// Copyright 2022 The Ebitengine Authors // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package builtinshader import ( "bytes" "fmt" "sync" "text/template" ) type Filter int const ( FilterNearest Filter = iota FilterLinear ) const FilterCount = 2 type Address int const ( AddressUnsafe Address = iota AddressClampToZero AddressRepeat ) const AddressCount = 3 const ( UniformColorMBody = "ColorMBody" UniformColorMTranslation = "ColorMTranslation" ) var ( shaders [FilterCount][AddressCount][2][]byte shadersM sync.Mutex ) var tmpl = template.Must(template.New("tmpl").Parse(`//kage:unit pixels package main {{if .UseColorM}} var ColorMBody mat4 var ColorMTranslation vec4 {{end}} {{if eq .Address .AddressRepeat}} func adjustTexelForAddressRepeat(p vec2) vec2 { origin := imageSrc0Origin() size := imageSrc0Size() return mod(p - origin, size) + origin } {{end}} func Fragment(position vec4, texCoord vec2, color vec4) vec4 { {{if eq .Filter .FilterNearest}} {{if eq .Address .AddressUnsafe}} clr := imageSrc0UnsafeAt(texCoord) {{else if eq .Address .AddressClampToZero}} clr := imageSrc0At(texCoord) {{else if eq .Address .AddressRepeat}} clr := imageSrc0At(adjustTexelForAddressRepeat(texCoord)) {{end}} {{else if eq .Filter .FilterLinear}} p0 := texCoord - 1/2.0 p1 := texCoord + 1/2.0 {{if eq .Address .AddressRepeat}} p0 = adjustTexelForAddressRepeat(p0) p1 = adjustTexelForAddressRepeat(p1) {{end}} {{if eq .Address .AddressUnsafe}} c0 := imageSrc0UnsafeAt(p0) c1 := imageSrc0UnsafeAt(vec2(p1.x, p0.y)) c2 := imageSrc0UnsafeAt(vec2(p0.x, p1.y)) c3 := imageSrc0UnsafeAt(p1) {{else}} c0 := imageSrc0At(p0) c1 := imageSrc0At(vec2(p1.x, p0.y)) c2 := imageSrc0At(vec2(p0.x, p1.y)) c3 := imageSrc0At(p1) {{end}} rate := fract(p1) clr := mix(mix(c0, c1, rate.x), mix(c2, c3, rate.x), rate.y) {{end}} {{if .UseColorM}} // Un-premultiply alpha. // When the alpha is 0, 1-sign(alpha) is 1.0, which means division does nothing. clr.rgb /= clr.a + (1-sign(clr.a)) // Apply the clr matrix. clr = (ColorMBody * clr) + ColorMTranslation // Premultiply alpha clr.rgb *= clr.a // Apply the color scale. clr *= color // Clamp the output. clr.rgb = min(clr.rgb, clr.a) {{else}} // Apply the color scale. clr *= color {{end}} return clr } `)) // Shader returns the built-in shader based on the given parameters. // // The returned shader always uses a color matrix so far. func Shader(filter Filter, address Address, useColorM bool) []byte { shadersM.Lock() defer shadersM.Unlock() var c int if useColorM { c = 1 } if s := shaders[filter][address][c]; s != nil { return s } var buf bytes.Buffer if err := tmpl.Execute(&buf, struct { Filter Filter FilterNearest Filter FilterLinear Filter Address Address AddressUnsafe Address AddressClampToZero Address AddressRepeat Address UseColorM bool }{ Filter: filter, FilterNearest: FilterNearest, FilterLinear: FilterLinear, Address: address, AddressUnsafe: AddressUnsafe, AddressClampToZero: AddressClampToZero, AddressRepeat: AddressRepeat, UseColorM: useColorM, }); err != nil { panic(fmt.Sprintf("builtinshader: tmpl.Execute failed: %v", err)) } b := buf.Bytes() shaders[filter][address][c] = b return b }