d image_atlas) { spvUnsafeArray rgba; for (uint i = 0u; i < 8u; i++) { uint param = i; int2 uv = int2(xy + chunk_offset(param)) + cmd_img.offset; float4 fg_rgba = image_atlas.read(uint2(uv)); float3 param_1 = fg_rgba.xyz; float3 _1493 = fromsRGB(param_1); fg_rgba.x = _1493.x; fg_rgba.y = _1493.y; fg_rgba.z = _1493.z; rgba[i] = fg_rgba; } return rgba; } static inline __attribute__((always_inline)) float3 tosRGB(thread const float3& rgb) { bool3 cutoff = rgb >= float3(0.003130800090730190277099609375); float3 below = float3(12.9200000762939453125) * rgb; float3 above = (float3(1.05499994754791259765625) * pow(rgb, float3(0.416660010814666748046875))) - float3(0.054999999701976776123046875); return select(below, above, cutoff); } static inline __attribute__((always_inline)) uint packsRGB(thread float4& rgba) { float3 param = rgba.xyz; rgba = float4(tosRGB(param), rgba.w); return pack_float_to_unorm4x8(rgba.wzyx); } static inline __attribute__((always_inline)) CmdEndClip CmdEndClip_read(thread const Alloc& a, thread const CmdEndClipRef& ref, device Memory& v_278) { uint ix = ref.offset >> uint(2); Alloc param = a; uint param_1 = ix + 0u; uint raw0 = read_mem(param, param_1, v_278); CmdEndClip s; s.blend = raw0; return s; } static inline __attribute__((always_inline)) CmdEndClip Cmd_EndClip_read(thread const Alloc& a, thread const CmdRef& ref, device Memory& v_278) { Alloc param = a; CmdEndClipRef param_1 = CmdEndClipRef{ ref.offset + 4u }; return CmdEndClip_read(param, param_1, v_278); } static inline __attribute__((always_inline)) float3 screen(thread const float3& cb, thread const float3& cs) { return (cb + cs) - (cb * cs); } static inline __attribute__((always_inline)) float3 hard_light(thread const float3& cb, thread const float3& cs) { float3 param = cb; float3 param_1 = (cs * 2.0) - float3(1.0); return mix(screen(param, param_1), (cb * 2.0) * cs, float3(cs <= float3(0.5))); } static inline __attribute__((always_inline)) float color_dodge(thread const float& cb, thread const float& cs) { if (cb == 0.0) { return 0.0; } else { if (cs == 1.0) { return 1.0; } else { return fast::min(1.0, cb / (1.0 - cs)); } } } static inline __attribute__((always_inline)) float color_burn(thread const float& cb, thread const float& cs) { if (cb == 1.0) { return 1.0; } else { if (cs == 0.0) { return 0.0; } else { return 1.0 - fast::min(1.0, (1.0 - cb) / cs); } } } static inline __attribute__((always_inline)) float3 soft_light(thread const float3& cb, thread const float3& cs) { float3 d = mix(sqrt(cb), ((((cb * 16.0) - float3(12.0)) * cb) + float3(4.0)) * cb, float3(cb <= float3(0.25))); return mix(cb + (((cs * 2.0) - float3(1.0)) * (d - cb)), cb - (((float3(1.0) - (cs * 2.0)) * cb) * (float3(1.0) - cb)), float3(cs <= float3(0.5))); } static inline __attribute__((always_inline)) float sat(thread const float3& c) { return fast::max(c.x, fast::max(c.y, c.z)) - fast::min(c.x, fast::min(c.y, c.z)); } static inline __attribute__((always_inline)) void set_sat_inner(thread float& cmin, thread float& cmid, thread float& cmax, thread const float& s) { if (cmax > cmin) { cmid = ((cmid - cmin) * s) / (cmax - cmin); cmax = s; } else { cmid = 0.0; cmax = 0.0; } cmin = 0.0; } static inline __attribute__((always_inline)) float3 set_sat(thread float3& c, thread const float& s) { if (c.x <= c.y) { if (c.y <= c.z) { float param = c.x; float param_1 = c.y; float param_2 = c.z; float param_3 = s; set_sat_inner(param, param_1, param_2, param_3); c.x = param; c.y = param_1; c.z = param_2; } else { if (c.x <= c.z) { float param_4 = c.x; float param_5 = c.z; float param_6 = c.y; float param_7 = s; set_sat_inner(param_4, param_5, param_6, param_7); c.x = param_4; c.z = param_5; c.y = param_6; } else { float param_8 = c.z; float param_9 = c.x; float param_10 = c.y; float param_11 = s; set_sat_inner(param_8, param_9, param_10, param_11); c.z = param_8; c.x = param_9; c.y = param_10; } } } else { if (c.x <= c.z) { float param_12 = c.y; float param_13 = c.x; float param_14 = c.z; float param_15 = s; set_sat_inner(param_12, param_13, param_14, param_15); c.y = param_12; c.x = param_13; c.z = param_14; } else { if (c.y <= c.z) { float param_16 = c.y; float param_17 = c.z; float param_18 = c.x; float param_19 = s; set_sat_inner(param_16, param_17, param_18, param_19); c.y = param_16; c.z = param_17; c.x = param_18; } else { float param_20 = c.z; float param_21 = c.y; float param_22 = c.x; float param_23 = s; set_sat_inner(param_20, param_21, param_22, param_23); c.z = param_20; c.y = param_21; c.x = param_22; } } } return c; } static inline __attribute__((always_inline)) float lum(thread const float3& c) { float3 f = float3(0.300000011920928955078125, 0.589999973773956298828125, 0.10999999940395355224609375); return dot(c, f); } static inline __attribute__((always_inline)) float3 clip_color(thread float3& c) { float3 param = c; float L = lum(param); float n = fast::min(c.x, fast::min(c.y, c.z)); float x = fast::max(c.x, fast::max(c.y, c.z)); if (n < 0.0) { c = float3(L) + (((c - float3(L)) * L) / float3(L - n)); } if (x > 1.0) { c = float3(L) + (((c - float3(L)) * (1.0 - L)) / float3(x - L)); } return c; } static inline __attribute__((always_inline)) float3 set_lum(thread const float3& c, thread const float& l) { float3 param = c; float3 param_1 = c + float3(l - lum(param)); float3 _901 = clip_color(param_1); return _901; } static inline __attribute__((always_inline)) float3 mix_blend(thread const float3& cb, thread const float3& cs, thread const uint& mode) { float3 b = float3(0.0); switch (mode) { case 1u: { b = cb * cs; break; } case 2u: { float3 param = cb; float3 param_1 = cs; b = screen(param, param_1); break; } case 3u: { float3 param_2 = cs; float3 param_3 = cb; b = hard_light(param_2, param_3); break; } case 4u: { b = fast::min(cb, cs); break; } case 5u: { b = fast::max(cb, cs); break; } case 6u: { float param_4 = cb.x; float param_5 = cs.x; float param_6 = cb.y; float param_7 = cs.y; float param_8 = cb.z; float param_9 = cs.z; b = float3(color_dodge(param_4, param_5), color_dodge(param_6, param_7), color_dodge(param_8, param_9)); break; } case 7u: { float param_10 = cb.x; float param_11 = cs.x; float param_12 = cb.y; float param_13 = cs.y; float param_14 = cb.z; float param_15 = cs.z; b = float3(color_burn(param_10, param_11), color_burn(param_12, param_13), color_burn(param_14, param_15)); break; } case 8u: { float3 param_16 = cb; float3 param_17 = cs; b = hard_light(param_16, param_17); break; } case 9u: { float3 param_18 = cb; float3 param_19 = cs; b = soft_light(param_18, param_19); break; } case 10u: { b = abs(cb - cs); break; } case 11u: { b = (cb + cs) - ((cb * 2.0) * cs); break; } case 12u: { float3 param_20 = cb; float3 param_21 = cs; float param_22 = sat(param_20); float3 _1192 = set_sat(param_21, param_22); float3 param_23 = cb; float3 param_24 = _1192; float param_25 = lum(param_23); b = set_lum(param_24, param_25); break; } case 13u: { float3 param_26 = cs; float3 param_27 = cb; float param_28 = sat(param_26); float3 _1206 = set_sat(param_27, param_28); float3 param_29 = cb; float3 param_30 = _1206; float param_31 = lum(param_29); b = set_lum(param_30, param_31); break; } case 14u: { float3 param_32 = cb; float3 param_33 = cs; float param_34 = lum(param_32); b = set_lum(param_33, param_34); break; } case 15u: { float3 param_35 = cs; float3 param_36 = cb; float param_37 = lum(param_35); b = set_lum(param_36, param_37); break; } default: { b = cs; break; } } return b; } static inline __attribute__((always_inline)) float4 mix_compose(thread const float3& cb, thread const float3& cs, thread const float& ab, thread const float& as, thread const uint& mode) { float fa = 0.0; float fb = 0.0; switch (mode) { case 1u: { fa = 1.0; fb = 0.0; break; } case 2u: { fa = 0.0; fb = 1.0; break; } case 3u: { fa = 1.0; fb = 1.0 - as; break; } case 4u: { fa = 1.0 - ab; fb = 1.0; break; } case 5u: { fa = ab; fb = 0.0; break; } case 6u: { fa = 0.0; fb = as; break; } case 7u: { fa = 1.0 - ab; fb = 0.0; break; } case 8u: { fa = 0.0; fb = 1.0 - as; break; } case 9u: { fa = ab; fb = 1.0 - as; break; } case 10u: { fa = 1.0 - ab; fb = as; break; } case 11u: { fa = 1.0 - ab; fb = 1.0 - as; break; } case 12u: { fa = 1.0; fb = 1.0; break; } case 13u: { return float4(fast::max(float4(0.0), ((float4(1.0) - (float4(cs, as) * as)) + float4(1.0)) - (float4(cb, ab) * ab)).xyz, fast::max(0.0, ((1.0 - as) + 1.0) - ab)); } case 14u: { return float4(fast::min(float4(1.0), (float4(cs, as) * as) + (float4(cb, ab) * ab)).xyz, fast::min(1.0, as + ab)); } default: { break; } } return (float4(cs, as) * (as * fa)) + (float4(cb, ab) * (ab * fb)); } static inline __attribute__((always_inline)) CmdJump CmdJump_read(thread const Alloc& a, thread const CmdJumpRef& ref, device Memory& v_278) { uint ix = ref.offset >> uint(2); Alloc param = a; uint param_1 = ix + 0u; uint raw0 = read_mem(param, param_1, v_278); CmdJump s; s.new_ref = raw0; return s; } static inline __attribute__((always_inline)) CmdJump Cmd_Jump_read(thread const Alloc& a, thread const CmdRef& ref, device Memory& v_278) { Alloc param = a; CmdJumpRef param_1 = CmdJumpRef{ ref.offset + 4u }; return CmdJump_read(param, param_1, v_278); } kernel void main0(device Memory& v_278 [[buffer(0)]], const device ConfigBuf& _1521 [[buffer(1)]], texture2d image [[texture(2)]], texture2d image_atlas [[texture(3)]], texture2d gradients [[texture(4)]], uint3 gl_WorkGroupID [[threadgroup_position_in_grid]], uint3 gl_LocalInvocationID [[thread_position_in_threadgroup]]) { uint tile_ix = (gl_WorkGroupID.y * _1521.conf.width_in_tiles) + gl_WorkGroupID.x; Alloc param; param.offset = _1521.conf.ptcl_alloc.offset; uint param_1 = tile_ix * 1024u; uint param_2 = 1024u; Alloc cmd_alloc = slice_mem(param, param_1, param_2); CmdRef cmd_ref = CmdRef{ cmd_alloc.offset }; uint2 xy_uint = uint2(gl_LocalInvocationID.x + (16u * gl_WorkGroupID.x), gl_LocalInvocationID.y + (16u * gl_WorkGroupID.y)); float2 xy = float2(xy_uint); spvUnsafeArray rgba; for (uint i = 0u; i < 8u; i++) { rgba[i] = float4(0.0); } uint clip_depth = 0u; bool mem_ok = v_278.mem_error == 0u; spvUnsafeArray df; TileSegRef tile_seg_ref; spvUnsafeArray area; spvUnsafeArray, 128> blend_stack; while (mem_ok) { Alloc param_3 = cmd_alloc; CmdRef param_4 = cmd_ref; uint tag = Cmd_tag(param_3, param_4, v_278).tag; if (tag == 0u) { break; } switch (tag) { case 2u: { Alloc param_5 = cmd_alloc; CmdRef param_6 = cmd_ref; CmdStroke stroke = Cmd_Stroke_read(param_5, param_6, v_278); for (uint k = 0u; k < 8u; k++) { df[k] = 1000000000.0; } tile_seg_ref = TileSegRef{ stroke.tile_ref }; do { uint param_7 = tile_seg_ref.offset; uint param_8 = 24u; bool param_9 = mem_ok; Alloc param_10 = new_alloc(param_7, param_8, param_9); TileSegRef param_11 = tile_seg_ref; TileSeg seg = TileSeg_read(param_10, param_11, v_278); float2 line_vec = seg.vector; for (uint k_1 = 0u; k_1 < 8u; k_1++) { float2 dpos = (xy + float2(0.5)) - seg.origin; uint param_12 = k_1; dpos += float2(chunk_offset(param_12)); float t = fast::clamp(dot(line_vec, dpos) / dot(line_vec, line_vec), 0.0, 1.0); df[k_1] = fast::min(df[k_1], length((line_vec * t) - dpos)); } tile_seg_ref = seg.next; } while (tile_seg_ref.offset != 0u); for (uint k_2 = 0u; k_2 < 8u; k_2++) { area[k_2] = fast::clamp((stroke.half_width + 0.5) - df[k_2], 0.0, 1.0); } cmd_ref.offset += 12u; break; } case 1u: { Alloc param_13 = cmd_alloc; CmdRef param_14 = cmd_ref; CmdFill fill = Cmd_Fill_read(param_13, param_14, v_278); for (uint k_3 = 0u; k_3 < 8u; k_3++) { area[k_3] = float(fill.backdrop); } tile_seg_ref = TileSegRef{ fill.tile_ref }; do { uint param_15 = tile_seg_ref.offset; uint param_16 = 24u; bool param_17 = mem_ok; Alloc param_18 = new_alloc(param_15, param_16, param_17); TileSegRef param_19 = tile_seg_ref; TileSeg seg_1 = TileSeg_read(param_18, param_19, v_278); for (uint k_4 = 0u; k_4 < 8u; k_4++) { uint param_20 = k_4; float2 my_xy = xy + float2(chunk_offset(param_20)); float2 start = seg_1.origin - my_xy; float2 end = start + seg_1.vector; float2 window = fast::clamp(float2(start.y, end.y), float2(0.0), float2(1.0)); if ((isunordered(window.x, window.y) || window.x != window.y)) { float2 t_1 = (window - float2(start.y)) / float2(seg_1.vector.y); float2 xs = float2(mix(start.x, end.x, t_1.x), mix(start.x, end.x, t_1.y)); float xmin = fast::min(fast::min(xs.x, xs.y), 1.0) - 9.9999999747524270787835121154785e-07; float xmax = fast::max(xs.x, xs.y); float b = fast::min(xmax, 1.0); float c = fast::max(b, 0.0); float d = fast::max(xmin, 0.0); float a = ((b + (0.5 * ((d * d) - (c * c)))) - xmin) / (xmax - xmin); area[k_4] += (a * (window.x - window.y)); } area[k_4] += (sign(seg_1.vector.x) * fast::clamp((my_xy.y - seg_1.y_edge) + 1.0, 0.0, 1.0)); } tile_seg_ref = seg_1.next; } while (tile_seg_ref.offset != 0u); for (uint k_5 = 0u; k_5 < 8u; k_5++) { area[k_5] = fast::min(abs(area[k_5]), 1.0); } cmd_ref.offset += 12u; break; } case 3u: { for (uint k_6 = 0u; k_6 < 8u; k_6++) { area[k_6] = 1.0; } cmd_ref.offset += 4u; break; } case 4u: { Alloc param_21 = cmd_alloc; CmdRef param_22 = cmd_ref; CmdAlpha alpha = Cmd_Alpha_read(param_21, param_22, v_278); for (uint k_7 = 0u; k_7 < 8u; k_7++) { area[k_7] = alpha.alpha; } cmd_ref.offset += 8u; break; } case 5u: { Alloc param_23 = cmd_alloc; CmdRef param_24 = cmd_ref; CmdColor color = Cmd_Color_read(param_23, param_24, v_278); uint param_25 = color.rgba_color; float4 fg = unpacksRGB(param_25); for (uint k_8 = 0u; k_8 < 8u; k_8++) { float4 fg_k = fg * area[k_8]; rgba[k_8] = (rgba[k_8] * (1.0 - fg_k.w)) + fg_k; } cmd_ref.offset += 8u; break; } case 6u: { Alloc param_26 = cmd_alloc; CmdRef param_27 = cmd_ref; CmdLinGrad lin = Cmd_LinGrad_read(param_26, param_27, v_278); float d_1 = ((lin.line_x * xy.x) + (lin.line_y * xy.y)) + lin.line_c; for (uint k_9 = 0u; k_9 < 8u; k_9++) { uint param_28 = k_9; float2 chunk_xy = float2(chunk_offset(param_28)); float my_d = (d_1 + (lin.line_x * chunk_xy.x)) + (lin.line_y * chunk_xy.y); int x = int(round(fast::clamp(my_d, 0.0, 1.0) * 511.0)); float4 fg_rgba = gradients.read(uint2(int2(x, int(lin.index)))); float3 param_29 = fg_rgba.xyz; float3 _2092 = fromsRGB(param_29); fg_rgba.x = _2092.x; fg_rgba.y = _2092.y; fg_rgba.z = _2092.z; rgba[k_9] = fg_rgba; } cmd_ref.offset += 20u; break; } case 7u: { Alloc param_30 = cmd_alloc; CmdRef param_31 = cmd_ref; CmdImage fill_img = Cmd_Image_read(param_30, param_31, v_278); uint2 param_32 = xy_uint; CmdImage param_33 = fill_img; spvUnsafeArray img; img = fillImage(param_32, param_33, image_atlas); for (uint k_10 = 0u; k_10 < 8u; k_10++) { float4 fg_k_1 = img[k_10] * area[k_10]; rgba[k_10] = (rgba[k_10] * (1.0 - fg_k_1.w)) + fg_k_1; } cmd_ref.offset += 12u; break; } case 8u: { for (uint k_11 = 0u; k_11 < 8u; k_11++) { uint d_2 = min(clip_depth, 127u); float4 param_34 = float4(rgba[k_11]); uint _2184 = packsRGB(param_34); blend_stack[d_2][k_11] = _2184; rgba[k_11] = float4(0.0); } clip_depth++; cmd_ref.offset += 4u; break; } case 9u: { Alloc param_35 = cmd_alloc; CmdRef param_36 = cmd_ref; CmdEndClip end_clip = Cmd_EndClip_read(param_35, param_36, v_278); uint blend_mode = end_clip.blend >> uint(8); uint comp_mode = end_clip.blend & 255u; clip_depth--; for (uint k_12 = 0u; k_12 < 8u; k_12++) { uint d_3 = min(clip_depth, 127u); uint param_37 = blend_stack[d_3][k_12]; float4 bg = unpacksRGB(param_37); float4 fg_1 = rgba[k_12] * area[k_12]; float3 param_38 = bg.xyz; float3 param_39 = fg_1.xyz; uint param_40 = blend_mode; float3 blend = mix_blend(param_38, param_39, param_40); float4 _2251 = fg_1; float _2255 = fg_1.w; float3 _2262 = mix(_2251.xyz, blend, float3(float((_2255 * bg.w) > 0.0))); fg_1.x = _2262.x; fg_1.y = _2262.y; fg_1.z = _2262.z; float3 param_41 = bg.xyz; float3 param_42 = fg_1.xyz; float param_43 = bg.w; float param_44 = fg_1.w; uint param_45 = comp_mode; rgba[k_12] = mix_compose(param_41, param_42, param_43, param_44, param_45); } cmd_ref.offset += 8u; break; } case 10u: { Alloc param_46 = cmd_alloc; CmdRef param_47 = cmd_ref; cmd_ref = CmdRef{ Cmd_Jump_read(param_46, param_47, v_278).new_ref }; cmd_alloc.offset = cmd_ref.offset; break; } } } for (uint i_1 = 0u; i_1 < 8u; i_1++) { uint param_48 = i_1; image.write(float4(rgba[i_1].w), uint2(int2(xy_uint + chunk_offset(param_48)))); } }