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271 lines
11 KiB
271 lines
11 KiB
package compiler
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// This file lowers channel operations (make/send/recv/close) to runtime calls
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// or pseudo-operations that are lowered during goroutine lowering.
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import (
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"go/types"
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"github.com/tinygo-org/tinygo/compiler/llvmutil"
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"golang.org/x/tools/go/ssa"
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"tinygo.org/x/go-llvm"
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)
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func (b *builder) createMakeChan(expr *ssa.MakeChan) llvm.Value {
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elementSize := b.targetData.TypeAllocSize(b.getLLVMType(expr.Type().Underlying().(*types.Chan).Elem()))
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elementSizeValue := llvm.ConstInt(b.uintptrType, elementSize, false)
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bufSize := b.getValue(expr.Size)
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b.createChanBoundsCheck(elementSize, bufSize, expr.Size.Type().Underlying().(*types.Basic), expr.Pos())
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if bufSize.Type().IntTypeWidth() < b.uintptrType.IntTypeWidth() {
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bufSize = b.CreateZExt(bufSize, b.uintptrType, "")
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} else if bufSize.Type().IntTypeWidth() > b.uintptrType.IntTypeWidth() {
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bufSize = b.CreateTrunc(bufSize, b.uintptrType, "")
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}
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return b.createRuntimeCall("chanMake", []llvm.Value{elementSizeValue, bufSize}, "")
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}
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// createChanSend emits a pseudo chan send operation. It is lowered to the
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// actual channel send operation during goroutine lowering.
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func (b *builder) createChanSend(instr *ssa.Send) {
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ch := b.getValue(instr.Chan)
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chanValue := b.getValue(instr.X)
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// store value-to-send
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valueType := b.getLLVMType(instr.X.Type())
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isZeroSize := b.targetData.TypeAllocSize(valueType) == 0
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var valueAlloca, valueAllocaCast, valueAllocaSize llvm.Value
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if isZeroSize {
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valueAlloca = llvm.ConstNull(llvm.PointerType(valueType, 0))
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valueAllocaCast = llvm.ConstNull(b.i8ptrType)
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} else {
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valueAlloca, valueAllocaCast, valueAllocaSize = b.createTemporaryAlloca(valueType, "chan.value")
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b.CreateStore(chanValue, valueAlloca)
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}
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// Allocate blockedlist buffer.
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channelBlockedList := b.mod.GetTypeByName("runtime.channelBlockedList")
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channelBlockedListAlloca, channelBlockedListAllocaCast, channelBlockedListAllocaSize := b.createTemporaryAlloca(channelBlockedList, "chan.blockedList")
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// Do the send.
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b.createRuntimeCall("chanSend", []llvm.Value{ch, valueAllocaCast, channelBlockedListAlloca}, "")
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// End the lifetime of the allocas.
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// This also works around a bug in CoroSplit, at least in LLVM 8:
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// https://bugs.llvm.org/show_bug.cgi?id=41742
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b.emitLifetimeEnd(channelBlockedListAllocaCast, channelBlockedListAllocaSize)
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if !isZeroSize {
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b.emitLifetimeEnd(valueAllocaCast, valueAllocaSize)
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}
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}
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// createChanRecv emits a pseudo chan receive operation. It is lowered to the
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// actual channel receive operation during goroutine lowering.
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func (b *builder) createChanRecv(unop *ssa.UnOp) llvm.Value {
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valueType := b.getLLVMType(unop.X.Type().Underlying().(*types.Chan).Elem())
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ch := b.getValue(unop.X)
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// Allocate memory to receive into.
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isZeroSize := b.targetData.TypeAllocSize(valueType) == 0
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var valueAlloca, valueAllocaCast, valueAllocaSize llvm.Value
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if isZeroSize {
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valueAlloca = llvm.ConstNull(llvm.PointerType(valueType, 0))
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valueAllocaCast = llvm.ConstNull(b.i8ptrType)
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} else {
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valueAlloca, valueAllocaCast, valueAllocaSize = b.createTemporaryAlloca(valueType, "chan.value")
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}
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// Allocate blockedlist buffer.
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channelBlockedList := b.mod.GetTypeByName("runtime.channelBlockedList")
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channelBlockedListAlloca, channelBlockedListAllocaCast, channelBlockedListAllocaSize := b.createTemporaryAlloca(channelBlockedList, "chan.blockedList")
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// Do the receive.
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commaOk := b.createRuntimeCall("chanRecv", []llvm.Value{ch, valueAllocaCast, channelBlockedListAlloca}, "")
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var received llvm.Value
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if isZeroSize {
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received = llvm.ConstNull(valueType)
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} else {
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received = b.CreateLoad(valueType, valueAlloca, "chan.received")
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b.emitLifetimeEnd(valueAllocaCast, valueAllocaSize)
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}
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b.emitLifetimeEnd(channelBlockedListAllocaCast, channelBlockedListAllocaSize)
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if unop.CommaOk {
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tuple := llvm.Undef(b.ctx.StructType([]llvm.Type{valueType, b.ctx.Int1Type()}, false))
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tuple = b.CreateInsertValue(tuple, received, 0, "")
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tuple = b.CreateInsertValue(tuple, commaOk, 1, "")
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return tuple
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} else {
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return received
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}
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}
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// createChanClose closes the given channel.
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func (b *builder) createChanClose(ch llvm.Value) {
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b.createRuntimeCall("chanClose", []llvm.Value{ch}, "")
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}
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// createSelect emits all IR necessary for a select statements. That's a
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// non-trivial amount of code because select is very complex to implement.
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func (b *builder) createSelect(expr *ssa.Select) llvm.Value {
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if len(expr.States) == 0 {
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// Shortcuts for some simple selects.
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llvmType := b.getLLVMType(expr.Type())
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if expr.Blocking {
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// Blocks forever:
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// select {}
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b.createRuntimeCall("deadlock", nil, "")
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return llvm.Undef(llvmType)
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} else {
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// No-op:
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// select {
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// default:
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// }
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retval := llvm.Undef(llvmType)
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retval = b.CreateInsertValue(retval, llvm.ConstInt(b.intType, 0xffffffffffffffff, true), 0, "")
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return retval // {-1, false}
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}
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}
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// This code create a (stack-allocated) slice containing all the select
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// cases and then calls runtime.chanSelect to perform the actual select
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// statement.
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// Simple selects (blocking and with just one case) are already transformed
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// into regular chan operations during SSA construction so we don't have to
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// optimize such small selects.
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// Go through all the cases. Create the selectStates slice and and
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// determine the receive buffer size and alignment.
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recvbufSize := uint64(0)
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recvbufAlign := 0
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var selectStates []llvm.Value
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chanSelectStateType := b.getLLVMRuntimeType("chanSelectState")
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for _, state := range expr.States {
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ch := b.getValue(state.Chan)
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selectState := llvm.ConstNull(chanSelectStateType)
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selectState = b.CreateInsertValue(selectState, ch, 0, "")
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switch state.Dir {
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case types.RecvOnly:
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// Make sure the receive buffer is big enough and has the correct alignment.
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llvmType := b.getLLVMType(state.Chan.Type().Underlying().(*types.Chan).Elem())
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if size := b.targetData.TypeAllocSize(llvmType); size > recvbufSize {
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recvbufSize = size
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}
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if align := b.targetData.ABITypeAlignment(llvmType); align > recvbufAlign {
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recvbufAlign = align
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}
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case types.SendOnly:
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// Store this value in an alloca and put a pointer to this alloca
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// in the send state.
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sendValue := b.getValue(state.Send)
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alloca := llvmutil.CreateEntryBlockAlloca(b.Builder, sendValue.Type(), "select.send.value")
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b.CreateStore(sendValue, alloca)
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ptr := b.CreateBitCast(alloca, b.i8ptrType, "")
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selectState = b.CreateInsertValue(selectState, ptr, 1, "")
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default:
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panic("unreachable")
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}
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selectStates = append(selectStates, selectState)
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}
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// Create a receive buffer, where the received value will be stored.
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recvbuf := llvm.Undef(b.i8ptrType)
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if recvbufSize != 0 {
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allocaType := llvm.ArrayType(b.ctx.Int8Type(), int(recvbufSize))
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recvbufAlloca, _, _ := b.createTemporaryAlloca(allocaType, "select.recvbuf.alloca")
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recvbufAlloca.SetAlignment(recvbufAlign)
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recvbuf = b.CreateGEP(allocaType, recvbufAlloca, []llvm.Value{
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llvm.ConstInt(b.ctx.Int32Type(), 0, false),
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llvm.ConstInt(b.ctx.Int32Type(), 0, false),
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}, "select.recvbuf")
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}
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// Create the states slice (allocated on the stack).
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statesAllocaType := llvm.ArrayType(chanSelectStateType, len(selectStates))
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statesAlloca, statesI8, statesSize := b.createTemporaryAlloca(statesAllocaType, "select.states.alloca")
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for i, state := range selectStates {
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// Set each slice element to the appropriate channel.
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gep := b.CreateGEP(statesAllocaType, statesAlloca, []llvm.Value{
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llvm.ConstInt(b.ctx.Int32Type(), 0, false),
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llvm.ConstInt(b.ctx.Int32Type(), uint64(i), false),
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}, "")
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b.CreateStore(state, gep)
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}
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statesPtr := b.CreateGEP(statesAllocaType, statesAlloca, []llvm.Value{
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llvm.ConstInt(b.ctx.Int32Type(), 0, false),
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llvm.ConstInt(b.ctx.Int32Type(), 0, false),
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}, "select.states")
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statesLen := llvm.ConstInt(b.uintptrType, uint64(len(selectStates)), false)
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// Do the select in the runtime.
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var results llvm.Value
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if expr.Blocking {
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// Stack-allocate operation structures.
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// If these were simply created as a slice, they would heap-allocate.
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chBlockAllocaType := llvm.ArrayType(b.getLLVMRuntimeType("channelBlockedList"), len(selectStates))
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chBlockAlloca, chBlockAllocaPtr, chBlockSize := b.createTemporaryAlloca(chBlockAllocaType, "select.block.alloca")
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chBlockLen := llvm.ConstInt(b.uintptrType, uint64(len(selectStates)), false)
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chBlockPtr := b.CreateGEP(chBlockAllocaType, chBlockAlloca, []llvm.Value{
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llvm.ConstInt(b.ctx.Int32Type(), 0, false),
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llvm.ConstInt(b.ctx.Int32Type(), 0, false),
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}, "select.block")
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results = b.createRuntimeCall("chanSelect", []llvm.Value{
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recvbuf,
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statesPtr, statesLen, statesLen, // []chanSelectState
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chBlockPtr, chBlockLen, chBlockLen, // []channelBlockList
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}, "select.result")
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// Terminate the lifetime of the operation structures.
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b.emitLifetimeEnd(chBlockAllocaPtr, chBlockSize)
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} else {
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results = b.createRuntimeCall("tryChanSelect", []llvm.Value{
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recvbuf,
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statesPtr, statesLen, statesLen, // []chanSelectState
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}, "select.result")
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}
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// Terminate the lifetime of the states alloca.
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b.emitLifetimeEnd(statesI8, statesSize)
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// The result value does not include all the possible received values,
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// because we can't load them in advance. Instead, the *ssa.Extract
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// instruction will treat a *ssa.Select specially and load it there inline.
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// Store the receive alloca in a sidetable until we hit this extract
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// instruction.
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if b.selectRecvBuf == nil {
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b.selectRecvBuf = make(map[*ssa.Select]llvm.Value)
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}
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b.selectRecvBuf[expr] = recvbuf
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return results
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}
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// getChanSelectResult returns the special values from a *ssa.Extract expression
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// when extracting a value from a select statement (*ssa.Select). Because
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// *ssa.Select cannot load all values in advance, it does this later in the
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// *ssa.Extract expression.
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func (b *builder) getChanSelectResult(expr *ssa.Extract) llvm.Value {
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if expr.Index == 0 {
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// index
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value := b.getValue(expr.Tuple)
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index := b.CreateExtractValue(value, expr.Index, "")
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if index.Type().IntTypeWidth() < b.intType.IntTypeWidth() {
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index = b.CreateSExt(index, b.intType, "")
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}
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return index
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} else if expr.Index == 1 {
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// comma-ok
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value := b.getValue(expr.Tuple)
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return b.CreateExtractValue(value, expr.Index, "")
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} else {
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// Select statements are (index, ok, ...) where ... is a number of
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// received values, depending on how many receive statements there
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// are. They are all combined into one alloca (because only one
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// receive can proceed at a time) so we'll get that alloca, bitcast
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// it to the correct type, and dereference it.
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recvbuf := b.selectRecvBuf[expr.Tuple.(*ssa.Select)]
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typ := b.getLLVMType(expr.Type())
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ptr := b.CreateBitCast(recvbuf, llvm.PointerType(typ, 0), "")
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return b.CreateLoad(typ, ptr, "")
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}
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}
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