aboutsummaryrefslogtreecommitdiffhomepage
path: root/transform/gc.go
diff options
context:
space:
mode:
Diffstat (limited to 'transform/gc.go')
-rw-r--r--transform/gc.go398
1 files changed, 398 insertions, 0 deletions
diff --git a/transform/gc.go b/transform/gc.go
new file mode 100644
index 000000000..ee32ed0ce
--- /dev/null
+++ b/transform/gc.go
@@ -0,0 +1,398 @@
+package transform
+
+import (
+ "math/big"
+
+ "tinygo.org/x/go-llvm"
+)
+
+// MakeGCStackSlots converts all calls to runtime.trackPointer to explicit
+// stores to stack slots that are scannable by the GC.
+func MakeGCStackSlots(mod llvm.Module) bool {
+ // Check whether there are allocations at all.
+ alloc := mod.NamedFunction("runtime.alloc")
+ if alloc.IsNil() {
+ // Nothing to. Make sure all remaining bits and pieces for stack
+ // chains are neutralized.
+ for _, call := range getUses(mod.NamedFunction("runtime.trackPointer")) {
+ call.EraseFromParentAsInstruction()
+ }
+ stackChainStart := mod.NamedGlobal("runtime.stackChainStart")
+ if !stackChainStart.IsNil() {
+ stackChainStart.SetInitializer(llvm.ConstNull(stackChainStart.Type().ElementType()))
+ stackChainStart.SetGlobalConstant(true)
+ }
+ return false
+ }
+
+ trackPointer := mod.NamedFunction("runtime.trackPointer")
+ if trackPointer.IsNil() || trackPointer.FirstUse().IsNil() {
+ return false // nothing to do
+ }
+
+ ctx := mod.Context()
+ builder := ctx.NewBuilder()
+ targetData := llvm.NewTargetData(mod.DataLayout())
+ uintptrType := ctx.IntType(targetData.PointerSize() * 8)
+
+ // Look at *all* functions to see whether they are free of function pointer
+ // calls.
+ // This takes less than 5ms for ~100kB of WebAssembly but would perhaps be
+ // faster when written in C++ (to avoid the CGo overhead).
+ funcsWithFPCall := map[llvm.Value]struct{}{}
+ n := 0
+ for fn := mod.FirstFunction(); !fn.IsNil(); fn = llvm.NextFunction(fn) {
+ n++
+ if _, ok := funcsWithFPCall[fn]; ok {
+ continue // already found
+ }
+ done := false
+ for bb := fn.FirstBasicBlock(); !bb.IsNil() && !done; bb = llvm.NextBasicBlock(bb) {
+ for call := bb.FirstInstruction(); !call.IsNil() && !done; call = llvm.NextInstruction(call) {
+ if call.IsACallInst().IsNil() {
+ continue // only looking at calls
+ }
+ called := call.CalledValue()
+ if !called.IsAFunction().IsNil() {
+ continue // only looking for function pointers
+ }
+ funcsWithFPCall[fn] = struct{}{}
+ markParentFunctions(funcsWithFPCall, fn)
+ done = true
+ }
+ }
+ }
+
+ // Determine which functions need stack objects. Many leaf functions don't
+ // need it: it only causes overhead for them.
+ // Actually, in one test it was only able to eliminate stack object from 12%
+ // of functions that had a call to runtime.trackPointer (8 out of 68
+ // functions), so this optimization is not as big as it may seem.
+ allocatingFunctions := map[llvm.Value]struct{}{} // set of allocating functions
+
+ // Work from runtime.alloc and trace all parents to check which functions do
+ // a heap allocation (and thus which functions do not).
+ markParentFunctions(allocatingFunctions, alloc)
+
+ // Also trace all functions that call a function pointer.
+ for fn := range funcsWithFPCall {
+ // Assume that functions that call a function pointer do a heap
+ // allocation as a conservative guess because the called function might
+ // do a heap allocation.
+ allocatingFunctions[fn] = struct{}{}
+ markParentFunctions(allocatingFunctions, fn)
+ }
+
+ // Collect some variables used below in the loop.
+ stackChainStart := mod.NamedGlobal("runtime.stackChainStart")
+ if stackChainStart.IsNil() {
+ // This may be reached in a weird scenario where we call runtime.alloc but the garbage collector is unreachable.
+ // This can be accomplished by allocating 0 bytes.
+ // There is no point in tracking anything.
+ for _, use := range getUses(trackPointer) {
+ use.EraseFromParentAsInstruction()
+ }
+ return false
+ }
+ stackChainStartType := stackChainStart.Type().ElementType()
+ stackChainStart.SetInitializer(llvm.ConstNull(stackChainStartType))
+
+ // Iterate until runtime.trackPointer has no uses left.
+ for use := trackPointer.FirstUse(); !use.IsNil(); use = trackPointer.FirstUse() {
+ // Pick the first use of runtime.trackPointer.
+ call := use.User()
+ if call.IsACallInst().IsNil() {
+ panic("expected runtime.trackPointer use to be a call")
+ }
+
+ // Pick the parent function.
+ fn := call.InstructionParent().Parent()
+
+ if _, ok := allocatingFunctions[fn]; !ok {
+ // This function nor any of the functions it calls (recursively)
+ // allocate anything from the heap, so it will not trigger a garbage
+ // collection cycle. Thus, it does not need to track local pointer
+ // values.
+ // This is a useful optimization but not as big as you might guess,
+ // as described above (it avoids stack objects for ~12% of
+ // functions).
+ call.EraseFromParentAsInstruction()
+ continue
+ }
+
+ // Find all calls to runtime.trackPointer in this function.
+ var calls []llvm.Value
+ var returns []llvm.Value
+ for bb := fn.FirstBasicBlock(); !bb.IsNil(); bb = llvm.NextBasicBlock(bb) {
+ for inst := bb.FirstInstruction(); !inst.IsNil(); inst = llvm.NextInstruction(inst) {
+ switch inst.InstructionOpcode() {
+ case llvm.Call:
+ if inst.CalledValue() == trackPointer {
+ calls = append(calls, inst)
+ }
+ case llvm.Ret:
+ returns = append(returns, inst)
+ }
+ }
+ }
+
+ // Determine what to do with each call.
+ var allocas, pointers []llvm.Value
+ for _, call := range calls {
+ ptr := call.Operand(0)
+ call.EraseFromParentAsInstruction()
+ if ptr.IsAInstruction().IsNil() {
+ continue
+ }
+
+ // Some trivial optimizations.
+ if ptr.IsAInstruction().IsNil() {
+ continue
+ }
+ switch ptr.InstructionOpcode() {
+ case llvm.PHI, llvm.GetElementPtr:
+ // These values do not create new values: the values already
+ // existed locally in this function so must have been tracked
+ // already.
+ continue
+ case llvm.ExtractValue, llvm.BitCast:
+ // These instructions do not create new values, but their
+ // original value may not be tracked. So keep tracking them for
+ // now.
+ // With more analysis, it should be possible to optimize a
+ // significant chunk of these away.
+ case llvm.Call, llvm.Load, llvm.IntToPtr:
+ // These create new values so must be stored locally. But
+ // perhaps some of these can be fused when they actually refer
+ // to the same value.
+ default:
+ // Ambiguous. These instructions are uncommon, but perhaps could
+ // be optimized if needed.
+ }
+
+ if !ptr.IsAAllocaInst().IsNil() {
+ if typeHasPointers(ptr.Type().ElementType()) {
+ allocas = append(allocas, ptr)
+ }
+ } else {
+ pointers = append(pointers, ptr)
+ }
+ }
+
+ if len(allocas) == 0 && len(pointers) == 0 {
+ // This function does not need to keep track of stack pointers.
+ continue
+ }
+
+ // Determine the type of the required stack slot.
+ fields := []llvm.Type{
+ stackChainStartType, // Pointer to parent frame.
+ uintptrType, // Number of elements in this frame.
+ }
+ for _, alloca := range allocas {
+ fields = append(fields, alloca.Type().ElementType())
+ }
+ for _, ptr := range pointers {
+ fields = append(fields, ptr.Type())
+ }
+ stackObjectType := ctx.StructType(fields, false)
+
+ // Create the stack object at the function entry.
+ builder.SetInsertPointBefore(fn.EntryBasicBlock().FirstInstruction())
+ stackObject := builder.CreateAlloca(stackObjectType, "gc.stackobject")
+ initialStackObject := llvm.ConstNull(stackObjectType)
+ numSlots := (targetData.TypeAllocSize(stackObjectType) - uint64(targetData.PointerSize())*2) / uint64(targetData.ABITypeAlignment(uintptrType))
+ numSlotsValue := llvm.ConstInt(uintptrType, numSlots, false)
+ initialStackObject = llvm.ConstInsertValue(initialStackObject, numSlotsValue, []uint32{1})
+ builder.CreateStore(initialStackObject, stackObject)
+
+ // Update stack start.
+ parent := builder.CreateLoad(stackChainStart, "")
+ gep := builder.CreateGEP(stackObject, []llvm.Value{
+ llvm.ConstInt(ctx.Int32Type(), 0, false),
+ llvm.ConstInt(ctx.Int32Type(), 0, false),
+ }, "")
+ builder.CreateStore(parent, gep)
+ stackObjectCast := builder.CreateBitCast(stackObject, stackChainStartType, "")
+ builder.CreateStore(stackObjectCast, stackChainStart)
+
+ // Replace all independent allocas with GEPs in the stack object.
+ for i, alloca := range allocas {
+ gep := builder.CreateGEP(stackObject, []llvm.Value{
+ llvm.ConstInt(ctx.Int32Type(), 0, false),
+ llvm.ConstInt(ctx.Int32Type(), uint64(2+i), false),
+ }, "")
+ alloca.ReplaceAllUsesWith(gep)
+ alloca.EraseFromParentAsInstruction()
+ }
+
+ // Do a store to the stack object after each new pointer that is created.
+ for i, ptr := range pointers {
+ builder.SetInsertPointBefore(llvm.NextInstruction(ptr))
+ gep := builder.CreateGEP(stackObject, []llvm.Value{
+ llvm.ConstInt(ctx.Int32Type(), 0, false),
+ llvm.ConstInt(ctx.Int32Type(), uint64(2+len(allocas)+i), false),
+ }, "")
+ builder.CreateStore(ptr, gep)
+ }
+
+ // Make sure this stack object is popped from the linked list of stack
+ // objects at return.
+ for _, ret := range returns {
+ builder.SetInsertPointBefore(ret)
+ builder.CreateStore(parent, stackChainStart)
+ }
+ }
+
+ return true
+}
+
+// AddGlobalsBitmap performs a few related functions. It is needed for scanning
+// globals on platforms where the .data/.bss section is not easily accessible by
+// the GC, and thus all globals that contain pointers must be made reachable by
+// the GC in some other way.
+//
+// First, it scans all globals, and bundles all globals that contain a pointer
+// into one large global (updating all uses in the process). Then it creates a
+// bitmap (bit vector) to locate all the pointers in this large global. This
+// bitmap allows the GC to know in advance where exactly all the pointers live
+// in the large globals bundle, to avoid false positives.
+func AddGlobalsBitmap(mod llvm.Module) bool {
+ if mod.NamedGlobal("runtime.trackedGlobalsStart").IsNil() {
+ return false // nothing to do: no GC in use
+ }
+
+ ctx := mod.Context()
+ targetData := llvm.NewTargetData(mod.DataLayout())
+ uintptrType := ctx.IntType(targetData.PointerSize() * 8)
+
+ // Collect all globals that contain pointers (and thus must be scanned by
+ // the GC).
+ var trackedGlobals []llvm.Value
+ var trackedGlobalTypes []llvm.Type
+ for global := mod.FirstGlobal(); !global.IsNil(); global = llvm.NextGlobal(global) {
+ if global.IsDeclaration() {
+ continue
+ }
+ typ := global.Type().ElementType()
+ ptrs := getPointerBitmap(targetData, typ, global.Name())
+ if ptrs.BitLen() == 0 {
+ continue
+ }
+ trackedGlobals = append(trackedGlobals, global)
+ trackedGlobalTypes = append(trackedGlobalTypes, typ)
+ }
+
+ // Make a new global that bundles all existing globals, and remove the
+ // existing globals. All uses of the previous independent globals are
+ // replaced with a GEP into the new globals bundle.
+ globalsBundleType := ctx.StructType(trackedGlobalTypes, false)
+ globalsBundle := llvm.AddGlobal(mod, globalsBundleType, "tinygo.trackedGlobals")
+ globalsBundle.SetLinkage(llvm.InternalLinkage)
+ globalsBundle.SetUnnamedAddr(true)
+ initializer := llvm.Undef(globalsBundleType)
+ for i, global := range trackedGlobals {
+ initializer = llvm.ConstInsertValue(initializer, global.Initializer(), []uint32{uint32(i)})
+ gep := llvm.ConstGEP(globalsBundle, []llvm.Value{
+ llvm.ConstInt(ctx.Int32Type(), 0, false),
+ llvm.ConstInt(ctx.Int32Type(), uint64(i), false),
+ })
+ global.ReplaceAllUsesWith(gep)
+ global.EraseFromParentAsGlobal()
+ }
+ globalsBundle.SetInitializer(initializer)
+
+ // Update trackedGlobalsStart, which points to the globals bundle.
+ trackedGlobalsStart := llvm.ConstPtrToInt(globalsBundle, uintptrType)
+ mod.NamedGlobal("runtime.trackedGlobalsStart").SetInitializer(trackedGlobalsStart)
+
+ // Update trackedGlobalsLength, which contains the length (in words) of the
+ // globals bundle.
+ alignment := targetData.PrefTypeAlignment(llvm.PointerType(ctx.Int8Type(), 0))
+ trackedGlobalsLength := llvm.ConstInt(uintptrType, targetData.TypeAllocSize(globalsBundleType)/uint64(alignment), false)
+ mod.NamedGlobal("runtime.trackedGlobalsLength").SetInitializer(trackedGlobalsLength)
+
+ // Create a bitmap (a new global) that stores for each word in the globals
+ // bundle whether it contains a pointer. This allows globals to be scanned
+ // precisely: no non-pointers will be considered pointers if the bit pattern
+ // looks like one.
+ // This code assumes that pointers are self-aligned. For example, that a
+ // 32-bit (4-byte) pointer is also aligned to 4 bytes.
+ bitmapBytes := getPointerBitmap(targetData, globalsBundleType, "globals bundle").Bytes()
+ bitmapValues := make([]llvm.Value, len(bitmapBytes))
+ for i, b := range bitmapBytes {
+ bitmapValues[len(bitmapBytes)-i-1] = llvm.ConstInt(ctx.Int8Type(), uint64(b), false)
+ }
+ bitmapArray := llvm.ConstArray(ctx.Int8Type(), bitmapValues)
+ bitmapNew := llvm.AddGlobal(mod, bitmapArray.Type(), "runtime.trackedGlobalsBitmap.tmp")
+ bitmapOld := mod.NamedGlobal("runtime.trackedGlobalsBitmap")
+ bitmapOld.ReplaceAllUsesWith(llvm.ConstBitCast(bitmapNew, bitmapOld.Type()))
+ bitmapNew.SetInitializer(bitmapArray)
+ bitmapNew.SetName("runtime.trackedGlobalsBitmap")
+
+ return true // the IR was changed
+}
+
+// getPointerBitmap scans the given LLVM type for pointers and sets bits in a
+// bigint at the word offset that contains a pointer. This scan is recursive.
+func getPointerBitmap(targetData llvm.TargetData, typ llvm.Type, name string) *big.Int {
+ alignment := targetData.PrefTypeAlignment(llvm.PointerType(typ.Context().Int8Type(), 0))
+ switch typ.TypeKind() {
+ case llvm.IntegerTypeKind, llvm.FloatTypeKind, llvm.DoubleTypeKind:
+ return big.NewInt(0)
+ case llvm.PointerTypeKind:
+ return big.NewInt(1)
+ case llvm.StructTypeKind:
+ ptrs := big.NewInt(0)
+ for i, subtyp := range typ.StructElementTypes() {
+ subptrs := getPointerBitmap(targetData, subtyp, name)
+ if subptrs.BitLen() == 0 {
+ continue
+ }
+ offset := targetData.ElementOffset(typ, i)
+ if offset%uint64(alignment) != 0 {
+ panic("precise GC: global contains unaligned pointer: " + name)
+ }
+ subptrs.Lsh(subptrs, uint(offset)/uint(alignment))
+ ptrs.Or(ptrs, subptrs)
+ }
+ return ptrs
+ case llvm.ArrayTypeKind:
+ subtyp := typ.ElementType()
+ subptrs := getPointerBitmap(targetData, subtyp, name)
+ ptrs := big.NewInt(0)
+ if subptrs.BitLen() == 0 {
+ return ptrs
+ }
+ elementSize := targetData.TypeAllocSize(subtyp)
+ for i := 0; i < typ.ArrayLength(); i++ {
+ ptrs.Lsh(ptrs, uint(elementSize)/uint(alignment))
+ ptrs.Or(ptrs, subptrs)
+ }
+ return ptrs
+ default:
+ panic("unknown type kind of global: " + name)
+ }
+}
+
+// markParentFunctions traverses all parent function calls (recursively) and
+// adds them to the set of marked functions. It only considers function calls:
+// any other uses of such a function is ignored.
+func markParentFunctions(marked map[llvm.Value]struct{}, fn llvm.Value) {
+ worklist := []llvm.Value{fn}
+ for len(worklist) != 0 {
+ fn := worklist[len(worklist)-1]
+ worklist = worklist[:len(worklist)-1]
+ for _, use := range getUses(fn) {
+ if use.IsACallInst().IsNil() || use.CalledValue() != fn {
+ // Not the parent function.
+ continue
+ }
+ parent := use.InstructionParent().Parent()
+ if _, ok := marked[parent]; !ok {
+ marked[parent] = struct{}{}
+ worklist = append(worklist, parent)
+ }
+ }
+ }
+}