ginger/expr/build.go

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package expr
import (
"fmt"
"log"
"llvm.org/llvm/bindings/go/llvm"
)
func init() {
log.Printf("initializing llvm")
llvm.LinkInMCJIT()
llvm.InitializeNativeTarget()
llvm.InitializeNativeAsmPrinter()
}
type BuildCtx struct {
B llvm.Builder
M llvm.Module
}
func NewBuildCtx(moduleName string) BuildCtx {
return BuildCtx{
B: llvm.NewBuilder(),
M: llvm.NewModule(moduleName),
}
}
func (bctx BuildCtx) Build(ctx Ctx, stmts ...Statement) llvm.Value {
var lastVal llvm.Value
for _, stmt := range stmts {
if e := bctx.BuildStmt(ctx, stmt); e != nil {
if lv, ok := e.(llvmVal); ok {
lastVal = llvm.Value(lv)
} else {
log.Printf("BuildStmt returned non llvmVal from %v: %v (%T)", stmt, e, e)
}
}
}
if (lastVal == llvm.Value{}) {
lastVal = bctx.B.CreateRetVoid()
}
return lastVal
}
func (bctx BuildCtx) BuildStmt(ctx Ctx, s Statement) Expr {
log.Printf("building: %v", s)
switch o := s.Op.(type) {
case Macro:
return ctx.Macro(o)(bctx, ctx, s.Arg)
case Identifier:
s2 := s
s2.Op = ctx.Identifier(o).(llvmVal)
return bctx.BuildStmt(ctx, s2)
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case Statement:
s2 := s
s2.Op = bctx.BuildStmt(ctx, o)
return bctx.BuildStmt(ctx, s2)
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case llvmVal:
arg := bctx.buildExpr(ctx, s.Arg).(llvmVal)
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out := bctx.B.CreateCall(llvm.Value(o), []llvm.Value{llvm.Value(arg)}, "")
return llvmVal(out)
default:
panic(fmt.Sprintf("non op type %v (%T)", s.Op, s.Op))
}
}
// may return nil if e is a Statement which has no return
func (bctx BuildCtx) buildExpr(ctx Ctx, e Expr) Expr {
return bctx.buildExprTill(ctx, e, func(Expr) bool { return false })
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}
// like buildExpr, but will stop short and stop recursing when the function
// returns true
func (bctx BuildCtx) buildExprTill(ctx Ctx, e Expr, fn func(e Expr) bool) Expr {
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if fn(e) {
return e
}
switch ea := e.(type) {
case llvmVal:
return e
case Int:
return llvmVal(llvm.ConstInt(llvm.Int64Type(), uint64(ea), false))
case Identifier:
return ctx.Identifier(ea)
case Statement:
return bctx.BuildStmt(ctx, ea)
case Tuple:
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// if the tuple is empty then it is a void
if len(ea) == 0 {
return llvmVal(llvm.Undef(llvm.VoidType()))
}
ea2 := make(Tuple, len(ea))
for i := range ea {
ea2[i] = bctx.buildExprTill(ctx, ea[i], fn)
}
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// if the fields of the tuple are all llvmVal then we can make a proper
// struct
vals := make([]llvm.Value, len(ea2))
typs := make([]llvm.Type, len(ea2))
for i := range ea2 {
if v, ok := ea2[i].(llvmVal); ok {
val := llvm.Value(v)
vals[i] = val
typs[i] = val.Type()
} else {
return ea2
}
}
str := llvm.Undef(llvm.StructType(typs, false))
for i := range vals {
str = bctx.B.CreateInsertValue(str, vals[i], i, "")
}
return llvmVal(str)
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case List:
ea2 := make(Tuple, len(ea))
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for i := range ea {
ea2[i] = bctx.buildExprTill(ctx, ea[i], fn)
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}
return ea2
case Ctx:
return ea
default:
panicf("%v (type %T) can't express a value", ea, ea)
}
panic("go is dumb")
}
func (bctx BuildCtx) buildVal(ctx Ctx, e Expr) llvm.Value {
return llvm.Value(bctx.buildExpr(ctx, e).(llvmVal))
}
// globalCtx describes what's available to *all* contexts, and is what all
// contexts should have as the root parent in the tree.
//
// We define in this weird way cause NewCtx actually references globalCtx
var globalCtx *Ctx
var _ = func() bool {
globalCtx = &Ctx{
macros: map[Macro]MacroFn{
"add": func(bctx BuildCtx, ctx Ctx, e Expr) Expr {
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tup := bctx.buildExpr(ctx, e).(llvmVal)
a := bctx.B.CreateExtractValue(llvm.Value(tup), 0, "")
b := bctx.B.CreateExtractValue(llvm.Value(tup), 1, "")
return llvmVal(bctx.B.CreateAdd(a, b, ""))
},
// TODO this chould be a user macro!!!! WUT this language is baller
"bind": func(bctx BuildCtx, ctx Ctx, e Expr) Expr {
tup := bctx.buildExprTill(ctx, e, isIdentifier).(Tuple)
id := bctx.buildExprTill(ctx, tup[0], isIdentifier).(Identifier)
val := bctx.buildExpr(ctx, tup[1])
ctx.Bind(id, val)
return NewTuple()
},
"ctxnew": func(bctx BuildCtx, ctx Ctx, e Expr) Expr {
return NewCtx()
},
"ctxthis": func(bctx BuildCtx, ctx Ctx, e Expr) Expr {
return ctx
},
"ctxbind": func(bctx BuildCtx, ctx Ctx, e Expr) Expr {
tup := bctx.buildExprTill(ctx, e, isIdentifier).(Tuple)
thisCtx := bctx.buildExpr(ctx, tup[0]).(Ctx)
id := bctx.buildExprTill(ctx, tup[1], isIdentifier).(Identifier)
thisCtx.Bind(id, bctx.buildExpr(ctx, tup[2]))
return NewTuple()
},
"ctxget": func(bctx BuildCtx, ctx Ctx, e Expr) Expr {
tup := bctx.buildExprTill(ctx, e, isIdentifier).(Tuple)
thisCtx := bctx.buildExpr(ctx, tup[0]).(Ctx)
id := bctx.buildExprTill(ctx, tup[1], isIdentifier).(Identifier)
return thisCtx.Identifier(id)
},
"do": func(bctx BuildCtx, ctx Ctx, e Expr) Expr {
tup := bctx.buildExprTill(ctx, e, isStmt).(Tuple)
thisCtx := tup[0].(Ctx)
for _, stmtE := range tup[1].(List) {
bctx.BuildStmt(thisCtx, stmtE.(Statement))
}
return NewTuple()
},
"op": func(bctx BuildCtx, ctx Ctx, e Expr) Expr {
l := bctx.buildExprTill(ctx, e, isList).(List)
stmts := make([]Statement, len(l))
for i := range l {
stmts[i] = l[i].(Statement)
}
// TODO obviously this needs to be fixed
fn := llvm.AddFunction(bctx.M, "", llvm.FunctionType(llvm.Int64Type(), []llvm.Type{llvm.Int64Type()}, false))
fnbl := llvm.AddBasicBlock(fn, "")
prevbl := bctx.B.GetInsertBlock()
bctx.B.SetInsertPoint(fnbl, fnbl.FirstInstruction())
out := bctx.Build(NewCtx(), stmts...)
bctx.B.CreateRet(out)
bctx.B.SetInsertPointAtEnd(prevbl)
return llvmVal(fn)
},
"in": func(bctx BuildCtx, ctx Ctx, e Expr) Expr {
fn := bctx.B.GetInsertBlock().Parent()
return llvmVal(fn.Param(0))
},
},
}
return false
}()