private.rs source code [crates/typenum/src/private.rs]

1	//! Ignore me!* This module is for things that are conceptually private but that must*
2	//! be made public for typenum to work correctly.
3	//!
4	//! Unless you are working on typenum itself, there is no need to view anything here.
5	//!
6	//! Certainly don't implement any of the traits here for anything.
7	//!
8	//!
9	//! Just look away.
10	//!
11	//!
12	//! Loooooooooooooooooooooooooooooooooook awaaaaaaaaaaaayyyyyyyyyyyyyyyyyyyyyyyyyyyyy...
13	//!
14	//!
15	//! If you do manage to find something of use in here, please let me know. If you can make a
16	//! compelling case, it may be moved out of __private.
17	//!
18	//! Note: Aliases for private type operators will all be named simply that operator followed
19	//! by an abbreviated name of its associated type.
20
21	#![doc(hidden)]
22
23	use crate::{
24	bit::{Bit, B0, B1},
25	uint::{UInt, UTerm, Unsigned},
26	};
27
28	/// A marker for restricting a method on a public trait to internal use only.
29	pub(crate) enum Internal {}
30
31	pub trait InternalMarker {}
32
33	impl InternalMarker for Internal {}
34
35	/// Convenience trait. Calls `Invert` -> `TrimTrailingZeros` -> `Invert`
36	pub trait Trim {
37	type Output;
38
39	fn trim(self) -> Self::Output;
40	}
41	pub type TrimOut<A> = <A as Trim>::Output;
42
43	/// Gets rid of all zeros until it hits a one.
44
45	// ONLY IMPLEMENT FOR INVERTED NUMBERS!
46	pub trait TrimTrailingZeros {
47	type Output;
48
49	fn trim_trailing_zeros(self) -> Self::Output;
50	}
51	pub type TrimTrailingZerosOut<A> = <A as TrimTrailingZeros>::Output;
52
53	/// Converts between standard numbers and inverted ones that have the most significant
54	/// digit on the outside.
55	pub trait Invert {
56	type Output;
57
58	fn invert(self) -> Self::Output;
59	}
60	pub type InvertOut<A> = <A as Invert>::Output;
61
62	/// Doubly private! Called by invert to make the magic happen once its done the first step.
63	/// The Rhs is what we've got so far.
64	pub trait PrivateInvert<Rhs> {
65	type Output;
66
67	fn private_invert(self, rhs: Rhs) -> Self::Output;
68	}
69	pub type PrivateInvertOut<A, Rhs> = <A as PrivateInvert<Rhs>>::Output;
70
71	/// Terminating character for `InvertedUInt`s
72	pub struct InvertedUTerm;
73
74	/// Inverted `UInt` (has most significant digit on the outside)
75	pub struct InvertedUInt<IU: InvertedUnsigned, B: Bit> {
76	msb: IU,
77	lsb: B,
78	}
79
80	/// Does the real anding for `UInt`s; `And` just calls this and then `Trim`.
81	pub trait PrivateAnd<Rhs = Self> {
82	type Output;
83
84	fn private_and(self, rhs: Rhs) -> Self::Output;
85	}
86	pub type PrivateAndOut<A, Rhs> = <A as PrivateAnd<Rhs>>::Output;
87
88	/// Does the real xoring for `UInt`s; `Xor` just calls this and then `Trim`.
89	pub trait PrivateXor<Rhs = Self> {
90	type Output;
91
92	fn private_xor(self, rhs: Rhs) -> Self::Output;
93	}
94	pub type PrivateXorOut<A, Rhs> = <A as PrivateXor<Rhs>>::Output;
95
96	/// Does the real subtraction for `UInt`s; `Sub` just calls this and then `Trim`.
97	pub trait PrivateSub<Rhs = Self> {
98	type Output;
99
100	fn private_sub(self, rhs: Rhs) -> Self::Output;
101	}
102	pub type PrivateSubOut<A, Rhs> = <A as PrivateSub<Rhs>>::Output;
103
104	/// Used for addition of signed integers; `C = P.cmp(N)`
105	/// Assumes `P = Self` is positive and `N` is negative
106	/// where `P` and `N` are both passed as unsigned integers
107	pub trait PrivateIntegerAdd<C, N> {
108	type Output;
109
110	fn private_integer_add(self, _: C, _: N) -> Self::Output;
111	}
112	pub type PrivateIntegerAddOut<P, C, N> = <P as PrivateIntegerAdd<C, N>>::Output;
113
114	pub trait PrivatePow<Y, N> {
115	type Output;
116
117	fn private_pow(self, _: Y, _: N) -> Self::Output;
118	}
119	pub type PrivatePowOut<A, Y, N> = <A as PrivatePow<Y, N>>::Output;
120
121	/// Performs `Shl` on `Lhs` so that `SizeOf(Lhs) = SizeOf(Rhs)`
122	/// Fails if `SizeOf(Lhs) > SizeOf(Rhs)`
123	pub trait ShiftDiff<Rhs> {
124	type Output;
125	}
126	pub type ShiftDiffOut<A, Rhs> = <A as ShiftDiff<Rhs>>::Output;
127
128	/// Gives `SizeOf(Lhs) - SizeOf(Rhs)`
129	pub trait BitDiff<Rhs> {
130	type Output;
131	}
132	pub type BitDiffOut<A, Rhs> = <A as BitDiff<Rhs>>::Output;
133
134	/// Inverted unsigned numbers
135	pub trait InvertedUnsigned {
136	fn to_u64() -> u64;
137	}
138
139	impl InvertedUnsigned for InvertedUTerm {
140	#[inline]
141	fn to_u64() -> u64 {
142	`0`
143	}
144	}
145
146	impl<IU: InvertedUnsigned, B: Bit> InvertedUnsigned for InvertedUInt<IU, B> {
147	#[inline]
148	fn to_u64() -> u64 {
149	u64::from(B::to_u8()) \| IU::to_u64() << `1`
150	}
151	}
152
153	impl Invert for UTerm {
154	type Output = InvertedUTerm;
155
156	#[inline]
157	fn invert(self) -> Self::Output {
158	InvertedUTerm
159	}
160	}
161
162	impl<U: Unsigned, B: Bit> Invert for UInt<U, B>
163	where
164	U: PrivateInvert<InvertedUInt<InvertedUTerm, B>>,
165	{
166	type Output = PrivateInvertOut<U, InvertedUInt<InvertedUTerm, B>>;
167
168	#[inline]
169	fn invert(self) -> Self::Output {
170	self.msb.private_invert(InvertedUInt {
171	msb: InvertedUTerm,
172	lsb: self.lsb,
173	})
174	}
175	}
176
177	impl<IU: InvertedUnsigned> PrivateInvert<IU> for UTerm {
178	type Output = IU;
179
180	#[inline]
181	fn private_invert(self, rhs: IU) -> Self::Output {
182	rhs
183	}
184	}
185
186	impl<IU: InvertedUnsigned, U: Unsigned, B: Bit> PrivateInvert<IU> for UInt<U, B>
187	where
188	U: PrivateInvert<InvertedUInt<IU, B>>,
189	{
190	type Output = PrivateInvertOut<U, InvertedUInt<IU, B>>;
191
192	#[inline]
193	fn private_invert(self, rhs: IU) -> Self::Output {
194	self.msb.private_invert(InvertedUInt {
195	msb: rhs,
196	lsb: self.lsb,
197	})
198	}
199	}
200
201	#[test]
202	fn test_inversion() {
203	type Test4 = <crate::consts::U4 as Invert>::Output;
204	type Test5 = <crate::consts::U5 as Invert>::Output;
205	type Test12 = <crate::consts::U12 as Invert>::Output;
206	type Test16 = <crate::consts::U16 as Invert>::Output;
207
208	assert_eq!(`1`, <Test4 as InvertedUnsigned>::to_u64());
209	assert_eq!(`5`, <Test5 as InvertedUnsigned>::to_u64());
210	assert_eq!(`3`, <Test12 as InvertedUnsigned>::to_u64());
211	assert_eq!(`1`, <Test16 as InvertedUnsigned>::to_u64());
212	}
213
214	impl Invert for InvertedUTerm {
215	type Output = UTerm;
216
217	#[inline]
218	fn invert(self) -> Self::Output {
219	UTerm
220	}
221	}
222
223	impl<IU: InvertedUnsigned, B: Bit> Invert for InvertedUInt<IU, B>
224	where
225	IU: PrivateInvert<UInt<UTerm, B>>,
226	{
227	type Output = <IU as PrivateInvert<UInt<UTerm, B>>>::Output;
228
229	#[inline]
230	fn invert(self) -> Self::Output {
231	self.msb.private_invert(UInt {
232	msb: UTerm,
233	lsb: self.lsb,
234	})
235	}
236	}
237
238	impl<U: Unsigned> PrivateInvert<U> for InvertedUTerm {
239	type Output = U;
240
241	#[inline]
242	fn private_invert(self, rhs: U) -> Self::Output {
243	rhs
244	}
245	}
246
247	impl<U: Unsigned, IU: InvertedUnsigned, B: Bit> PrivateInvert<U> for InvertedUInt<IU, B>
248	where
249	IU: PrivateInvert<UInt<U, B>>,
250	{
251	type Output = <IU as PrivateInvert<UInt<U, B>>>::Output;
252
253	#[inline]
254	fn private_invert(self, rhs: U) -> Self::Output {
255	self.msb.private_invert(UInt {
256	msb: rhs,
257	lsb: self.lsb,
258	})
259	}
260	}
261
262	#[test]
263	fn test_double_inversion() {
264	type Test4 = <<crate::consts::U4 as Invert>::Output as Invert>::Output;
265	type Test5 = <<crate::consts::U5 as Invert>::Output as Invert>::Output;
266	type Test12 = <<crate::consts::U12 as Invert>::Output as Invert>::Output;
267	type Test16 = <<crate::consts::U16 as Invert>::Output as Invert>::Output;
268
269	assert_eq!(`4`, <Test4 as Unsigned>::to_u64());
270	assert_eq!(`5`, <Test5 as Unsigned>::to_u64());
271	assert_eq!(`12`, <Test12 as Unsigned>::to_u64());
272	assert_eq!(`16`, <Test16 as Unsigned>::to_u64());
273	}
274
275	impl TrimTrailingZeros for InvertedUTerm {
276	type Output = InvertedUTerm;
277
278	#[inline]
279	fn trim_trailing_zeros(self) -> Self::Output {
280	InvertedUTerm
281	}
282	}
283
284	impl<IU: InvertedUnsigned> TrimTrailingZeros for InvertedUInt<IU, B1> {
285	type Output = Self;
286
287	#[inline]
288	fn trim_trailing_zeros(self) -> Self::Output {
289	self
290	}
291	}
292
293	impl<IU: InvertedUnsigned> TrimTrailingZeros for InvertedUInt<IU, B0>
294	where
295	IU: TrimTrailingZeros,
296	{
297	type Output = <IU as TrimTrailingZeros>::Output;
298
299	#[inline]
300	fn trim_trailing_zeros(self) -> Self::Output {
301	self.msb.trim_trailing_zeros()
302	}
303	}
304
305	impl<U: Unsigned> Trim for U
306	where
307	U: Invert,
308	<U as Invert>::Output: TrimTrailingZeros,
309	<<U as Invert>::Output as TrimTrailingZeros>::Output: Invert,
310	{
311	type Output = <<<U as Invert>::Output as TrimTrailingZeros>::Output as Invert>::Output;
312
313	#[inline]
314	fn trim(self) -> Self::Output {
315	self.invert().trim_trailing_zeros().invert()
316	}
317	}
318
319	// Note: Trimming is tested when we do subtraction.
320
321	pub trait PrivateCmp<Rhs, SoFar> {
322	type Output;
323
324	fn private_cmp(&self, _: &Rhs, _: SoFar) -> Self::Output;
325	}
326	pub type PrivateCmpOut<A, Rhs, SoFar> = <A as PrivateCmp<Rhs, SoFar>>::Output;
327
328	// Set Bit
329	pub trait PrivateSetBit<I, B> {
330	type Output;
331
332	fn private_set_bit(self, _: I, _: B) -> Self::Output;
333	}
334	pub type PrivateSetBitOut<N, I, B> = <N as PrivateSetBit<I, B>>::Output;
335
336	// Div
337	pub trait PrivateDiv<N, D, Q, R, I> {
338	type Quotient;
339	type Remainder;
340
341	fn private_div_quotient(self, _: N, _: D, _: Q, _: R, _: I) -> Self::Quotient;
342
343	fn private_div_remainder(self, _: N, _: D, _: Q, _: R, _: I) -> Self::Remainder;
344	}
345
346	pub type PrivateDivQuot<N, D, Q, R, I> = <() as PrivateDiv<N, D, Q, R, I>>::Quotient;
347	pub type PrivateDivRem<N, D, Q, R, I> = <() as PrivateDiv<N, D, Q, R, I>>::Remainder;
348
349	pub trait PrivateDivIf<N, D, Q, R, I, RcmpD> {
350	type Quotient;
351	type Remainder;
352
353	fn private_div_if_quotient(self, _: N, _: D, _: Q, _: R, _: I, _: RcmpD) -> Self::Quotient;
354
355	fn private_div_if_remainder(self, _: N, _: D, _: Q, _: R, _: I, _: RcmpD) -> Self::Remainder;
356	}
357
358	pub type PrivateDivIfQuot<N, D, Q, R, I, RcmpD> =
359	<() as PrivateDivIf<N, D, Q, R, I, RcmpD>>::Quotient;
360	pub type PrivateDivIfRem<N, D, Q, R, I, RcmpD> =
361	<() as PrivateDivIf<N, D, Q, R, I, RcmpD>>::Remainder;
362
363	// Div for signed ints
364	pub trait PrivateDivInt<C, Divisor> {
365	type Output;
366
367	fn private_div_int(self, _: C, _: Divisor) -> Self::Output;
368	}
369	pub type PrivateDivIntOut<A, C, Divisor> = <A as PrivateDivInt<C, Divisor>>::Output;
370
371	pub trait PrivateRem<URem, Divisor> {
372	type Output;
373
374	fn private_rem(self, _: URem, _: Divisor) -> Self::Output;
375	}
376	pub type PrivateRemOut<A, URem, Divisor> = <A as PrivateRem<URem, Divisor>>::Output;
377
378	// min max
379	pub trait PrivateMin<Rhs, CmpResult> {
380	type Output;
381	fn private_min(self, rhs: Rhs) -> Self::Output;
382	}
383	pub type PrivateMinOut<A, B, CmpResult> = <A as PrivateMin<B, CmpResult>>::Output;
384
385	pub trait PrivateMax<Rhs, CmpResult> {
386	type Output;
387	fn private_max(self, rhs: Rhs) -> Self::Output;
388	}
389	pub type PrivateMaxOut<A, B, CmpResult> = <A as PrivateMax<B, CmpResult>>::Output;
390
391	// Comparisons
392
393	use crate::{Equal, False, Greater, Less, True};
394
395	pub trait IsLessPrivate<Rhs, Cmp> {
396	type Output: Bit;
397
398	fn is_less_private(self, _: Rhs, _: Cmp) -> Self::Output;
399	}
400
401	impl<A, B> IsLessPrivate<B, Less> for A {
402	type Output = True;
403
404	#[inline]
405	fn is_less_private(self, _: B, _: Less) -> Self::Output {
406	B1
407	}
408	}
409	impl<A, B> IsLessPrivate<B, Equal> for A {
410	type Output = False;
411
412	#[inline]
413	fn is_less_private(self, _: B, _: Equal) -> Self::Output {
414	B0
415	}
416	}
417	impl<A, B> IsLessPrivate<B, Greater> for A {
418	type Output = False;
419
420	#[inline]
421	fn is_less_private(self, _: B, _: Greater) -> Self::Output {
422	B0
423	}
424	}
425
426	pub trait IsEqualPrivate<Rhs, Cmp> {
427	type Output: Bit;
428
429	fn is_equal_private(self, _: Rhs, _: Cmp) -> Self::Output;
430	}
431
432	impl<A, B> IsEqualPrivate<B, Less> for A {
433	type Output = False;
434
435	#[inline]
436	fn is_equal_private(self, _: B, _: Less) -> Self::Output {
437	B0
438	}
439	}
440	impl<A, B> IsEqualPrivate<B, Equal> for A {
441	type Output = True;
442
443	#[inline]
444	fn is_equal_private(self, _: B, _: Equal) -> Self::Output {
445	B1
446	}
447	}
448	impl<A, B> IsEqualPrivate<B, Greater> for A {
449	type Output = False;
450
451	#[inline]
452	fn is_equal_private(self, _: B, _: Greater) -> Self::Output {
453	B0
454	}
455	}
456
457	pub trait IsGreaterPrivate<Rhs, Cmp> {
458	type Output: Bit;
459
460	fn is_greater_private(self, _: Rhs, _: Cmp) -> Self::Output;
461	}
462
463	impl<A, B> IsGreaterPrivate<B, Less> for A {
464	type Output = False;
465
466	#[inline]
467	fn is_greater_private(self, _: B, _: Less) -> Self::Output {
468	B0
469	}
470	}
471	impl<A, B> IsGreaterPrivate<B, Equal> for A {
472	type Output = False;
473
474	#[inline]
475	fn is_greater_private(self, _: B, _: Equal) -> Self::Output {
476	B0
477	}
478	}
479	impl<A, B> IsGreaterPrivate<B, Greater> for A {
480	type Output = True;
481
482	#[inline]
483	fn is_greater_private(self, _: B, _: Greater) -> Self::Output {
484	B1
485	}
486	}
487
488	pub trait IsLessOrEqualPrivate<Rhs, Cmp> {
489	type Output: Bit;
490
491	fn is_less_or_equal_private(self, _: Rhs, _: Cmp) -> Self::Output;
492	}
493
494	impl<A, B> IsLessOrEqualPrivate<B, Less> for A {
495	type Output = True;
496
497	#[inline]
498	fn is_less_or_equal_private(self, _: B, _: Less) -> Self::Output {
499	B1
500	}
501	}
502	impl<A, B> IsLessOrEqualPrivate<B, Equal> for A {
503	type Output = True;
504
505	#[inline]
506	fn is_less_or_equal_private(self, _: B, _: Equal) -> Self::Output {
507	B1
508	}
509	}
510	impl<A, B> IsLessOrEqualPrivate<B, Greater> for A {
511	type Output = False;
512
513	#[inline]
514	fn is_less_or_equal_private(self, _: B, _: Greater) -> Self::Output {
515	B0
516	}
517	}
518
519	pub trait IsNotEqualPrivate<Rhs, Cmp> {
520	type Output: Bit;
521
522	fn is_not_equal_private(self, _: Rhs, _: Cmp) -> Self::Output;
523	}
524
525	impl<A, B> IsNotEqualPrivate<B, Less> for A {
526	type Output = True;
527
528	#[inline]
529	fn is_not_equal_private(self, _: B, _: Less) -> Self::Output {
530	B1
531	}
532	}
533	impl<A, B> IsNotEqualPrivate<B, Equal> for A {
534	type Output = False;
535
536	#[inline]
537	fn is_not_equal_private(self, _: B, _: Equal) -> Self::Output {
538	B0
539	}
540	}
541	impl<A, B> IsNotEqualPrivate<B, Greater> for A {
542	type Output = True;
543
544	#[inline]
545	fn is_not_equal_private(self, _: B, _: Greater) -> Self::Output {
546	B1
547	}
548	}
549
550	pub trait IsGreaterOrEqualPrivate<Rhs, Cmp> {
551	type Output: Bit;
552
553	fn is_greater_or_equal_private(self, _: Rhs, _: Cmp) -> Self::Output;
554	}
555
556	impl<A, B> IsGreaterOrEqualPrivate<B, Less> for A {
557	type Output = False;
558
559	#[inline]
560	fn is_greater_or_equal_private(self, _: B, _: Less) -> Self::Output {
561	B0
562	}
563	}
564	impl<A, B> IsGreaterOrEqualPrivate<B, Equal> for A {
565	type Output = True;
566
567	#[inline]
568	fn is_greater_or_equal_private(self, _: B, _: Equal) -> Self::Output {
569	B1
570	}
571	}
572	impl<A, B> IsGreaterOrEqualPrivate<B, Greater> for A {
573	type Output = True;
574
575	#[inline]
576	fn is_greater_or_equal_private(self, _: B, _: Greater) -> Self::Output {
577	B1
578	}
579	}
580
581	pub trait PrivateSquareRoot {
582	type Output;
583	}
584
585	pub trait PrivateLogarithm2 {
586	type Output;
587	}
588