# # # Nim's Runtime Library # (c) Copyright 2015 Dominik Picheta # # See the file "copying.txt", included in this # distribution, for details about the copyright. # ## AsyncMacro ## ************* ## `asyncdispatch` module depends on the `asyncmacro` module to work properly. import macros, strutils, asyncfutures2 proc skipUntilStmtList(node: NimNode): NimNode {.compileTime.} = # Skips a nest of StmtList's. result = node if node[0].kind == nnkStmtList: result = skipUntilStmtList(node[0]) proc skipStmtList(node: NimNode): NimNode {.compileTime.} = result = node if node[0].kind == nnkStmtList: result = node[0] template createCb(retFutureSym, iteratorNameSym, strName, identName, futureVarCompletions: untyped) = bind finished var nameIterVar = iteratorNameSym #{.push stackTrace: off.} proc identName(udata: pointer = nil) {.closure.} = try: if not nameIterVar.finished: var next = nameIterVar() # Continue while the yielded future is already finished. while (not next.isNil) and next.finished: next = nameIterVar() if nameIterVar.finished: break if next == nil: if not retFutureSym.finished: let msg = "Async procedure ($1) yielded `nil`, are you await'ing a " & "`nil` Future?" raise newException(AssertionError, msg % strName) else: {.gcsafe.}: {.push hint[ConvFromXtoItselfNotNeeded]: off.} next.callback = CallbackFunc(identName) {.pop.} except: futureVarCompletions if retFutureSym.finished: # Take a look at tasyncexceptions for the bug which this fixes. # That test explains it better than I can here. raise else: retFutureSym.fail(getCurrentException()) identName() #{.pop.} proc generateExceptionCheck(futSym, tryStmt, rootReceiver, fromNode: NimNode): NimNode {.compileTime.} = if tryStmt.kind == nnkNilLit: result = rootReceiver else: var exceptionChecks: seq[tuple[cond, body: NimNode]] = @[] let errorNode = newDotExpr(futSym, newIdentNode("error")) for i in 1 ..< tryStmt.len: let exceptBranch = tryStmt[i] if exceptBranch[0].kind == nnkStmtList: exceptionChecks.add((newIdentNode("true"), exceptBranch[0])) else: var exceptIdentCount = 0 var ifCond: NimNode for i in 0 ..< exceptBranch.len: let child = exceptBranch[i] if child.kind == nnkIdent: let cond = infix(errorNode, "of", child) if exceptIdentCount == 0: ifCond = cond else: ifCond = infix(ifCond, "or", cond) else: break exceptIdentCount.inc expectKind(exceptBranch[exceptIdentCount], nnkStmtList) exceptionChecks.add((ifCond, exceptBranch[exceptIdentCount])) # -> -> else: raise futSym.error exceptionChecks.add((newIdentNode("true"), newNimNode(nnkRaiseStmt).add(errorNode))) # Read the future if there is no error. # -> else: futSym.read let elseNode = newNimNode(nnkElse, fromNode) elseNode.add newNimNode(nnkStmtList, fromNode) elseNode[0].add rootReceiver let ifBody = newStmtList() ifBody.add newCall(newIdentNode("setCurrentException"), errorNode) ifBody.add newIfStmt(exceptionChecks) ifBody.add newCall(newIdentNode("setCurrentException"), newNilLit()) result = newIfStmt( (newDotExpr(futSym, newIdentNode("failed")), ifBody) ) result.add elseNode template useVar(result: var NimNode, futureVarNode: NimNode, valueReceiver, rootReceiver: untyped, fromNode: NimNode) = ## Params: ## futureVarNode: The NimNode which is a symbol identifying the Future[T] ## variable to yield. ## fromNode: Used for better debug information (to give context). ## valueReceiver: The node which defines an expression that retrieves the ## future's value. ## ## rootReceiver: ??? TODO # -> yield future result.add newNimNode(nnkYieldStmt, fromNode).add(futureVarNode) # -> future.read valueReceiver = newDotExpr(futureVarNode, newIdentNode("read")) result.add generateExceptionCheck(futureVarNode, tryStmt, rootReceiver, fromNode) template createVar(result: var NimNode, futSymName: string, asyncProc: NimNode, valueReceiver, rootReceiver: untyped, fromNode: NimNode) = result = newNimNode(nnkStmtList, fromNode) var futSym = genSym(nskVar, "future") result.add newVarStmt(futSym, asyncProc) # -> var future = y useVar(result, futSym, valueReceiver, rootReceiver, fromNode) proc createFutureVarCompletions(futureVarIdents: seq[NimNode], fromNode: NimNode): NimNode {.compileTime.} = result = newNimNode(nnkStmtList, fromNode) # Add calls to complete each FutureVar parameter. for ident in futureVarIdents: # Only complete them if they have not been completed already by the user. # TODO: Once https://github.com/nim-lang/Nim/issues/5617 is fixed. # TODO: Add line info to the complete() call! # In the meantime, this was really useful for debugging :) #result.add(newCall(newIdentNode("echo"), newStrLitNode(fromNode.lineinfo))) result.add newIfStmt( ( newCall(newIdentNode("not"), newDotExpr(ident, newIdentNode("finished"))), newCall(newIdentNode("complete"), ident) ) ) proc processBody(node, retFutureSym: NimNode, subTypeIsVoid: bool, futureVarIdents: seq[NimNode], tryStmt: NimNode): NimNode {.compileTime.} = #echo(node.treeRepr) result = node case node.kind of nnkReturnStmt: result = newNimNode(nnkStmtList, node) # As I've painfully found out, the order here really DOES matter. result.add createFutureVarCompletions(futureVarIdents, node) if node[0].kind == nnkEmpty: if not subTypeIsVoid: result.add newCall(newIdentNode("complete"), retFutureSym, newIdentNode("result")) else: result.add newCall(newIdentNode("complete"), retFutureSym) else: let x = node[0].processBody(retFutureSym, subTypeIsVoid, futureVarIdents, tryStmt) if x.kind == nnkYieldStmt: result.add x else: result.add newCall(newIdentNode("complete"), retFutureSym, x) result.add newNimNode(nnkReturnStmt, node).add(newNilLit()) return # Don't process the children of this return stmt of nnkCommand, nnkCall: if node[0].kind == nnkIdent and node[0].eqIdent("await"): case node[1].kind of nnkIdent, nnkInfix, nnkDotExpr, nnkCall, nnkCommand: # await x # await x or y # await foo(p, x) # await foo p, x var futureValue: NimNode result.createVar("future" & $node[1][0].toStrLit, node[1], futureValue, futureValue, node) else: error("Invalid node kind in 'await', got: " & $node[1].kind) elif node.len > 1 and node[1].kind == nnkCommand and node[1][0].kind == nnkIdent and node[1][0].eqIdent("await"): # foo await x var newCommand = node result.createVar("future" & $node[0].toStrLit, node[1][1], newCommand[1], newCommand, node) of nnkVarSection, nnkLetSection: case node[0][2].kind of nnkCommand: if node[0][2][0].kind == nnkIdent and node[0][2][0].eqIdent("await"): # var x = await y var newVarSection = node # TODO: Should this use copyNimNode? result.createVar("future" & node[0][0].strVal, node[0][2][1], newVarSection[0][2], newVarSection, node) else: discard of nnkAsgn: case node[1].kind of nnkCommand: if node[1][0].eqIdent("await"): # x = await y var newAsgn = node result.createVar("future" & $node[0].toStrLit, node[1][1], newAsgn[1], newAsgn, node) else: discard of nnkDiscardStmt: # discard await x if node[0].kind == nnkCommand and node[0][0].kind == nnkIdent and node[0][0].eqIdent("await"): var newDiscard = node result.createVar("futureDiscard_" & $toStrLit(node[0][1]), node[0][1], newDiscard[0], newDiscard, node) of nnkTryStmt: # try: await x; except: ... result = newNimNode(nnkStmtList, node) template wrapInTry(n, tryBody: untyped) = var temp = n n[0] = tryBody tryBody = temp # Transform ``except`` body. # TODO: Could we perform some ``await`` transformation here to get it # working in ``except``? tryBody[1] = processBody(n[1], retFutureSym, subTypeIsVoid, futureVarIdents, nil) proc processForTry(n: NimNode, i: var int, res: NimNode): bool {.compileTime.} = ## Transforms the body of the tryStmt. Does not transform the ## body in ``except``. ## Returns true if the tryStmt node was transformed into an ifStmt. result = false var skipped = n.skipStmtList() while i < skipped.len: var processed = processBody(skipped[i], retFutureSym, subTypeIsVoid, futureVarIdents, n) # Check if we transformed the node into an exception check. # This suggests skipped[i] contains ``await``. if processed.kind != skipped[i].kind or processed.len != skipped[i].len: processed = processed.skipUntilStmtList() expectKind(processed, nnkStmtList) expectKind(processed[2][1], nnkElse) i.inc if not processForTry(n, i, processed[2][1][0]): # We need to wrap the nnkElse nodes back into a tryStmt. # As they are executed if an exception does not happen # inside the awaited future. # The following code will wrap the nodes inside the # original tryStmt. wrapInTry(n, processed[2][1][0]) res.add processed result = true else: res.add skipped[i] i.inc var i = 0 if not processForTry(node, i, result): # If the tryStmt hasn't been transformed we can just put the body # back into it. wrapInTry(node, result) return else: discard for i in 0 ..< result.len: result[i] = processBody(result[i], retFutureSym, subTypeIsVoid, futureVarIdents, nil) proc getName(node: NimNode): string {.compileTime.} = case node.kind of nnkPostfix: return node[1].strVal of nnkIdent: return node.strVal of nnkEmpty: return "anonymous" else: error("Unknown name.") proc getFutureVarIdents(params: NimNode): seq[NimNode] {.compileTime.} = result = @[] for i in 1 ..< len(params): expectKind(params[i], nnkIdentDefs) if params[i][1].kind == nnkBracketExpr and params[i][1][0].eqIdent("futurevar"): result.add(params[i][0]) proc isInvalidReturnType(typeName: string): bool = return typeName notin ["Future"] #, "FutureStream"] proc verifyReturnType(typeName: string) {.compileTime.} = if typeName.isInvalidReturnType: error("Expected return type of 'Future' got '$1'" % typeName) proc asyncSingleProc(prc: NimNode): NimNode {.compileTime.} = ## This macro transforms a single procedure into a closure iterator. ## The ``async`` macro supports a stmtList holding multiple async procedures. if prc.kind notin {nnkProcDef, nnkLambda, nnkMethodDef, nnkDo}: error("Cannot transform this node kind into an async proc." & " proc/method definition or lambda node expected.") let prcName = prc.name.getName let returnType = prc.params[0] var baseType: NimNode # Verify that the return type is a Future[T] if returnType.kind == nnkBracketExpr: let fut = repr(returnType[0]) verifyReturnType(fut) baseType = returnType[1] elif returnType.kind in nnkCallKinds and returnType[0].eqIdent("[]"): let fut = repr(returnType[1]) verifyReturnType(fut) baseType = returnType[2] elif returnType.kind == nnkEmpty: baseType = returnType else: verifyReturnType(repr(returnType)) let subtypeIsVoid = returnType.kind == nnkEmpty or (baseType.kind == nnkIdent and returnType[1].eqIdent("void")) let futureVarIdents = getFutureVarIdents(prc.params) var outerProcBody = newNimNode(nnkStmtList, prc.body) # -> var retFuture = newFuture[T]() var retFutureSym = genSym(nskVar, "retFuture") var subRetType = if returnType.kind == nnkEmpty: newIdentNode("void") else: baseType outerProcBody.add( newVarStmt(retFutureSym, newCall( newNimNode(nnkBracketExpr, prc.body).add( newIdentNode("newFuture"), subRetType), newLit(prcName)))) # Get type from return type of this proc # -> iterator nameIter(): FutureBase {.closure.} = # -> {.push warning[resultshadowed]: off.} # -> var result: T # -> {.pop.} # -> # -> complete(retFuture, result) var iteratorNameSym = genSym(nskIterator, $prcName & "Iter") var procBody = prc.body.processBody(retFutureSym, subtypeIsVoid, futureVarIdents, nil) # don't do anything with forward bodies (empty) if procBody.kind != nnkEmpty: procBody.add(createFutureVarCompletions(futureVarIdents, nil)) if not subtypeIsVoid: procBody.insert(0, newNimNode(nnkPragma).add(newIdentNode("push"), newNimNode(nnkExprColonExpr).add(newNimNode(nnkBracketExpr).add( newIdentNode("warning"), newIdentNode("resultshadowed")), newIdentNode("off")))) # -> {.push warning[resultshadowed]: off.} procBody.insert(1, newNimNode(nnkVarSection, prc.body).add( newIdentDefs(newIdentNode("result"), baseType))) # -> var result: T procBody.insert(2, newNimNode(nnkPragma).add( newIdentNode("pop"))) # -> {.pop.}) procBody.add( newCall(newIdentNode("complete"), retFutureSym, newIdentNode("result"))) # -> complete(retFuture, result) else: # -> complete(retFuture) procBody.add(newCall(newIdentNode("complete"), retFutureSym)) var closureIterator = newProc(iteratorNameSym, [newIdentNode("FutureBase")], procBody, nnkIteratorDef) closureIterator.pragma = newNimNode(nnkPragma, lineInfoFrom=prc.body) closureIterator.addPragma(newIdentNode("closure")) # If proc has an explicit gcsafe pragma, we add it to iterator as well. if prc.pragma.findChild(it.kind in {nnkSym, nnkIdent} and $it == "gcsafe") != nil: closureIterator.addPragma(newIdentNode("gcsafe")) outerProcBody.add(closureIterator) # -> createCb(retFuture) # NOTE: The "_continue" suffix is checked for in asyncfutures.nim to produce # friendlier stack traces: var cbName = genSym(nskProc, prcName & "_continue") var procCb = getAst createCb(retFutureSym, iteratorNameSym, newStrLitNode(prcName), cbName, createFutureVarCompletions(futureVarIdents, nil)) outerProcBody.add procCb # -> return retFuture outerProcBody.add newNimNode(nnkReturnStmt, prc.body[^1]).add(retFutureSym) result = prc if subtypeIsVoid: # Add discardable pragma. if returnType.kind == nnkEmpty: # Add Future[void] result.params[0] = parseExpr("Future[void]") if procBody.kind != nnkEmpty: result.body = outerProcBody #echo(treeRepr(result)) #if prcName == "recvLineInto": # echo(toStrLit(result)) macro async*(prc: untyped): untyped = ## Macro which processes async procedures into the appropriate ## iterators and yield statements. if prc.kind == nnkStmtList: for oneProc in prc: result = newStmtList() result.add asyncSingleProc(oneProc) else: result = asyncSingleProc(prc) when defined(nimDumpAsync): echo repr result # Multisync proc emptyNoop[T](x: T): T = # The ``await``s are replaced by a call to this for simplicity. when T isnot void: return x proc stripAwait(node: NimNode): NimNode = ## Strips out all ``await`` commands from a procedure body, replaces them ## with ``emptyNoop`` for simplicity. result = node let emptyNoopSym = bindSym("emptyNoop") case node.kind of nnkCommand, nnkCall: if node[0].kind == nnkIdent and node[0].eqIdent("await"): node[0] = emptyNoopSym elif node.len > 1 and node[1].kind == nnkCommand and node[1][0].kind == nnkIdent and node[1][0].eqIdent("await"): # foo await x node[1][0] = emptyNoopSym of nnkVarSection, nnkLetSection: case node[0][2].kind of nnkCommand: if node[0][2][0].kind == nnkIdent and node[0][2][0].eqIdent("await"): # var x = await y node[0][2][0] = emptyNoopSym else: discard of nnkAsgn: case node[1].kind of nnkCommand: if node[1][0].eqIdent("await"): # x = await y node[1][0] = emptyNoopSym else: discard of nnkDiscardStmt: # discard await x if node[0].kind == nnkCommand and node[0][0].kind == nnkIdent and node[0][0].eqIdent("await"): node[0][0] = emptyNoopSym else: discard for i in 0 ..< result.len: result[i] = stripAwait(result[i]) proc splitParamType(paramType: NimNode, async: bool): NimNode = result = paramType if paramType.kind == nnkInfix and paramType[0].strVal in ["|", "or"]: let firstAsync = "async" in paramType[1].strVal.normalize let secondAsync = "async" in paramType[2].strVal.normalize if firstAsync: result = paramType[if async: 1 else: 2] elif secondAsync: result = paramType[if async: 2 else: 1] proc stripReturnType(returnType: NimNode): NimNode = # Strip out the 'Future' from 'Future[T]'. result = returnType if returnType.kind == nnkBracketExpr: let fut = repr(returnType[0]) verifyReturnType(fut) result = returnType[1] proc splitProc(prc: NimNode): (NimNode, NimNode) = ## Takes a procedure definition which takes a generic union of arguments, ## for example: proc (socket: Socket | AsyncSocket). ## It transforms them so that ``proc (socket: Socket)`` and ## ``proc (socket: AsyncSocket)`` are returned. result[0] = prc.copyNimTree() # Retrieve the `T` inside `Future[T]`. let returnType = stripReturnType(result[0][3][0]) result[0][3][0] = splitParamType(returnType, async=false) for i in 1 ..< result[0][3].len: # Sync proc (0) -> FormalParams (3) -> IdentDefs, the parameter (i) -> # parameter type (1). result[0][3][i][1] = splitParamType(result[0][3][i][1], async=false) result[0][6] = stripAwait(result[0][6]) result[1] = prc.copyNimTree() if result[1][3][0].kind == nnkBracketExpr: result[1][3][0][1] = splitParamType(result[1][3][0][1], async=true) for i in 1 ..< result[1][3].len: # Async proc (1) -> FormalParams (3) -> IdentDefs, the parameter (i) -> # parameter type (1). result[1][3][i][1] = splitParamType(result[1][3][i][1], async=true) macro multisync*(prc: untyped): untyped = ## Macro which processes async procedures into both asynchronous and ## synchronous procedures. ## ## The generated async procedures use the ``async`` macro, whereas the ## generated synchronous procedures simply strip off the ``await`` calls. let (sync, asyncPrc) = splitProc(prc) result = newStmtList() result.add(asyncSingleProc(asyncPrc)) result.add(sync)