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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 common simple lowerings.
const
genPrefix* = ":tmp" # prefix for generated names
import ast, astalgo, types, idents, magicsys, msgs, options, modulegraphs,
lineinfos
when defined(nimPreviewSlimSystem):
import std/assertions
proc newDeref*(n: PNode): PNode {.inline.} =
result = newNodeIT(nkHiddenDeref, n.info, n.typ.elementType)
result.add n
proc newTupleAccess*(g: ModuleGraph; tup: PNode, i: int): PNode =
if tup.kind == nkHiddenAddr:
result = newNodeIT(nkHiddenAddr, tup.info, tup.typ.skipTypes(abstractInst+{tyPtr, tyVar, tyLent}))
result.add newNodeIT(nkBracketExpr, tup.info, tup.typ.skipTypes(abstractInst+{tyPtr, tyVar, tyLent})[i])
result[0].add tup[0]
var lit = newNodeIT(nkIntLit, tup.info, getSysType(g, tup.info, tyInt))
lit.intVal = i
result[0].add lit
else:
result = newNodeIT(nkBracketExpr, tup.info, tup.typ.skipTypes(
abstractInst)[i])
result.add copyTree(tup)
var lit = newNodeIT(nkIntLit, tup.info, getSysType(g, tup.info, tyInt))
lit.intVal = i
result.add lit
proc addVar*(father, v: PNode) =
var vpart = newNodeI(nkIdentDefs, v.info, 3)
vpart[0] = v
vpart[1] = newNodeI(nkEmpty, v.info)
vpart[2] = vpart[1]
father.add vpart
proc addVar*(father, v, value: PNode) =
var vpart = newNodeI(nkIdentDefs, v.info, 3)
vpart[0] = v
vpart[1] = newNodeI(nkEmpty, v.info)
vpart[2] = value
father.add vpart
proc newAsgnStmt*(le, ri: PNode): PNode =
result = newNodeI(nkAsgn, le.info, 2)
result[0] = le
result[1] = ri
proc newFastAsgnStmt*(le, ri: PNode): PNode =
result = newNodeI(nkFastAsgn, le.info, 2)
result[0] = le
result[1] = ri
proc newFastMoveStmt*(g: ModuleGraph, le, ri: PNode): PNode =
result = newNodeI(nkFastAsgn, le.info, 2)
result[0] = le
result[1] = newNodeIT(nkCall, ri.info, ri.typ)
result[1].add newSymNode(getSysMagic(g, ri.info, "move", mMove))
result[1].add ri
proc lowerTupleUnpacking*(g: ModuleGraph; n: PNode; idgen: IdGenerator; owner: PSym): PNode =
assert n.kind == nkVarTuple
let value = n.lastSon
result = newNodeI(nkStmtList, n.info)
var tempAsNode: PNode
let avoidTemp = value.kind == nkSym
if avoidTemp:
tempAsNode = value
else:
var temp = newSym(skTemp, getIdent(g.cache, genPrefix), idgen,
owner, value.info, g.config.options)
temp.typ = skipTypes(value.typ, abstractInst)
incl(temp.flags, sfFromGeneric)
tempAsNode = newSymNode(temp)
var v = newNodeI(nkVarSection, value.info)
if not avoidTemp:
v.addVar(tempAsNode, value)
result.add(v)
for i in 0..<n.len-2:
let val = newTupleAccess(g, tempAsNode, i)
if n[i].kind == nkSym: v.addVar(n[i], val)
else: result.add newAsgnStmt(n[i], val)
proc evalOnce*(g: ModuleGraph; value: PNode; idgen: IdGenerator; owner: PSym): PNode =
## Turns (value) into (let tmp = value; tmp) so that 'value' can be re-used
## freely, multiple times. This is frequently required and such a builtin would also be
## handy to have in macros.nim. The value that can be reused is 'result.lastSon'!
result = newNodeIT(nkStmtListExpr, value.info, value.typ)
var temp = newSym(skTemp, getIdent(g.cache, genPrefix), idgen,
owner, value.info, g.config.options)
temp.typ = skipTypes(value.typ, abstractInst)
incl(temp.flags, sfFromGeneric)
var v = newNodeI(nkLetSection, value.info)
let tempAsNode = newSymNode(temp)
v.addVar(tempAsNode)
result.add(v)
result.add newAsgnStmt(tempAsNode, value)
result.add tempAsNode
proc newTupleAccessRaw*(tup: PNode, i: int): PNode =
result = newNodeI(nkBracketExpr, tup.info)
result.add copyTree(tup)
var lit = newNodeI(nkIntLit, tup.info)
lit.intVal = i
result.add lit
proc newTryFinally*(body, final: PNode): PNode =
result = newTree(nkHiddenTryStmt, body, newTree(nkFinally, final))
proc lowerSwap*(g: ModuleGraph; n: PNode; idgen: IdGenerator; owner: PSym): PNode =
result = newNodeI(nkStmtList, n.info)
# note: cannot use 'skTemp' here cause we really need the copy for the VM :-(
var temp = newSym(skVar, getIdent(g.cache, genPrefix), idgen, owner, n.info, owner.options)
temp.typ = n[1].typ
incl(temp.flags, sfFromGeneric)
incl(temp.flags, sfGenSym)
var v = newNodeI(nkVarSection, n.info)
let tempAsNode = newSymNode(temp)
var vpart = newNodeI(nkIdentDefs, v.info, 3)
vpart[0] = tempAsNode
vpart[1] = newNodeI(nkEmpty, v.info)
vpart[2] = n[1]
v.add vpart
result.add(v)
result.add newFastAsgnStmt(n[1], n[2])
result.add newFastAsgnStmt(n[2], tempAsNode)
proc createObj*(g: ModuleGraph; idgen: IdGenerator; owner: PSym, info: TLineInfo; final=true): PType =
result = newType(tyObject, idgen, owner)
if final:
rawAddSon(result, nil)
incl result.flags, tfFinal
else:
rawAddSon(result, getCompilerProc(g, "RootObj").typ)
result.n = newNodeI(nkRecList, info)
let s = newSym(skType, getIdent(g.cache, "Env_" & toFilename(g.config, info) & "_" & $owner.name.s),
idgen, owner, info, owner.options)
incl s.flags, sfAnon
s.typ = result
result.sym = s
template fieldCheck {.dirty.} =
when false:
if tfCheckedForDestructor in obj.flags:
echo "missed field ", field.name.s
writeStackTrace()
proc rawAddField*(obj: PType; field: PSym) =
assert field.kind == skField
field.position = obj.n.len
obj.n.add newSymNode(field)
propagateToOwner(obj, field.typ)
fieldCheck()
proc rawIndirectAccess*(a: PNode; field: PSym; info: TLineInfo): PNode =
# returns a[].field as a node
assert field.kind == skField
var deref = newNodeI(nkHiddenDeref, info)
deref.typ = a.typ.skipTypes(abstractInst)[0]
deref.add a
result = newNodeI(nkDotExpr, info)
result.add deref
result.add newSymNode(field)
result.typ = field.typ
proc rawDirectAccess*(obj, field: PSym): PNode =
# returns a.field as a node
assert field.kind == skField
result = newNodeI(nkDotExpr, field.info)
result.add newSymNode(obj)
result.add newSymNode(field)
result.typ = field.typ
proc lookupInRecord(n: PNode, id: ItemId): PSym =
result = nil
case n.kind
of nkRecList:
for i in 0..<n.len:
result = lookupInRecord(n[i], id)
if result != nil: return
of nkRecCase:
if n[0].kind != nkSym: return
result = lookupInRecord(n[0], id)
if result != nil: return
for i in 1..<n.len:
case n[i].kind
of nkOfBranch, nkElse:
result = lookupInRecord(lastSon(n[i]), id)
if result != nil: return
else: discard
of nkSym:
if n.sym.itemId.module == id.module and n.sym.itemId.item == -abs(id.item): result = n.sym
else: discard
proc addField*(obj: PType; s: PSym; cache: IdentCache; idgen: IdGenerator): PSym =
# because of 'gensym' support, we have to mangle the name with its ID.
# This is hacky but the clean solution is much more complex than it looks.
var field = newSym(skField, getIdent(cache, s.name.s & $obj.n.len),
idgen, s.owner, s.info, s.options)
field.itemId = ItemId(module: s.itemId.module, item: -s.itemId.item)
let t = skipIntLit(s.typ, idgen)
field.typ = t
if s.kind in {skLet, skVar, skField, skForVar}:
#field.bitsize = s.bitsize
field.alignment = s.alignment
assert t.kind != tyTyped
propagateToOwner(obj, t)
field.position = obj.n.len
# sfNoInit flag for skField is used in closureiterator codegen
field.flags = s.flags * {sfCursor, sfNoInit}
obj.n.add newSymNode(field)
fieldCheck()
result = field
proc addUniqueField*(obj: PType; s: PSym; cache: IdentCache; idgen: IdGenerator): PSym {.discardable.} =
result = lookupInRecord(obj.n, s.itemId)
if result == nil:
var field = newSym(skField, getIdent(cache, s.name.s & $obj.n.len), idgen,
s.owner, s.info, s.options)
field.itemId = ItemId(module: s.itemId.module, item: -s.itemId.item)
let t = skipIntLit(s.typ, idgen)
field.typ = t
assert t.kind != tyTyped
propagateToOwner(obj, t)
field.position = obj.n.len
obj.n.add newSymNode(field)
result = field
proc newDotExpr*(obj, b: PSym): PNode =
result = newNodeI(nkDotExpr, obj.info)
let field = lookupInRecord(obj.typ.n, b.itemId)
assert field != nil, b.name.s
result.add newSymNode(obj)
result.add newSymNode(field)
result.typ = field.typ
proc indirectAccess*(a: PNode, b: ItemId, info: TLineInfo): PNode =
# returns a[].b as a node
var deref = newNodeI(nkHiddenDeref, info)
deref.typ = a.typ.skipTypes(abstractInst).elementType
var t = deref.typ.skipTypes(abstractInst)
var field: PSym
while true:
assert t.kind == tyObject
field = lookupInRecord(t.n, b)
if field != nil: break
t = t.baseClass
if t == nil: break
t = t.skipTypes(skipPtrs)
#if field == nil:
# echo "FIELD ", b
# debug deref.typ
assert field != nil
deref.add a
result = newNodeI(nkDotExpr, info)
result.add deref
result.add newSymNode(field)
result.typ = field.typ
proc indirectAccess*(a: PNode, b: string, info: TLineInfo; cache: IdentCache): PNode =
# returns a[].b as a node
var deref = newNodeI(nkHiddenDeref, info)
deref.typ = a.typ.skipTypes(abstractInst).elementType
var t = deref.typ.skipTypes(abstractInst)
var field: PSym
let bb = getIdent(cache, b)
while true:
assert t.kind == tyObject
field = getSymFromList(t.n, bb)
if field != nil: break
t = t.baseClass
if t == nil: break
t = t.skipTypes(skipPtrs)
#if field == nil:
# echo "FIELD ", b
# debug deref.typ
assert field != nil
deref.add a
result = newNodeI(nkDotExpr, info)
result.add deref
result.add newSymNode(field)
result.typ = field.typ
proc getFieldFromObj*(t: PType; v: PSym): PSym =
assert v.kind != skField
var t = t
while true:
assert t.kind == tyObject
result = lookupInRecord(t.n, v.itemId)
if result != nil: break
t = t.baseClass
if t == nil: break
t = t.skipTypes(skipPtrs)
proc indirectAccess*(a: PNode, b: PSym, info: TLineInfo): PNode =
# returns a[].b as a node
result = indirectAccess(a, b.itemId, info)
proc indirectAccess*(a, b: PSym, info: TLineInfo): PNode =
result = indirectAccess(newSymNode(a), b, info)
proc genAddrOf*(n: PNode; idgen: IdGenerator; typeKind = tyPtr): PNode =
result = newNodeI(nkAddr, n.info, 1)
result[0] = n
result.typ = newType(typeKind, idgen, n.typ.owner)
result.typ.rawAddSon(n.typ)
proc genDeref*(n: PNode; k = nkHiddenDeref): PNode =
result = newNodeIT(k, n.info,
n.typ.skipTypes(abstractInst).elementType)
result.add n
proc callCodegenProc*(g: ModuleGraph; name: string;
info: TLineInfo = unknownLineInfo;
arg1: PNode = nil, arg2: PNode = nil,
arg3: PNode = nil, optionalArgs: PNode = nil): PNode =
result = newNodeI(nkCall, info)
let sym = magicsys.getCompilerProc(g, name)
if sym == nil:
localError(g.config, info, "system module needs: " & name)
else:
result.add newSymNode(sym)
if arg1 != nil: result.add arg1
if arg2 != nil: result.add arg2
if arg3 != nil: result.add arg3
if optionalArgs != nil:
for i in 1..<optionalArgs.len-2:
result.add optionalArgs[i]
result.typ = sym.typ.returnType
proc newIntLit*(g: ModuleGraph; info: TLineInfo; value: BiggestInt): PNode =
result = nkIntLit.newIntNode(value)
result.typ = getSysType(g, info, tyInt)
proc genHigh*(g: ModuleGraph; n: PNode): PNode =
if skipTypes(n.typ, abstractVar).kind == tyArray:
result = newIntLit(g, n.info, toInt64(lastOrd(g.config, skipTypes(n.typ, abstractVar))))
else:
result = newNodeI(nkCall, n.info, 2)
result.typ = getSysType(g, n.info, tyInt)
result[0] = newSymNode(getSysMagic(g, n.info, "high", mHigh))
result[1] = n
proc genLen*(g: ModuleGraph; n: PNode): PNode =
if skipTypes(n.typ, abstractVar).kind == tyArray:
result = newIntLit(g, n.info, toInt64(lastOrd(g.config, skipTypes(n.typ, abstractVar)) + 1))
else:
result = newNodeI(nkCall, n.info, 2)
result.typ = getSysType(g, n.info, tyInt)
result[0] = newSymNode(getSysMagic(g, n.info, "len", mLengthSeq))
result[1] = n
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