// Copyright 2020 The Ebiten 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 shader import ( "fmt" "go/ast" gconstant "go/constant" "go/token" "regexp" "strconv" "github.com/hajimehoshi/ebiten/v2/internal/shaderir" ) func canTruncateToInteger(v gconstant.Value) bool { return gconstant.ToInt(v).Kind() != gconstant.Unknown } func canTruncateToFloat(v gconstant.Value) bool { return gconstant.ToFloat(v).Kind() != gconstant.Unknown } func isUntypedInteger(expr *shaderir.Expr) bool { return expr.Const.Kind() == gconstant.Int && expr.ConstType == shaderir.ConstTypeNone } func isModAvailableForConsts(lhs, rhs *shaderir.Expr) bool { // % is available only when // 1) both are untyped integers // 2) either is an typed integer and the other is truncatable to an integer if isUntypedInteger(lhs) && isUntypedInteger(rhs) { return true } if lhs.ConstType == shaderir.ConstTypeInt && canTruncateToInteger(rhs.Const) { return true } if rhs.ConstType == shaderir.ConstTypeInt && canTruncateToInteger(lhs.Const) { return true } return false } func canApplyBinaryOp(lhs, rhs *shaderir.Expr, lhst, rhst shaderir.Type, op shaderir.Op) bool { if op == shaderir.AndAnd || op == shaderir.OrOr { return lhst.Main == shaderir.Bool && rhst.Main == shaderir.Bool } switch { case lhs.Const != nil && rhs.Const != nil: switch { case lhs.ConstType == shaderir.ConstTypeNone && rhs.ConstType == shaderir.ConstTypeNone: if canTruncateToFloat(lhs.Const) && canTruncateToFloat(rhs.Const) { return true } if canTruncateToInteger(lhs.Const) && canTruncateToInteger(rhs.Const) { return true } return lhs.Const.Kind() == rhs.Const.Kind() case lhs.ConstType == shaderir.ConstTypeNone: switch rhs.ConstType { case shaderir.ConstTypeFloat: return canTruncateToFloat(lhs.Const) case shaderir.ConstTypeInt: return canTruncateToInteger(lhs.Const) } case rhs.ConstType == shaderir.ConstTypeNone: switch lhs.ConstType { case shaderir.ConstTypeInt: return canTruncateToInteger(rhs.Const) case shaderir.ConstTypeFloat: return canTruncateToFloat(rhs.Const) } } return lhs.ConstType == rhs.ConstType case lhs.Const != nil: switch lhs.ConstType { case shaderir.ConstTypeNone: if rhst.Main == shaderir.Float { return canTruncateToFloat(lhs.Const) } if rhst.Main == shaderir.Int { return canTruncateToInteger(lhs.Const) } case shaderir.ConstTypeFloat: return rhst.Main == shaderir.Float case shaderir.ConstTypeInt: return rhst.Main == shaderir.Int case shaderir.ConstTypeBool: return rhst.Main == shaderir.Bool } case rhs.Const != nil: switch rhs.ConstType { case shaderir.ConstTypeNone: if lhst.Main == shaderir.Float { return canTruncateToFloat(rhs.Const) } if lhst.Main == shaderir.Int { return canTruncateToInteger(rhs.Const) } case shaderir.ConstTypeFloat: return lhst.Main == shaderir.Float case shaderir.ConstTypeInt: return lhst.Main == shaderir.Int case shaderir.ConstTypeBool: return lhst.Main == shaderir.Bool } } // Comparing matrices are forbidden (#2187). if lhst.IsMatrix() || rhst.IsMatrix() { return false } return lhst.Equal(&rhst) } func goConstantKindString(k gconstant.Kind) string { switch k { case gconstant.Bool: return "bool" case gconstant.String: return "string" case gconstant.Int: return "int" case gconstant.Float: return "float" case gconstant.Complex: return "complex" } return "unknown" } var textureVariableRe = regexp.MustCompile(`\A__t(\d+)\z`) func (cs *compileState) parseExpr(block *block, fname string, expr ast.Expr, markLocalVariableUsed bool) ([]shaderir.Expr, []shaderir.Type, []shaderir.Stmt, bool) { switch e := expr.(type) { case *ast.BasicLit: switch e.Kind { case token.INT: return []shaderir.Expr{ { Type: shaderir.NumberExpr, Const: gconstant.MakeFromLiteral(e.Value, e.Kind, 0), }, }, []shaderir.Type{{Main: shaderir.Int}}, nil, true case token.FLOAT: return []shaderir.Expr{ { Type: shaderir.NumberExpr, Const: gconstant.MakeFromLiteral(e.Value, e.Kind, 0), }, }, []shaderir.Type{{Main: shaderir.Float}}, nil, true default: cs.addError(e.Pos(), fmt.Sprintf("literal not implemented: %#v", e)) } case *ast.BinaryExpr: var stmts []shaderir.Stmt // Prase LHS first for the order of the statements. lhs, ts, ss, ok := cs.parseExpr(block, fname, e.X, markLocalVariableUsed) if !ok { return nil, nil, nil, false } if len(lhs) != 1 { cs.addError(e.Pos(), fmt.Sprintf("multiple-value context is not available at a binary operator: %s", e.X)) return nil, nil, nil, false } stmts = append(stmts, ss...) lhst := ts[0] rhs, ts, ss, ok := cs.parseExpr(block, fname, e.Y, markLocalVariableUsed) if !ok { return nil, nil, nil, false } if len(rhs) != 1 { cs.addError(e.Pos(), fmt.Sprintf("multiple-value context is not available at a binary operator: %s", e.Y)) return nil, nil, nil, false } stmts = append(stmts, ss...) rhst := ts[0] if lhs[0].Const != nil && rhs[0].Const != nil { op := e.Op // https://golang.org/pkg/go/constant/#BinaryOp // "To force integer division of Int operands, use op == token.QUO_ASSIGN instead of // token.QUO; the result is guaranteed to be Int in this case." if op == token.QUO && lhs[0].Const.Kind() == gconstant.Int && rhs[0].Const.Kind() == gconstant.Int { op = token.QUO_ASSIGN } var v gconstant.Value var t shaderir.Type switch op { case token.EQL, token.NEQ, token.LSS, token.LEQ, token.GTR, token.GEQ, token.LAND, token.LOR: op2, ok := shaderir.OpFromToken(op, lhst, rhst) if !ok { cs.addError(e.Pos(), fmt.Sprintf("unexpected operator: %s", op)) return nil, nil, nil, false } if !canApplyBinaryOp(&lhs[0], &rhs[0], lhst, rhst, op2) { cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), op, rhst.String())) return nil, nil, nil, false } switch op { case token.LAND, token.LOR: b := gconstant.BoolVal(gconstant.BinaryOp(lhs[0].Const, op, rhs[0].Const)) v = gconstant.MakeBool(b) default: v = gconstant.MakeBool(gconstant.Compare(lhs[0].Const, op, rhs[0].Const)) } t = shaderir.Type{Main: shaderir.Bool} default: if op == token.REM { if !isModAvailableForConsts(&lhs[0], &rhs[0]) { var wrongTypeName string if lhs[0].Const.Kind() != gconstant.Int { wrongTypeName = goConstantKindString(lhs[0].Const.Kind()) } else { wrongTypeName = goConstantKindString(rhs[0].Const.Kind()) } cs.addError(e.Pos(), fmt.Sprintf("invalid operation: operator %% not defined on untyped %s", wrongTypeName)) return nil, nil, nil, false } if !cs.forceToInt(e, &lhs[0]) { return nil, nil, nil, false } if !cs.forceToInt(e, &rhs[0]) { return nil, nil, nil, false } } v = gconstant.BinaryOp(lhs[0].Const, op, rhs[0].Const) if v.Kind() == gconstant.Float { t = shaderir.Type{Main: shaderir.Float} } else { t = shaderir.Type{Main: shaderir.Int} } } return []shaderir.Expr{ { Type: shaderir.NumberExpr, Const: v, }, }, []shaderir.Type{t}, stmts, true } op, ok := shaderir.OpFromToken(e.Op, lhst, rhst) if !ok { cs.addError(e.Pos(), fmt.Sprintf("unexpected operator: %s", e.Op)) return nil, nil, nil, false } var t shaderir.Type switch { case op == shaderir.LessThanOp || op == shaderir.LessThanEqualOp || op == shaderir.GreaterThanOp || op == shaderir.GreaterThanEqualOp || op == shaderir.EqualOp || op == shaderir.NotEqualOp || op == shaderir.VectorEqualOp || op == shaderir.VectorNotEqualOp || op == shaderir.AndAnd || op == shaderir.OrOr: if !canApplyBinaryOp(&lhs[0], &rhs[0], lhst, rhst, op) { cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Bool} case lhs[0].Const != nil && rhs[0].Const == nil: switch rhst.Main { case shaderir.Mat2, shaderir.Mat3, shaderir.Mat4: if op != shaderir.MatrixMul { cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } fallthrough case shaderir.Vec2, shaderir.Vec3, shaderir.Vec4: if lhs[0].ConstType == shaderir.ConstTypeInt { cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } case shaderir.Int: if !canTruncateToInteger(lhs[0].Const) { cs.addError(e.Pos(), fmt.Sprintf("constant %s truncated to integer", lhs[0].Const.String())) return nil, nil, nil, false } lhs[0].ConstType = shaderir.ConstTypeInt } t = rhst case lhs[0].Const == nil && rhs[0].Const != nil: switch lhst.Main { case shaderir.Mat2, shaderir.Mat3, shaderir.Mat4: if op != shaderir.MatrixMul && op != shaderir.Div { cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } fallthrough case shaderir.Vec2, shaderir.Vec3, shaderir.Vec4: if rhs[0].ConstType == shaderir.ConstTypeInt { cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } case shaderir.Int: if !canTruncateToInteger(rhs[0].Const) { cs.addError(e.Pos(), fmt.Sprintf("constant %s truncated to integer", rhs[0].Const.String())) return nil, nil, nil, false } rhs[0].ConstType = shaderir.ConstTypeInt } t = lhst case lhst.Equal(&rhst): if op == shaderir.Div && (rhst.Main == shaderir.Mat2 || rhst.Main == shaderir.Mat3 || rhst.Main == shaderir.Mat4) { cs.addError(e.Pos(), fmt.Sprintf("invalid operation: operator %s not defined on %s", e.Op, rhst.String())) return nil, nil, nil, false } t = lhst case lhst.Main == shaderir.Float: switch rhst.Main { case shaderir.Float, shaderir.Vec2, shaderir.Vec3, shaderir.Vec4: t = rhst case shaderir.Mat2, shaderir.Mat3, shaderir.Mat4: if op != shaderir.MatrixMul { cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } t = rhst default: cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } case rhst.Main == shaderir.Float: switch lhst.Main { case shaderir.Float, shaderir.Vec2, shaderir.Vec3, shaderir.Vec4: t = lhst case shaderir.Mat2, shaderir.Mat3, shaderir.Mat4: if op != shaderir.MatrixMul && op != shaderir.Div { cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } t = lhst default: cs.addError(e.Pos(), fmt.Sprintf("types don't match: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } case op == shaderir.MatrixMul && (lhst.Main == shaderir.Vec2 && rhst.Main == shaderir.Mat2 || lhst.Main == shaderir.Mat2 && rhst.Main == shaderir.Vec2): t = shaderir.Type{Main: shaderir.Vec2} case op == shaderir.MatrixMul && (lhst.Main == shaderir.Vec3 && rhst.Main == shaderir.Mat3 || lhst.Main == shaderir.Mat3 && rhst.Main == shaderir.Vec3): t = shaderir.Type{Main: shaderir.Vec3} case op == shaderir.MatrixMul && (lhst.Main == shaderir.Vec4 && rhst.Main == shaderir.Mat4 || lhst.Main == shaderir.Mat4 && rhst.Main == shaderir.Vec4): t = shaderir.Type{Main: shaderir.Vec4} default: cs.addError(e.Pos(), fmt.Sprintf("invalid expression: %s %s %s", lhst.String(), e.Op, rhst.String())) return nil, nil, nil, false } // For `%`, both types must be deducible to integers. if op == shaderir.ModOp { // TODO: What about ivec? if lhst.Main != shaderir.Int && (lhs[0].ConstType == shaderir.ConstTypeNone || !canTruncateToInteger(lhs[0].Const)) || rhst.Main != shaderir.Int && (rhs[0].ConstType == shaderir.ConstTypeNone || !canTruncateToInteger(rhs[0].Const)) { var wrongType shaderir.Type if lhst.Main != shaderir.Int { wrongType = lhst } else { wrongType = rhst } cs.addError(e.Pos(), fmt.Sprintf("invalid operation: operator %% not defined on %s", wrongType.String())) return nil, nil, nil, false } } return []shaderir.Expr{ { Type: shaderir.Binary, Op: op, Exprs: []shaderir.Expr{lhs[0], rhs[0]}, }, }, []shaderir.Type{t}, stmts, true case *ast.CallExpr: var ( callee shaderir.Expr args []shaderir.Expr argts []shaderir.Type stmts []shaderir.Stmt ) // Parse the argument first for the order of the statements. for _, a := range e.Args { es, ts, ss, ok := cs.parseExpr(block, fname, a, markLocalVariableUsed) if !ok { return nil, nil, nil, false } if len(es) > 1 && len(e.Args) > 1 { cs.addError(e.Pos(), fmt.Sprintf("single-value context and multiple-value context cannot be mixed: %s", e.Fun)) return nil, nil, nil, false } args = append(args, es...) argts = append(argts, ts...) stmts = append(stmts, ss...) } // TODO: When len(ss) is not 0? es, _, ss, ok := cs.parseExpr(block, fname, e.Fun, markLocalVariableUsed) if !ok { return nil, nil, nil, false } if len(es) != 1 { cs.addError(e.Pos(), fmt.Sprintf("multiple-value context is not available at a callee: %s", e.Fun)) return nil, nil, nil, false } callee = es[0] stmts = append(stmts, ss...) // For built-in functions, we can call this in this position. Return an expression for the function // call. if callee.Type == shaderir.BuiltinFuncExpr { // Process compile-time evaluations. switch callee.BuiltinFunc { case shaderir.Len, shaderir.Cap: if len(args) != 1 { cs.addError(e.Pos(), fmt.Sprintf("number of %s's arguments must be 1 but %d", callee.BuiltinFunc, len(args))) return nil, nil, nil, false } if argts[0].Main != shaderir.Array { cs.addError(e.Pos(), fmt.Sprintf("%s takes an array but %s", callee.BuiltinFunc, argts[0].String())) return nil, nil, nil, false } return []shaderir.Expr{ { Type: shaderir.NumberExpr, Const: gconstant.MakeInt64(int64(argts[0].Length)), ConstType: shaderir.ConstTypeInt, }, }, []shaderir.Type{{Main: shaderir.Int}}, stmts, true case shaderir.IntF: if len(args) == 1 && args[0].Const != nil { if !canTruncateToInteger(args[0].Const) { cs.addError(e.Pos(), fmt.Sprintf("cannot convert %s to type int", args[0].Const.String())) return nil, nil, nil, false } return []shaderir.Expr{ { Type: shaderir.NumberExpr, Const: gconstant.ToInt(args[0].Const), ConstType: shaderir.ConstTypeInt, }, }, []shaderir.Type{{Main: shaderir.Int}}, stmts, true } case shaderir.FloatF: if len(args) == 1 && args[0].Const != nil { if gconstant.ToFloat(args[0].Const).Kind() != gconstant.Unknown { return []shaderir.Expr{ { Type: shaderir.NumberExpr, Const: gconstant.ToFloat(args[0].Const), ConstType: shaderir.ConstTypeFloat, }, }, []shaderir.Type{{Main: shaderir.Float}}, stmts, true } } } // Process the expression as a regular function call. var t shaderir.Type switch callee.BuiltinFunc { case shaderir.BoolF: if err := checkArgsForBoolBuiltinFunc(args, argts); err != nil { cs.addError(e.Pos(), err.Error()) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Bool} case shaderir.IntF: if err := checkArgsForIntBuiltinFunc(args, argts); err != nil { cs.addError(e.Pos(), err.Error()) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Int} case shaderir.FloatF: if err := checkArgsForFloatBuiltinFunc(args, argts); err != nil { cs.addError(e.Pos(), err.Error()) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Float} case shaderir.Vec2F: if err := checkArgsForVec2BuiltinFunc(args, argts); err != nil { cs.addError(e.Pos(), err.Error()) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Vec2} case shaderir.Vec3F: if err := checkArgsForVec3BuiltinFunc(args, argts); err != nil { cs.addError(e.Pos(), err.Error()) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Vec3} case shaderir.Vec4F: if err := checkArgsForVec4BuiltinFunc(args, argts); err != nil { cs.addError(e.Pos(), err.Error()) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Vec4} case shaderir.Mat2F: if err := checkArgsForMat2BuiltinFunc(args, argts); err != nil { cs.addError(e.Pos(), err.Error()) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Mat2} case shaderir.Mat3F: if err := checkArgsForMat3BuiltinFunc(args, argts); err != nil { cs.addError(e.Pos(), err.Error()) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Mat3} case shaderir.Mat4F: if err := checkArgsForMat4BuiltinFunc(args, argts); err != nil { cs.addError(e.Pos(), err.Error()) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Mat4} case shaderir.Texture2DF: if len(args) != 2 { cs.addError(e.Pos(), fmt.Sprintf("number of %s's arguments must be 2 but %d", callee.BuiltinFunc, len(args))) return nil, nil, nil, false } if argts[0].Main != shaderir.Texture { cs.addError(e.Pos(), fmt.Sprintf("cannot use %s as texture value in argument to %s", argts[0].String(), callee.BuiltinFunc)) return nil, nil, nil, false } if argts[1].Main != shaderir.Vec2 { cs.addError(e.Pos(), fmt.Sprintf("cannot use %s as vec2 value in argument to %s", argts[1].String(), callee.BuiltinFunc)) return nil, nil, nil, false } t = shaderir.Type{Main: shaderir.Vec4} case shaderir.DiscardF: if len(args) != 0 { cs.addError(e.Pos(), fmt.Sprintf("number of %s's arguments must be 0 but %d", callee.BuiltinFunc, len(args))) return nil, nil, nil, false } if fname != cs.fragmentEntry { cs.addError(e.Pos(), fmt.Sprintf("discard is available only in %s", cs.fragmentEntry)) return nil, nil, nil, false } stmts = append(stmts, shaderir.Stmt{ Type: shaderir.Discard, }) return nil, nil, stmts, true case shaderir.Clamp, shaderir.Mix, shaderir.Smoothstep, shaderir.Faceforward, shaderir.Refract: // 3 arguments if len(args) != 3 { cs.addError(e.Pos(), fmt.Sprintf("number of %s's arguments must be 3 but %d", callee.BuiltinFunc, len(args))) return nil, nil, nil, false } for i := range args { // If the argument is a non-typed constant value, treat this as a float value (#1874). if args[i].Const != nil && args[i].ConstType == shaderir.ConstTypeNone && gconstant.ToFloat(args[i].Const).Kind() != gconstant.Unknown { args[i].Const = gconstant.ToFloat(args[i].Const) args[i].ConstType = shaderir.ConstTypeFloat argts[i] = shaderir.Type{Main: shaderir.Float} } if argts[i].Main != shaderir.Float && argts[i].Main != shaderir.Vec2 && argts[i].Main != shaderir.Vec3 && argts[i].Main != shaderir.Vec4 { cs.addError(e.Pos(), fmt.Sprintf("cannot use %s as float, vec2, vec3, or vec4 value in argument to %s", argts[i].String(), callee.BuiltinFunc)) return nil, nil, nil, false } } switch callee.BuiltinFunc { case shaderir.Clamp: if (!argts[0].Equal(&argts[1]) || !argts[0].Equal(&argts[2])) && (argts[1].Main != shaderir.Float || argts[2].Main != shaderir.Float) { cs.addError(e.Pos(), fmt.Sprintf("the second and the third arguments for %s must equal to the first argument %s or float but %s and %s", callee.BuiltinFunc, argts[0].String(), argts[1].String(), argts[2].String())) return nil, nil, nil, false } case shaderir.Mix: if !argts[0].Equal(&argts[1]) { cs.addError(e.Pos(), fmt.Sprintf("%s and %s don't match in argument to %s", argts[0].String(), argts[1].String(), callee.BuiltinFunc)) return nil, nil, nil, false } if !argts[0].Equal(&argts[2]) && argts[2].Main != shaderir.Float { cs.addError(e.Pos(), fmt.Sprintf("the third arguments for %s must equal to the first/second argument %s or float but %s", callee.BuiltinFunc, argts[0].String(), argts[2].String())) return nil, nil, nil, false } case shaderir.Smoothstep: if (!argts[0].Equal(&argts[1]) || !argts[0].Equal(&argts[2])) && (argts[0].Main != shaderir.Float || argts[1].Main != shaderir.Float) { cs.addError(e.Pos(), fmt.Sprintf("the first and the second arguments for %s must equal to the third argument %s or float but %s and %s", callee.BuiltinFunc, argts[2].String(), argts[0].String(), argts[1].String())) return nil, nil, nil, false } case shaderir.Refract: if !argts[0].Equal(&argts[1]) { cs.addError(e.Pos(), fmt.Sprintf("%s and %s don't match in argument to %s", argts[0].String(), argts[1].String(), callee.BuiltinFunc)) return nil, nil, nil, false } if argts[2].Main != shaderir.Float { cs.addError(e.Pos(), fmt.Sprintf("cannot use %s as float value in argument to %s", argts[2].String(), callee.BuiltinFunc)) return nil, nil, nil, false } default: if !argts[0].Equal(&argts[1]) || !argts[0].Equal(&argts[2]) { cs.addError(e.Pos(), fmt.Sprintf("all the argument types for %s must be the same but %s, %s, and %s", callee.BuiltinFunc, argts[0].String(), argts[1].String(), argts[2].String())) return nil, nil, nil, false } } switch callee.BuiltinFunc { case shaderir.Smoothstep: t = argts[2] default: t = argts[0] } case shaderir.Atan2, shaderir.Mod, shaderir.Min, shaderir.Max, shaderir.Step, shaderir.Distance, shaderir.Dot, shaderir.Cross, shaderir.Reflect: // 2 arguments if len(args) != 2 { cs.addError(e.Pos(), fmt.Sprintf("number of %s's arguments must be 2 but %d", callee.BuiltinFunc, len(args))) return nil, nil, nil, false } for i := range args { // If the argument is a non-typed constant value, treat this as a float value (#1874). if args[i].Const != nil && args[i].ConstType == shaderir.ConstTypeNone && gconstant.ToFloat(args[i].Const).Kind() != gconstant.Unknown { args[i].Const = gconstant.ToFloat(args[i].Const) args[i].ConstType = shaderir.ConstTypeFloat argts[i] = shaderir.Type{Main: shaderir.Float} } if argts[i].Main != shaderir.Float && argts[i].Main != shaderir.Vec2 && argts[i].Main != shaderir.Vec3 && argts[i].Main != shaderir.Vec4 { cs.addError(e.Pos(), fmt.Sprintf("cannot use %s as float, vec2, vec3, or vec4 value in argument to %s", argts[i].String(), callee.BuiltinFunc)) return nil, nil, nil, false } } switch callee.BuiltinFunc { case shaderir.Mod, shaderir.Min, shaderir.Max: if !argts[0].Equal(&argts[1]) && argts[1].Main != shaderir.Float { cs.addError(e.Pos(), fmt.Sprintf("the second argument for %s must equal to the first argument %s or float but %s", callee.BuiltinFunc, argts[0].String(), argts[1].String())) return nil, nil, nil, false } case shaderir.Step: if !argts[0].Equal(&argts[1]) && argts[0].Main != shaderir.Float { cs.addError(e.Pos(), fmt.Sprintf("the first argument for %s must equal to the second argument %s or float but %s", callee.BuiltinFunc, argts[1].String(), argts[0].String())) return nil, nil, nil, false } case shaderir.Cross: for i := range argts { if argts[i].Main != shaderir.Vec3 { cs.addError(e.Pos(), fmt.Sprintf("cannot use %s as vec3 value in argument to %s", argts[i].String(), callee.BuiltinFunc)) return nil, nil, nil, false } } default: if !argts[0].Equal(&argts[1]) { cs.addError(e.Pos(), fmt.Sprintf("%s and %s don't match in argument to %s", argts[0].String(), argts[1].String(), callee.BuiltinFunc)) return nil, nil, nil, false } } switch callee.BuiltinFunc { case shaderir.Distance, shaderir.Dot: t = shaderir.Type{Main: shaderir.Float} case shaderir.Step: t = argts[1] default: t = argts[0] } default: // 1 argument if len(args) != 1 { cs.addError(e.Pos(), fmt.Sprintf("number of %s's arguments must be 1 but %d", callee.BuiltinFunc, len(args))) return nil, nil, nil, false } // If the argument is a non-typed constant value, treat this as a float value (#1874). if args[0].Const != nil && args[0].ConstType == shaderir.ConstTypeNone && gconstant.ToFloat(args[0].Const).Kind() != gconstant.Unknown { args[0].Const = gconstant.ToFloat(args[0].Const) args[0].ConstType = shaderir.ConstTypeFloat argts[0] = shaderir.Type{Main: shaderir.Float} } switch callee.BuiltinFunc { case shaderir.Transpose: if argts[0].Main != shaderir.Mat2 && argts[0].Main != shaderir.Mat3 && argts[0].Main != shaderir.Mat4 { cs.addError(e.Pos(), fmt.Sprintf("cannot use %s as mat2, mat3, or mat4 value in argument to %s", argts[0].String(), callee.BuiltinFunc)) return nil, nil, nil, false } default: if argts[0].Main != shaderir.Float && argts[0].Main != shaderir.Vec2 && argts[0].Main != shaderir.Vec3 && argts[0].Main != shaderir.Vec4 { cs.addError(e.Pos(), fmt.Sprintf("cannot use %s as float, vec2, vec3, or vec4 value in argument to %s", argts[0].String(), callee.BuiltinFunc)) return nil, nil, nil, false } } if callee.BuiltinFunc == shaderir.Length { t = shaderir.Type{Main: shaderir.Float} } else { t = argts[0] } } return []shaderir.Expr{ { Type: shaderir.Call, Exprs: append([]shaderir.Expr{callee}, args...), }, }, []shaderir.Type{t}, stmts, true } if callee.Type != shaderir.FunctionExpr { cs.addError(e.Pos(), fmt.Sprintf("function callee must be a function name but %s", e.Fun)) return nil, nil, nil, false } f := cs.funcs[callee.Index] if len(f.ir.InParams) < len(args) { cs.addError(e.Pos(), fmt.Sprintf("too many arguments in call to %s", e.Fun)) return nil, nil, nil, false } if len(f.ir.InParams) > len(args) { cs.addError(e.Pos(), fmt.Sprintf("not enough arguments in call to %s", e.Fun)) return nil, nil, nil, false } for i, p := range f.ir.InParams { if args[i].Const != nil && p.Main == shaderir.Int { if !cs.forceToInt(e, &args[i]) { return nil, nil, nil, false } } if !canAssign(&args[i], &p, &argts[i]) { cs.addError(e.Pos(), fmt.Sprintf("cannot use type %s as type %s in argument", argts[i].String(), p.String())) return nil, nil, nil, false } } var outParams []int for _, p := range f.ir.OutParams { idx := block.totalLocalVariableCount() block.vars = append(block.vars, variable{ typ: p, }) args = append(args, shaderir.Expr{ Type: shaderir.LocalVariable, Index: idx, }) outParams = append(outParams, idx) } if t := f.ir.Return; t.Main != shaderir.None { if len(outParams) != 0 { cs.addError(e.Pos(), fmt.Sprintf("a function returning value cannot have out-params so far: %s", e.Fun)) return nil, nil, nil, false } // The actual expression here is just a local variable that includes the result of the // function call. return []shaderir.Expr{ { Type: shaderir.Call, Exprs: append([]shaderir.Expr{callee}, args...), }, }, []shaderir.Type{t}, stmts, true } // Even if the function doesn't return anything, calling the function should be done eariler to keep // the evaluation order. stmts = append(stmts, shaderir.Stmt{ Type: shaderir.ExprStmt, Exprs: []shaderir.Expr{ { Type: shaderir.Call, Exprs: append([]shaderir.Expr{callee}, args...), }, }, }) if len(outParams) == 0 { // TODO: Is this an error? } // These local-variable expressions are used for an outside function callers. var exprs []shaderir.Expr for _, p := range outParams { exprs = append(exprs, shaderir.Expr{ Type: shaderir.LocalVariable, Index: p, }) } return exprs, f.ir.OutParams, stmts, true case *ast.Ident: if e.Name == "_" { // In the context where a local variable is marked as used, any expressions must have its // meaning. Then, a blank identifier is not available there. if markLocalVariableUsed { cs.addError(e.Pos(), fmt.Sprintf("cannot use _ as value")) return nil, nil, nil, false } return []shaderir.Expr{ { Type: shaderir.Blank, }, }, []shaderir.Type{{}}, nil, true } if i, t, ok := block.findLocalVariable(e.Name, markLocalVariableUsed); ok { return []shaderir.Expr{ { Type: shaderir.LocalVariable, Index: i, }, }, []shaderir.Type{t}, nil, true } if c, ok := block.findConstant(e.Name); ok { return []shaderir.Expr{ { Type: shaderir.NumberExpr, Const: c.value, ConstType: c.ctyp, }, }, []shaderir.Type{c.typ}, nil, true } if i, ok := cs.findFunction(e.Name); ok { return []shaderir.Expr{ { Type: shaderir.FunctionExpr, Index: i, }, }, nil, nil, true } if i, ok := cs.findUniformVariable(e.Name); ok { return []shaderir.Expr{ { Type: shaderir.UniformVariable, Index: i, }, }, []shaderir.Type{cs.ir.Uniforms[i]}, nil, true } if f, ok := shaderir.ParseBuiltinFunc(e.Name); ok { return []shaderir.Expr{ { Type: shaderir.BuiltinFuncExpr, BuiltinFunc: f, }, }, nil, nil, true } if m := textureVariableRe.FindStringSubmatch(e.Name); m != nil { i, _ := strconv.Atoi(m[1]) return []shaderir.Expr{ { Type: shaderir.TextureVariable, Index: i, }, }, []shaderir.Type{{Main: shaderir.Texture}}, nil, true } if e.Name == "true" || e.Name == "false" { return []shaderir.Expr{ { Type: shaderir.NumberExpr, Const: gconstant.MakeBool(e.Name == "true"), }, }, []shaderir.Type{{Main: shaderir.Bool}}, nil, true } cs.addError(e.Pos(), fmt.Sprintf("unexpected identifier: %s", e.Name)) case *ast.ParenExpr: return cs.parseExpr(block, fname, e.X, markLocalVariableUsed) case *ast.SelectorExpr: exprs, _, stmts, ok := cs.parseExpr(block, fname, e.X, true) if !ok { return nil, nil, nil, false } if len(exprs) != 1 { cs.addError(e.Pos(), fmt.Sprintf("multiple-value context is not available at a selector: %s", e.X)) return nil, nil, nil, false } var t shaderir.Type switch len(e.Sel.Name) { case 1: t.Main = shaderir.Float case 2: t.Main = shaderir.Vec2 case 3: t.Main = shaderir.Vec3 case 4: t.Main = shaderir.Vec4 default: cs.addError(e.Pos(), fmt.Sprintf("unexpected swizzling: %s", e.Sel.Name)) return nil, nil, nil, false } return []shaderir.Expr{ { Type: shaderir.FieldSelector, Exprs: []shaderir.Expr{ exprs[0], { Type: shaderir.SwizzlingExpr, Swizzling: e.Sel.Name, }, }, }, }, []shaderir.Type{t}, stmts, true case *ast.UnaryExpr: exprs, t, stmts, ok := cs.parseExpr(block, fname, e.X, markLocalVariableUsed) if !ok { return nil, nil, nil, false } if len(exprs) != 1 { cs.addError(e.Pos(), fmt.Sprintf("multiple-value context is not available at a unary operator: %s", e.X)) return nil, nil, nil, false } if exprs[0].Const != nil { v := gconstant.UnaryOp(e.Op, exprs[0].Const, 0) t := shaderir.Type{Main: shaderir.Int} if v.Kind() == gconstant.Float { t = shaderir.Type{Main: shaderir.Float} } return []shaderir.Expr{ { Type: shaderir.NumberExpr, Const: v, }, }, []shaderir.Type{t}, stmts, true } var op shaderir.Op switch e.Op { case token.ADD: op = shaderir.Add case token.SUB: op = shaderir.Sub case token.NOT: op = shaderir.NotOp default: cs.addError(e.Pos(), fmt.Sprintf("unexpected operator: %s", e.Op)) return nil, nil, nil, false } return []shaderir.Expr{ { Type: shaderir.Unary, Op: op, Exprs: exprs, }, }, t, stmts, true case *ast.CompositeLit: t, ok := cs.parseType(block, fname, e.Type) if !ok { return nil, nil, nil, false } if t.Main == shaderir.Array && t.Length == -1 { t.Length = len(e.Elts) } idx := block.totalLocalVariableCount() block.vars = append(block.vars, variable{ typ: t, }) var stmts []shaderir.Stmt for i, e := range e.Elts { exprs, _, ss, ok := cs.parseExpr(block, fname, e, markLocalVariableUsed) if !ok { return nil, nil, nil, false } if len(exprs) != 1 { cs.addError(e.Pos(), fmt.Sprintf("multiple-value context is not available at a composite literal")) return nil, nil, nil, false } stmts = append(stmts, ss...) stmts = append(stmts, shaderir.Stmt{ Type: shaderir.Assign, Exprs: []shaderir.Expr{ { Type: shaderir.Index, Exprs: []shaderir.Expr{ { Type: shaderir.LocalVariable, Index: idx, }, { Type: shaderir.NumberExpr, Const: gconstant.MakeInt64(int64(i)), ConstType: shaderir.ConstTypeInt, }, }, }, exprs[0], }, }) } return []shaderir.Expr{ { Type: shaderir.LocalVariable, Index: idx, }, }, []shaderir.Type{t}, stmts, true case *ast.IndexExpr: var stmts []shaderir.Stmt // Parse the index first exprs, _, ss, ok := cs.parseExpr(block, fname, e.Index, markLocalVariableUsed) if !ok { return nil, nil, nil, false } stmts = append(stmts, ss...) if len(exprs) != 1 { cs.addError(e.Pos(), fmt.Sprintf("multiple-value context is not available at an index expression")) return nil, nil, nil, false } idx := exprs[0] if idx.Const != nil { if !canTruncateToInteger(idx.Const) { cs.addError(e.Pos(), fmt.Sprintf("constant %s truncated to integer", idx.Const.String())) return nil, nil, nil, false } idx.ConstType = shaderir.ConstTypeInt } exprs, ts, ss, ok := cs.parseExpr(block, fname, e.X, markLocalVariableUsed) if !ok { return nil, nil, nil, false } stmts = append(stmts, ss...) if len(exprs) != 1 { cs.addError(e.Pos(), fmt.Sprintf("multiple-value context is not available at an index expression")) return nil, nil, nil, false } x := exprs[0] t := ts[0] var typ shaderir.Type switch t.Main { case shaderir.Vec2, shaderir.Vec3, shaderir.Vec4: typ = shaderir.Type{Main: shaderir.Float} case shaderir.Mat2: typ = shaderir.Type{Main: shaderir.Vec2} case shaderir.Mat3: typ = shaderir.Type{Main: shaderir.Vec3} case shaderir.Mat4: typ = shaderir.Type{Main: shaderir.Vec4} case shaderir.Array: typ = t.Sub[0] default: cs.addError(e.Pos(), fmt.Sprintf("index operator cannot be applied to the type %s", t.String())) return nil, nil, nil, false } return []shaderir.Expr{ { Type: shaderir.Index, Exprs: []shaderir.Expr{ x, idx, }, }, }, []shaderir.Type{typ}, stmts, true default: cs.addError(e.Pos(), fmt.Sprintf("expression not implemented: %#v", e)) } return nil, nil, nil, false }