#
#
# Nim's Runtime Library
# (c) Copyright 2012 Andreas Rumpf
#
# See the file "copying.txt", included in this
# distribution, for details about the copyright.
#
# string & sequence handling procedures needed by the code generator
# strings are dynamically resized, have a length field
# and are zero-terminated, so they can be casted to C
# strings easily
# we don't use refcounts because that's a behaviour
# the programmer may not want
proc resize(old: int): int {.inline.} =
if old <= 0: result = 4
elif old < 65536: result = old * 2
else: result = old * 3 div 2 # for large arrays * 3/2 is better
when declared(allocAtomic):
template allocStr(size: untyped): untyped =
cast[NimString](allocAtomic(size))
template allocStrNoInit(size: untyped): untyped =
cast[NimString](boehmAllocAtomic(size))
elif defined(gcRegions):
template allocStr(size: untyped): untyped =
cast[NimString](newStr(addr(strDesc), size, true))
template allocStrNoInit(size: untyped): untyped =
cast[NimString](newStr(addr(strDesc), size, false))
else:
template allocStr(size: untyped): untyped =
cast[NimString](newObj(addr(strDesc), size))
template allocStrNoInit(size: untyped): untyped =
cast[NimString](newObjNoInit(addr(strDesc), size))
proc rawNewStringNoInit(space: int): NimString {.compilerProc.} =
var s = space
if s < 7: s = 7
result = allocStrNoInit(sizeof(TGenericSeq) + s + 1)
result.reserved = s
result.len = 0
when defined(gogc):
result.elemSize = 1
proc rawNewString(space: int): NimString {.compilerProc.} =
var s = space
if s < 7: s = 7
result = allocStr(sizeof(TGenericSeq) + s + 1)
result.reserved = s
result.len = 0
when defined(gogc):
result.elemSize = 1
proc mnewString(len: int): NimString {.compilerProc.} =
result = rawNewString(len)
result.len = len
proc copyStrLast(s: NimString, start, last: int): NimString {.compilerProc.} =
# This is not used by most recent versions of the compiler anymore, but
# required for bootstrapping purposes.
let start = max(start, 0)
if s == nil: return nil
let len = min(last, s.len-1) - start + 1
if len > 0:
result = rawNewStringNoInit(len)
result.len = len
copyMem(addr(result.data), addr(s.data[start]), len)
result.data[len] = '\0'
else:
result = rawNewString(len)
proc copyStr(s: NimString, start: int): NimString {.compilerProc.} =
# This is not used by most recent versions of the compiler anymore, but
# required for bootstrapping purposes.
if s == nil: return nil
result = copyStrLast(s, start, s.len-1)
proc nimToCStringConv(s: NimString): cstring {.compilerProc, inline.} =
if s == nil or s.len == 0: result = cstring""
else: result = cstring(addr s.data)
proc toNimStr(str: cstring, len: int): NimString {.compilerProc.} =
result = rawNewStringNoInit(len)
result.len = len
copyMem(addr(result.data), str, len + 1)
proc cstrToNimstr(str: cstring): NimString {.compilerRtl.} =
if str == nil: NimString(nil)
else: toNimStr(str, str.len)
proc copyString(src: NimString): NimString {.compilerRtl.} =
if src != nil:
if (src.reserved and seqShallowFlag) != 0:
result = src
else:
result = rawNewStringNoInit(src.len)
result.len = src.len
copyMem(addr(result.data), addr(src.data), src.len + 1)
sysAssert((seqShallowFlag and result.reserved) == 0, "copyString")
when defined(nimShallowStrings):
if (src.reserved and strlitFlag) != 0:
result.reserved = (result.reserved and not strlitFlag) or seqShallowFlag
proc newOwnedString(src: NimString; n: int): NimString =
result = rawNewStringNoInit(n)
result.len = n
copyMem(addr(result.data), addr(src.data), n)
result.data[n] = '\0'
proc copyStringRC1(src: NimString): NimString {.compilerRtl.} =
if src != nil:
when declared(newObjRC1) and not defined(gcRegions):
var s = src.len
if s < 7: s = 7
result = cast[NimString](newObjRC1(addr(strDesc), sizeof(TGenericSeq) +
s+1))
result.reserved = s
when defined(gogc):
result.elemSize = 1
else:
result = rawNewStringNoInit(src.len)
result.len = src.len
copyMem(addr(result.data), addr(src.data), src.len + 1)
sysAssert((seqShallowFlag and result.reserved) == 0, "copyStringRC1")
when defined(nimShallowStrings):
if (src.reserved and strlitFlag) != 0:
result.reserved = (result.reserved and not strlitFlag) or seqShallowFlag
proc copyDeepString(src: NimString): NimString {.inline.} =
if src != nil:
result = rawNewStringNoInit(src.len)
result.len = src.len
copyMem(addr(result.data), addr(src.data), src.len + 1)
proc addChar(s: NimString, c: char): NimString =
# is compilerproc!
if s == nil:
result = rawNewStringNoInit(1)
result.len = 0
else:
result = s
if result.len >= result.space:
let r = resize(result.space)
when defined(nimIncrSeqV3):
result = rawNewStringNoInit(r)
result.len = s.len
copyMem(addr result.data[0], unsafeAddr(s.data[0]), s.len+1)
else:
result = cast[NimString](growObj(result,
sizeof(TGenericSeq) + r + 1))
result.reserved = r
result.data[result.len] = c
result.data[result.len+1] = '\0'
inc(result.len)
# These routines should be used like following:
# <Nim code>
# s &= "Hello " & name & ", how do you feel?"
#
# <generated C code>
# {
# s = resizeString(s, 6 + name->len + 17);
# appendString(s, strLit1);
# appendString(s, strLit2);
# appendString(s, strLit3);
# }
#
# <Nim code>
# s = "Hello " & name & ", how do you feel?"
#
# <generated C code>
# {
# string tmp0;
# tmp0 = rawNewString(6 + name->len + 17);
# appendString(s, strLit1);
# appendString(s, strLit2);
# appendString(s, strLit3);
# s = tmp0;
# }
#
# <Nim code>
# s = ""
#
# <generated C code>
# s = rawNewString(0);
proc resizeString(dest: NimString, addlen: int): NimString {.compilerRtl.} =
if dest == nil:
result = rawNewStringNoInit(addlen)
elif dest.len + addlen <= dest.space:
result = dest
else: # slow path:
let sp = max(resize(dest.space), dest.len + addlen)
when defined(nimIncrSeqV3):
result = rawNewStringNoInit(sp)
result.len = dest.len
copyMem(addr result.data[0], unsafeAddr(dest.data[0]), dest.len+1)
else:
result = cast[NimString](growObj(dest, sizeof(TGenericSeq) + sp + 1))
result.reserved = sp
#result = rawNewString(sp)
#copyMem(result, dest, dest.len + sizeof(TGenericSeq))
# DO NOT UPDATE LEN YET: dest.len = newLen
proc appendString(dest, src: NimString) {.compilerproc, inline.} =
if src != nil:
copyMem(addr(dest.data[dest.len]), addr(src.data), src.len + 1)
inc(dest.len, src.len)
proc appendChar(dest: NimString, c: char) {.compilerproc, inline.} =
dest.data[dest.len] = c
dest.data[dest.len+1] = '\0'
inc(dest.len)
proc setLengthStr(s: NimString, newLen: int): NimString {.compilerRtl.} =
let n = max(newLen, 0)
if s == nil:
result = mnewString(newLen)
elif n <= s.space:
result = s
else:
let sp = max(resize(s.space), newLen)
when defined(nimIncrSeqV3):
result = rawNewStringNoInit(sp)
result.len = s.len
copyMem(addr result.data[0], unsafeAddr(s.data[0]), s.len+1)
zeroMem(addr result.data[s.len], newLen - s.len)
result.reserved = sp
else:
result = resizeString(s, n)
result.len = n
result.data[n] = '\0'
# ----------------- sequences ----------------------------------------------
proc incrSeq(seq: PGenericSeq, elemSize: int): PGenericSeq {.compilerProc.} =
# increments the length by one:
# this is needed for supporting ``add``;
#
# add(seq, x) generates:
# seq = incrSeq(seq, sizeof(x));
# seq[seq->len-1] = x;
result = seq
if result.len >= result.space:
let r = resize(result.space)
result = cast[PGenericSeq](growObj(result, elemSize * r +
GenericSeqSize))
result.reserved = r
inc(result.len)
proc incrSeqV2(seq: PGenericSeq, elemSize: int): PGenericSeq {.compilerProc.} =
# incrSeq version 2
result = seq
if result.len >= result.space:
let r = resize(result.space)
result = cast[PGenericSeq](growObj(result, elemSize * r +
GenericSeqSize))
result.reserved = r
template `+!`(p: pointer, s: int): pointer =
cast[pointer](cast[int](p) +% s)
proc incrSeqV3(s: PGenericSeq, typ: PNimType): PGenericSeq {.compilerProc.} =
if s == nil:
result = cast[PGenericSeq](newSeq(typ, 1))
result.len = 0
else:
result = s
if result.len >= result.space:
let r = resize(result.space)
when defined(nimIncrSeqV3):
result = cast[PGenericSeq](newSeq(typ, r))
result.len = s.len
copyMem(result +! GenericSeqSize, s +! GenericSeqSize, s.len * typ.base.size)
# since we steal the content from 's', it's crucial to set s's len to 0.
s.len = 0
else:
result = cast[PGenericSeq](growObj(result, typ.base.size * r +
GenericSeqSize))
result.reserved = r
proc setLengthSeq(seq: PGenericSeq, elemSize, newLen: int): PGenericSeq {.
compilerRtl, inl.} =
result = seq
if result.space < newLen:
let r = max(resize(result.space), newLen)
result = cast[PGenericSeq](growObj(result, elemSize * r +
GenericSeqSize))
result.reserved = r
elif newLen < result.len:
# we need to decref here, otherwise the GC leaks!
when not defined(boehmGC) and not defined(nogc) and
not defined(gcMarkAndSweep) and not defined(gogc) and
not defined(gcRegions):
when false: # compileOption("gc", "v2"):
for i in newLen..result.len-1:
let len0 = gch.tempStack.len
forAllChildrenAux(cast[pointer](cast[ByteAddress](result) +%
GenericSeqSize +% (i*%elemSize)),
extGetCellType(result).base, waPush)
let len1 = gch.tempStack.len
for i in len0 ..< len1:
doDecRef(gch.tempStack.d[i], LocalHeap, MaybeCyclic)
gch.tempStack.len = len0
else:
if ntfNoRefs notin extGetCellType(result).base.flags:
for i in newLen..result.len-1:
forAllChildrenAux(cast[pointer](cast[ByteAddress](result) +%
GenericSeqSize +% (i*%elemSize)),
extGetCellType(result).base, waZctDecRef)
# XXX: zeroing out the memory can still result in crashes if a wiped-out
# cell is aliased by another pointer (ie proc parameter or a let variable).
# This is a tough problem, because even if we don't zeroMem here, in the
# presence of user defined destructors, the user will expect the cell to be
# "destroyed" thus creating the same problem. We can destoy the cell in the
# finalizer of the sequence, but this makes destruction non-deterministic.
zeroMem(cast[pointer](cast[ByteAddress](result) +% GenericSeqSize +%
(newLen*%elemSize)), (result.len-%newLen) *% elemSize)
result.len = newLen
proc setLengthSeqV2(s: PGenericSeq, typ: PNimType, newLen: int): PGenericSeq {.
compilerRtl.} =
sysAssert typ.kind == tySequence, "setLengthSeqV2: type is not a seq"
if s == nil:
result = cast[PGenericSeq](newSeq(typ, newLen))
else:
when defined(nimIncrSeqV3):
let elemSize = typ.base.size
if s.space < newLen:
let r = max(resize(s.space), newLen)
result = cast[PGenericSeq](newSeq(typ, r))
copyMem(result +! GenericSeqSize, s +! GenericSeqSize, s.len * elemSize)
# since we steal the content from 's', it's crucial to set s's len to 0.
s.len = 0
elif newLen < s.len:
result = s
# we need to decref here, otherwise the GC leaks!
when not defined(boehmGC) and not defined(nogc) and
not defined(gcMarkAndSweep) and not defined(gogc) and
not defined(gcRegions):
if ntfNoRefs notin typ.base.flags:
for i in newLen..result.len-1:
forAllChildrenAux(cast[pointer](cast[ByteAddress](result) +%
GenericSeqSize +% (i*%elemSize)),
extGetCellType(result).base, waZctDecRef)
# XXX: zeroing out the memory can still result in crashes if a wiped-out
# cell is aliased by another pointer (ie proc parameter or a let variable).
# This is a tough problem, because even if we don't zeroMem here, in the
# presence of user defined destructors, the user will expect the cell to be
# "destroyed" thus creating the same problem. We can destoy the cell in the
# finalizer of the sequence, but this makes destruction non-deterministic.
zeroMem(cast[pointer](cast[ByteAddress](result) +% GenericSeqSize +%
(newLen*%elemSize)), (result.len-%newLen) *% elemSize)
else:
result = s
result.len = newLen
else:
result = setLengthSeq(s, typ.base.size, newLen)