ginger/vm/op.go

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package vm
import (
"fmt"
"github.com/mediocregopher/ginger/gg"
"github.com/mediocregopher/ginger/graph"
)
// Operation is an entity which accepts an argument Value and performs some
// internal processing on that argument to return a resultant Value.
type Operation interface {
Perform(Value) Value
}
// OperationFunc is a function which implements the Operation interface.
type OperationFunc func(Value) Value
// Perform calls the underlying OperationFunc directly.
func (f OperationFunc) Perform(arg Value) Value {
return f(arg)
}
// Identity returns an Operation which always returns the given Value,
// regardless of the input argument.
//
// TODO this might not be the right name
func Identity(val Value) Operation {
return OperationFunc(func(Value) Value {
return val
})
}
type graphOp struct {
*gg.Graph
scope Scope
}
var (
valNameIn = Value{Value: gg.Name("in")}
valNameOut = Value{Value: gg.Name("out")}
valNameIf = Value{Value: gg.Name("if")}
valNameRecur = Value{Value: gg.Name("recur")}
valNumberZero = Value{Value: gg.Number(0)}
)
// OperationFromGraph wraps the given Graph such that it can be used as an
// Operation. The given Scope determines what values outside of the Graph are
// available for use within the Operation.
func OperationFromGraph(g *gg.Graph, scope Scope) (Operation, error) {
// edgeOp is distinct from a generic Operation in that the Value passed into
// Perform will _always_ be the value of "in" for the overall Operation.
//
// edgeOps will wrap each other, passing "in" downwards to the leaf edgeOps.
type edgeOp Operation
var compileEdge func(*gg.OpenEdge) (edgeOp, error)
// TODO memoize?
valToEdgeOp := func(val Value) (edgeOp, error) {
if val.Name == nil {
return edgeOp(Identity(val)), nil
}
name := *val.Name
if val.Equal(valNameIn) {
return edgeOp(OperationFunc(func(inArg Value) Value {
return inArg
})), nil
}
// TODO intercept if and recur?
edgesIn := g.ValueIns(val.Value)
if l := len(edgesIn); l == 0 {
val, err := scope.Resolve(name)
if err != nil {
return nil, fmt.Errorf("resolving name %q from the outer scope: %w", name, err)
}
return edgeOp(Identity(val)), nil
} else if l != 1 {
return nil, fmt.Errorf("resolved name %q to %d input edges, rather than one", name, l)
}
edge := edgesIn[0]
return compileEdge(edge)
}
// "out" resolves to more than a static value, treat the graph as a full
// operation.
// thisOp is used to support recur. It will get filled in with the Operation
// which is returned by this function, once that Operation is created.
thisOp := new(Operation)
compileEdge = func(edge *gg.OpenEdge) (edgeOp, error) {
return graph.MapReduce[gg.Value, gg.Value, edgeOp](
edge,
func(ggVal gg.Value) (edgeOp, error) {
return valToEdgeOp(Value{Value: ggVal})
},
func(ggEdgeVal gg.Value, inEdgeOps []edgeOp) (edgeOp, error) {
if ggEdgeVal.Equal(valNameIf.Value) {
if len(inEdgeOps) != 3 {
return nil, fmt.Errorf("'if' requires a 3-tuple argument")
}
return edgeOp(OperationFunc(func(inArg Value) Value {
if pred := inEdgeOps[0].Perform(inArg); pred.Equal(valNumberZero) {
return inEdgeOps[2].Perform(inArg)
}
return inEdgeOps[1].Perform(inArg)
})), nil
}
// "if" statements (above) are the only case where we want the
// input edges to remain separated, otherwise they should always
// be combined into a single edge whose value is a tuple. Do
// that here.
inEdgeOp := inEdgeOps[0]
if len(inEdgeOps) > 1 {
inEdgeOp = edgeOp(OperationFunc(func(inArg Value) Value {
tupVals := make([]Value, len(inEdgeOps))
for i := range inEdgeOps {
tupVals[i] = inEdgeOps[i].Perform(inArg)
}
return Tuple(tupVals...)
}))
}
edgeVal := Value{Value: ggEdgeVal}
if edgeVal.IsZero() {
return inEdgeOp, nil
}
if edgeVal.Equal(valNameRecur) {
return edgeOp(OperationFunc(func(inArg Value) Value {
return (*thisOp).Perform(inEdgeOp.Perform(inArg))
})), nil
}
if edgeVal.Graph != nil {
opFromGraph, err := OperationFromGraph(
edgeVal.Graph,
scope.NewScope(),
)
if err != nil {
return nil, fmt.Errorf("compiling graph to operation: %w", err)
}
edgeVal = Value{Operation: opFromGraph}
}
// The Operation is known at compile-time, so we can wrap it
// directly into an edgeVal using the existing inEdgeOp as the
// input.
if edgeVal.Operation != nil {
return edgeOp(OperationFunc(func(inArg Value) Value {
return edgeVal.Operation.Perform(inEdgeOp.Perform(inArg))
})), nil
}
// the edgeVal is not an Operation at compile time, and so
// it must become one at runtime. We must resolve edgeVal to an
// edgeOp as well (edgeEdgeOp), and then at runtime that is
// given the inArg and (hopefully) the resultant Operation is
// called.
edgeEdgeOp, err := valToEdgeOp(edgeVal)
if err != nil {
return nil, err
}
return edgeOp(OperationFunc(func(inArg Value) Value {
runtimeEdgeVal := edgeEdgeOp.Perform(inArg)
if runtimeEdgeVal.Graph != nil {
runtimeOp, err := OperationFromGraph(
runtimeEdgeVal.Graph,
scope.NewScope(),
)
if err != nil {
panic(fmt.Sprintf("compiling graph to operation: %v", err))
}
runtimeEdgeVal = Value{Operation: runtimeOp}
}
if runtimeEdgeVal.Operation == nil {
panic("edge value must be an operation")
}
return runtimeEdgeVal.Operation.Perform(inEdgeOp.Perform(inArg))
})), nil
},
)
}
graphOp, err := valToEdgeOp(valNameOut)
if err != nil {
return nil, err
}
*thisOp = Operation(graphOp)
return Operation(graphOp), nil
}