swrdco

Description: Mapping of words commutes with the substring operation. (Contributed by AV, 11-Nov-2018)

		Ref	Expression
	Assertion	swrdco	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ( F o. ( W substr <. M , N >. ) ) = ( ( F o. W ) substr <. M , N >. ) )

Proof

Step	Hyp	Ref	Expression
1		ffn	\|- ( F : A --> B -> F Fn A )
2	1	3ad2ant3	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> F Fn A )
3		swrdvalfn	\|- ( ( W e. Word A /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) -> ( W substr <. M , N >. ) Fn ( 0 ..^ ( N - M ) ) )
4	3	3expb	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) ) -> ( W substr <. M , N >. ) Fn ( 0 ..^ ( N - M ) ) )
5	4	3adant3	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ( W substr <. M , N >. ) Fn ( 0 ..^ ( N - M ) ) )
6		swrdrn	\|- ( ( W e. Word A /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) -> ran ( W substr <. M , N >. ) C_ A )
7	6	3expb	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) ) -> ran ( W substr <. M , N >. ) C_ A )
8	7	3adant3	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ran ( W substr <. M , N >. ) C_ A )
9		fnco	\|- ( ( F Fn A /\ ( W substr <. M , N >. ) Fn ( 0 ..^ ( N - M ) ) /\ ran ( W substr <. M , N >. ) C_ A ) -> ( F o. ( W substr <. M , N >. ) ) Fn ( 0 ..^ ( N - M ) ) )
10	2 5 8 9	syl3anc	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ( F o. ( W substr <. M , N >. ) ) Fn ( 0 ..^ ( N - M ) ) )
11		wrdco	\|- ( ( W e. Word A /\ F : A --> B ) -> ( F o. W ) e. Word B )
12	11	3adant2	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ( F o. W ) e. Word B )
13		simp2l	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> M e. ( 0 ... N ) )
14		lenco	\|- ( ( W e. Word A /\ F : A --> B ) -> ( # ` ( F o. W ) ) = ( # ` W ) )
15	14	eqcomd	\|- ( ( W e. Word A /\ F : A --> B ) -> ( # ` W ) = ( # ` ( F o. W ) ) )
16	15	oveq2d	\|- ( ( W e. Word A /\ F : A --> B ) -> ( 0 ... ( # ` W ) ) = ( 0 ... ( # ` ( F o. W ) ) ) )
17	16	eleq2d	\|- ( ( W e. Word A /\ F : A --> B ) -> ( N e. ( 0 ... ( # ` W ) ) <-> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) )
18	17	biimpd	\|- ( ( W e. Word A /\ F : A --> B ) -> ( N e. ( 0 ... ( # ` W ) ) -> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) )
19	18	expcom	\|- ( F : A --> B -> ( W e. Word A -> ( N e. ( 0 ... ( # ` W ) ) -> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) ) )
20	19	com13	\|- ( N e. ( 0 ... ( # ` W ) ) -> ( W e. Word A -> ( F : A --> B -> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) ) )
21	20	adantl	\|- ( ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) -> ( W e. Word A -> ( F : A --> B -> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) ) )
22	21	3imp21	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> N e. ( 0 ... ( # ` ( F o. W ) ) ) )
23		swrdvalfn	\|- ( ( ( F o. W ) e. Word B /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` ( F o. W ) ) ) ) -> ( ( F o. W ) substr <. M , N >. ) Fn ( 0 ..^ ( N - M ) ) )
24	12 13 22 23	syl3anc	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ( ( F o. W ) substr <. M , N >. ) Fn ( 0 ..^ ( N - M ) ) )
25		3anass	\|- ( ( W e. Word A /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) <-> ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) ) )
26	25	biimpri	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) ) -> ( W e. Word A /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) )
27	26	3adant3	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ( W e. Word A /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) )
28		swrdfv	\|- ( ( ( W e. Word A /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( ( W substr <. M , N >. ) ` i ) = ( W ` ( i + M ) ) )
29	28	fveq2d	\|- ( ( ( W e. Word A /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( F ` ( ( W substr <. M , N >. ) ` i ) ) = ( F ` ( W ` ( i + M ) ) ) )
30	27 29	sylan	\|- ( ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( F ` ( ( W substr <. M , N >. ) ` i ) ) = ( F ` ( W ` ( i + M ) ) ) )
31		wrdfn	\|- ( W e. Word A -> W Fn ( 0 ..^ ( # ` W ) ) )
32	31	3ad2ant1	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> W Fn ( 0 ..^ ( # ` W ) ) )
33		elfzodifsumelfzo	\|- ( ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) -> ( i e. ( 0 ..^ ( N - M ) ) -> ( i + M ) e. ( 0 ..^ ( # ` W ) ) ) )
34	33	3ad2ant2	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ( i e. ( 0 ..^ ( N - M ) ) -> ( i + M ) e. ( 0 ..^ ( # ` W ) ) ) )
35	34	imp	\|- ( ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( i + M ) e. ( 0 ..^ ( # ` W ) ) )
36		fvco2	\|- ( ( W Fn ( 0 ..^ ( # ` W ) ) /\ ( i + M ) e. ( 0 ..^ ( # ` W ) ) ) -> ( ( F o. W ) ` ( i + M ) ) = ( F ` ( W ` ( i + M ) ) ) )
37	32 35 36	syl2an2r	\|- ( ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( ( F o. W ) ` ( i + M ) ) = ( F ` ( W ` ( i + M ) ) ) )
38	30 37	eqtr4d	\|- ( ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( F ` ( ( W substr <. M , N >. ) ` i ) ) = ( ( F o. W ) ` ( i + M ) ) )
39		fvco2	\|- ( ( ( W substr <. M , N >. ) Fn ( 0 ..^ ( N - M ) ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( ( F o. ( W substr <. M , N >. ) ) ` i ) = ( F ` ( ( W substr <. M , N >. ) ` i ) ) )
40	5 39	sylan	\|- ( ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( ( F o. ( W substr <. M , N >. ) ) ` i ) = ( F ` ( ( W substr <. M , N >. ) ` i ) ) )
41	14	ancoms	\|- ( ( F : A --> B /\ W e. Word A ) -> ( # ` ( F o. W ) ) = ( # ` W ) )
42	41	eqcomd	\|- ( ( F : A --> B /\ W e. Word A ) -> ( # ` W ) = ( # ` ( F o. W ) ) )
43	42	oveq2d	\|- ( ( F : A --> B /\ W e. Word A ) -> ( 0 ... ( # ` W ) ) = ( 0 ... ( # ` ( F o. W ) ) ) )
44	43	eleq2d	\|- ( ( F : A --> B /\ W e. Word A ) -> ( N e. ( 0 ... ( # ` W ) ) <-> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) )
45	44	biimpd	\|- ( ( F : A --> B /\ W e. Word A ) -> ( N e. ( 0 ... ( # ` W ) ) -> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) )
46	45	ex	\|- ( F : A --> B -> ( W e. Word A -> ( N e. ( 0 ... ( # ` W ) ) -> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) ) )
47	46	com13	\|- ( N e. ( 0 ... ( # ` W ) ) -> ( W e. Word A -> ( F : A --> B -> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) ) )
48	47	adantl	\|- ( ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) -> ( W e. Word A -> ( F : A --> B -> N e. ( 0 ... ( # ` ( F o. W ) ) ) ) ) )
49	48	3imp21	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> N e. ( 0 ... ( # ` ( F o. W ) ) ) )
50	12 13 49	3jca	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ( ( F o. W ) e. Word B /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` ( F o. W ) ) ) ) )
51		swrdfv	\|- ( ( ( ( F o. W ) e. Word B /\ M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` ( F o. W ) ) ) ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( ( ( F o. W ) substr <. M , N >. ) ` i ) = ( ( F o. W ) ` ( i + M ) ) )
52	50 51	sylan	\|- ( ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( ( ( F o. W ) substr <. M , N >. ) ` i ) = ( ( F o. W ) ` ( i + M ) ) )
53	38 40 52	3eqtr4d	\|- ( ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) /\ i e. ( 0 ..^ ( N - M ) ) ) -> ( ( F o. ( W substr <. M , N >. ) ) ` i ) = ( ( ( F o. W ) substr <. M , N >. ) ` i ) )
54	10 24 53	eqfnfvd	\|- ( ( W e. Word A /\ ( M e. ( 0 ... N ) /\ N e. ( 0 ... ( # ` W ) ) ) /\ F : A --> B ) -> ( F o. ( W substr <. M , N >. ) ) = ( ( F o. W ) substr <. M , N >. ) )

Metamath Proof Explorer

Theorem swrdco

Proof