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gerrit-public.fairphone.software / toolchain / llvm-project / f3718a9bf100596cce88f0d5ed27c16a204fe58f / . / llgo / irgen / ssa.go
blob: 903e80416e108b727baf0130a13663af64aa0fe6 [file] [log] [blame]
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]1//===- ssa.go - IR generation from go/ssa ---------------------------------===//
2//
3// The LLVM Compiler Infrastructure
4//
5// This file is distributed under the University of Illinois Open Source
6// License. See LICENSE.TXT for details.
7//
8//===----------------------------------------------------------------------===//
9//
10// This file implements the top-level LLVM IR generation from go/ssa form.
11//
12//===----------------------------------------------------------------------===//
13
14package irgen
15
16import (
17 "fmt"
18 "go/ast"
19 "go/token"
20 "os"
21 "sort"
22
23 "llvm.org/llgo/ssaopt"
24 "llvm.org/llgo/third_party/go.tools/go/ssa"
25 "llvm.org/llgo/third_party/go.tools/go/ssa/ssautil"
26 "llvm.org/llgo/third_party/go.tools/go/types"
27 "llvm.org/llvm/bindings/go/llvm"
28)
29
30// A globalInit is used to temporarily store a global's initializer until
31// we are ready to build it.
32type globalInit struct {
33 val llvm.Value
34 elems []globalInit
35}
36
37func (gi *globalInit) update(typ llvm.Type, indices []uint32, val llvm.Value) {
38 if len(indices) == 0 {
39 gi.val = val
40 return
41 }
42
43 if gi.val.C != nil {
44 gi.val = llvm.ConstInsertValue(gi.val, val, indices)
45 }
46
47 tk := typ.TypeKind()
48
49 if len(gi.elems) == 0 {
50 switch tk {
51 case llvm.StructTypeKind:
52 gi.elems = make([]globalInit, typ.StructElementTypesCount())
53 case llvm.ArrayTypeKind:
54 gi.elems = make([]globalInit, typ.ArrayLength())
55 default:
56 panic("unexpected type")
57 }
58 }
59
60 var eltyp llvm.Type
61 switch tk {
62 case llvm.StructTypeKind:
63 eltyp = typ.StructElementTypes()[indices[0]]
64 case llvm.ArrayTypeKind:
65 eltyp = typ.ElementType()
66 default:
67 panic("unexpected type")
68 }
69
70 gi.elems[indices[0]].update(eltyp, indices[1:], val)
71}
72
73func (gi *globalInit) build(typ llvm.Type) llvm.Value {
74 if gi.val.C != nil {
75 return gi.val
76 }
77 if len(gi.elems) == 0 {
78 return llvm.ConstNull(typ)
79 }
80
81 switch typ.TypeKind() {
82 case llvm.StructTypeKind:
83 eltypes := typ.StructElementTypes()
84 elems := make([]llvm.Value, len(eltypes))
85 for i, eltyp := range eltypes {
86 elems[i] = gi.elems[i].build(eltyp)
87 }
88 return llvm.ConstStruct(elems, false)
89 case llvm.ArrayTypeKind:
90 eltyp := typ.ElementType()
91 elems := make([]llvm.Value, len(gi.elems))
92 for i := range gi.elems {
93 elems[i] = gi.elems[i].build(eltyp)
94 }
95 return llvm.ConstArray(eltyp, elems)
96 default:
97 panic("unexpected type")
98 }
99}
100
101type unit struct {
102 *compiler
103 pkg *ssa.Package
104 globals map[ssa.Value]llvm.Value
105 globalInits map[llvm.Value]*globalInit
106
107 // funcDescriptors maps *ssa.Functions to function descriptors,
108 // the first-class representation of functions.
109 funcDescriptors map[*ssa.Function]llvm.Value
110
111 // undefinedFuncs contains functions that have been resolved
112 // (declared) but not defined.
113 undefinedFuncs map[*ssa.Function]bool
114
115 gcRoots []llvm.Value
116}
117
118func newUnit(c *compiler, pkg *ssa.Package) *unit {
119 u := &unit{
120 compiler: c,
121 pkg: pkg,
122 globals: make(map[ssa.Value]llvm.Value),
123 globalInits: make(map[llvm.Value]*globalInit),
124 funcDescriptors: make(map[*ssa.Function]llvm.Value),
125 undefinedFuncs: make(map[*ssa.Function]bool),
126 }
127 return u
128}
129
130type byMemberName []ssa.Member
131
132func (ms byMemberName) Len() int { return len(ms) }
133func (ms byMemberName) Swap(i, j int) {
134 ms[i], ms[j] = ms[j], ms[i]
135}
136func (ms byMemberName) Less(i, j int) bool {
137 return ms[i].Name() < ms[j].Name()
138}
139
140type byFunctionString []*ssa.Function
141
142func (fns byFunctionString) Len() int { return len(fns) }
143func (fns byFunctionString) Swap(i, j int) {
144 fns[i], fns[j] = fns[j], fns[i]
145}
146func (fns byFunctionString) Less(i, j int) bool {
147 return fns[i].String() < fns[j].String()
148}
149
150// Emit functions in order of their fully qualified names. This is so that a
151// bootstrap build can be verified by comparing the stage2 and stage3 binaries.
152func (u *unit) defineFunctionsInOrder(functions map[*ssa.Function]bool) {
153 fns := []*ssa.Function{}
154 for f, _ := range functions {
155 fns = append(fns, f)
156 }
157 sort.Sort(byFunctionString(fns))
158 for _, f := range fns {
159 u.defineFunction(f)
160 }
161}
162
163// translatePackage translates an *ssa.Package into an LLVM module, and returns
164// the translation unit information.
165func (u *unit) translatePackage(pkg *ssa.Package) {
166 ms := make([]ssa.Member, len(pkg.Members))
167 i := 0
168 for _, m := range pkg.Members {
169 ms[i] = m
170 i++
171 }
172
173 sort.Sort(byMemberName(ms))
174
175 // Initialize global storage and type descriptors for this package.
176 // We must create globals regardless of whether they're referenced,
177 // hence the duplication in frame.value.
178 for _, m := range ms {
179 switch v := m.(type) {
180 case *ssa.Global:
181 elemtyp := deref(v.Type())
182 llelemtyp := u.llvmtypes.ToLLVM(elemtyp)
183 vname := u.types.mc.mangleGlobalName(v)
184 global := llvm.AddGlobal(u.module.Module, llelemtyp, vname)
185 if !v.Object().Exported() {
186 global.SetLinkage(llvm.InternalLinkage)
187 }
188 u.addGlobal(global, elemtyp)
189 global = llvm.ConstBitCast(global, u.llvmtypes.ToLLVM(v.Type()))
190 u.globals[v] = global
191 case *ssa.Type:
192 u.types.getTypeDescriptorPointer(v.Type())
193 }
194 }
195
196 // Define functions.
197 u.defineFunctionsInOrder(ssautil.AllFunctions(pkg.Prog))
198
199 // Emit initializers for type descriptors, which may trigger
200 // the resolution of additional functions.
201 u.types.emitTypeDescInitializers()
202
203 // Define remaining functions that were resolved during
204 // runtime type mapping, but not defined.
205 u.defineFunctionsInOrder(u.undefinedFuncs)
206
207 // Set initializers for globals.
208 for global, init := range u.globalInits {
209 initval := init.build(global.Type().ElementType())
210 global.SetInitializer(initval)
211 }
212}
213
214func (u *unit) addGlobal(global llvm.Value, ty types.Type) {
215 u.globalInits[global] = new(globalInit)
216
217 if hasPointers(ty) {
218 global = llvm.ConstBitCast(global, llvm.PointerType(llvm.Int8Type(), 0))
219 size := llvm.ConstInt(u.types.inttype, uint64(u.types.Sizeof(ty)), false)
220 root := llvm.ConstStruct([]llvm.Value{global, size}, false)
221 u.gcRoots = append(u.gcRoots, root)
222 }
223}
224
225// ResolveMethod implements MethodResolver.ResolveMethod.
226func (u *unit) ResolveMethod(s *types.Selection) *govalue {
227 m := u.pkg.Prog.Method(s)
228 llfn := u.resolveFunctionGlobal(m)
229 llfn = llvm.ConstBitCast(llfn, llvm.PointerType(llvm.Int8Type(), 0))
230 return newValue(llfn, m.Signature)
231}
232
233// resolveFunctionDescriptorGlobal returns a reference to the LLVM global
234// storing the function's descriptor.
235func (u *unit) resolveFunctionDescriptorGlobal(f *ssa.Function) llvm.Value {
236 llfd, ok := u.funcDescriptors[f]
237 if !ok {
238 name := u.types.mc.mangleFunctionName(f) + "$descriptor"
239 llfd = llvm.AddGlobal(u.module.Module, llvm.PointerType(llvm.Int8Type(), 0), name)
240 llfd.SetGlobalConstant(true)
241 u.funcDescriptors[f] = llfd
242 }
243 return llfd
244}
245
246// resolveFunctionDescriptor returns a function's
247// first-class value representation.
248func (u *unit) resolveFunctionDescriptor(f *ssa.Function) *govalue {
249 llfd := u.resolveFunctionDescriptorGlobal(f)
250 llfd = llvm.ConstBitCast(llfd, llvm.PointerType(llvm.Int8Type(), 0))
251 return newValue(llfd, f.Signature)
252}
253
254// resolveFunctionGlobal returns an llvm.Value for a function global.
255func (u *unit) resolveFunctionGlobal(f *ssa.Function) llvm.Value {
256 if v, ok := u.globals[f]; ok {
257 return v
258 }
259 name := u.types.mc.mangleFunctionName(f)
260 // It's possible that the function already exists in the module;
261 // for example, if it's a runtime intrinsic that the compiler
262 // has already referenced.
263 llvmFunction := u.module.Module.NamedFunction(name)
264 if llvmFunction.IsNil() {
265 fti := u.llvmtypes.getSignatureInfo(f.Signature)
266 llvmFunction = fti.declare(u.module.Module, name)
267 u.undefinedFuncs[f] = true
268 }
269 u.globals[f] = llvmFunction
270 return llvmFunction
271}
272
273func (u *unit) getFunctionLinkage(f *ssa.Function) llvm.Linkage {
274 switch {
275 case f.Pkg == nil:
276 // Synthetic functions outside packages may appear in multiple packages.
277 return llvm.LinkOnceODRLinkage
278
279 case f.Parent() != nil:
280 // Anonymous.
281 return llvm.InternalLinkage
282
283 case f.Signature.Recv() == nil && !ast.IsExported(f.Name()) &&
284 !(f.Name() == "main" && f.Pkg.Object.Path() == "main") &&
285 f.Name() != "init":
286 // Unexported methods may be referenced as part of an interface method
287 // table in another package. TODO(pcc): detect when this cannot happen.
288 return llvm.InternalLinkage
289
290 default:
291 return llvm.ExternalLinkage
292 }
293}
294
295func (u *unit) defineFunction(f *ssa.Function) {
296 // Only define functions from this package, or synthetic
297 // wrappers (which do not have a package).
298 if f.Pkg != nil && f.Pkg != u.pkg {
299 return
300 }
301
302 llfn := u.resolveFunctionGlobal(f)
303 linkage := u.getFunctionLinkage(f)
304
305 isMethod := f.Signature.Recv() != nil
306
307 // Methods cannot be referred to via a descriptor.
308 if !isMethod {
309 llfd := u.resolveFunctionDescriptorGlobal(f)
310 llfd.SetInitializer(llvm.ConstBitCast(llfn, llvm.PointerType(llvm.Int8Type(), 0)))
311 llfd.SetLinkage(linkage)
312 }
313
314 // We only need to emit a descriptor for functions without bodies.
315 if len(f.Blocks) == 0 {
316 return
317 }
318
319 ssaopt.LowerAllocsToStack(f)
320
321 if u.DumpSSA {
322 f.WriteTo(os.Stderr)
323 }
324
325 fr := newFrame(u, llfn)
326 defer fr.dispose()
327 fr.addCommonFunctionAttrs(fr.function)
328 fr.function.SetLinkage(linkage)
329
330 fr.logf("Define function: %s", f.String())
331 fti := u.llvmtypes.getSignatureInfo(f.Signature)
332 delete(u.undefinedFuncs, f)
333 fr.retInf = fti.retInf
334
335 // Push the compile unit and function onto the debug context.
336 if u.GenerateDebug {
337 u.debug.PushFunction(fr.function, f.Signature, f.Pos())
338 defer u.debug.PopFunction()
339 u.debug.SetLocation(fr.builder, f.Pos())
340 }
341
342 // If a function calls recover, we create a separate function to
343 // hold the real function, and this function calls __go_can_recover
344 // and bridges to it.
345 if callsRecover(f) {
346 fr = fr.bridgeRecoverFunc(fr.function, fti)
347 }
348
349 fr.blocks = make([]llvm.BasicBlock, len(f.Blocks))
350 fr.lastBlocks = make([]llvm.BasicBlock, len(f.Blocks))
351 for i, block := range f.Blocks {
352 fr.blocks[i] = llvm.AddBasicBlock(fr.function, fmt.Sprintf(".%d.%s", i, block.Comment))
353 }
354 fr.builder.SetInsertPointAtEnd(fr.blocks[0])
Andrew Wilkinsf3718a92015-01-08 07:49:28 +0000[diff] [blame^]355 fr.transformSwitches(f)
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]356
357 prologueBlock := llvm.InsertBasicBlock(fr.blocks[0], "prologue")
358 fr.builder.SetInsertPointAtEnd(prologueBlock)
359
360 // Map parameter positions to indices. We use this
361 // when processing locals to map back to parameters
362 // when generating debug metadata.
363 paramPos := make(map[token.Pos]int)
364 for i, param := range f.Params {
365 paramPos[param.Pos()] = i
366 llparam := fti.argInfos[i].decode(llvm.GlobalContext(), fr.builder, fr.builder)
367 if isMethod && i == 0 {
368 if _, ok := param.Type().Underlying().(*types.Pointer); !ok {
369 llparam = fr.builder.CreateBitCast(llparam, llvm.PointerType(fr.types.ToLLVM(param.Type()), 0), "")
370 llparam = fr.builder.CreateLoad(llparam, "")
371 }
372 }
373 fr.env[param] = newValue(llparam, param.Type())
374 }
375
376 // Load closure, extract free vars.
377 if len(f.FreeVars) > 0 {
378 for _, fv := range f.FreeVars {
379 fr.env[fv] = newValue(llvm.ConstNull(u.llvmtypes.ToLLVM(fv.Type())), fv.Type())
380 }
381 elemTypes := make([]llvm.Type, len(f.FreeVars)+1)
382 elemTypes[0] = llvm.PointerType(llvm.Int8Type(), 0) // function pointer
383 for i, fv := range f.FreeVars {
384 elemTypes[i+1] = u.llvmtypes.ToLLVM(fv.Type())
385 }
386 structType := llvm.StructType(elemTypes, false)
387 closure := fr.runtime.getClosure.call(fr)[0]
388 closure = fr.builder.CreateBitCast(closure, llvm.PointerType(structType, 0), "")
389 for i, fv := range f.FreeVars {
390 ptr := fr.builder.CreateStructGEP(closure, i+1, "")
391 ptr = fr.builder.CreateLoad(ptr, "")
392 fr.env[fv] = newValue(ptr, fv.Type())
393 }
394 }
395
396 // Allocate stack space for locals in the prologue block.
397 for _, local := range f.Locals {
398 typ := fr.llvmtypes.ToLLVM(deref(local.Type()))
399 alloca := fr.builder.CreateAlloca(typ, local.Comment)
400 fr.memsetZero(alloca, llvm.SizeOf(typ))
401 bcalloca := fr.builder.CreateBitCast(alloca, llvm.PointerType(llvm.Int8Type(), 0), "")
402 value := newValue(bcalloca, local.Type())
403 fr.env[local] = value
404 if fr.GenerateDebug {
405 paramIndex, ok := paramPos[local.Pos()]
406 if !ok {
407 paramIndex = -1
408 }
409 fr.debug.Declare(fr.builder, local, alloca, paramIndex)
410 }
411 }
412
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]413 // If the function contains any defers, we must first create
414 // an unwind block. We can short-circuit the check for defers with
415 // f.Recover != nil.
416 if f.Recover != nil || hasDefer(f) {
417 fr.unwindBlock = llvm.AddBasicBlock(fr.function, "")
418 fr.frameptr = fr.builder.CreateAlloca(llvm.Int8Type(), "")
419 }
420
Peter Collingbourned34d92f2014-12-31 00:25:39 +0000[diff] [blame]421 // Keep track of the block into which we need to insert the call
422 // to __go_register_gc_roots. This needs to be inserted after the
423 // init guard check under the llgo ABI.
424 var registerGcBlock llvm.BasicBlock
425
426 // If this is the "init" function, emit the init guard check and
427 // enable init-specific optimizations.
428 if !isMethod && f.Name() == "init" {
429 registerGcBlock = fr.emitInitPrologue()
430 fr.isInit = true
431 }
432
433 fr.builder.CreateBr(fr.blocks[0])
434 fr.allocaBuilder.SetInsertPointBefore(prologueBlock.FirstInstruction())
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]435
436 for _, block := range f.DomPreorder() {
Andrew Wilkinsf3718a92015-01-08 07:49:28 +0000[diff] [blame^]437 llblock := fr.blocks[block.Index]
438 if llblock.IsNil() {
439 continue
440 }
441 fr.translateBlock(block, llblock)
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]442 }
443
444 fr.fixupPhis()
445
446 if !fr.unwindBlock.IsNil() {
447 fr.setupUnwindBlock(f.Recover, f.Signature.Results())
448 }
449
450 // The init function needs to register the GC roots first. We do this
451 // after generating code for it because allocations may have caused
452 // additional GC roots to be created.
453 if fr.isInit {
Peter Collingbourned34d92f2014-12-31 00:25:39 +0000[diff] [blame]454 fr.builder.SetInsertPointBefore(registerGcBlock.FirstInstruction())
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]455 fr.registerGcRoots()
456 }
457}
458
459type pendingPhi struct {
460 ssa *ssa.Phi
461 llvm llvm.Value
462}
463
464type frame struct {
465 *unit
466 function llvm.Value
467 builder, allocaBuilder llvm.Builder
468 retInf retInfo
469 blocks []llvm.BasicBlock
470 lastBlocks []llvm.BasicBlock
471 runtimeErrorBlocks [gccgoRuntimeErrorCount]llvm.BasicBlock
472 unwindBlock llvm.BasicBlock
473 frameptr llvm.Value
474 env map[ssa.Value]*govalue
475 ptr map[ssa.Value]llvm.Value
476 tuples map[ssa.Value][]*govalue
477 phis []pendingPhi
478 canRecover llvm.Value
479 isInit bool
480}
481
482func newFrame(u *unit, fn llvm.Value) *frame {
483 return &frame{
484 unit: u,
485 function: fn,
486 builder: llvm.GlobalContext().NewBuilder(),
487 allocaBuilder: llvm.GlobalContext().NewBuilder(),
488 env: make(map[ssa.Value]*govalue),
489 ptr: make(map[ssa.Value]llvm.Value),
490 tuples: make(map[ssa.Value][]*govalue),
491 }
492}
493
494func (fr *frame) dispose() {
495 fr.builder.Dispose()
496 fr.allocaBuilder.Dispose()
497}
498
Peter Collingbourned34d92f2014-12-31 00:25:39 +0000[diff] [blame]499// emitInitPrologue emits the init-specific function prologue (guard check and
500// initialization of dependent packages under the llgo native ABI), and returns
501// the basic block into which the GC registration call should be emitted.
502func (fr *frame) emitInitPrologue() llvm.BasicBlock {
503 if fr.GccgoABI {
504 return fr.builder.GetInsertBlock()
505 }
506
507 initGuard := llvm.AddGlobal(fr.module.Module, llvm.Int1Type(), "init$guard")
508 initGuard.SetLinkage(llvm.InternalLinkage)
509 initGuard.SetInitializer(llvm.ConstNull(llvm.Int1Type()))
510
511 returnBlock := llvm.AddBasicBlock(fr.function, "")
512 initBlock := llvm.AddBasicBlock(fr.function, "")
513
514 initGuardVal := fr.builder.CreateLoad(initGuard, "")
515 fr.builder.CreateCondBr(initGuardVal, returnBlock, initBlock)
516
517 fr.builder.SetInsertPointAtEnd(returnBlock)
518 fr.builder.CreateRetVoid()
519
520 fr.builder.SetInsertPointAtEnd(initBlock)
521 fr.builder.CreateStore(llvm.ConstInt(llvm.Int1Type(), 1, false), initGuard)
522 ftyp := llvm.FunctionType(llvm.VoidType(), nil, false)
523 for _, pkg := range fr.pkg.Object.Imports() {
524 initname := ManglePackagePath(pkg.Path()) + "..import"
525 initfn := fr.module.Module.NamedFunction(initname)
526 if initfn.IsNil() {
527 initfn = llvm.AddFunction(fr.module.Module, initname, ftyp)
528 }
529 fr.builder.CreateCall(initfn, nil, "")
530 }
531
532 return initBlock
533}
534
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]535// bridgeRecoverFunc creates a function that may call recover(), and creates
536// a call to it from the current frame. The created function will be called
537// with a boolean parameter that indicates whether it may call recover().
538//
539// The created function will have the same name as the current frame's function
540// with "$recover" appended, having the same return types and parameters with
541// an additional boolean parameter appended.
542//
543// A new frame will be returned for the newly created function.
544func (fr *frame) bridgeRecoverFunc(llfn llvm.Value, fti functionTypeInfo) *frame {
545 // The bridging function must not be inlined, or the return address
546 // may not correspond to the source function.
547 llfn.AddFunctionAttr(llvm.NoInlineAttribute)
548
549 // Call __go_can_recover, passing in the function's return address.
550 entry := llvm.AddBasicBlock(llfn, "entry")
551 fr.builder.SetInsertPointAtEnd(entry)
552 canRecover := fr.runtime.canRecover.call(fr, fr.returnAddress(0))[0]
553 returnType := fti.functionType.ReturnType()
554 argTypes := fti.functionType.ParamTypes()
555 argTypes = append(argTypes, canRecover.Type())
556
557 // Create and call the $recover function.
558 ftiRecover := fti
559 ftiRecover.functionType = llvm.FunctionType(returnType, argTypes, false)
560 llfnRecover := ftiRecover.declare(fr.module.Module, llfn.Name()+"$recover")
561 fr.addCommonFunctionAttrs(llfnRecover)
562 llfnRecover.SetLinkage(llvm.InternalLinkage)
563 args := make([]llvm.Value, len(argTypes)-1, len(argTypes))
564 for i := range args {
565 args[i] = llfn.Param(i)
566 }
567 args = append(args, canRecover)
568 result := fr.builder.CreateCall(llfnRecover, args, "")
569 if returnType.TypeKind() == llvm.VoidTypeKind {
570 fr.builder.CreateRetVoid()
571 } else {
572 fr.builder.CreateRet(result)
573 }
574
575 // The $recover function must condition calls to __go_recover on
576 // the result of __go_can_recover passed in as an argument.
577 fr = newFrame(fr.unit, llfnRecover)
578 fr.retInf = ftiRecover.retInf
579 fr.canRecover = fr.function.Param(len(argTypes) - 1)
580 return fr
581}
582
583func (fr *frame) registerGcRoots() {
584 if len(fr.gcRoots) != 0 {
585 rootty := fr.gcRoots[0].Type()
586 roots := append(fr.gcRoots, llvm.ConstNull(rootty))
587 rootsarr := llvm.ConstArray(rootty, roots)
588 rootsstruct := llvm.ConstStruct([]llvm.Value{llvm.ConstNull(llvm.PointerType(llvm.Int8Type(), 0)), rootsarr}, false)
589
590 rootsglobal := llvm.AddGlobal(fr.module.Module, rootsstruct.Type(), "")
591 rootsglobal.SetInitializer(rootsstruct)
592 rootsglobal.SetLinkage(llvm.InternalLinkage)
593 fr.runtime.registerGcRoots.callOnly(fr, llvm.ConstBitCast(rootsglobal, llvm.PointerType(llvm.Int8Type(), 0)))
594 }
595}
596
597func (fr *frame) fixupPhis() {
598 for _, phi := range fr.phis {
599 values := make([]llvm.Value, len(phi.ssa.Edges))
600 blocks := make([]llvm.BasicBlock, len(phi.ssa.Edges))
601 block := phi.ssa.Block()
602 for i, edge := range phi.ssa.Edges {
603 values[i] = fr.llvmvalue(edge)
604 blocks[i] = fr.lastBlock(block.Preds[i])
605 }
606 phi.llvm.AddIncoming(values, blocks)
607 }
608}
609
610func (fr *frame) createLandingPad(cleanup bool) llvm.Value {
611 lp := fr.builder.CreateLandingPad(fr.runtime.gccgoExceptionType, fr.runtime.gccgoPersonality, 0, "")
612 if cleanup {
613 lp.SetCleanup(true)
614 } else {
615 lp.AddClause(llvm.ConstNull(llvm.PointerType(llvm.Int8Type(), 0)))
616 }
617 return lp
618}
619
620// Runs defers. If a defer panics, check for recovers in later defers.
621func (fr *frame) runDefers() {
622 loopbb := llvm.AddBasicBlock(fr.function, "")
623 fr.builder.CreateBr(loopbb)
624
625 retrylpad := llvm.AddBasicBlock(fr.function, "")
626 fr.builder.SetInsertPointAtEnd(retrylpad)
627 fr.createLandingPad(false)
628 fr.runtime.checkDefer.callOnly(fr, fr.frameptr)
629 fr.builder.CreateBr(loopbb)
630
631 fr.builder.SetInsertPointAtEnd(loopbb)
632 fr.runtime.undefer.invoke(fr, retrylpad, fr.frameptr)
633}
634
635func (fr *frame) setupUnwindBlock(rec *ssa.BasicBlock, results *types.Tuple) {
636 recoverbb := llvm.AddBasicBlock(fr.function, "")
637 if rec != nil {
638 fr.translateBlock(rec, recoverbb)
639 } else if results.Len() == 0 || results.At(0).Anonymous() {
640 // TODO(pcc): Remove this code after https://codereview.appspot.com/87210044/ lands
641 fr.builder.SetInsertPointAtEnd(recoverbb)
642 values := make([]llvm.Value, results.Len())
643 for i := range values {
644 values[i] = llvm.ConstNull(fr.llvmtypes.ToLLVM(results.At(i).Type()))
645 }
646 fr.retInf.encode(llvm.GlobalContext(), fr.allocaBuilder, fr.builder, values)
647 } else {
648 fr.builder.SetInsertPointAtEnd(recoverbb)
649 fr.builder.CreateUnreachable()
650 }
651
652 checkunwindbb := llvm.AddBasicBlock(fr.function, "")
653 fr.builder.SetInsertPointAtEnd(checkunwindbb)
654 exc := fr.createLandingPad(true)
655 fr.runDefers()
656
657 frame := fr.builder.CreateLoad(fr.frameptr, "")
658 shouldresume := fr.builder.CreateIsNull(frame, "")
659
660 resumebb := llvm.AddBasicBlock(fr.function, "")
661 fr.builder.CreateCondBr(shouldresume, resumebb, recoverbb)
662
663 fr.builder.SetInsertPointAtEnd(resumebb)
664 fr.builder.CreateResume(exc)
665
666 fr.builder.SetInsertPointAtEnd(fr.unwindBlock)
667 fr.createLandingPad(false)
668 fr.runtime.checkDefer.invoke(fr, checkunwindbb, fr.frameptr)
669 fr.runDefers()
670 fr.builder.CreateBr(recoverbb)
671}
672
673func (fr *frame) translateBlock(b *ssa.BasicBlock, llb llvm.BasicBlock) {
674 fr.builder.SetInsertPointAtEnd(llb)
675 for _, instr := range b.Instrs {
676 fr.instruction(instr)
677 }
678 fr.lastBlocks[b.Index] = fr.builder.GetInsertBlock()
679}
680
681func (fr *frame) block(b *ssa.BasicBlock) llvm.BasicBlock {
682 return fr.blocks[b.Index]
683}
684
685func (fr *frame) lastBlock(b *ssa.BasicBlock) llvm.BasicBlock {
686 return fr.lastBlocks[b.Index]
687}
688
689func (fr *frame) value(v ssa.Value) (result *govalue) {
690 switch v := v.(type) {
691 case nil:
692 return nil
693 case *ssa.Function:
694 return fr.resolveFunctionDescriptor(v)
695 case *ssa.Const:
696 return fr.newValueFromConst(v.Value, v.Type())
697 case *ssa.Global:
698 if g, ok := fr.globals[v]; ok {
699 return newValue(g, v.Type())
700 }
701 // Create an external global. Globals for this package are defined
702 // on entry to translatePackage, and have initialisers.
703 llelemtyp := fr.llvmtypes.ToLLVM(deref(v.Type()))
704 vname := fr.types.mc.mangleGlobalName(v)
705 llglobal := llvm.AddGlobal(fr.module.Module, llelemtyp, vname)
706 llglobal = llvm.ConstBitCast(llglobal, fr.llvmtypes.ToLLVM(v.Type()))
707 fr.globals[v] = llglobal
708 return newValue(llglobal, v.Type())
709 }
710 if value, ok := fr.env[v]; ok {
711 return value
712 }
713
Peter Collingbourne1f89ffd2014-12-17 09:45:05 +0000[diff] [blame]714 panic(fmt.Errorf("Instruction %q not visited yet", v.Name()))
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]715}
716
717func (fr *frame) llvmvalue(v ssa.Value) llvm.Value {
718 if gv := fr.value(v); gv != nil {
719 return gv.value
720 } else {
721 return llvm.Value{nil}
722 }
723}
724
725func (fr *frame) isNonNull(v ssa.Value) bool {
726 switch v.(type) {
727 case
728 // Globals have a fixed (non-nil) address.
729 *ssa.Global,
730 // The language does not specify what happens if an allocation fails.
731 *ssa.Alloc,
732 // These have already been nil checked.
733 *ssa.FieldAddr, *ssa.IndexAddr:
734 return true
735 default:
736 return false
737 }
738}
739
740func (fr *frame) nilCheck(v ssa.Value, llptr llvm.Value) {
741 if !fr.isNonNull(v) {
742 ptrnull := fr.builder.CreateIsNull(llptr, "")
743 fr.condBrRuntimeError(ptrnull, gccgoRuntimeErrorNIL_DEREFERENCE)
744 }
745}
746
Peter Collingbourne1f89ffd2014-12-17 09:45:05 +0000[diff] [blame]747func (fr *frame) canAvoidElementLoad(ptr ssa.Value) bool {
748 for _, ref := range *ptr.Referrers() {
749 switch ref := ref.(type) {
750 case *ssa.Field:
751 case *ssa.Index:
752 if ref.X != ptr {
753 return false
754 }
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]755 // ok
756 default:
757 return false
758 }
759 }
760
761 return true
762}
763
764// If this value is sufficiently large, look through referrers to see if we can
765// avoid a load.
766func (fr *frame) canAvoidLoad(instr *ssa.UnOp, op llvm.Value) bool {
Peter Collingbourne1f89ffd2014-12-17 09:45:05 +0000[diff] [blame]767 if fr.types.Sizeof(instr.Type()) < 2*fr.types.Sizeof(types.Typ[types.Int]) {
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]768 // Don't bother with small values.
769 return false
770 }
771
772 // Keep track of whether our pointer may escape. We conservatively assume
773 // that MakeInterfaces will escape.
774 esc := false
775
776 // We only know how to avoid loads if they are used to create an interface
777 // or read an element of the structure. If we see any other referrer, abort.
778 for _, ref := range *instr.Referrers() {
Peter Collingbourne1f89ffd2014-12-17 09:45:05 +0000[diff] [blame]779 switch ref := ref.(type) {
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]780 case *ssa.MakeInterface:
781 esc = true
Peter Collingbourne1f89ffd2014-12-17 09:45:05 +0000[diff] [blame]782 case *ssa.Field:
783 case *ssa.Index:
784 if ref.X != instr {
785 // This should never happen, as indices are always of type int
786 // and we don't bother with values smaller than 2*sizeof(int).
787 panic("impossible")
788 }
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]789 // ok
790 default:
791 return false
792 }
793 }
794
795 var opcopy llvm.Value
796 if esc {
797 opcopy = fr.createTypeMalloc(instr.Type())
798 } else {
799 opcopy = fr.allocaBuilder.CreateAlloca(fr.types.ToLLVM(instr.Type()), "")
800 }
801 fr.memcpy(opcopy, op, llvm.ConstInt(fr.types.inttype, uint64(fr.types.Sizeof(instr.Type())), false))
802
803 fr.ptr[instr] = opcopy
804 return true
805}
806
807// Return true iff we think it might be beneficial to turn this alloc instruction
808// into a statically allocated global.
809// Precondition: we are compiling the init function.
810func (fr *frame) shouldStaticallyAllocate(alloc *ssa.Alloc) bool {
811 // First, see if the allocated type is an array or struct, and if so determine
812 // the number of elements in the type. If the type is anything else, we
813 // statically allocate unconditionally.
814 var numElems int64
815 switch ty := deref(alloc.Type()).Underlying().(type) {
816 case *types.Array:
817 numElems = ty.Len()
818 case *types.Struct:
819 numElems = int64(ty.NumFields())
820 default:
821 return true
822 }
823
824 // We treat the number of referrers to the alloc instruction as a rough
825 // proxy for the number of elements initialized. If the data structure
826 // is densely initialized (> 1/4 elements initialized), enable the
827 // optimization.
828 return int64(len(*alloc.Referrers()))*4 > numElems
829}
830
831// If val is a constant and addr refers to a global variable which is defined in
832// this module or an element thereof, simulate the effect of storing val at addr
833// in the global variable's initializer and return true, otherwise return false.
834// Precondition: we are compiling the init function.
835func (fr *frame) maybeStoreInInitializer(val, addr llvm.Value) bool {
836 if val.IsAConstant().IsNil() {
837 return false
838 }
839
840 if !addr.IsAConstantExpr().IsNil() && addr.OperandsCount() >= 2 &&
841 // TODO(pcc): Explicitly check that this is a constant GEP.
842 // I don't think there are any other kinds of constantexpr which
843 // satisfy the conditions we test for here, so this is probably safe.
844 !addr.Operand(0).IsAGlobalVariable().IsNil() &&
845 addr.Operand(1).IsNull() {
846 gv := addr.Operand(0)
847 globalInit, ok := fr.globalInits[gv]
848 if !ok {
849 return false
850 }
851 indices := make([]uint32, addr.OperandsCount()-2)
852 for i := range indices {
853 op := addr.Operand(i + 2)
854 if op.IsAConstantInt().IsNil() {
855 return false
856 }
857 indices[i] = uint32(op.ZExtValue())
858 }
859 globalInit.update(gv.Type().ElementType(), indices, val)
860 return true
861 } else if !addr.IsAGlobalVariable().IsNil() {
862 if globalInit, ok := fr.globalInits[addr]; ok {
863 globalInit.update(addr.Type().ElementType(), nil, val)
864 return true
865 }
866 return false
867 } else {
868 return false
869 }
870}
871
872func (fr *frame) instruction(instr ssa.Instruction) {
873 fr.logf("[%T] %v @ %s\n", instr, instr, fr.pkg.Prog.Fset.Position(instr.Pos()))
874 if fr.GenerateDebug {
875 fr.debug.SetLocation(fr.builder, instr.Pos())
876 }
877
878 switch instr := instr.(type) {
879 case *ssa.Alloc:
880 typ := deref(instr.Type())
881 llvmtyp := fr.llvmtypes.ToLLVM(typ)
882 var value llvm.Value
883 if !instr.Heap {
884 value = fr.env[instr].value
885 fr.memsetZero(value, llvm.SizeOf(llvmtyp))
886 } else if fr.isInit && fr.shouldStaticallyAllocate(instr) {
887 // If this is the init function and we think it may be beneficial,
888 // allocate memory statically in the object file rather than on the
889 // heap. This allows us to optimize constant stores into such
890 // variables as static initializations.
891 global := llvm.AddGlobal(fr.module.Module, llvmtyp, "")
892 global.SetLinkage(llvm.InternalLinkage)
893 fr.addGlobal(global, typ)
894 ptr := llvm.ConstBitCast(global, llvm.PointerType(llvm.Int8Type(), 0))
895 fr.env[instr] = newValue(ptr, instr.Type())
896 } else {
897 value = fr.createTypeMalloc(typ)
898 value.SetName(instr.Comment)
899 value = fr.builder.CreateBitCast(value, llvm.PointerType(llvm.Int8Type(), 0), "")
900 fr.env[instr] = newValue(value, instr.Type())
901 }
902
903 case *ssa.BinOp:
904 lhs, rhs := fr.value(instr.X), fr.value(instr.Y)
905 fr.env[instr] = fr.binaryOp(lhs, instr.Op, rhs)
906
907 case *ssa.Call:
908 tuple := fr.callInstruction(instr)
909 if len(tuple) == 1 {
910 fr.env[instr] = tuple[0]
911 } else {
912 fr.tuples[instr] = tuple
913 }
914
915 case *ssa.ChangeInterface:
916 x := fr.value(instr.X)
917 // The source type must be a non-empty interface,
918 // as ChangeInterface cannot fail (E2I may fail).
919 if instr.Type().Underlying().(*types.Interface).NumMethods() > 0 {
920 x = fr.changeInterface(x, instr.Type(), false)
921 } else {
922 x = fr.convertI2E(x)
923 }
924 fr.env[instr] = x
925
926 case *ssa.ChangeType:
927 value := fr.llvmvalue(instr.X)
928 if _, ok := instr.Type().Underlying().(*types.Pointer); ok {
929 value = fr.builder.CreateBitCast(value, fr.llvmtypes.ToLLVM(instr.Type()), "")
930 }
931 fr.env[instr] = newValue(value, instr.Type())
932
933 case *ssa.Convert:
934 v := fr.value(instr.X)
935 fr.env[instr] = fr.convert(v, instr.Type())
936
937 case *ssa.Defer:
938 fn, arg := fr.createThunk(instr)
939 fr.runtime.Defer.call(fr, fr.frameptr, fn, arg)
940
941 case *ssa.Extract:
942 var elem llvm.Value
943 if t, ok := fr.tuples[instr.Tuple]; ok {
944 elem = t[instr.Index].value
945 } else {
946 tuple := fr.llvmvalue(instr.Tuple)
947 elem = fr.builder.CreateExtractValue(tuple, instr.Index, instr.Name())
948 }
949 elemtyp := instr.Type()
950 fr.env[instr] = newValue(elem, elemtyp)
951
952 case *ssa.Field:
953 fieldtyp := instr.Type()
954 if p, ok := fr.ptr[instr.X]; ok {
955 field := fr.builder.CreateStructGEP(p, instr.Field, instr.Name())
Peter Collingbourne1f89ffd2014-12-17 09:45:05 +0000[diff] [blame]956 if fr.canAvoidElementLoad(instr) {
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]957 fr.ptr[instr] = field
958 } else {
959 fr.env[instr] = newValue(fr.builder.CreateLoad(field, ""), fieldtyp)
960 }
961 } else {
962 value := fr.llvmvalue(instr.X)
963 field := fr.builder.CreateExtractValue(value, instr.Field, instr.Name())
964 fr.env[instr] = newValue(field, fieldtyp)
965 }
966
967 case *ssa.FieldAddr:
968 ptr := fr.llvmvalue(instr.X)
969 fr.nilCheck(instr.X, ptr)
970 xtyp := instr.X.Type().Underlying().(*types.Pointer).Elem()
971 ptrtyp := llvm.PointerType(fr.llvmtypes.ToLLVM(xtyp), 0)
972 ptr = fr.builder.CreateBitCast(ptr, ptrtyp, "")
973 fieldptr := fr.builder.CreateStructGEP(ptr, instr.Field, instr.Name())
974 fieldptr = fr.builder.CreateBitCast(fieldptr, llvm.PointerType(llvm.Int8Type(), 0), "")
975 fieldptrtyp := instr.Type()
976 fr.env[instr] = newValue(fieldptr, fieldptrtyp)
977
978 case *ssa.Go:
979 fn, arg := fr.createThunk(instr)
980 fr.runtime.Go.call(fr, fn, arg)
981
982 case *ssa.If:
983 cond := fr.llvmvalue(instr.Cond)
984 block := instr.Block()
985 trueBlock := fr.block(block.Succs[0])
986 falseBlock := fr.block(block.Succs[1])
987 cond = fr.builder.CreateTrunc(cond, llvm.Int1Type(), "")
988 fr.builder.CreateCondBr(cond, trueBlock, falseBlock)
989
990 case *ssa.Index:
991 var arrayptr llvm.Value
992
993 if ptr, ok := fr.ptr[instr.X]; ok {
994 arrayptr = ptr
995 } else {
996 array := fr.llvmvalue(instr.X)
997 arrayptr = fr.allocaBuilder.CreateAlloca(array.Type(), "")
998
999 fr.builder.CreateStore(array, arrayptr)
1000 }
1001 index := fr.llvmvalue(instr.Index)
1002
1003 arraytyp := instr.X.Type().Underlying().(*types.Array)
1004 arraylen := llvm.ConstInt(fr.llvmtypes.inttype, uint64(arraytyp.Len()), false)
1005
1006 // The index may not have been promoted to int (for example, if it
1007 // came from a composite literal).
1008 index = fr.createZExtOrTrunc(index, fr.types.inttype, "")
1009
1010 // Bounds checking: 0 <= index < len
1011 zero := llvm.ConstNull(fr.types.inttype)
1012 i0 := fr.builder.CreateICmp(llvm.IntSLT, index, zero, "")
1013 li := fr.builder.CreateICmp(llvm.IntSLE, arraylen, index, "")
1014
1015 cond := fr.builder.CreateOr(i0, li, "")
1016
1017 fr.condBrRuntimeError(cond, gccgoRuntimeErrorARRAY_INDEX_OUT_OF_BOUNDS)
1018
1019 addr := fr.builder.CreateGEP(arrayptr, []llvm.Value{zero, index}, "")
Peter Collingbourne1f89ffd2014-12-17 09:45:05 +0000[diff] [blame]1020 if fr.canAvoidElementLoad(instr) {
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]1021 fr.ptr[instr] = addr
1022 } else {
1023 fr.env[instr] = newValue(fr.builder.CreateLoad(addr, ""), instr.Type())
1024 }
1025
1026 case *ssa.IndexAddr:
1027 x := fr.llvmvalue(instr.X)
1028 index := fr.llvmvalue(instr.Index)
1029 var arrayptr, arraylen llvm.Value
1030 var elemtyp types.Type
1031 var errcode uint64
1032 switch typ := instr.X.Type().Underlying().(type) {
1033 case *types.Slice:
1034 elemtyp = typ.Elem()
1035 arrayptr = fr.builder.CreateExtractValue(x, 0, "")
1036 arraylen = fr.builder.CreateExtractValue(x, 1, "")
1037 errcode = gccgoRuntimeErrorSLICE_INDEX_OUT_OF_BOUNDS
1038 case *types.Pointer: // *array
1039 arraytyp := typ.Elem().Underlying().(*types.Array)
1040 elemtyp = arraytyp.Elem()
1041 fr.nilCheck(instr.X, x)
1042 arrayptr = x
1043 arraylen = llvm.ConstInt(fr.llvmtypes.inttype, uint64(arraytyp.Len()), false)
1044 errcode = gccgoRuntimeErrorARRAY_INDEX_OUT_OF_BOUNDS
1045 }
1046
1047 // The index may not have been promoted to int (for example, if it
1048 // came from a composite literal).
1049 index = fr.createZExtOrTrunc(index, fr.types.inttype, "")
1050
1051 // Bounds checking: 0 <= index < len
1052 zero := llvm.ConstNull(fr.types.inttype)
1053 i0 := fr.builder.CreateICmp(llvm.IntSLT, index, zero, "")
1054 li := fr.builder.CreateICmp(llvm.IntSLE, arraylen, index, "")
1055
1056 cond := fr.builder.CreateOr(i0, li, "")
1057
1058 fr.condBrRuntimeError(cond, errcode)
1059
1060 ptrtyp := llvm.PointerType(fr.llvmtypes.ToLLVM(elemtyp), 0)
1061 arrayptr = fr.builder.CreateBitCast(arrayptr, ptrtyp, "")
1062 addr := fr.builder.CreateGEP(arrayptr, []llvm.Value{index}, "")
1063 addr = fr.builder.CreateBitCast(addr, llvm.PointerType(llvm.Int8Type(), 0), "")
1064 fr.env[instr] = newValue(addr, types.NewPointer(elemtyp))
1065
1066 case *ssa.Jump:
1067 succ := instr.Block().Succs[0]
1068 fr.builder.CreateBr(fr.block(succ))
1069
1070 case *ssa.Lookup:
1071 x := fr.value(instr.X)
1072 index := fr.value(instr.Index)
1073 if isString(x.Type().Underlying()) {
1074 fr.env[instr] = fr.stringIndex(x, index)
1075 } else {
1076 v, ok := fr.mapLookup(x, index)
1077 if instr.CommaOk {
1078 fr.tuples[instr] = []*govalue{v, ok}
1079 } else {
1080 fr.env[instr] = v
1081 }
1082 }
1083
1084 case *ssa.MakeChan:
1085 fr.env[instr] = fr.makeChan(instr.Type(), fr.value(instr.Size))
1086
1087 case *ssa.MakeClosure:
1088 llfn := fr.resolveFunctionGlobal(instr.Fn.(*ssa.Function))
1089 llfn = llvm.ConstBitCast(llfn, llvm.PointerType(llvm.Int8Type(), 0))
1090 fn := newValue(llfn, instr.Fn.(*ssa.Function).Signature)
1091 bindings := make([]*govalue, len(instr.Bindings))
1092 for i, binding := range instr.Bindings {
1093 bindings[i] = fr.value(binding)
1094 }
1095 fr.env[instr] = fr.makeClosure(fn, bindings)
1096
1097 case *ssa.MakeInterface:
1098 // fr.ptr[instr.X] will be set if a pointer load was elided by canAvoidLoad
1099 if ptr, ok := fr.ptr[instr.X]; ok {
1100 fr.env[instr] = fr.makeInterfaceFromPointer(ptr, instr.X.Type(), instr.Type())
1101 } else {
1102 receiver := fr.llvmvalue(instr.X)
1103 fr.env[instr] = fr.makeInterface(receiver, instr.X.Type(), instr.Type())
1104 }
1105
1106 case *ssa.MakeMap:
1107 fr.env[instr] = fr.makeMap(instr.Type(), fr.value(instr.Reserve))
1108
1109 case *ssa.MakeSlice:
1110 length := fr.value(instr.Len)
1111 capacity := fr.value(instr.Cap)
1112 fr.env[instr] = fr.makeSlice(instr.Type(), length, capacity)
1113
1114 case *ssa.MapUpdate:
1115 m := fr.value(instr.Map)
1116 k := fr.value(instr.Key)
1117 v := fr.value(instr.Value)
1118 fr.mapUpdate(m, k, v)
1119
1120 case *ssa.Next:
1121 iter := fr.tuples[instr.Iter]
1122 if instr.IsString {
1123 fr.tuples[instr] = fr.stringIterNext(iter)
1124 } else {
1125 fr.tuples[instr] = fr.mapIterNext(iter)
1126 }
1127
1128 case *ssa.Panic:
1129 arg := fr.value(instr.X)
Peter Collingbourneb6edff92014-12-28 22:39:01 +0000[diff] [blame]1130 fr.callPanic(arg, true)
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]1131
1132 case *ssa.Phi:
1133 typ := instr.Type()
1134 phi := fr.builder.CreatePHI(fr.llvmtypes.ToLLVM(typ), instr.Comment)
1135 fr.env[instr] = newValue(phi, typ)
1136 fr.phis = append(fr.phis, pendingPhi{instr, phi})
1137
1138 case *ssa.Range:
1139 x := fr.value(instr.X)
1140 switch x.Type().Underlying().(type) {
1141 case *types.Map:
1142 fr.tuples[instr] = fr.mapIterInit(x)
1143 case *types.Basic: // string
1144 fr.tuples[instr] = fr.stringIterInit(x)
1145 default:
1146 panic(fmt.Sprintf("unhandled range for type %T", x.Type()))
1147 }
1148
1149 case *ssa.Return:
1150 vals := make([]llvm.Value, len(instr.Results))
1151 for i, res := range instr.Results {
1152 vals[i] = fr.llvmvalue(res)
1153 }
1154 fr.retInf.encode(llvm.GlobalContext(), fr.allocaBuilder, fr.builder, vals)
1155
1156 case *ssa.RunDefers:
1157 fr.runDefers()
1158
1159 case *ssa.Select:
Andrew Wilkins75f34af2014-12-31 03:46:49 +0000[diff] [blame]1160 index, recvOk, recvElems := fr.chanSelect(instr)
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]1161 tuple := append([]*govalue{index, recvOk}, recvElems...)
1162 fr.tuples[instr] = tuple
1163
1164 case *ssa.Send:
1165 fr.chanSend(fr.value(instr.Chan), fr.value(instr.X))
1166
1167 case *ssa.Slice:
1168 x := fr.llvmvalue(instr.X)
1169 low := fr.llvmvalue(instr.Low)
1170 high := fr.llvmvalue(instr.High)
1171 max := fr.llvmvalue(instr.Max)
1172 slice := fr.slice(x, instr.X.Type(), low, high, max)
1173 fr.env[instr] = newValue(slice, instr.Type())
1174
1175 case *ssa.Store:
1176 addr := fr.llvmvalue(instr.Addr)
1177 value := fr.llvmvalue(instr.Val)
1178 addr = fr.builder.CreateBitCast(addr, llvm.PointerType(value.Type(), 0), "")
1179 // If this is the init function, see if we can simulate the effect
1180 // of the store in a global's initializer, in which case we can avoid
1181 // generating code for it.
1182 if !fr.isInit || !fr.maybeStoreInInitializer(value, addr) {
1183 fr.nilCheck(instr.Addr, addr)
1184 fr.builder.CreateStore(value, addr)
1185 }
1186
Andrew Wilkinsf3718a92015-01-08 07:49:28 +0000[diff] [blame^]1187 case *switchInstr:
1188 fr.emitSwitch(instr)
1189
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]1190 case *ssa.TypeAssert:
1191 x := fr.value(instr.X)
1192 if instr.CommaOk {
1193 v, ok := fr.interfaceTypeCheck(x, instr.AssertedType)
1194 fr.tuples[instr] = []*govalue{v, ok}
1195 } else {
1196 fr.env[instr] = fr.interfaceTypeAssert(x, instr.AssertedType)
1197 }
1198
1199 case *ssa.UnOp:
1200 operand := fr.value(instr.X)
1201 switch instr.Op {
1202 case token.ARROW:
1203 x, ok := fr.chanRecv(operand, instr.CommaOk)
1204 if instr.CommaOk {
1205 fr.tuples[instr] = []*govalue{x, ok}
1206 } else {
1207 fr.env[instr] = x
1208 }
1209 case token.MUL:
1210 fr.nilCheck(instr.X, operand.value)
1211 if !fr.canAvoidLoad(instr, operand.value) {
1212 // The bitcast is necessary to handle recursive pointer loads.
1213 llptr := fr.builder.CreateBitCast(operand.value, llvm.PointerType(fr.llvmtypes.ToLLVM(instr.Type()), 0), "")
1214 fr.env[instr] = newValue(fr.builder.CreateLoad(llptr, ""), instr.Type())
1215 }
1216 default:
1217 fr.env[instr] = fr.unaryOp(operand, instr.Op)
1218 }
1219
1220 default:
1221 panic(fmt.Sprintf("unhandled: %v", instr))
1222 }
1223}
1224
1225func (fr *frame) callBuiltin(typ types.Type, builtin *ssa.Builtin, args []ssa.Value) []*govalue {
1226 switch builtin.Name() {
1227 case "print", "println":
1228 llargs := make([]*govalue, len(args))
1229 for i, arg := range args {
1230 llargs[i] = fr.value(arg)
1231 }
1232 fr.printValues(builtin.Name() == "println", llargs...)
1233 return nil
1234
1235 case "panic":
Peter Collingbourneb6edff92014-12-28 22:39:01 +0000[diff] [blame]1236 fr.callPanic(fr.value(args[0]), false)
Peter Collingbournead9841e2014-11-27 00:06:42 +0000[diff] [blame]1237 return nil
1238
1239 case "recover":
1240 return []*govalue{fr.callRecover(false)}
1241
1242 case "append":
1243 return []*govalue{fr.callAppend(fr.value(args[0]), fr.value(args[1]))}
1244
1245 case "close":
1246 fr.chanClose(fr.value(args[0]))
1247 return nil
1248
1249 case "cap":
1250 return []*govalue{fr.callCap(fr.value(args[0]))}
1251
1252 case "len":
1253 return []*govalue{fr.callLen(fr.value(args[0]))}
1254
1255 case "copy":
1256 return []*govalue{fr.callCopy(fr.value(args[0]), fr.value(args[1]))}
1257
1258 case "delete":
1259 fr.mapDelete(fr.value(args[0]), fr.value(args[1]))
1260 return nil
1261
1262 case "real":
1263 return []*govalue{fr.extractRealValue(fr.value(args[0]))}
1264
1265 case "imag":
1266 return []*govalue{fr.extractImagValue(fr.value(args[0]))}
1267
1268 case "complex":
1269 r := fr.llvmvalue(args[0])
1270 i := fr.llvmvalue(args[1])
1271 cmplx := llvm.Undef(fr.llvmtypes.ToLLVM(typ))
1272 cmplx = fr.builder.CreateInsertValue(cmplx, r, 0, "")
1273 cmplx = fr.builder.CreateInsertValue(cmplx, i, 1, "")
1274 return []*govalue{newValue(cmplx, typ)}
1275
1276 case "ssa:wrapnilchk":
1277 ptr := fr.value(args[0])
1278 fr.nilCheck(args[0], ptr.value)
1279 return []*govalue{ptr}
1280
1281 default:
1282 panic("unimplemented: " + builtin.Name())
1283 }
1284}
1285
1286// callInstruction translates function call instructions.
1287func (fr *frame) callInstruction(instr ssa.CallInstruction) []*govalue {
1288 call := instr.Common()
1289 if builtin, ok := call.Value.(*ssa.Builtin); ok {
1290 var typ types.Type
1291 if v := instr.Value(); v != nil {
1292 typ = v.Type()
1293 }
1294 return fr.callBuiltin(typ, builtin, call.Args)
1295 }
1296
1297 args := make([]*govalue, len(call.Args))
1298 for i, arg := range call.Args {
1299 args[i] = fr.value(arg)
1300 }
1301
1302 var fn *govalue
1303 if call.IsInvoke() {
1304 var recv *govalue
1305 fn, recv = fr.interfaceMethod(fr.llvmvalue(call.Value), call.Value.Type(), call.Method)
1306 args = append([]*govalue{recv}, args...)
1307 } else {
1308 if ssafn, ok := call.Value.(*ssa.Function); ok {
1309 llfn := fr.resolveFunctionGlobal(ssafn)
1310 llfn = llvm.ConstBitCast(llfn, llvm.PointerType(llvm.Int8Type(), 0))
1311 fn = newValue(llfn, ssafn.Type())
1312 } else {
1313 // First-class function values are stored as *{*fnptr}, so
1314 // we must extract the function pointer. We must also
1315 // call __go_set_closure, in case the function is a closure.
1316 fn = fr.value(call.Value)
1317 fr.runtime.setClosure.call(fr, fn.value)
1318 fnptr := fr.builder.CreateBitCast(fn.value, llvm.PointerType(fn.value.Type(), 0), "")
1319 fnptr = fr.builder.CreateLoad(fnptr, "")
1320 fn = newValue(fnptr, fn.Type())
1321 }
1322 if recv := call.Signature().Recv(); recv != nil {
1323 if _, ok := recv.Type().Underlying().(*types.Pointer); !ok {
1324 recvalloca := fr.allocaBuilder.CreateAlloca(args[0].value.Type(), "")
1325 fr.builder.CreateStore(args[0].value, recvalloca)
1326 args[0] = newValue(recvalloca, types.NewPointer(args[0].Type()))
1327 }
1328 }
1329 }
1330 return fr.createCall(fn, args)
1331}
1332
1333func hasDefer(f *ssa.Function) bool {
1334 for _, b := range f.Blocks {
1335 for _, instr := range b.Instrs {
1336 if _, ok := instr.(*ssa.Defer); ok {
1337 return true
1338 }
1339 }
1340 }
1341 return false
1342}
1343
1344func callsRecover(f *ssa.Function) bool {
1345 for _, b := range f.Blocks {
1346 for _, instr := range b.Instrs {
1347 if instr, ok := instr.(ssa.CallInstruction); ok {
1348 b, ok := instr.Common().Value.(*ssa.Builtin)
1349 if ok && b.Name() == "recover" {
1350 return true
1351 }
1352 }
1353 }
1354 }
1355 return false
1356}