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- #
- #
- # The Nim Compiler
- # (c) Copyright 2015 Andreas Rumpf
- #
- # See the file "copying.txt", included in this
- # distribution, for details about the copyright.
- #
- # This module implements the transformator. It transforms the syntax tree
- # to ease the work of the code generators. Does some transformations:
- #
- # * inlines iterators
- # * inlines constants
- # * performs constant folding
- # * converts "continue" to "break"; disambiguates "break"
- # * introduces method dispatchers
- # * performs lambda lifting for closure support
- # * transforms 'defer' into a 'try finally' statement
- import
- options, ast, astalgo, trees, msgs,
- idents, renderer, types, semfold, magicsys, cgmeth,
- lowerings, liftlocals,
- modulegraphs, lineinfos
- proc transformBody*(g: ModuleGraph, prc: PSym, cache: bool): PNode
- import closureiters, lambdalifting
- type
- PTransCon = ref TTransCon
- TTransCon{.final.} = object # part of TContext; stackable
- mapping: TIdNodeTable # mapping from symbols to nodes
- owner: PSym # current owner
- forStmt: PNode # current for stmt
- forLoopBody: PNode # transformed for loop body
- yieldStmts: int # we count the number of yield statements,
- # because we need to introduce new variables
- # if we encounter the 2nd yield statement
- next: PTransCon # for stacking
- TTransfContext = object of TPassContext
- module: PSym
- transCon: PTransCon # top of a TransCon stack
- inlining: int # > 0 if we are in inlining context (copy vars)
- nestedProcs: int # > 0 if we are in a nested proc
- contSyms, breakSyms: seq[PSym] # to transform 'continue' and 'break'
- deferDetected, tooEarly: bool
- graph: ModuleGraph
- PTransf = ref TTransfContext
- proc newTransNode(a: PNode): PNode {.inline.} =
- result = shallowCopy(a)
- proc newTransNode(kind: TNodeKind, info: TLineInfo,
- sons: int): PNode {.inline.} =
- var x = newNodeI(kind, info)
- newSeq(x.sons, sons)
- result = x
- proc newTransNode(kind: TNodeKind, n: PNode,
- sons: int): PNode {.inline.} =
- var x = newNodeIT(kind, n.info, n.typ)
- newSeq(x.sons, sons)
- x.typ = n.typ
- # x.flags = n.flags
- result = x
- proc newTransCon(owner: PSym): PTransCon =
- assert owner != nil
- new(result)
- initIdNodeTable(result.mapping)
- result.owner = owner
- proc pushTransCon(c: PTransf, t: PTransCon) =
- t.next = c.transCon
- c.transCon = t
- proc popTransCon(c: PTransf) =
- if (c.transCon == nil): internalError(c.graph.config, "popTransCon")
- c.transCon = c.transCon.next
- proc getCurrOwner(c: PTransf): PSym =
- if c.transCon != nil: result = c.transCon.owner
- else: result = c.module
- proc newTemp(c: PTransf, typ: PType, info: TLineInfo): PNode =
- let r = newSym(skTemp, getIdent(c.graph.cache, genPrefix), getCurrOwner(c), info)
- r.typ = typ #skipTypes(typ, {tyGenericInst, tyAlias, tySink})
- incl(r.flags, sfFromGeneric)
- let owner = getCurrOwner(c)
- if owner.isIterator and not c.tooEarly:
- result = freshVarForClosureIter(c.graph, r, owner)
- else:
- result = newSymNode(r)
- proc transform(c: PTransf, n: PNode): PNode
- proc transformSons(c: PTransf, n: PNode): PNode =
- result = newTransNode(n)
- for i in 0..<n.len:
- result[i] = transform(c, n[i])
- proc newAsgnStmt(c: PTransf, kind: TNodeKind, le: PNode, ri: PNode): PNode =
- result = newTransNode(kind, ri.info, 2)
- result[0] = le
- result[1] = ri
- proc transformSymAux(c: PTransf, n: PNode): PNode =
- let s = n.sym
- if s.typ != nil and s.typ.callConv == ccClosure:
- if s.kind in routineKinds:
- discard transformBody(c.graph, s, true)
- if s.kind == skIterator:
- if c.tooEarly: return n
- else: return liftIterSym(c.graph, n, getCurrOwner(c))
- elif s.kind in {skProc, skFunc, skConverter, skMethod} and not c.tooEarly:
- # top level .closure procs are still somewhat supported for 'Nake':
- return makeClosure(c.graph, s, nil, n.info)
- #elif n.sym.kind in {skVar, skLet} and n.sym.typ.callConv == ccClosure:
- # echo n.info, " come heer for ", c.tooEarly
- # if not c.tooEarly:
- var b: PNode
- var tc = c.transCon
- if sfBorrow in s.flags and s.kind in routineKinds:
- # simply exchange the symbol:
- b = s.getBody
- if b.kind != nkSym: internalError(c.graph.config, n.info, "wrong AST for borrowed symbol")
- b = newSymNode(b.sym, n.info)
- elif c.inlining > 0:
- # see bug #13596: we use ref-based equality in the DFA for destruction
- # injections so we need to ensure unique nodes after iterator inlining
- # which can lead to duplicated for loop bodies! Consider:
- #[
- while remaining > 0:
- if ending == nil:
- yield ms
- break
- ...
- yield ms
- ]#
- b = newSymNode(n.sym, n.info)
- else:
- b = n
- while tc != nil:
- result = idNodeTableGet(tc.mapping, b.sym)
- if result != nil:
- # this slightly convoluted way ensures the line info stays correct:
- if result.kind == nkSym:
- result = copyNode(result)
- result.info = n.info
- return
- tc = tc.next
- result = b
- proc transformSym(c: PTransf, n: PNode): PNode =
- result = transformSymAux(c, n)
- proc freshVar(c: PTransf; v: PSym): PNode =
- let owner = getCurrOwner(c)
- if owner.isIterator and not c.tooEarly:
- result = freshVarForClosureIter(c.graph, v, owner)
- else:
- var newVar = copySym(v)
- incl(newVar.flags, sfFromGeneric)
- newVar.owner = owner
- result = newSymNode(newVar)
- proc transformVarSection(c: PTransf, v: PNode): PNode =
- result = newTransNode(v)
- for i in 0..<v.len:
- var it = v[i]
- if it.kind == nkCommentStmt:
- result[i] = it
- elif it.kind == nkIdentDefs:
- if it[0].kind == nkSym:
- internalAssert(c.graph.config, it.len == 3)
- let x = freshVar(c, it[0].sym)
- idNodeTablePut(c.transCon.mapping, it[0].sym, x)
- var defs = newTransNode(nkIdentDefs, it.info, 3)
- if importantComments(c.graph.config):
- # keep documentation information:
- defs.comment = it.comment
- defs[0] = x
- defs[1] = it[1]
- defs[2] = transform(c, it[2])
- if x.kind == nkSym: x.sym.ast = defs[2]
- result[i] = defs
- else:
- # has been transformed into 'param.x' for closure iterators, so just
- # transform it:
- result[i] = transform(c, it)
- else:
- if it.kind != nkVarTuple:
- internalError(c.graph.config, it.info, "transformVarSection: not nkVarTuple")
- var defs = newTransNode(it.kind, it.info, it.len)
- for j in 0..<it.len-2:
- if it[j].kind == nkSym:
- let x = freshVar(c, it[j].sym)
- idNodeTablePut(c.transCon.mapping, it[j].sym, x)
- defs[j] = x
- else:
- defs[j] = transform(c, it[j])
- assert(it[^2].kind == nkEmpty)
- defs[^2] = newNodeI(nkEmpty, it.info)
- defs[^1] = transform(c, it[^1])
- result[i] = defs
- proc transformConstSection(c: PTransf, v: PNode): PNode =
- result = v
- when false:
- result = newTransNode(v)
- for i in 0..<v.len:
- var it = v[i]
- if it.kind == nkCommentStmt:
- result[i] = it
- else:
- if it.kind != nkConstDef: internalError(c.graph.config, it.info, "transformConstSection")
- if it[0].kind != nkSym:
- debug it[0]
- internalError(c.graph.config, it.info, "transformConstSection")
- result[i] = it
- proc hasContinue(n: PNode): bool =
- case n.kind
- of nkEmpty..nkNilLit, nkForStmt, nkParForStmt, nkWhileStmt: discard
- of nkContinueStmt: result = true
- else:
- for i in 0..<n.len:
- if hasContinue(n[i]): return true
- proc newLabel(c: PTransf, n: PNode): PSym =
- result = newSym(skLabel, nil, getCurrOwner(c), n.info)
- result.name = getIdent(c.graph.cache, genPrefix)
- proc transformBlock(c: PTransf, n: PNode): PNode =
- var labl: PSym
- if c.inlining > 0:
- labl = newLabel(c, n[0])
- idNodeTablePut(c.transCon.mapping, n[0].sym, newSymNode(labl))
- else:
- labl =
- if n[0].kind != nkEmpty:
- n[0].sym # already named block? -> Push symbol on the stack
- else:
- newLabel(c, n)
- c.breakSyms.add(labl)
- result = transformSons(c, n)
- discard c.breakSyms.pop
- result[0] = newSymNode(labl)
- proc transformLoopBody(c: PTransf, n: PNode): PNode =
- # What if it contains "continue" and "break"? "break" needs
- # an explicit label too, but not the same!
- # We fix this here by making every 'break' belong to its enclosing loop
- # and changing all breaks that belong to a 'block' by annotating it with
- # a label (if it hasn't one already).
- if hasContinue(n):
- let labl = newLabel(c, n)
- c.contSyms.add(labl)
- result = newTransNode(nkBlockStmt, n.info, 2)
- result[0] = newSymNode(labl)
- result[1] = transform(c, n)
- discard c.contSyms.pop()
- else:
- result = transform(c, n)
- proc transformWhile(c: PTransf; n: PNode): PNode =
- if c.inlining > 0:
- result = transformSons(c, n)
- else:
- let labl = newLabel(c, n)
- c.breakSyms.add(labl)
- result = newTransNode(nkBlockStmt, n.info, 2)
- result[0] = newSymNode(labl)
- var body = newTransNode(n)
- for i in 0..<n.len-1:
- body[i] = transform(c, n[i])
- body[^1] = transformLoopBody(c, n[^1])
- result[1] = body
- discard c.breakSyms.pop
- proc transformBreak(c: PTransf, n: PNode): PNode =
- result = transformSons(c, n)
- if n[0].kind == nkEmpty and c.breakSyms.len > 0:
- let labl = c.breakSyms[c.breakSyms.high]
- result[0] = newSymNode(labl)
- proc introduceNewLocalVars(c: PTransf, n: PNode): PNode =
- case n.kind
- of nkSym:
- result = transformSym(c, n)
- of nkEmpty..pred(nkSym), succ(nkSym)..nkNilLit:
- # nothing to be done for leaves:
- result = n
- of nkVarSection, nkLetSection:
- result = transformVarSection(c, n)
- of nkClosure:
- # it can happen that for-loop-inlining produced a fresh
- # set of variables, including some computed environment
- # (bug #2604). We need to patch this environment here too:
- let a = n[1]
- if a.kind == nkSym:
- n[1] = transformSymAux(c, a)
- return n
- else:
- result = newTransNode(n)
- for i in 0..<n.len:
- result[i] = introduceNewLocalVars(c, n[i])
- proc transformAsgn(c: PTransf, n: PNode): PNode =
- let rhs = n[1]
- if rhs.kind != nkTupleConstr:
- return transformSons(c, n)
- # Unpack the tuple assignment into N temporary variables and then pack them
- # into a tuple: this allows us to get the correct results even when the rhs
- # depends on the value of the lhs
- let letSection = newTransNode(nkLetSection, n.info, rhs.len)
- let newTupleConstr = newTransNode(nkTupleConstr, n.info, rhs.len)
- for i, field in rhs:
- let val = if field.kind == nkExprColonExpr: field[1] else: field
- let def = newTransNode(nkIdentDefs, field.info, 3)
- def[0] = newTemp(c, val.typ, field.info)
- def[1] = newNodeI(nkEmpty, field.info)
- def[2] = transform(c, val)
- letSection[i] = def
- # NOTE: We assume the constructor fields are in the correct order for the
- # given tuple type
- newTupleConstr[i] = def[0]
- newTupleConstr.typ = rhs.typ
- let asgnNode = newTransNode(nkAsgn, n.info, 2)
- asgnNode[0] = transform(c, n[0])
- asgnNode[1] = newTupleConstr
- result = newTransNode(nkStmtList, n.info, 2)
- result[0] = letSection
- result[1] = asgnNode
- proc transformYield(c: PTransf, n: PNode): PNode =
- proc asgnTo(lhs: PNode, rhs: PNode): PNode =
- # Choose the right assignment instruction according to the given ``lhs``
- # node since it may not be a nkSym (a stack-allocated skForVar) but a
- # nkDotExpr (a heap-allocated slot into the envP block)
- case lhs.kind
- of nkSym:
- internalAssert c.graph.config, lhs.sym.kind == skForVar
- result = newAsgnStmt(c, nkFastAsgn, lhs, rhs)
- of nkDotExpr:
- result = newAsgnStmt(c, nkAsgn, lhs, rhs)
- else:
- internalAssert c.graph.config, false
- result = newTransNode(nkStmtList, n.info, 0)
- var e = n[0]
- # c.transCon.forStmt.len == 3 means that there is one for loop variable
- # and thus no tuple unpacking:
- if e.typ.isNil: return result # can happen in nimsuggest for unknown reasons
- if c.transCon.forStmt.len != 3:
- e = skipConv(e)
- if e.kind in {nkPar, nkTupleConstr}:
- for i in 0..<e.len:
- var v = e[i]
- if v.kind == nkExprColonExpr: v = v[1]
- if c.transCon.forStmt[i].kind == nkVarTuple:
- for j in 0..<c.transCon.forStmt[i].len-1:
- let lhs = c.transCon.forStmt[i][j]
- let rhs = transform(c, newTupleAccess(c.graph, v, j))
- result.add(asgnTo(lhs, rhs))
- else:
- let lhs = c.transCon.forStmt[i]
- let rhs = transform(c, v)
- result.add(asgnTo(lhs, rhs))
- else:
- # Unpack the tuple into the loop variables
- # XXX: BUG: what if `n` is an expression with side-effects?
- for i in 0..<c.transCon.forStmt.len - 2:
- let lhs = c.transCon.forStmt[i]
- let rhs = transform(c, newTupleAccess(c.graph, e, i))
- result.add(asgnTo(lhs, rhs))
- else:
- if c.transCon.forStmt[0].kind == nkVarTuple:
- for i in 0..<c.transCon.forStmt[0].len-1:
- let lhs = c.transCon.forStmt[0][i]
- let rhs = transform(c, newTupleAccess(c.graph, e, i))
- result.add(asgnTo(lhs, rhs))
- else:
- let lhs = c.transCon.forStmt[0]
- let rhs = transform(c, e)
- result.add(asgnTo(lhs, rhs))
- inc(c.transCon.yieldStmts)
- if c.transCon.yieldStmts <= 1:
- # common case
- result.add(c.transCon.forLoopBody)
- else:
- # we need to introduce new local variables:
- result.add(introduceNewLocalVars(c, c.transCon.forLoopBody))
- if result.len > 0:
- var changeNode = result[0]
- changeNode.info = c.transCon.forStmt.info
- for i, child in changeNode:
- child.info = changeNode.info
- proc transformAddrDeref(c: PTransf, n: PNode, a, b: TNodeKind): PNode =
- result = transformSons(c, n)
- if c.graph.config.backend == backendCpp or sfCompileToCpp in c.module.flags: return
- var n = result
- case n[0].kind
- of nkObjUpConv, nkObjDownConv, nkChckRange, nkChckRangeF, nkChckRange64:
- var m = n[0][0]
- if m.kind == a or m.kind == b:
- # addr ( nkConv ( deref ( x ) ) ) --> nkConv(x)
- n[0][0] = m[0]
- result = n[0]
- if n.typ.skipTypes(abstractVar).kind != tyOpenArray:
- result.typ = n.typ
- elif n.typ.skipTypes(abstractInst).kind in {tyVar}:
- result.typ = toVar(result.typ, n.typ.skipTypes(abstractInst).kind)
- of nkHiddenStdConv, nkHiddenSubConv, nkConv:
- var m = n[0][1]
- if m.kind == a or m.kind == b:
- # addr ( nkConv ( deref ( x ) ) ) --> nkConv(x)
- n[0][1] = m[0]
- result = n[0]
- if n.typ.skipTypes(abstractVar).kind != tyOpenArray:
- result.typ = n.typ
- elif n.typ.skipTypes(abstractInst).kind in {tyVar}:
- result.typ = toVar(result.typ, n.typ.skipTypes(abstractInst).kind)
- else:
- if n[0].kind == a or n[0].kind == b:
- # addr ( deref ( x )) --> x
- result = n[0][0]
- if n.typ.skipTypes(abstractVar).kind != tyOpenArray:
- result.typ = n.typ
- proc generateThunk(c: PTransf; prc: PNode, dest: PType): PNode =
- ## Converts 'prc' into '(thunk, nil)' so that it's compatible with
- ## a closure.
- # we cannot generate a proper thunk here for GC-safety reasons
- # (see internal documentation):
- if c.graph.config.backend == backendJs: return prc
- result = newNodeIT(nkClosure, prc.info, dest)
- var conv = newNodeIT(nkHiddenSubConv, prc.info, dest)
- conv.add(newNodeI(nkEmpty, prc.info))
- conv.add(prc)
- if prc.kind == nkClosure:
- internalError(c.graph.config, prc.info, "closure to closure created")
- result.add(conv)
- result.add(newNodeIT(nkNilLit, prc.info, getSysType(c.graph, prc.info, tyNil)))
- proc transformConv(c: PTransf, n: PNode): PNode =
- # numeric types need range checks:
- var dest = skipTypes(n.typ, abstractVarRange)
- var source = skipTypes(n[1].typ, abstractVarRange)
- case dest.kind
- of tyInt..tyInt64, tyEnum, tyChar, tyUInt8..tyUInt32:
- # we don't include uint and uint64 here as these are no ordinal types ;-)
- if not isOrdinalType(source):
- # float -> int conversions. ugh.
- result = transformSons(c, n)
- elif firstOrd(c.graph.config, n.typ) <= firstOrd(c.graph.config, n[1].typ) and
- lastOrd(c.graph.config, n[1].typ) <= lastOrd(c.graph.config, n.typ):
- # BUGFIX: simply leave n as it is; we need a nkConv node,
- # but no range check:
- result = transformSons(c, n)
- else:
- # generate a range check:
- if dest.kind == tyInt64 or source.kind == tyInt64:
- result = newTransNode(nkChckRange64, n, 3)
- else:
- result = newTransNode(nkChckRange, n, 3)
- dest = skipTypes(n.typ, abstractVar)
- result[0] = transform(c, n[1])
- result[1] = newIntTypeNode(firstOrd(c.graph.config, dest), dest)
- result[2] = newIntTypeNode(lastOrd(c.graph.config, dest), dest)
- of tyFloat..tyFloat128:
- # XXX int64 -> float conversion?
- if skipTypes(n.typ, abstractVar).kind == tyRange:
- result = newTransNode(nkChckRangeF, n, 3)
- dest = skipTypes(n.typ, abstractVar)
- result[0] = transform(c, n[1])
- result[1] = copyTree(dest.n[0])
- result[2] = copyTree(dest.n[1])
- else:
- result = transformSons(c, n)
- of tyOpenArray, tyVarargs:
- result = transform(c, n[1])
- #result = transformSons(c, n)
- result.typ = takeType(n.typ, n[1].typ)
- #echo n.info, " came here and produced ", typeToString(result.typ),
- # " from ", typeToString(n.typ), " and ", typeToString(n[1].typ)
- of tyCString:
- if source.kind == tyString:
- result = newTransNode(nkStringToCString, n, 1)
- result[0] = transform(c, n[1])
- else:
- result = transformSons(c, n)
- of tyString:
- if source.kind == tyCString:
- result = newTransNode(nkCStringToString, n, 1)
- result[0] = transform(c, n[1])
- else:
- result = transformSons(c, n)
- of tyRef, tyPtr:
- dest = skipTypes(dest, abstractPtrs)
- source = skipTypes(source, abstractPtrs)
- if source.kind == tyObject:
- var diff = inheritanceDiff(dest, source)
- if diff < 0:
- result = newTransNode(nkObjUpConv, n, 1)
- result[0] = transform(c, n[1])
- elif diff > 0 and diff != high(int):
- result = newTransNode(nkObjDownConv, n, 1)
- result[0] = transform(c, n[1])
- else:
- result = transform(c, n[1])
- else:
- result = transformSons(c, n)
- of tyObject:
- var diff = inheritanceDiff(dest, source)
- if diff < 0:
- result = newTransNode(nkObjUpConv, n, 1)
- result[0] = transform(c, n[1])
- elif diff > 0 and diff != high(int):
- result = newTransNode(nkObjDownConv, n, 1)
- result[0] = transform(c, n[1])
- else:
- result = transform(c, n[1])
- of tyGenericParam, tyOrdinal:
- result = transform(c, n[1])
- # happens sometimes for generated assignments, etc.
- of tyProc:
- result = transformSons(c, n)
- if dest.callConv == ccClosure and source.callConv == ccNimCall:
- result = generateThunk(c, result[1], dest)
- else:
- result = transformSons(c, n)
- type
- TPutArgInto = enum
- paDirectMapping, paFastAsgn, paFastAsgnTakeTypeFromArg
- paVarAsgn, paComplexOpenarray
- proc putArgInto(arg: PNode, formal: PType): TPutArgInto =
- # This analyses how to treat the mapping "formal <-> arg" in an
- # inline context.
- if formal.kind == tyTypeDesc: return paDirectMapping
- if skipTypes(formal, abstractInst).kind in {tyOpenArray, tyVarargs}:
- case arg.kind
- of nkStmtListExpr:
- return paComplexOpenarray
- of nkBracket:
- return paFastAsgnTakeTypeFromArg
- else:
- # XXX incorrect, causes #13417 when `arg` has side effects.
- return paDirectMapping
- case arg.kind
- of nkEmpty..nkNilLit:
- result = paDirectMapping
- of nkDotExpr, nkDerefExpr, nkHiddenDeref, nkAddr, nkHiddenAddr:
- result = putArgInto(arg[0], formal)
- of nkCurly, nkBracket:
- for i in 0..<arg.len:
- if putArgInto(arg[i], formal) != paDirectMapping:
- return paFastAsgn
- result = paDirectMapping
- of nkPar, nkTupleConstr, nkObjConstr:
- for i in 0..<arg.len:
- let a = if arg[i].kind == nkExprColonExpr: arg[i][1]
- else: arg[0]
- if putArgInto(a, formal) != paDirectMapping:
- return paFastAsgn
- result = paDirectMapping
- else:
- if skipTypes(formal, abstractInst).kind in {tyVar, tyLent}: result = paVarAsgn
- else: result = paFastAsgn
- proc findWrongOwners(c: PTransf, n: PNode) =
- if n.kind == nkVarSection:
- let x = n[0][0]
- if x.kind == nkSym and x.sym.owner != getCurrOwner(c):
- internalError(c.graph.config, x.info, "bah " & x.sym.name.s & " " &
- x.sym.owner.name.s & " " & getCurrOwner(c).name.s)
- else:
- for i in 0..<n.safeLen: findWrongOwners(c, n[i])
- proc isSimpleIteratorVar(iter: PSym): bool =
- proc rec(n: PNode; owner: PSym; dangerousYields: var int) =
- case n.kind
- of nkEmpty..nkNilLit: discard
- of nkYieldStmt:
- if n[0].kind == nkSym and n[0].sym.owner == owner:
- discard "good: yield a single variable that we own"
- else:
- inc dangerousYields
- else:
- for c in n: rec(c, owner, dangerousYields)
- var dangerousYields = 0
- rec(iter.ast[bodyPos], iter, dangerousYields)
- result = dangerousYields == 0
- proc transformFor(c: PTransf, n: PNode): PNode =
- # generate access statements for the parameters (unless they are constant)
- # put mapping from formal parameters to actual parameters
- if n.kind != nkForStmt: internalError(c.graph.config, n.info, "transformFor")
- var call = n[^2]
- let labl = newLabel(c, n)
- result = newTransNode(nkBlockStmt, n.info, 2)
- result[0] = newSymNode(labl)
- if call.typ.isNil:
- # see bug #3051
- result[1] = newNode(nkEmpty)
- return result
- c.breakSyms.add(labl)
- if call.kind notin nkCallKinds or call[0].kind != nkSym or
- call[0].typ.skipTypes(abstractInst).callConv == ccClosure:
- result[1] = n
- result[1][^1] = transformLoopBody(c, n[^1])
- result[1][^2] = transform(c, n[^2])
- result[1] = lambdalifting.liftForLoop(c.graph, result[1], getCurrOwner(c))
- discard c.breakSyms.pop
- return result
- #echo "transforming: ", renderTree(n)
- var stmtList = newTransNode(nkStmtList, n.info, 0)
- result[1] = stmtList
- var loopBody = transformLoopBody(c, n[^1])
- discard c.breakSyms.pop
- let iter = call[0].sym
- var v = newNodeI(nkVarSection, n.info)
- for i in 0..<n.len - 2:
- if n[i].kind == nkVarTuple:
- for j in 0..<n[i].len-1:
- addVar(v, copyTree(n[i][j])) # declare new vars
- else:
- if n[i].kind == nkSym and isSimpleIteratorVar(iter):
- incl n[i].sym.flags, sfCursor
- addVar(v, copyTree(n[i])) # declare new vars
- stmtList.add(v)
- # Bugfix: inlined locals belong to the invoking routine, not to the invoked
- # iterator!
- var newC = newTransCon(getCurrOwner(c))
- newC.forStmt = n
- newC.forLoopBody = loopBody
- # this can fail for 'nimsuggest' and 'check':
- if iter.kind != skIterator: return result
- # generate access statements for the parameters (unless they are constant)
- pushTransCon(c, newC)
- for i in 1..<call.len:
- var arg = transform(c, call[i])
- let ff = skipTypes(iter.typ, abstractInst)
- # can happen for 'nim check':
- if i >= ff.n.len: return result
- var formal = ff.n[i].sym
- let pa = putArgInto(arg, formal.typ)
- case pa
- of paDirectMapping:
- idNodeTablePut(newC.mapping, formal, arg)
- of paFastAsgn, paFastAsgnTakeTypeFromArg:
- var t = formal.typ
- if pa == paFastAsgnTakeTypeFromArg:
- t = arg.typ
- elif formal.ast != nil and formal.ast.typ.destructor != nil and t.destructor == nil:
- t = formal.ast.typ # better use the type that actually has a destructor.
- elif t.destructor == nil and arg.typ.destructor != nil:
- t = arg.typ
- # generate a temporary and produce an assignment statement:
- var temp = newTemp(c, t, formal.info)
- addVar(v, temp)
- stmtList.add(newAsgnStmt(c, nkFastAsgn, temp, arg))
- idNodeTablePut(newC.mapping, formal, temp)
- of paVarAsgn:
- assert(skipTypes(formal.typ, abstractInst).kind in {tyVar})
- idNodeTablePut(newC.mapping, formal, arg)
- # XXX BUG still not correct if the arg has a side effect!
- of paComplexOpenarray:
- # arrays will deep copy here (pretty bad).
- var temp = newTemp(c, arg.typ, formal.info)
- addVar(v, temp)
- stmtList.add(newAsgnStmt(c, nkFastAsgn, temp, arg))
- idNodeTablePut(newC.mapping, formal, temp)
- let body = transformBody(c.graph, iter, true)
- pushInfoContext(c.graph.config, n.info)
- inc(c.inlining)
- stmtList.add(transform(c, body))
- #findWrongOwners(c, stmtList.pnode)
- dec(c.inlining)
- popInfoContext(c.graph.config)
- popTransCon(c)
- # echo "transformed: ", stmtList.renderTree
- proc transformCase(c: PTransf, n: PNode): PNode =
- # removes `elif` branches of a case stmt
- # adds ``else: nil`` if needed for the code generator
- result = newTransNode(nkCaseStmt, n, 0)
- var ifs: PNode = nil
- for it in n:
- var e = transform(c, it)
- case it.kind
- of nkElifBranch:
- if ifs == nil:
- # Generate the right node depending on whether `n` is used as a stmt or
- # as an expr
- let kind = if n.typ != nil: nkIfExpr else: nkIfStmt
- ifs = newTransNode(kind, it.info, 0)
- ifs.typ = n.typ
- ifs.add(e)
- of nkElse:
- if ifs == nil: result.add(e)
- else: ifs.add(e)
- else:
- result.add(e)
- if ifs != nil:
- var elseBranch = newTransNode(nkElse, n.info, 1)
- elseBranch[0] = ifs
- result.add(elseBranch)
- elif result.lastSon.kind != nkElse and not (
- skipTypes(n[0].typ, abstractVarRange).kind in
- {tyInt..tyInt64, tyChar, tyEnum, tyUInt..tyUInt64}):
- # fix a stupid code gen bug by normalizing:
- var elseBranch = newTransNode(nkElse, n.info, 1)
- elseBranch[0] = newTransNode(nkNilLit, n.info, 0)
- result.add(elseBranch)
- proc transformArrayAccess(c: PTransf, n: PNode): PNode =
- # XXX this is really bad; transf should use a proper AST visitor
- if n[0].kind == nkSym and n[0].sym.kind == skType:
- result = n
- else:
- result = newTransNode(n)
- for i in 0..<n.len:
- result[i] = transform(c, skipConv(n[i]))
- proc getMergeOp(n: PNode): PSym =
- case n.kind
- of nkCall, nkHiddenCallConv, nkCommand, nkInfix, nkPrefix, nkPostfix,
- nkCallStrLit:
- if n[0].kind == nkSym and n[0].sym.magic == mConStrStr:
- result = n[0].sym
- else: discard
- proc flattenTreeAux(d, a: PNode, op: PSym) =
- let op2 = getMergeOp(a)
- if op2 != nil and
- (op2.id == op.id or op.magic != mNone and op2.magic == op.magic):
- for i in 1..<a.len: flattenTreeAux(d, a[i], op)
- else:
- d.add copyTree(a)
- proc flattenTree(root: PNode): PNode =
- let op = getMergeOp(root)
- if op != nil:
- result = copyNode(root)
- result.add copyTree(root[0])
- flattenTreeAux(result, root, op)
- else:
- result = root
- proc transformCall(c: PTransf, n: PNode): PNode =
- var n = flattenTree(n)
- let op = getMergeOp(n)
- let magic = getMagic(n)
- if op != nil and op.magic != mNone and n.len >= 3:
- result = newTransNode(nkCall, n, 0)
- result.add(transform(c, n[0]))
- var j = 1
- while j < n.len:
- var a = transform(c, n[j])
- inc(j)
- if isConstExpr(a):
- while (j < n.len):
- let b = transform(c, n[j])
- if not isConstExpr(b): break
- a = evalOp(op.magic, n, a, b, nil, c.graph)
- inc(j)
- result.add(a)
- if result.len == 2: result = result[1]
- elif magic == mAddr:
- result = newTransNode(nkAddr, n, 1)
- result[0] = n[1]
- result = transformAddrDeref(c, result, nkDerefExpr, nkHiddenDeref)
- elif magic in {mNBindSym, mTypeOf, mRunnableExamples}:
- # for bindSym(myconst) we MUST NOT perform constant folding:
- result = n
- elif magic == mProcCall:
- # but do not change to its dispatcher:
- result = transformSons(c, n[1])
- elif magic == mStrToStr:
- result = transform(c, n[1])
- else:
- let s = transformSons(c, n)
- # bugfix: check after 'transformSons' if it's still a method call:
- # use the dispatcher for the call:
- if s[0].kind == nkSym and s[0].sym.kind == skMethod:
- when false:
- let t = lastSon(s[0].sym.ast)
- if t.kind != nkSym or sfDispatcher notin t.sym.flags:
- methodDef(s[0].sym, false)
- result = methodCall(s, c.graph.config)
- else:
- result = s
- proc transformExceptBranch(c: PTransf, n: PNode): PNode =
- if n[0].isInfixAs() and not isImportedException(n[0][1].typ, c.graph.config):
- let excTypeNode = n[0][1]
- let actions = newTransNode(nkStmtListExpr, n[1], 2)
- # Generating `let exc = (excType)(getCurrentException())`
- # -> getCurrentException()
- let excCall = callCodegenProc(c.graph, "getCurrentException")
- # -> (excType)
- let convNode = newTransNode(nkHiddenSubConv, n[1].info, 2)
- convNode[0] = newNodeI(nkEmpty, n.info)
- convNode[1] = excCall
- convNode.typ = excTypeNode.typ.toRef()
- # -> let exc = ...
- let identDefs = newTransNode(nkIdentDefs, n[1].info, 3)
- identDefs[0] = n[0][2]
- identDefs[1] = newNodeI(nkEmpty, n.info)
- identDefs[2] = convNode
- let letSection = newTransNode(nkLetSection, n[1].info, 1)
- letSection[0] = identDefs
- # Place the let statement and body of the 'except' branch into new stmtList.
- actions[0] = letSection
- actions[1] = transform(c, n[1])
- # Overwrite 'except' branch body with our stmtList.
- result = newTransNode(nkExceptBranch, n[1].info, 2)
- # Replace the `Exception as foobar` with just `Exception`.
- result[0] = transform(c, n[0][1])
- result[1] = actions
- else:
- result = transformSons(c, n)
- proc dontInlineConstant(orig, cnst: PNode): bool {.inline.} =
- # symbols that expand to a complex constant (array, etc.) should not be
- # inlined, unless it's the empty array:
- result = orig.kind == nkSym and
- cnst.kind in {nkCurly, nkPar, nkTupleConstr, nkBracket} and
- cnst.len != 0
- proc commonOptimizations*(g: ModuleGraph; c: PSym, n: PNode): PNode =
- result = n
- for i in 0..<n.safeLen:
- result[i] = commonOptimizations(g, c, n[i])
- var op = getMergeOp(n)
- if (op != nil) and (op.magic != mNone) and (n.len >= 3):
- result = newNodeIT(nkCall, n.info, n.typ)
- result.add(n[0])
- var args = newNode(nkArgList)
- flattenTreeAux(args, n, op)
- var j = 0
- while j < args.len:
- var a = args[j]
- inc(j)
- if isConstExpr(a):
- while j < args.len:
- let b = args[j]
- if not isConstExpr(b): break
- a = evalOp(op.magic, result, a, b, nil, g)
- inc(j)
- result.add(a)
- if result.len == 2: result = result[1]
- else:
- var cnst = getConstExpr(c, n, g)
- # we inline constants if they are not complex constants:
- if cnst != nil and not dontInlineConstant(n, cnst):
- result = cnst
- else:
- result = n
- proc transform(c: PTransf, n: PNode): PNode =
- when false:
- var oldDeferAnchor: PNode
- if n.kind in {nkElifBranch, nkOfBranch, nkExceptBranch, nkElifExpr,
- nkElseExpr, nkElse, nkForStmt, nkWhileStmt, nkFinally,
- nkBlockStmt, nkBlockExpr}:
- oldDeferAnchor = c.deferAnchor
- c.deferAnchor = n
- case n.kind
- of nkSym:
- result = transformSym(c, n)
- of nkEmpty..pred(nkSym), succ(nkSym)..nkNilLit, nkComesFrom:
- # nothing to be done for leaves:
- result = n
- of nkBracketExpr: result = transformArrayAccess(c, n)
- of procDefs:
- var s = n[namePos].sym
- if n.typ != nil and s.typ.callConv == ccClosure:
- result = transformSym(c, n[namePos])
- # use the same node as before if still a symbol:
- if result.kind == nkSym: result = n
- else:
- result = n
- of nkMacroDef:
- # XXX no proper closure support yet:
- when false:
- if n[genericParamsPos].kind == nkEmpty:
- var s = n[namePos].sym
- n[bodyPos] = transform(c, s.getBody)
- if n.kind == nkMethodDef: methodDef(s, false)
- result = n
- of nkForStmt:
- result = transformFor(c, n)
- of nkParForStmt:
- result = transformSons(c, n)
- of nkCaseStmt:
- result = transformCase(c, n)
- of nkWhileStmt: result = transformWhile(c, n)
- of nkBlockStmt, nkBlockExpr:
- result = transformBlock(c, n)
- of nkDefer:
- c.deferDetected = true
- result = transformSons(c, n)
- when false:
- let deferPart = newNodeI(nkFinally, n.info)
- deferPart.add n[0]
- let tryStmt = newNodeI(nkTryStmt, n.info)
- if c.deferAnchor.isNil:
- tryStmt.add c.root
- c.root = tryStmt
- result = tryStmt
- else:
- # modify the corresponding *action*, don't rely on nkStmtList:
- tryStmt.add c.deferAnchor[^1]
- c.deferAnchor[^1] = tryStmt
- result = newTransNode(nkCommentStmt, n.info, 0)
- tryStmt.add deferPart
- # disable the original 'defer' statement:
- n.kind = nkEmpty
- of nkContinueStmt:
- result = newNodeI(nkBreakStmt, n.info)
- var labl = c.contSyms[c.contSyms.high]
- result.add(newSymNode(labl))
- of nkBreakStmt: result = transformBreak(c, n)
- of nkCallKinds:
- result = transformCall(c, n)
- of nkAddr, nkHiddenAddr:
- result = transformAddrDeref(c, n, nkDerefExpr, nkHiddenDeref)
- of nkDerefExpr, nkHiddenDeref:
- result = transformAddrDeref(c, n, nkAddr, nkHiddenAddr)
- of nkHiddenStdConv, nkHiddenSubConv, nkConv:
- result = transformConv(c, n)
- of nkDiscardStmt:
- result = n
- if n[0].kind != nkEmpty:
- result = transformSons(c, n)
- if isConstExpr(result[0]):
- # ensure that e.g. discard "some comment" gets optimized away
- # completely:
- result = newNode(nkCommentStmt)
- of nkCommentStmt, nkTemplateDef, nkImportStmt, nkStaticStmt,
- nkExportStmt, nkExportExceptStmt:
- return n
- of nkConstSection:
- # do not replace ``const c = 3`` with ``const 3 = 3``
- return transformConstSection(c, n)
- of nkTypeSection, nkTypeOfExpr:
- # no need to transform type sections:
- return n
- of nkVarSection, nkLetSection:
- if c.inlining > 0:
- # we need to copy the variables for multiple yield statements:
- result = transformVarSection(c, n)
- else:
- result = transformSons(c, n)
- of nkYieldStmt:
- if c.inlining > 0:
- result = transformYield(c, n)
- else:
- result = transformSons(c, n)
- of nkAsgn:
- result = transformAsgn(c, n)
- of nkIdentDefs, nkConstDef:
- result = n
- result[0] = transform(c, n[0])
- # Skip the second son since it only contains an unsemanticized copy of the
- # variable type used by docgen
- result[2] = transform(c, n[2])
- # XXX comment handling really sucks:
- if importantComments(c.graph.config):
- result.comment = n.comment
- of nkClosure:
- # it can happen that for-loop-inlining produced a fresh
- # set of variables, including some computed environment
- # (bug #2604). We need to patch this environment here too:
- let a = n[1]
- if a.kind == nkSym:
- n[1] = transformSymAux(c, a)
- return n
- of nkExceptBranch:
- result = transformExceptBranch(c, n)
- else:
- result = transformSons(c, n)
- when false:
- if oldDeferAnchor != nil: c.deferAnchor = oldDeferAnchor
- # Constants can be inlined here, but only if they cannot result in a cast
- # in the back-end (e.g. var p: pointer = someProc)
- let exprIsPointerCast = n.kind in {nkCast, nkConv, nkHiddenStdConv} and
- n.typ.kind == tyPointer
- if not exprIsPointerCast:
- var cnst = getConstExpr(c.module, result, c.graph)
- # we inline constants if they are not complex constants:
- if cnst != nil and not dontInlineConstant(n, cnst):
- result = cnst # do not miss an optimization
- proc processTransf(c: PTransf, n: PNode, owner: PSym): PNode =
- # Note: For interactive mode we cannot call 'passes.skipCodegen' and skip
- # this step! We have to rely that the semantic pass transforms too errornous
- # nodes into an empty node.
- if nfTransf in n.flags: return n
- pushTransCon(c, newTransCon(owner))
- result = transform(c, n)
- popTransCon(c)
- incl(result.flags, nfTransf)
- proc openTransf(g: ModuleGraph; module: PSym, filename: string): PTransf =
- new(result)
- result.contSyms = @[]
- result.breakSyms = @[]
- result.module = module
- result.graph = g
- proc flattenStmts(n: PNode) =
- var goOn = true
- while goOn:
- goOn = false
- var i = 0
- while i < n.len:
- let it = n[i]
- if it.kind in {nkStmtList, nkStmtListExpr}:
- n.sons[i..i] = it.sons[0..<it.len]
- goOn = true
- inc i
- proc liftDeferAux(n: PNode) =
- if n.kind in {nkStmtList, nkStmtListExpr}:
- flattenStmts(n)
- var goOn = true
- while goOn:
- goOn = false
- let last = n.len-1
- for i in 0..last:
- if n[i].kind == nkDefer:
- let deferPart = newNodeI(nkFinally, n[i].info)
- deferPart.add n[i][0]
- var tryStmt = newNodeIT(nkTryStmt, n[i].info, n.typ)
- var body = newNodeIT(n.kind, n[i].info, n.typ)
- if i < last:
- body.sons = n.sons[(i+1)..last]
- tryStmt.add body
- tryStmt.add deferPart
- n[i] = tryStmt
- n.sons.setLen(i+1)
- n.typ = tryStmt.typ
- goOn = true
- break
- for i in 0..n.safeLen-1:
- liftDeferAux(n[i])
- template liftDefer(c, root) =
- if c.deferDetected:
- liftDeferAux(root)
- proc transformBody*(g: ModuleGraph, prc: PSym, cache: bool): PNode =
- assert prc.kind in routineKinds
- if prc.transformedBody != nil:
- result = prc.transformedBody
- elif nfTransf in prc.ast[bodyPos].flags or prc.kind in {skTemplate}:
- result = prc.ast[bodyPos]
- else:
- prc.transformedBody = newNode(nkEmpty) # protects from recursion
- var c = openTransf(g, prc.getModule, "")
- result = liftLambdas(g, prc, prc.ast[bodyPos], c.tooEarly)
- result = processTransf(c, result, prc)
- liftDefer(c, result)
- result = liftLocalsIfRequested(prc, result, g.cache, g.config)
- if prc.isIterator:
- result = g.transformClosureIterator(prc, result)
- incl(result.flags, nfTransf)
- if cache or prc.typ.callConv == ccInline:
- # genProc for inline procs will be called multiple times from different modules,
- # it is important to transform exactly once to get sym ids and locations right
- prc.transformedBody = result
- else:
- prc.transformedBody = nil
- #if prc.name.s == "main":
- # echo "transformed into ", renderTree(result, {renderIds})
- proc transformStmt*(g: ModuleGraph; module: PSym, n: PNode): PNode =
- if nfTransf in n.flags:
- result = n
- else:
- var c = openTransf(g, module, "")
- result = processTransf(c, n, module)
- liftDefer(c, result)
- #result = liftLambdasForTopLevel(module, result)
- incl(result.flags, nfTransf)
- proc transformExpr*(g: ModuleGraph; module: PSym, n: PNode): PNode =
- if nfTransf in n.flags:
- result = n
- else:
- var c = openTransf(g, module, "")
- result = processTransf(c, n, module)
- liftDefer(c, result)
- # expressions are not to be injected with destructor calls as that
- # the list of top level statements needs to be collected before.
- incl(result.flags, nfTransf)
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