# # # Nim's Runtime Library # (c) Copyright 2010 Andreas Rumpf # # See the file "copying.txt", included in this # distribution, for details about the copyright. # ## This module contains support for a `rope`:idx: data type. ## Ropes can represent very long strings efficiently; especially concatenation ## is done in O(1) instead of O(n). They are essentially concatenation ## trees that are only flattened when converting to a native Nim ## string. The empty string is represented by ``nil``. Ropes are immutable and ## subtrees can be shared without copying. ## Leaves can be cached for better memory efficiency at the cost of ## runtime efficiency. include "system/inclrtl" import streams {.deadCodeElim: on.} # dce option deprecated {.push debugger:off .} # the user does not want to trace a part # of the standard library! const countCacheMisses = false var cacheEnabled = false type Rope* = ref RopeObj ## empty rope is represented by nil RopeObj {.acyclic.} = object left, right: Rope length: int data: string # != nil if a leaf # Note that the left and right pointers are not needed for leafs. # Leaves have relatively high memory overhead (~30 bytes on a 32 # bit machine) and we produce many of them. This is why we cache and # share leafs across different rope trees. # To cache them they are inserted in another tree, a splay tree for best # performance. But for the caching tree we use the leaf's left and right # pointers. proc len*(a: Rope): int {.rtl, extern: "nro$1".} = ## the rope's length if a == nil: result = 0 else: result = a.length proc newRope(): Rope = new(result) proc newRope(data: string): Rope = new(result) result.length = len(data) result.data = data var cache {.threadvar.}: Rope # the root of the cache tree N {.threadvar.}: Rope # dummy rope needed for splay algorithm when countCacheMisses: var misses, hits: int proc splay(s: string, tree: Rope, cmpres: var int): Rope = var c: int var t = tree N.left = nil N.right = nil # reset to nil var le = N var r = N while true: c = cmp(s, t.data) if c < 0: if (t.left != nil) and (s < t.left.data): var y = t.left t.left = y.right y.right = t t = y if t.left == nil: break r.left = t r = t t = t.left elif c > 0: if (t.right != nil) and (s > t.right.data): var y = t.right t.right = y.left y.left = t t = y if t.right == nil: break le.right = t le = t t = t.right else: break cmpres = c le.right = t.left r.left = t.right t.left = N.right t.right = N.left result = t proc insertInCache(s: string, tree: Rope): Rope = var t = tree if t == nil: result = newRope(s) when countCacheMisses: inc(misses) return var cmp: int t = splay(s, t, cmp) if cmp == 0: # We get here if it's already in the Tree # Don't add it again result = t when countCacheMisses: inc(hits) else: when countCacheMisses: inc(misses) result = newRope(s) if cmp < 0: result.left = t.left result.right = t t.left = nil else: # i > t.item: result.right = t.right result.left = t t.right = nil proc rope*(s: string = ""): Rope {.rtl, extern: "nro$1Str".} = ## Converts a string to a rope. if s.len == 0: result = nil else: when nimvm: # No caching in VM context result = newRope(s) else: if cacheEnabled: result = insertInCache(s, cache) cache = result else: result = newRope(s) proc rope*(i: BiggestInt): Rope {.rtl, extern: "nro$1BiggestInt".} = ## Converts an int to a rope. result = rope($i) proc rope*(f: BiggestFloat): Rope {.rtl, extern: "nro$1BiggestFloat".} = ## Converts a float to a rope. result = rope($f) proc enableCache*() {.rtl, extern: "nro$1".} = ## Enables the caching of leaves. This reduces the memory footprint at ## the cost of runtime efficiency. cacheEnabled = true proc disableCache*() {.rtl, extern: "nro$1".} = ## the cache is discarded and disabled. The GC will reuse its used memory. cache = nil cacheEnabled = false proc `&`*(a, b: Rope): Rope {.rtl, extern: "nroConcRopeRope".} = ## the concatenation operator for ropes. 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 `&`*(a: Rope, b: string): Rope {.rtl, extern: "nroConcRopeStr".} = ## the concatenation operator for ropes. result = a & rope(b) proc `&`*(a: string, b: Rope): Rope {.rtl, extern: "nroConcStrRope".} = ## the concatenation operator for ropes. result = rope(a) & b proc `&`*(a: openArray[Rope]): Rope {.rtl, extern: "nroConcOpenArray".} = ## the concatenation operator for an openarray of ropes. for i in countup(0, high(a)): result = result & a[i] proc add*(a: var Rope, b: Rope) {.rtl, extern: "nro$1Rope".} = ## adds `b` to the rope `a`. a = a & b proc add*(a: var Rope, b: string) {.rtl, extern: "nro$1Str".} = ## adds `b` to the rope `a`. a = a & b proc `[]`*(r: Rope, i: int): char {.rtl, extern: "nroCharAt".} = ## returns the character at position `i` in the rope `r`. This is quite ## expensive! Worst-case: O(n). If ``i >= r.len``, ``\0`` is returned. var x = r var j = i if x == nil: return while true: if x != nil and x.data.len > 0: if j < x.data.len: return x.data[j] return '\0' else: if x.left.length > j: x = x.left else: x = x.right dec(j, x.len) iterator leaves*(r: Rope): string = ## iterates over any leaf string in the rope `r`. if r != nil: var stack = @[r] while stack.len > 0: var it = stack.pop while it.left != nil: assert(it.right != nil) stack.add(it.right) it = it.left assert(it != nil) yield it.data iterator items*(r: Rope): char = ## iterates over any character in the rope `r`. for s in leaves(r): for c in items(s): yield c proc write*(f: File, r: Rope) {.rtl, extern: "nro$1".} = ## writes a rope to a file. for s in leaves(r): write(f, s) proc write*(s: Stream, r: Rope) {.rtl, extern: "nroWriteStream".} = ## writes a rope to a stream. for rs in leaves(r): write(s, rs) proc `$`*(r: Rope): string {.rtl, extern: "nroToString".}= ## converts a rope back to a string. result = newStringOfCap(r.len) for s in leaves(r): add(result, s) proc `%`*(frmt: string, args: openArray[Rope]): Rope {. rtl, extern: "nroFormat".} = ## `%` substitution operator for ropes. Does not support the ``$identifier`` ## nor ``${identifier}`` notations. var i = 0 var length = len(frmt) result = nil var num = 0 while i < length: if frmt[i] == '$': inc(i) case frmt[i] of '$': add(result, "$") inc(i) of '#': inc(i) add(result, args[num]) inc(num) of '0'..'9': var j = 0 while true: j = j * 10 + ord(frmt[i]) - ord('0') inc(i) if frmt[i] notin {'0'..'9'}: break add(result, args[j-1]) of '{': inc(i) var j = 0 while frmt[i] in {'0'..'9'}: j = j * 10 + ord(frmt[i]) - ord('0') inc(i) if frmt[i] == '}': inc(i) else: raise newException(ValueError, "invalid format string") add(result, args[j-1]) else: raise newException(ValueError, "invalid format string") var start = i while i < length: if frmt[i] != '$': inc(i) else: break if i - 1 >= start: add(result, substr(frmt, start, i - 1)) proc addf*(c: var Rope, frmt: string, args: openArray[Rope]) {. rtl, extern: "nro$1".} = ## shortcut for ``add(c, frmt % args)``. add(c, frmt % args) const bufSize = 1024 # 1 KB is reasonable proc equalsFile*(r: Rope, f: File): bool {.rtl, extern: "nro$1File".} = ## returns true if the contents of the file `f` equal `r`. var buf: array[bufSize, char] bpos = buf.len blen = buf.len for s in leaves(r): var spos = 0 let slen = s.len while spos < slen: if bpos == blen: # Read more data bpos = 0 blen = readBuffer(f, addr(buf[0]), buf.len) if blen == 0: # no more data in file result = false return let n = min(blen - bpos, slen - spos) # TODO There's gotta be a better way of comparing here... if not equalMem(addr(buf[bpos]), cast[pointer](cast[int](cstring(s))+spos), n): result = false return spos += n bpos += n result = readBuffer(f, addr(buf[0]), 1) == 0 # check that we've read all proc equalsFile*(r: Rope, filename: string): bool {.rtl, extern: "nro$1Str".} = ## returns true if the contents of the file `f` equal `r`. If `f` does not ## exist, false is returned. var f: File result = open(f, filename) if result: result = equalsFile(r, f) close(f) new(N) # init dummy node for splay algorithm {.pop.}