# # # Nim's Runtime Library # (c) Copyright 2012 Andreas Rumpf # # See the file "copying.txt", included in this # distribution, for details about the copyright. # ## This module implements some common generic algorithms. type SortOrder* = enum ## sort order Descending, Ascending {.deprecated: [TSortOrder: SortOrder].} proc `*`*(x: int, order: SortOrder): int {.inline.} = ## flips `x` if ``order == Descending``; ## if ``order == Ascending`` then `x` is returned. ## `x` is supposed to be the result of a comparator, ie ``< 0`` for ## *less than*, ``== 0`` for *equal*, ``> 0`` for *greater than*. var y = order.ord - 1 result = (x xor y) - y proc reverse*[T](a: var openArray[T], first, last: int) = ## reverses the array ``a[first..last]``. var x = first var y = last while x < y: swap(a[x], a[y]) dec(y) inc(x) proc reverse*[T](a: var openArray[T]) = ## reverses the array `a`. reverse(a, 0, a.high) proc reversed*[T](a: openArray[T], first, last: int): seq[T] = ## returns the reverse of the array `a[first..last]`. result = newSeq[T](last - first + 1) var x = first var y = last while x <= last: result[x] = a[y] dec(y) inc(x) proc reversed*[T](a: openArray[T]): seq[T] = ## returns the reverse of the array `a`. reversed(a, 0, a.high) proc binarySearch*[T](a: openArray[T], key: T): int = ## binary search for `key` in `a`. Returns -1 if not found. var b = len(a) while result < b: var mid = (result + b) div 2 if a[mid] < key: result = mid + 1 else: b = mid if result >= len(a) or a[result] != key: result = -1 proc smartBinarySearch*[T](a: openArray[T], key: T): int = ## ``a.len`` must be a power of 2 for this to work. var step = a.len div 2 while step > 0: if a[result or step] <= key: result = result or step step = step shr 1 if a[result] != key: result = -1 const onlySafeCode = true proc lowerBound*[T](a: openArray[T], key: T, cmp: proc(x,y: T): int {.closure.}): int = ## same as binarySearch except that if key is not in `a` then this ## returns the location where `key` would be if it were. In other ## words if you have a sorted sequence and you call insert(thing, elm, lowerBound(thing, elm)) ## the sequence will still be sorted ## ## `cmp` is the comparator function to use, the expected return values are the same as ## that of system.cmp ## ## example:: ## ## var arr = @[1,2,3,5,6,7,8,9] ## arr.insert(4, arr.lowerBound(4)) ## `after running the above arr is `[1,2,3,4,5,6,7,8,9]` result = a.low var pos = result var count, step: int count = a.high - a.low + 1 while count != 0: pos = result step = count div 2 pos += step if cmp(a[pos], key) < 0: pos.inc result = pos count -= step + 1 else: count = step proc lowerBound*[T](a: openArray[T], key: T): int = lowerBound(a, key, cmp[T]) proc merge[T](a, b: var openArray[T], lo, m, hi: int, cmp: proc (x, y: T): int {.closure.}, order: SortOrder) = template `<-` (a, b: expr) = when false: a = b elif onlySafeCode: shallowCopy(a, b) else: copyMem(addr(a), addr(b), sizeof(T)) # optimization: If max(left) <= min(right) there is nothing to do! # 1 2 3 4 ## 5 6 7 8 # -> O(n) for sorted arrays. # On random data this safes up to 40% of merge calls if cmp(a[m], a[m+1]) * order <= 0: return var j = lo # copy a[j..m] into b: assert j <= m when onlySafeCode: var bb = 0 while j <= m: b[bb] <- a[j] inc(bb) inc(j) else: copyMem(addr(b[0]), addr(a[j]), sizeof(T)*(m-j+1)) j = m+1 var i = 0 var k = lo # copy proper element back: while k < j and j <= hi: if cmp(b[i], a[j]) * order <= 0: a[k] <- b[i] inc(i) else: a[k] <- a[j] inc(j) inc(k) # copy rest of b: when onlySafeCode: while k < j: a[k] <- b[i] inc(k) inc(i) else: if k < j: copyMem(addr(a[k]), addr(b[i]), sizeof(T)*(j-k)) proc sort*[T](a: var openArray[T], cmp: proc (x, y: T): int {.closure.}, order = SortOrder.Ascending) = ## Default Nim sort. The sorting is guaranteed to be stable and ## the worst case is guaranteed to be O(n log n). ## The current implementation uses an iterative ## mergesort to achieve this. It uses a temporary sequence of ## length ``a.len div 2``. Currently Nim does not support a ## sensible default argument for ``cmp``, so you have to provide one ## of your own. However, the ``system.cmp`` procs can be used: ## ## .. code-block:: nim ## ## sort(myIntArray, system.cmp[int]) ## ## # do not use cmp[string] here as we want to use the specialized ## # overload: ## sort(myStrArray, system.cmp) ## ## You can inline adhoc comparison procs with the `do notation ## `_. Example: ## ## .. code-block:: nim ## ## people.sort do (x, y: Person) -> int: ## result = cmp(x.surname, y.surname) ## if result == 0: ## result = cmp(x.name, y.name) var n = a.len var b: seq[T] newSeq(b, n div 2) var s = 1 while s < n: var m = n-1-s while m >= 0: merge(a, b, max(m-s+1, 0), m, m+s, cmp, order) dec(m, s*2) s = s*2 proc product*[T](x: openArray[seq[T]]): seq[seq[T]] = ## produces the Cartesian product of the array. Warning: complexity ## may explode. result = @[] if x.len == 0: return if x.len == 1: result = @x return var indexes = newSeq[int](x.len) initial = newSeq[int](x.len) index = 0 # replace with newSeq as soon as #853 is fixed var next: seq[T] = @[] next.setLen(x.len) for i in 0..(x.len-1): if len(x[i]) == 0: return initial[i] = len(x[i])-1 indexes = initial while true: while indexes[index] == -1: indexes[index] = initial[index] index +=1 if index == x.len: return indexes[index] -=1 for ni, i in indexes: next[ni] = x[ni][i] var res: seq[T] shallowCopy(res, next) result.add(res) index = 0 indexes[index] -=1