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mirror of https://github.com/golang/go synced 2024-11-22 16:04:40 -07:00

[dev.typeparams] cmd/compile: add derived types and subdictionaries to dictionaries

This is code in progress to generate the two main other types of entries
in dictionaries:
 - all types in the instantiated function derived from the type
   arguments (which are currently concrete, but will eventually be
   gcshapes)
 - pointers (i.e. mainly the unique name) to all needed sub-dictionaries

In order to generate these entries, we now generate cached information
gfInfo about generic functions/methods that can be used for creating the
instantiated dictionaries. We use the type substituter to compute the
right type args for instantiated sub-dictionaries.

If infoPrintMode is changed to true, the code prints out all the
information gathered about generic functions, and also the entries in
all the dictionaries that are instantiated. The debug mode also prints
out the locations where we need main dictionaries in non-instantiated
functions.

Other changes:
 - Moved the dictionary generation back to stencil.go from reflect.go,
   since we need to do extra analysis for the new dictionary entries. In
   the process, made getInstantiation generate both the function
   instantiation and the associated dictionary.

 - Put in small change for now in reflect.go, so that we don't try
   generate separate dictionaries for Value[T].get and the
   auto-generated (*Value[T]).get.  The auto-generated wrapper shouldn't really
   need a dictionary.

 - Detected, but not handling yet, a new case which needs
   dictionaries - closures that have function params or captured
   variables whose types are derived from type arguments.

 - Added new tests in dictionaryCapture for use of method
   value/expressions in generic functions and for mutually recursive
   generic functions.

Change-Id: If0cbde8805a9f673a23f5ec798769c85c9c5359b
Reviewed-on: https://go-review.googlesource.com/c/go/+/327311
Trust: Dan Scales <danscales@google.com>
Run-TryBot: Dan Scales <danscales@google.com>
TryBot-Result: Go Bot <gobot@golang.org>
Reviewed-by: Keith Randall <khr@golang.org>
This commit is contained in:
Dan Scales 2021-06-07 18:13:15 -07:00
parent df00abc61b
commit ddb09af1b8
5 changed files with 398 additions and 55 deletions

View File

@ -700,6 +700,11 @@ func (n *UnaryExpr) SetOp(op Op) {
}
}
// Probably temporary: using Implicit() flag to mark generic function nodes that
// are called to make getGfInfo analysis easier in one pre-order pass.
func (n *InstExpr) Implicit() bool { return n.flags&miniExprImplicit != 0 }
func (n *InstExpr) SetImplicit(b bool) { n.flags.set(miniExprImplicit, b) }
// An InstExpr is a generic function or type instantiation.
type InstExpr struct {
miniExpr

View File

@ -96,6 +96,15 @@ func check2(noders []*noder) {
}
}
// gfInfo is information gathered on a generic function.
type gfInfo struct {
tparams []*types.Type
derivedTypes []*types.Type
// Node in generic function that requires a subdictionary. Some of these
// are not function/method values (not strictly calls).
subDictCalls []ir.Node
}
type irgen struct {
target *ir.Package
self *types2.Package
@ -110,6 +119,10 @@ type irgen struct {
instTypeList []*types.Type
dnum int // for generating unique dictionary variables
// Map from generic function to information about its type params, derived
// types, and subdictionaries.
gfInfoMap map[*types.Sym]*gfInfo
}
func (g *irgen) generate(noders []*noder) {

View File

@ -10,12 +10,15 @@ package noder
import (
"cmd/compile/internal/base"
"cmd/compile/internal/ir"
"cmd/compile/internal/objw"
"cmd/compile/internal/reflectdata"
"cmd/compile/internal/typecheck"
"cmd/compile/internal/types"
"cmd/internal/obj"
"cmd/internal/src"
"fmt"
"go/constant"
"strings"
)
func assert(p bool) {
@ -24,6 +27,16 @@ func assert(p bool) {
}
}
// Temporary - for outputting information on derived types, dictionaries, sub-dictionaries.
// Turn off when running tests.
var infoPrintMode = false
func infoPrint(format string, a ...interface{}) {
if infoPrintMode {
fmt.Printf(format, a...)
}
}
// stencil scans functions for instantiated generic function calls and creates the
// required instantiations for simple generic functions. It also creates
// instantiated methods for all fully-instantiated generic types that have been
@ -31,6 +44,7 @@ func assert(p bool) {
// process.
func (g *irgen) stencil() {
g.target.Stencils = make(map[*types.Sym]*ir.Func)
g.gfInfoMap = make(map[*types.Sym]*gfInfo)
// Instantiate the methods of instantiated generic types that we have seen so far.
g.instantiateMethods()
@ -87,7 +101,14 @@ func (g *irgen) stencil() {
// instantiation.
call := n.(*ir.CallExpr)
inst := call.X.(*ir.InstExpr)
st := g.getInstantiationForNode(inst)
st, dict := g.getInstantiationForNode(inst)
if infoPrintMode && g.target.Stencils[decl.Sym()] == nil {
if inst.X.Op() == ir.OCALLPART {
fmt.Printf("Main dictionary in %v at generic method call: %v - %v\n", decl, inst.X, call)
} else {
fmt.Printf("Main dictionary in %v at generic function call: %v - %v\n", decl, inst.X, call)
}
}
// Replace the OFUNCINST with a direct reference to the
// new stenciled function
call.X = st.Nname
@ -99,7 +120,6 @@ func (g *irgen) stencil() {
call.Args.Prepend(inst.X.(*ir.SelectorExpr).X)
}
// Add dictionary to argument list.
dict := reflectdata.GetDictionaryForInstantiation(inst)
call.Args.Prepend(dict)
// Transform the Call now, which changes OCALL
// to OCALLFUNC and does typecheckaste/assignconvfn.
@ -125,10 +145,9 @@ func (g *irgen) stencil() {
}
}
st := g.getInstantiation(gf, targs, true)
st, dict := g.getInstantiation(gf, targs, true)
call.SetOp(ir.OCALL)
call.X = st.Nname
dict := reflectdata.GetDictionaryForMethod(gf, targs)
call.Args.Prepend(dict, meth.X)
// Transform the Call now, which changes OCALL
// to OCALLFUNC and does typecheckaste/assignconvfn.
@ -212,13 +231,14 @@ func (g *irgen) buildClosure(outer *ir.Func, x ir.Node) ir.Node {
// For functions, the target expects a dictionary as its first argument.
// For method values, the target expects a dictionary and the receiver
// as its first two arguments.
target = g.getInstantiation(gf, targs, rcvrValue != nil)
// The value to use for the dictionary argument.
if rcvrValue == nil {
dictValue = reflectdata.GetDictionaryForFunc(gf, targs)
} else {
dictValue = reflectdata.GetDictionaryForMethod(gf, targs)
// dictValue is the value to use for the dictionary argument.
target, dictValue = g.getInstantiation(gf, targs, rcvrValue != nil)
if infoPrintMode && (outer == nil || g.target.Stencils[outer.Sym()] == nil) {
if rcvrValue == nil {
fmt.Printf("Main dictionary in %v for function value %v\n", outer, inst.X)
} else {
fmt.Printf("Main dictionary in %v for method value %v\n", outer, inst.X)
}
}
} else { // ir.OMETHEXPR
// Method expression T.M where T is a generic type.
@ -248,8 +268,10 @@ func (g *irgen) buildClosure(outer *ir.Func, x ir.Node) ir.Node {
break
}
}
target = g.getInstantiation(gf, targs, true)
dictValue = reflectdata.GetDictionaryForMethod(gf, targs)
target, dictValue = g.getInstantiation(gf, targs, true)
if infoPrintMode && (outer == nil || g.target.Stencils[outer.Sym()] == nil) {
fmt.Printf("Main dictionary in %v for method expression %v\n", outer, x)
}
}
// Build a closure to implement a function instantiation.
@ -444,7 +466,7 @@ func (g *irgen) instantiateMethods() {
baseType := baseSym.Def.(*ir.Name).Type()
for j, _ := range typ.Methods().Slice() {
baseNname := baseType.Methods().Slice()[j].Nname.(*ir.Name)
// Eagerly generate the instantiations that implement these methods.
// Eagerly generate the instantiations and dictionaries that implement these methods.
// We don't use the instantiations here, just generate them (and any
// further instantiations those generate, etc.).
// Note that we don't set the Func for any methods on instantiated
@ -452,16 +474,16 @@ func (g *irgen) instantiateMethods() {
// Direct method calls go directly to the instantiations, implemented above.
// Indirect method calls use wrappers generated in reflectcall. Those wrappers
// will use these instantiations if they are needed (for interface tables or reflection).
_ = g.getInstantiation(baseNname, typ.RParams(), true)
_, _ = g.getInstantiation(baseNname, typ.RParams(), true)
}
}
g.instTypeList = nil
}
// getInstantiationForNode returns the function/method instantiation for a
// InstExpr node inst.
func (g *irgen) getInstantiationForNode(inst *ir.InstExpr) *ir.Func {
// getInstantiationForNode returns the function/method instantiation and
// dictionary value for a InstExpr node inst.
func (g *irgen) getInstantiationForNode(inst *ir.InstExpr) (*ir.Func, ir.Node) {
if meth, ok := inst.X.(*ir.SelectorExpr); ok {
return g.getInstantiation(meth.Selection.Nname.(*ir.Name), typecheck.TypesOf(inst.Targs), true)
} else {
@ -469,10 +491,10 @@ func (g *irgen) getInstantiationForNode(inst *ir.InstExpr) *ir.Func {
}
}
// getInstantiation gets the instantiantion of the function or method nameNode
// getInstantiation gets the instantiantion and dictionary of the function or method nameNode
// with the type arguments targs. If the instantiated function is not already
// cached, then it calls genericSubst to create the new instantiation.
func (g *irgen) getInstantiation(nameNode *ir.Name, targs []*types.Type, isMeth bool) *ir.Func {
func (g *irgen) getInstantiation(nameNode *ir.Name, targs []*types.Type, isMeth bool) (*ir.Func, ir.Node) {
if nameNode.Func.Body == nil && nameNode.Func.Inl != nil {
// If there is no body yet but Func.Inl exists, then we can can
// import the whole generic body.
@ -497,7 +519,7 @@ func (g *irgen) getInstantiation(nameNode *ir.Name, targs []*types.Type, isMeth
ir.Dump(fmt.Sprintf("\nstenciled %v", st), st)
}
}
return st
return st, g.getDictionary(sym.Name, nameNode, targs)
}
// Struct containing info needed for doing the substitution as we create the
@ -994,3 +1016,245 @@ func deref(t *types.Type) *types.Type {
}
return t
}
// getDictionary returns the dictionary for the named instantiated function, which
// is instantiated from generic function or method gf, with the type arguments targs.
func (g *irgen) getDictionary(name string, gf *ir.Name, targs []*types.Type) ir.Node {
if len(targs) == 0 {
base.Fatalf("%s should have type arguments", name)
}
// The dictionary for this instantiation is named after the function
// and concrete types it is instantiated with.
// TODO: decouple this naming from the instantiation naming. The instantiation
// naming will be based on GC shapes, this naming must be fully stenciled.
if !strings.HasPrefix(name, ".inst.") {
base.Fatalf("%s should start in .inst.", name)
}
info := g.getGfInfo(gf)
name = ".dict." + name[6:]
// Get a symbol representing the dictionary.
sym := typecheck.Lookup(name)
// Initialize the dictionary, if we haven't yet already.
if lsym := sym.Linksym(); len(lsym.P) == 0 {
infoPrint("Creating dictionary %v\n", name)
off := 0
// Emit an entry for each targ (concrete type or gcshape).
for _, t := range targs {
infoPrint(" * %v\n", t)
s := reflectdata.TypeLinksym(t)
off = objw.SymPtr(lsym, off, s, 0)
}
subst := typecheck.Tsubster{
Tparams: info.tparams,
Targs: targs,
}
// Emit an entry for each derived type (after substituting targs)
for _, t := range info.derivedTypes {
ts := subst.Typ(t)
infoPrint(" - %v\n", ts)
s := reflectdata.TypeLinksym(ts)
off = objw.SymPtr(lsym, off, s, 0)
}
// Emit an entry for each subdictionary (after substituting targs)
// TODO: actually emit symbol for the subdictionary entry
for _, n := range info.subDictCalls {
if n.Op() == ir.OCALL {
call := n.(*ir.CallExpr)
if call.X.Op() == ir.OXDOT {
subtargs := deref(n.(*ir.CallExpr).X.(*ir.SelectorExpr).X.Type()).RParams()
s2targs := make([]*types.Type, len(subtargs))
for i, t := range subtargs {
s2targs[i] = subst.Typ(t)
}
sym := typecheck.MakeInstName(ir.MethodSym(call.X.(*ir.SelectorExpr).X.Type(), call.X.(*ir.SelectorExpr).Sel), s2targs, true)
infoPrint(" - Subdict .dict.%v\n", sym.Name[6:])
} else {
inst := n.(*ir.CallExpr).X.(*ir.InstExpr)
var nameNode *ir.Name
var meth *ir.SelectorExpr
var isMeth bool
if meth, isMeth = inst.X.(*ir.SelectorExpr); isMeth {
nameNode = meth.Selection.Nname.(*ir.Name)
} else {
nameNode = inst.X.(*ir.Name)
}
subtargs := typecheck.TypesOf(inst.Targs)
for i, t := range subtargs {
subtargs[i] = subst.Typ(t)
}
sym := typecheck.MakeInstName(nameNode.Sym(), subtargs, isMeth)
// TODO: This can actually be a static
// main dictionary, if all of the subtargs
// are concrete types (!HasTParam)
infoPrint(" - Subdict .dict.%v\n", sym.Name[6:])
}
} else if n.Op() == ir.OFUNCINST {
inst := n.(*ir.InstExpr)
nameNode := inst.X.(*ir.Name)
subtargs := typecheck.TypesOf(inst.Targs)
for i, t := range subtargs {
subtargs[i] = subst.Typ(t)
}
sym := typecheck.MakeInstName(nameNode.Sym(), subtargs, false)
// TODO: This can actually be a static
// main dictionary, if all of the subtargs
// are concrete types (!HasTParam)
infoPrint(" - Subdict .dict.%v\n", sym.Name[6:])
} else if n.Op() == ir.OXDOT {
selExpr := n.(*ir.SelectorExpr)
subtargs := selExpr.X.Type().RParams()
s2targs := make([]*types.Type, len(subtargs))
for i, t := range subtargs {
s2targs[i] = subst.Typ(t)
}
sym := typecheck.MakeInstName(ir.MethodSym(selExpr.X.Type(), selExpr.Sel), s2targs, true)
infoPrint(" - Subdict .dict.%v\n", sym.Name[6:])
}
// TODO: handle closure cases that need sub-dictionaries
}
objw.Global(lsym, int32(off), obj.DUPOK|obj.RODATA)
}
// Make a node referencing the dictionary symbol.
n := typecheck.NewName(sym)
n.SetType(types.Types[types.TUINTPTR]) // should probably be [...]uintptr, but doesn't really matter
n.SetTypecheck(1)
n.Class = ir.PEXTERN
sym.Def = n
// Return the address of the dictionary.
np := typecheck.NodAddr(n)
// Note: treat dictionary pointers as uintptrs, so they aren't pointers
// with respect to GC. That saves on stack scanning work, write barriers, etc.
// We can get away with it because dictionaries are global variables.
// TODO: use a cast, or is typing directly ok?
np.SetType(types.Types[types.TUINTPTR])
np.SetTypecheck(1)
return np
}
// getGfInfo get information for a generic function - type params, derived generic
// types, and subdictionaries.
func (g *irgen) getGfInfo(gn *ir.Name) *gfInfo {
infop := g.gfInfoMap[gn.Sym()]
if infop != nil {
return infop
}
var info gfInfo
gf := gn.Func
recv := gf.Type().Recv()
if recv != nil {
info.tparams = deref(recv.Type).RParams()
} else {
info.tparams = make([]*types.Type, len(gn.Type().TParams().FieldSlice()))
for i, f := range gn.Type().TParams().FieldSlice() {
info.tparams[i] = f.Type
}
}
for _, n := range gf.Dcl {
addType(&info, n, n.Type())
}
if infoPrintMode {
fmt.Printf(">>> Info for %v\n", gn)
for _, t := range info.tparams {
fmt.Printf(" Typeparam %v\n", t)
}
for _, t := range info.derivedTypes {
fmt.Printf(" Derived type %v\n", t)
}
}
for _, stmt := range gf.Body {
ir.Visit(stmt, func(n ir.Node) {
if n.Op() == ir.OFUNCINST && !n.(*ir.InstExpr).Implicit() {
infoPrint(" Closure&subdictionary required at generic function value %v\n", n.(*ir.InstExpr).X)
info.subDictCalls = append(info.subDictCalls, n)
} else if n.Op() == ir.OXDOT && !n.(*ir.SelectorExpr).Implicit() &&
!n.(*ir.SelectorExpr).X.Type().IsInterface() &&
len(n.(*ir.SelectorExpr).X.Type().RParams()) > 0 {
// Fix this - doesn't account for embedded fields, etc.
field := typecheck.Lookdot1(n.(*ir.SelectorExpr), n.(*ir.SelectorExpr).Sel, n.(*ir.SelectorExpr).X.Type(), n.(*ir.SelectorExpr).X.Type().Fields(), 0)
if field == nil {
if n.(*ir.SelectorExpr).X.Op() == ir.OTYPE {
infoPrint(" Closure&subdictionary required at generic meth expr %v\n", n)
} else {
infoPrint(" Closure&subdictionary required at generic meth value %v\n", n)
}
info.subDictCalls = append(info.subDictCalls, n)
}
}
if n.Op() == ir.OCALL && n.(*ir.CallExpr).X.Op() == ir.OFUNCINST {
infoPrint(" Subdictionary at generic function call: %v - %v\n", n.(*ir.CallExpr).X.(*ir.InstExpr).X, n)
n.(*ir.CallExpr).X.(*ir.InstExpr).SetImplicit(true)
info.subDictCalls = append(info.subDictCalls, n)
}
if n.Op() == ir.OCALL && n.(*ir.CallExpr).X.Op() == ir.OXDOT &&
!n.(*ir.CallExpr).X.(*ir.SelectorExpr).X.Type().IsInterface() &&
len(deref(n.(*ir.CallExpr).X.(*ir.SelectorExpr).X.Type()).RParams()) > 0 {
infoPrint(" Subdictionary at generic method call: %v\n", n)
n.(*ir.CallExpr).X.(*ir.SelectorExpr).SetImplicit(true)
info.subDictCalls = append(info.subDictCalls, n)
}
if n.Op() == ir.OCLOSURE {
oldfn := n.(*ir.ClosureExpr).Func
needDict := false
if oldfn.Nname.Type().HasTParam() {
needDict = true
infoPrint(" Subdictionary for closure that has generic params: %v\n", oldfn)
} else {
for _, cv := range oldfn.ClosureVars {
if cv.Type().HasTParam() {
needDict = true
infoPrint(" Subdictionary for closure that has generic capture: %v\n", oldfn)
break
}
}
}
if needDict {
info.subDictCalls = append(info.subDictCalls, n)
}
}
addType(&info, n, n.Type())
})
}
g.gfInfoMap[gn.Sym()] = &info
return &info
}
// addType adds t to info.derivedTypes if it is parameterized type (which is not
// just a simple type param) that is different from any existing type on
// info.derivedTypes.
func addType(info *gfInfo, n ir.Node, t *types.Type) {
if t == nil || !t.HasTParam() {
return
}
if t.IsTypeParam() && t.Underlying() == t {
return
}
if t.Kind() == types.TFUNC && n != nil &&
(n.Op() != ir.ONAME || n.Name().Class == ir.PFUNC) {
// For now, only record function types that are associate with a
// local/global variable (a name which is not a named global
// function).
return
}
if t.Kind() == types.TSTRUCT && t.IsFuncArgStruct() {
// Multiple return values are not a relevant new type (?).
return
}
// Ignore a derived type we've already added.
for _, et := range info.derivedTypes {
if types.Identical(t, et) {
return
}
}
info.derivedTypes = append(info.derivedTypes, t)
}

View File

@ -1716,8 +1716,12 @@ func methodWrapper(rcvr *types.Type, method *types.Field, forItab bool) *obj.LSy
rcvr = rcvr.PtrTo()
}
generic := false
if !rcvr.IsInterface() && len(rcvr.RParams()) > 0 || rcvr.IsPtr() && len(rcvr.Elem().RParams()) > 0 { // TODO: right detection?
// TODO: check that we do the right thing when rcvr.IsInterface().
if !types.IsInterfaceMethod(method.Type) &&
(len(rcvr.RParams()) > 0 ||
rcvr.IsPtr() && len(rcvr.Elem().RParams()) > 0) { // TODO: right detection?
// Don't need dictionary if we are reaching a method (possibly via
// an embedded field) which is an interface method.
// TODO: check that we do the right thing when method is an interface method.
generic = true
}
if base.Debug.Unified != 0 {
@ -1786,12 +1790,6 @@ func methodWrapper(rcvr *types.Type, method *types.Field, forItab bool) *obj.LSy
}
dot := typecheck.AddImplicitDots(ir.NewSelectorExpr(base.Pos, ir.OXDOT, nthis, method.Sym))
if generic && dot.X != nthis && dot.X.Type().IsInterface() {
// We followed some embedded fields, and the last type was
// actually an interface, so no need for a dictionary.
generic = false
}
// generate call
// It's not possible to use a tail call when dynamic linking on ppc64le. The
// bad scenario is when a local call is made to the wrapper: the wrapper will
@ -1815,6 +1813,14 @@ func methodWrapper(rcvr *types.Type, method *types.Field, forItab bool) *obj.LSy
} else {
fn.SetWrapper(true) // ignore frame for panic+recover matching
var call *ir.CallExpr
if generic && dot.X != nthis {
// TODO: for now, we don't try to generate dictionary wrappers for
// any methods involving embedded fields, because we're not
// generating the needed dictionaries in instantiateMethods.
generic = false
}
if generic {
var args []ir.Node
var targs []*types.Type
@ -1827,7 +1833,17 @@ func methodWrapper(rcvr *types.Type, method *types.Field, forItab bool) *obj.LSy
fmt.Printf("%s\n", ir.MethodSym(orig, method.Sym).Name)
panic("multiple .inst.")
}
args = append(args, getDictionary(".inst."+ir.MethodSym(orig, method.Sym).Name, targs)) // TODO: remove .inst.
// Temporary fix: the wrapper for an auto-generated
// pointer/non-pointer receiver method should share the
// same dictionary as the corresponding original
// (user-written) method.
baseOrig := orig
if baseOrig.IsPtr() && !method.Type.Recv().Type.IsPtr() {
baseOrig = baseOrig.Elem()
} else if !baseOrig.IsPtr() && method.Type.Recv().Type.IsPtr() {
baseOrig = types.NewPtr(baseOrig)
}
args = append(args, getDictionary(".inst."+ir.MethodSym(baseOrig, method.Sym).Name, targs)) // TODO: remove .inst.
if indirect {
args = append(args, ir.NewStarExpr(base.Pos, dot.X))
} else if methodrcvr.IsPtr() && methodrcvr.Elem() == dot.X.Type() {
@ -1852,6 +1868,9 @@ func methodWrapper(rcvr *types.Type, method *types.Field, forItab bool) *obj.LSy
}
target := ir.AsNode(sym.Def)
call = ir.NewCallExpr(base.Pos, ir.OCALL, target, args)
// Fill-in the generic method node that was not filled in
// in instantiateMethod.
method.Nname = fn.Nname
} else {
call = ir.NewCallExpr(base.Pos, ir.OCALL, dot, nil)
call.Args = ir.ParamNames(tfn.Type())
@ -1924,23 +1943,6 @@ func MarkUsedIfaceMethod(n *ir.CallExpr) {
r.Type = objabi.R_USEIFACEMETHOD
}
// getDictionaryForInstantiation returns the dictionary that should be used for invoking
// the concrete instantiation described by inst.
func GetDictionaryForInstantiation(inst *ir.InstExpr) ir.Node {
targs := typecheck.TypesOf(inst.Targs)
if meth, ok := inst.X.(*ir.SelectorExpr); ok {
return GetDictionaryForMethod(meth.Selection.Nname.(*ir.Name), targs)
}
return GetDictionaryForFunc(inst.X.(*ir.Name), targs)
}
func GetDictionaryForFunc(fn *ir.Name, targs []*types.Type) ir.Node {
return getDictionary(typecheck.MakeInstName(fn.Sym(), targs, false).Name, targs)
}
func GetDictionaryForMethod(meth *ir.Name, targs []*types.Type) ir.Node {
return getDictionary(typecheck.MakeInstName(meth.Sym(), targs, true).Name, targs)
}
// getDictionary returns the dictionary for the given named generic function
// or method, with the given type arguments.
// TODO: pass a reference to the generic function instead? We might need
@ -1964,14 +1966,7 @@ func getDictionary(name string, targs []*types.Type) ir.Node {
// Initialize the dictionary, if we haven't yet already.
if lsym := sym.Linksym(); len(lsym.P) == 0 {
off := 0
// Emit an entry for each concrete type.
for _, t := range targs {
s := TypeLinksym(t)
off = objw.SymPtr(lsym, off, s, 0)
}
// TODO: subdictionaries
objw.Global(lsym, int32(off), obj.DUPOK|obj.RODATA)
base.Fatalf("Dictionary should have alredy been generated: %v", sym)
}
// Make a node referencing the dictionary symbol.

View File

@ -10,12 +10,19 @@
package main
import (
"fmt"
)
func main() {
functions()
methodExpressions()
genMethodExpressions[int](7)
methodValues()
genMethodValues[int](7)
interfaceMethods()
globals()
recursive()
}
func g0[T any](x T) {
@ -72,6 +79,20 @@ func methodExpressions() {
is77(f2(x))
}
func genMethodExpressions[T comparable](want T) {
x := s[T]{a: want}
f0 := s[T].g0
f0(x)
f1 := s[T].g1
if got := f1(x); got != want {
panic(fmt.Sprintf("f1(x) == %d, want %d", got, want))
}
f2 := s[T].g2
if got1, got2 := f2(x); got1 != want || got2 != want {
panic(fmt.Sprintf("f2(x) == %d, %d, want %d, %d", got1, got2, want, want))
}
}
func methodValues() {
x := s[int]{a:7}
f0 := x.g0
@ -82,6 +103,20 @@ func methodValues() {
is77(f2())
}
func genMethodValues[T comparable](want T) {
x := s[T]{a: want}
f0 := x.g0
f0()
f1 := x.g1
if got := f1(); got != want {
panic(fmt.Sprintf("f1() == %d, want %d", got, want))
}
f2 := x.g2
if got1, got2 := f2(); got1 != want || got2 != want {
panic(fmt.Sprintf("f2() == %d, %d, want %d, %d", got1, got2, want, want))
}
}
var x interface{
g0()
g1()int
@ -124,3 +159,34 @@ func globals() {
is7(ii1())
is77(ii2())
}
func recursive() {
if got, want := recur1[int](5), 110; got != want {
panic(fmt.Sprintf("recur1[int](5) = %d, want = %d", got, want))
}
}
type Integer interface {
int | int32 | int64
}
func recur1[T Integer](n T) T {
if n == 0 || n == 1 {
return T(1)
} else {
return n * recur2(n - 1)
}
}
func recur2[T Integer](n T) T {
list := make([]T, n)
for i, _ := range list {
list[i] = T(i+1)
}
var sum T
for _, elt := range list {
sum += elt
}
return sum + recur1(n-1)
}