nim-ranges/ranges/typedranges.nim

import ./ptr_arith, typetraits, hashes

const rangesGCHoldEnabled = not defined(rangesDisableGCHold)
const unsafeAPIEnabled = defined(rangesEnableUnsafeAPI)

type
  # A view into immutable array
  Range* {.shallow.} [T] = object
    when rangesGCHoldEnabled:
      gcHold: seq[T]
    start: ptr T
    mLen: int32

  # A view into mutable array
  MutRange*[T] = distinct Range[T]

  ByteRange* = Range[byte]
  MutByteRange* = MutRange[byte]

proc toImmutableRange[T](a: seq[T]): Range[T] =
  if a.len != 0:
    when rangesGCHoldEnabled:
      result.gcHold = a
    result.start = addr result.gcHold[0]
    result.mLen = int32(a.len)

when unsafeAPIEnabled:
  proc toImmutableRangeNoGCHold[T](a: openarray[T]): Range[T] =
    if a.len != 0:
      result.start = unsafeAddr a[0]
      result.mLen = int32(a.len)

  proc toImmutableRange[T](a: openarray[T]): Range[T] {.inline.} =
    toImmutableRangeNoGCHold(a)

proc toRange*[T](a: var seq[T]): MutRange[T] {.inline.} =
  MutRange[T](toImmutableRange(a))

when unsafeAPIEnabled:
  proc toRange*[T](a: var openarray[T]): MutRange[T] {.inline.} =
    MutRange[T](toImmutableRange(a))

  template initStackRange*[T](sz: static[int]): MutRange[T] =
    var data: array[sz, T]
    data.toRange()

  proc toRange*[T](a: openarray[T]): Range[T] {.inline.} = toImmutableRange(a)

proc newRange*[T](sz: int): MutRange[T] {.inline.} =
  MutRange[T](toImmutableRange(newSeq[T](sz)))

proc toRange*[T](a: seq[T]): Range[T] {.inline.} = toImmutableRange(a)

converter toImmutableRange*[T](a: MutRange[T]): Range[T] {.inline.} = Range[T](a)

proc len*(r: Range): int {.inline.} = int(r.mLen)

proc high*(r: Range): int {.inline.} = r.len - 1
proc low*(r: Range): int {.inline.} = 0

proc elemAt[T](r: MutRange[T], idx: int): var T {.inline.} =
  assert(idx < r.len)
  Range[T](r).start.shift(idx)[]

proc `[]=`*[T](r: MutRange[T], idx: int, v: T) {.inline.} = r.elemAt(idx) = v
proc `[]`*[T](r: MutRange[T], i: int): var T = r.elemAt(i)

proc `[]`*[T](r: Range[T], idx: int): T {.inline.} =
  assert(idx < r.len)
  r.start.shift(idx)[]

proc `==`*[T](a, b: Range[T]): bool =
  if a.len != b.len: return false
  equalMem(a.start, b.start, sizeof(T) * a.len)

iterator ptrs[T](r: Range[T]): (int, ptr T) =
  var p = r.start
  var i = 0
  let e = r.len
  while i != e:
    yield (i, p)
    p = p.shift(1)
    inc i

iterator items*[T](r: Range[T]): T =
  for _, v in ptrs(r): yield v[]

iterator pairs*[T](r: Range[T]): (int, T) =
  for i, v in ptrs(r): yield (i, v[])

iterator mitems*[T](r: MutRange[T]): var T =
  for _, v in ptrs(r): yield v[]

iterator mpairs*[T](r: MutRange[T]): (int, var T) =
  for i, v in ptrs(r): yield (i, v[])

proc toSeq*[T](r: Range[T]): seq[T] =
  result = newSeqOfCap[T](r.len)
  for i in r: result.add(i)

proc `$`*(r: Range): string =
  result = "R["
  for i, v in r:
    if i != 0:
      result &= ", "
    result &= $v
  result &= "]"

proc sliceNormalized[T](r: Range[T], ibegin, iend: int): Range[T] =
  assert(ibegin >= 0 and ibegin < r.len and iend >= ibegin and iend < r.len)
  when rangesGCHoldEnabled:
    result.gcHold = r.gcHold
  result.start = r.start.shift(ibegin)
  result.mLen = int32(iend - ibegin + 1)

proc slice*[T](r: Range[T], ibegin = 0, iend = -1): Range[T] =
  let e = if iend < 0: r.len + iend
          else: iend
  sliceNormalized(r, ibegin, e)

proc slice*[T](r: MutRange[T], ibegin = 0, iend = -1): MutRange[T] {.inline.} =
  MutRange[T](Range[T](r).slice(ibegin, iend))

template `^^`(s, i: untyped): untyped =
  (when i is BackwardsIndex: s.len - int(i) else: int(i))

proc `[]`*[T, U, V](r: Range[T], s: HSlice[U, V]): Range[T] {.inline.} =
  sliceNormalized(r, r ^^ s.a, r ^^ s.b)

proc `[]`*[T, U, V](r: MutRange[T], s: HSlice[U, V]): MutRange[T] {.inline.} =
  MutRange[T](sliceNormalized(r, r ^^ s.a, r ^^ s.b))

proc `[]=`*[T, U, V](r: MutRange[T], s: HSlice[U, V], v: openarray[T]) =
  let a = r ^^ s.a
  let b = r ^^ s.b
  let L = b - a + 1
  if L == v.len:
    for i in 0..<L: r[i + a] = v[i]
  else:
    raise newException(RangeError, "different lengths for slice assignment")

template toOpenArray*[T](r: Range[T]): auto =
  # TODO: Casting through an {.unchecked.} array would be more appropriate
  # here, but currently this results in internal compiler error.
  toOpenArray(cast[ptr array[10000000, T]](r.start)[], 0, r.high)

proc `[]=`*[T, U, V](r: MutRange[T], s: HSlice[U, V], v: Range[T]) {.inline.} =
  r[s] = toOpenArray(v)

proc baseAddr*[T](r: Range[T]): ptr T {.inline.} = r.start

template toRange*[T](a: Range[T]): Range[T] = a

# this preferred syntax doesn't work
# see https://github.com/nim-lang/Nim/issues/7995
#template copyRange[T](dest: seq[T], destOffset: int, src: Range[T]) =
#  when supportsCopyMem(T):

template copyRange[T](E: typedesc, dest: seq[T], destOffset: int, src: Range[T]) =
  when supportsCopyMem(E):
    if dest.len != 0 and src.len != 0:
      copyMem(dest[destOffset].unsafeAddr, src.start, sizeof(T) * src.len)
  else:
    for i in 0..<src.len:
      dest[i + destOffset] = src[i]

proc concat*[T](v: varargs[Range[T], toRange]): seq[T] =
  var len = 0
  for c in v: inc(len, c.len)
  result = newSeq[T](len)
  len = 0
  for c in v:
    copyRange(T, result, len, c)
    inc(len, c.len)

proc `&`*[T](a, b: Range[T]): seq[T] =
  result = newSeq[T](a.len + b.len)
  copyRange(T, result, 0, a)
  copyRange(T, result, a.len, b)

proc hash*(x: Range): Hash =
  result = hash(toOpenArray(x))
add hash function 2018-06-16 11:46:02 +00:00			`import ./ptr_arith, typetraits, hashes`
Typed ranges 2018-03-26 12:52:48 +00:00
			`const rangesGCHoldEnabled = not defined(rangesDisableGCHold)`
			`const unsafeAPIEnabled = defined(rangesEnableUnsafeAPI)`

			`type`
			`# A view into immutable array`
			`Range* {.shallow.} [T] = object`
			`when rangesGCHoldEnabled:`
			`gcHold: seq[T]`
			`start: ptr T`
			`mLen: int32`

			`# A view into mutable array`
			`MutRange*[T] = distinct Range[T]`

helpers for manipulating binary formats using bit sequences 2018-06-20 16:45:10 +00:00			`ByteRange* = Range[byte]`
			`MutByteRange* = MutRange[byte]`

Typed ranges 2018-03-26 12:52:48 +00:00			`proc toImmutableRange[T](a: seq[T]): Range[T] =`
			`if a.len != 0:`
			`when rangesGCHoldEnabled:`
			`result.gcHold = a`
Fixes #10 2018-06-15 11:06:52 +00:00			`result.start = addr result.gcHold[0]`
Typed ranges 2018-03-26 12:52:48 +00:00			`result.mLen = int32(a.len)`

			`when unsafeAPIEnabled:`
			`proc toImmutableRangeNoGCHold[T](a: openarray[T]): Range[T] =`
			`if a.len != 0:`
			`result.start = unsafeAddr a[0]`
			`result.mLen = int32(a.len)`

			`proc toImmutableRange[T](a: openarray[T]): Range[T] {.inline.} =`
			`toImmutableRangeNoGCHold(a)`

			`proc toRange*[T](a: var seq[T]): MutRange[T] {.inline.} =`
			`MutRange[T](toImmutableRange(a))`

			`when unsafeAPIEnabled:`
			`proc toRange*[T](a: var openarray[T]): MutRange[T] {.inline.} =`
			`MutRange[T](toImmutableRange(a))`

			`template initStackRange*[T](sz: static[int]): MutRange[T] =`
			`var data: array[sz, T]`
			`data.toRange()`

			`proc toRange*[T](a: openarray[T]): Range[T] {.inline.} = toImmutableRange(a)`

			`proc newRange*[T](sz: int): MutRange[T] {.inline.} =`
			`MutRange[T](toImmutableRange(newSeq[T](sz)))`

			`proc toRange*[T](a: seq[T]): Range[T] {.inline.} = toImmutableRange(a)`

			`converter toImmutableRange*[T](a: MutRange[T]): Range[T] {.inline.} = Range[T](a)`

			`proc len*(r: Range): int {.inline.} = int(r.mLen)`

			`proc high*(r: Range): int {.inline.} = r.len - 1`
			`proc low*(r: Range): int {.inline.} = 0`

			`proc elemAt[T](r: MutRange[T], idx: int): var T {.inline.} =`
			`assert(idx < r.len)`
			`Range[T](r).start.shift(idx)[]`

			proc `[]=`*[T](r: MutRange[T], idx: int, v: T) {.inline.} = r.elemAt(idx) = v
			proc `[]`*[T](r: MutRange[T], i: int): var T = r.elemAt(i)

			proc `[]`*[T](r: Range[T], idx: int): T {.inline.} =
			`assert(idx < r.len)`
			`r.start.shift(idx)[]`

add equality operator 2018-06-06 15:53:02 +00:00			proc `==`*[T](a, b: Range[T]): bool =
			`if a.len != b.len: return false`
			`equalMem(a.start, b.start, sizeof(T) * a.len)`

Typed ranges 2018-03-26 12:52:48 +00:00			`iterator ptrs[T](r: Range[T]): (int, ptr T) =`
			`var p = r.start`
			`var i = 0`
			`let e = r.len`
			`while i != e:`
			`yield (i, p)`
			`p = p.shift(1)`
			`inc i`

			`iterator items*[T](r: Range[T]): T =`
			`for _, v in ptrs(r): yield v[]`

			`iterator pairs*[T](r: Range[T]): (int, T) =`
			`for i, v in ptrs(r): yield (i, v[])`

			`iterator mitems*[T](r: MutRange[T]): var T =`
			`for _, v in ptrs(r): yield v[]`

			`iterator mpairs*[T](r: MutRange[T]): (int, var T) =`
			`for i, v in ptrs(r): yield (i, v[])`

			`proc toSeq*[T](r: Range[T]): seq[T] =`
			`result = newSeqOfCap[T](r.len)`
			`for i in r: result.add(i)`

			proc `$`*(r: Range): string =
			`result = "R["`
			`for i, v in r:`
			`if i != 0:`
			`result &= ", "`
			`result &= $v`
			`result &= "]"`

			`proc sliceNormalized[T](r: Range[T], ibegin, iend: int): Range[T] =`
			`assert(ibegin >= 0 and ibegin < r.len and iend >= ibegin and iend < r.len)`
			`when rangesGCHoldEnabled:`
			`result.gcHold = r.gcHold`
			`result.start = r.start.shift(ibegin)`
			`result.mLen = int32(iend - ibegin + 1)`

			`proc slice*[T](r: Range[T], ibegin = 0, iend = -1): Range[T] =`
			`let e = if iend < 0: r.len + iend`
			`else: iend`
			`sliceNormalized(r, ibegin, e)`

			`proc slice*[T](r: MutRange[T], ibegin = 0, iend = -1): MutRange[T] {.inline.} =`
			`MutRange[T](Range[T](r).slice(ibegin, iend))`

			template `^^`(s, i: untyped): untyped =
			`(when i is BackwardsIndex: s.len - int(i) else: int(i))`

			proc `[]`*[T, U, V](r: Range[T], s: HSlice[U, V]): Range[T] {.inline.} =
			`sliceNormalized(r, r ^^ s.a, r ^^ s.b)`

			proc `[]`*[T, U, V](r: MutRange[T], s: HSlice[U, V]): MutRange[T] {.inline.} =
			`MutRange[T](sliceNormalized(r, r ^^ s.a, r ^^ s.b))`

			proc `[]=`*[T, U, V](r: MutRange[T], s: HSlice[U, V], v: openarray[T]) =
			`let a = r ^^ s.a`
			`let b = r ^^ s.b`
			`let L = b - a + 1`
			`if L == v.len:`
			`for i in 0..<L: r[i + a] = v[i]`
			`else:`
			`raise newException(RangeError, "different lengths for slice assignment")`

Moved toOpenArray above its usage 2018-04-11 11:26:46 +00:00			`template toOpenArray*[T](r: Range[T]): auto =`
			`# TODO: Casting through an {.unchecked.} array would be more appropriate`
			`# here, but currently this results in internal compiler error.`
			`toOpenArray(cast[ptr array[10000000, T]](r.start)[], 0, r.high)`

Typed ranges 2018-03-26 12:52:48 +00:00			proc `[]=`*[T, U, V](r: MutRange[T], s: HSlice[U, V], v: Range[T]) {.inline.} =
			`r[s] = toOpenArray(v)`

			`proc baseAddr*[T](r: Range[T]): ptr T {.inline.} = r.start`
add concat operation 2018-06-07 15:26:08 +00:00
			`template toRange*[T](a: Range[T]): Range[T] = a`

fix concat operation 2018-06-08 03:07:47 +00:00			`# this preferred syntax doesn't work`
			`# see https://github.com/nim-lang/Nim/issues/7995`
			`#template copyRange[T](dest: seq[T], destOffset: int, src: Range[T]) =`
			`# when supportsCopyMem(T):`

			`template copyRange[T](E: typedesc, dest: seq[T], destOffset: int, src: Range[T]) =`
			`when supportsCopyMem(E):`
fix zero length concat 2018-06-12 09:00:45 +00:00			`if dest.len != 0 and src.len != 0:`
			`copyMem(dest[destOffset].unsafeAddr, src.start, sizeof(T) * src.len)`
fix concat operation 2018-06-08 03:07:47 +00:00			`else:`
			`for i in 0..<src.len:`
			`dest[i + destOffset] = src[i]`

add concat operation 2018-06-07 15:26:08 +00:00			`proc concat*[T](v: varargs[Range[T], toRange]): seq[T] =`
			`var len = 0`
			`for c in v: inc(len, c.len)`
			`result = newSeq[T](len)`
			`len = 0`
			`for c in v:`
fix concat operation 2018-06-08 03:07:47 +00:00			`copyRange(T, result, len, c)`
add concat operation 2018-06-07 15:26:08 +00:00			`inc(len, c.len)`

			proc `&`*[T](a, b: Range[T]): seq[T] =
			`result = newSeq[T](a.len + b.len)`
fix concat operation 2018-06-08 03:07:47 +00:00			`copyRange(T, result, 0, a)`
			`copyRange(T, result, a.len, b)`
fix hash function 2018-06-17 00:20:46 +00:00
			`proc hash*(x: Range): Hash =`
			`result = hash(toOpenArray(x))`