go-ethereum/rlp/rlpgen/types.go

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rlp/rlpgen: RLP encoder code generator (#24251) This change adds a code generator tool for creating EncodeRLP method implementations. The generated methods will behave identically to the reflect-based encoder, but run faster because there is no reflection overhead. Package rlp now provides the EncoderBuffer type for incremental encoding. This is used by generated code, but the new methods can also be useful for hand-written encoders. There is also experimental support for generating DecodeRLP, and some new methods have been added to the existing Stream type to support this. Creating decoders with rlpgen is not recommended at this time because the generated methods create very poor error reporting. More detail about package rlp changes: * rlp: externalize struct field processing / validation This adds a new package, rlp/internal/rlpstruct, in preparation for the RLP encoder generator. I think the struct field rules are subtle enough to warrant extracting this into their own package, even though it means that a bunch of adapter code is needed for converting to/from rlpstruct.Type. * rlp: add more decoder methods (for rlpgen) This adds new methods on rlp.Stream: - Uint64, Uint32, Uint16, Uint8, BigInt - ReadBytes for decoding into []byte - MoreDataInList - useful for optional list elements * rlp: expose encoder buffer (for rlpgen) This exposes the internal encoder buffer type for use in EncodeRLP implementations. The new EncoderBuffer type is a sort-of 'opaque handle' for a pointer to encBuffer. It is implemented this way to ensure the global encBuffer pool is handled correctly.
2022-02-16 11:14:12 -06:00
package main
import (
"fmt"
"go/types"
"reflect"
)
// typeReflectKind gives the reflect.Kind that represents typ.
func typeReflectKind(typ types.Type) reflect.Kind {
switch typ := typ.(type) {
case *types.Basic:
k := typ.Kind()
if k >= types.Bool && k <= types.Complex128 {
// value order matches for Bool..Complex128
return reflect.Bool + reflect.Kind(k-types.Bool)
}
if k == types.String {
return reflect.String
}
if k == types.UnsafePointer {
return reflect.UnsafePointer
}
panic(fmt.Errorf("unhandled BasicKind %v", k))
case *types.Array:
return reflect.Array
case *types.Chan:
return reflect.Chan
case *types.Interface:
return reflect.Interface
case *types.Map:
return reflect.Map
case *types.Pointer:
return reflect.Ptr
case *types.Signature:
return reflect.Func
case *types.Slice:
return reflect.Slice
case *types.Struct:
return reflect.Struct
default:
panic(fmt.Errorf("unhandled type %T", typ))
}
}
// nonZeroCheck returns the expression that checks whether 'v' is a non-zero value of type 'vtyp'.
func nonZeroCheck(v string, vtyp types.Type, qualify types.Qualifier) string {
// Resolve type name.
typ := resolveUnderlying(vtyp)
switch typ := typ.(type) {
case *types.Basic:
k := typ.Kind()
switch {
case k == types.Bool:
return v
case k >= types.Uint && k <= types.Complex128:
return fmt.Sprintf("%s != 0", v)
case k == types.String:
return fmt.Sprintf(`%s != ""`, v)
default:
panic(fmt.Errorf("unhandled BasicKind %v", k))
}
case *types.Array, *types.Struct:
return fmt.Sprintf("%s != (%s{})", v, types.TypeString(vtyp, qualify))
case *types.Interface, *types.Pointer, *types.Signature:
return fmt.Sprintf("%s != nil", v)
case *types.Slice, *types.Map:
return fmt.Sprintf("len(%s) > 0", v)
default:
panic(fmt.Errorf("unhandled type %T", typ))
}
}
// isBigInt checks whether 'typ' is "math/big".Int.
func isBigInt(typ types.Type) bool {
named, ok := typ.(*types.Named)
if !ok {
return false
}
name := named.Obj()
return name.Pkg().Path() == "math/big" && name.Name() == "Int"
}
// isByte checks whether the underlying type of 'typ' is uint8.
func isByte(typ types.Type) bool {
basic, ok := resolveUnderlying(typ).(*types.Basic)
return ok && basic.Kind() == types.Uint8
}
func resolveUnderlying(typ types.Type) types.Type {
for {
t := typ.Underlying()
if t == typ {
return t
}
typ = t
}
}