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209#
#
# The Nimrod Compiler
# (c) Copyright 2012 Andreas Rumpf
#
# See the file "copying.txt", included in this
# distribution, for details about the copyright.
#
# Ropes for the C code generator
#
# Ropes are a data structure that represents a very long string
# efficiently; especially concatenation is done in O(1) instead of O(N).
# Ropes make use a lazy evaluation: They are essentially concatenation
# trees that are only flattened when converting to a native Nimrod
# string or when written to disk. The empty string is represented by a
# nil pointer.
# A little picture makes everything clear:
#
# "this string" & " is internally " & "represented as"
#
# con -- inner nodes do not contain raw data
# / \
# / \
# / \
# con "represented as"
# / \
# / \
# / \
# / \
# / \
#"this string" " is internally "
#
# Note that this is the same as:
# "this string" & (" is internally " & "represented as")
#
# con
# / \
# / \
# / \
# "this string" con
# / \
# / \
# / \
# / \
# / \
#" is internally " "represented as"
#
# The 'con' operator is associative! This does not matter however for
# the algorithms we use for ropes.
#
# Note that the left and right pointers are not needed for leaves.
# Leaves have relatively high memory overhead (~30 bytes on a 32
# bit machines) and we produce many of them. This is why we cache and
# share leaves accross different rope trees.
# To cache them they are inserted in a `cache` array.
import
strutils, platform, hashes, crc, options
type
TFormatStr* = string # later we may change it to CString for better
# performance of the code generator (assignments
# copy the format strings
# though it is not necessary)
PRope* = ref TRope
TRope*{.acyclic.} = object of TObject # the empty rope is represented
# by nil to safe space
left*, right*: PRope
length*: int
data*: string # != nil if a leaf
TRopeSeq* = seq[PRope]
TRopesError* = enum
rCannotOpenFile
rInvalidFormatStr
rTokenTooLong
proc con*(a, b: PRope): PRope
proc con*(a: PRope, b: string): PRope
proc con*(a: string, b: PRope): PRope
proc con*(a: varargs[PRope]): PRope
proc app*(a: var PRope, b: PRope)
proc app*(a: var PRope, b: string)
proc prepend*(a: var PRope, b: PRope)
proc toRope*(s: string): PRope
proc toRope*(i: BiggestInt): PRope
proc ropeLen*(a: PRope): int
proc writeRopeIfNotEqual*(r: PRope, filename: string): bool
proc ropeToStr*(p: PRope): string
proc ropef*(frmt: TFormatStr, args: varargs[PRope]): PRope
proc appf*(c: var PRope, frmt: TFormatStr, args: varargs[PRope])
proc RopeEqualsFile*(r: PRope, f: string): bool
# returns true if the rope r is the same as the contents of file f
proc RopeInvariant*(r: PRope): bool
# exported for debugging
# implementation
var ErrorHandler*: proc(err: TRopesError, msg: string, useWarning = false)
# avoid dependency on msgs.nim
proc ropeLen(a: PRope): int =
if a == nil: result = 0
else: result = a.length
proc newRope*(data: string = nil): PRope =
new(result)
if data != nil:
result.length = len(data)
result.data = data
proc newMutableRope*(capacity = 30): PRope =
## creates a new rope that supports direct modifications of the rope's
## 'data' and 'length' fields.
new(result)
result.data = newStringOfCap(capacity)
proc freezeMutableRope*(r: PRope) {.inline.} =
r.length = r.data.len
var
cache: array[0..2048*2 -1, PRope]
proc resetRopeCache* =
for i in low(cache)..high(cache):
cache[i] = nil
proc RopeInvariant(r: PRope): bool =
if r == nil:
result = true
else:
result = true #
# if r.data <> snil then
# result := true
# else begin
# result := (r.left <> nil) and (r.right <> nil);
# if result then result := ropeInvariant(r.left);
# if result then result := ropeInvariant(r.right);
# end
var gCacheTries* = 0
var gCacheMisses* = 0
var gCacheIntTries* = 0
proc insertInCache(s: string): PRope =
inc gCacheTries
var h = hash(s) and high(cache)
result = cache[h]
if isNil(result) or result.data != s:
inc gCacheMisses
result = newRope(s)
cache[h] = result
proc toRope(s: string): PRope =
if s.len == 0:
result = nil
else:
result = insertInCache(s)
assert(RopeInvariant(result))
proc RopeSeqInsert(rs: var TRopeSeq, r: PRope, at: Natural) =
var length = len(rs)
if at > length:
setlen(rs, at + 1)
else:
setlen(rs, length + 1) # move old rope elements:
for i in countdown(length, at + 1):
rs[i] = rs[i - 1] # this is correct, I used pen and paper to validate it
rs[at] = r
proc newRecRopeToStr(result: var string, resultLen: var int, r: PRope) =
var stack = @[r]
while len(stack) > 0:
var it = pop(stack)
while it.data == nil:
add(stack, it.right)
it = it.left
assert(it.data != nil)
CopyMem(addr(result[resultLen]), addr(it.data[0]), it.length)
Inc(resultLen, it.length)
assert(resultLen <= len(result))
proc ropeToStr(p: PRope): string =
if p == nil:
result = ""
else:
result = newString(p.length)
var resultLen = 0
newRecRopeToStr(result, resultLen, p)
proc con(a, b: PRope): PRope =
if a == nil: result = b
elif b == nil: result = a
else:
result = newRope()
result.length = a.length + b.length
result.left = a
result.right = b
proc con(a: PRope, b: string): PRope = result = con(a, toRope(b))
proc con(a: string, b: PRope): PRope = result = con(toRope(a), b)
proc con(a: varargs[PRope]): PRope =
for i in countup(0, high(a)): result = con(result, a[i])
proc ropeConcat*(a: varargs[PRope]): PRope =
# not overloaded version of concat to speed-up `rfmt` a little bit
for i in countup(0, high(a)): result = con(result, a[i])
proc toRope(i: BiggestInt): PRope =
inc gCacheIntTries
result = toRope($i)
proc app(a: var PRope, b: PRope) = a = con(a, b)
proc app(a: var PRope, b: string) = a = con(a, b)
proc prepend(a: var PRope, b: PRope) = a = con(b, a)
proc writeRope*(f: TFile, c: PRope) =
var stack = @[c]
while len(stack) > 0:
var it = pop(stack)
while it.data == nil:
add(stack, it.right)
it = it.left
assert(it != nil)
assert(it.data != nil)
write(f, it.data)
proc WriteRope*(head: PRope, filename: string, useWarning = false) =
var f: tfile
if open(f, filename, fmWrite):
if head != nil: WriteRope(f, head)
close(f)
else:
ErrorHandler(rCannotOpenFile, filename, useWarning)
var
rnl* = tnl.newRope
softRnl* = tnl.newRope
proc ropef(frmt: TFormatStr, args: varargs[PRope]): PRope =
var i = 0
var length = len(frmt)
result = nil
var num = 0
while i <= length - 1:
if frmt[i] == '$':
inc(i) # skip '$'
case frmt[i]
of '$':
app(result, "$")
inc(i)
of '#':
inc(i)
app(result, args[num])
inc(num)
of '0'..'9':
var j = 0
while true:
j = (j * 10) + Ord(frmt[i]) - ord('0')
inc(i)
if (i > length + 0 - 1) or not (frmt[i] in {'0'..'9'}): break
num = j
if j > high(args) + 1:
ErrorHandler(rInvalidFormatStr, $(j))
else:
app(result, args[j - 1])
of 'n':
app(result, softRnl)
inc i
of 'N':
app(result, rnl)
inc(i)
else:
ErrorHandler(rInvalidFormatStr, $(frmt[i]))
var start = i
while i < length:
if frmt[i] != '$': inc(i)
else: break
if i - 1 >= start:
app(result, substr(frmt, start, i - 1))
assert(RopeInvariant(result))
{.push stack_trace: off, line_trace: off.}
proc `~`*(r: expr[string]): PRope =
# this is the new optimized "to rope" operator
# the mnemonic is that `~` looks a bit like a rope :)
var r {.global.} = r.ropef
return r
{.pop.}
proc appf(c: var PRope, frmt: TFormatStr, args: varargs[PRope]) =
app(c, ropef(frmt, args))
const
bufSize = 1024 # 1 KB is reasonable
proc auxRopeEqualsFile(r: PRope, bin: var tfile, buf: Pointer): bool =
if r.data != nil:
if r.length > bufSize:
ErrorHandler(rTokenTooLong, r.data)
return
var readBytes = readBuffer(bin, buf, r.length)
result = readBytes == r.length and
equalMem(buf, addr(r.data[0]), r.length) # BUGFIX
else:
result = auxRopeEqualsFile(r.left, bin, buf)
if result: result = auxRopeEqualsFile(r.right, bin, buf)
proc RopeEqualsFile(r: PRope, f: string): bool =
var bin: tfile
result = open(bin, f)
if not result:
return # not equal if file does not exist
var buf = alloc(BufSize)
result = auxRopeEqualsFile(r, bin, buf)
if result:
result = readBuffer(bin, buf, bufSize) == 0 # really at the end of file?
dealloc(buf)
close(bin)
proc crcFromRopeAux(r: PRope, startVal: TCrc32): TCrc32 =
if r.data != nil:
result = startVal
for i in countup(0, len(r.data) - 1):
result = updateCrc32(r.data[i], result)
else:
result = crcFromRopeAux(r.left, startVal)
result = crcFromRopeAux(r.right, result)
proc newCrcFromRopeAux(r: PRope, startVal: TCrc32): TCrc32 =
# XXX profiling shows this is actually expensive
var stack: TRopeSeq = @[r]
result = startVal
while len(stack) > 0:
var it = pop(stack)
while it.data == nil:
add(stack, it.right)
it = it.left
assert(it.data != nil)
var i = 0
var L = len(it.data)
while i < L:
result = updateCrc32(it.data[i], result)
inc(i)
proc crcFromRope(r: PRope): TCrc32 =
result = newCrcFromRopeAux(r, initCrc32)
proc writeRopeIfNotEqual(r: PRope, filename: string): bool =
# returns true if overwritten
var c: TCrc32
c = crcFromFile(filename)
if c != crcFromRope(r):
writeRope(r, filename)
result = true
else:
result = false
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