lgsfcl2

Description: The function F is closed in integers with absolute value less than 1 (namely { -u 1 , 0 , 1 } , see zabsle1 ). (Contributed by Mario Carneiro, 4-Feb-2015)

	Ref	Expression
Hypotheses	lgsval.1	\|- F = ( n e. NN \|-> if ( n e. Prime , ( if ( n = 2 , if ( 2 \|\| A , 0 , if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) ) , ( ( ( ( A ^ ( ( n - 1 ) / 2 ) ) + 1 ) mod n ) - 1 ) ) ^ ( n pCnt N ) ) , 1 ) )
	lgsfcl2.z	\|- Z = { x e. ZZ \| ( abs ` x ) <_ 1 }
Assertion	lgsfcl2	\|- ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) -> F : NN --> Z )

Proof

Step	Hyp	Ref	Expression
1		lgsval.1	\|- F = ( n e. NN \|-> if ( n e. Prime , ( if ( n = 2 , if ( 2 \|\| A , 0 , if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) ) , ( ( ( ( A ^ ( ( n - 1 ) / 2 ) ) + 1 ) mod n ) - 1 ) ) ^ ( n pCnt N ) ) , 1 ) )
2		lgsfcl2.z	\|- Z = { x e. ZZ \| ( abs ` x ) <_ 1 }
3		0z	\|- 0 e. ZZ
4		0le1	\|- 0 <_ 1
5		fveq2	\|- ( x = 0 -> ( abs ` x ) = ( abs ` 0 ) )
6		abs0	\|- ( abs ` 0 ) = 0
7	5 6	eqtrdi	\|- ( x = 0 -> ( abs ` x ) = 0 )
8	7	breq1d	\|- ( x = 0 -> ( ( abs ` x ) <_ 1 <-> 0 <_ 1 ) )
9	8 2	elrab2	\|- ( 0 e. Z <-> ( 0 e. ZZ /\ 0 <_ 1 ) )
10	3 4 9	mpbir2an	\|- 0 e. Z
11		1z	\|- 1 e. ZZ
12		1le1	\|- 1 <_ 1
13		fveq2	\|- ( x = 1 -> ( abs ` x ) = ( abs ` 1 ) )
14		abs1	\|- ( abs ` 1 ) = 1
15	13 14	eqtrdi	\|- ( x = 1 -> ( abs ` x ) = 1 )
16	15	breq1d	\|- ( x = 1 -> ( ( abs ` x ) <_ 1 <-> 1 <_ 1 ) )
17	16 2	elrab2	\|- ( 1 e. Z <-> ( 1 e. ZZ /\ 1 <_ 1 ) )
18	11 12 17	mpbir2an	\|- 1 e. Z
19		neg1z	\|- -u 1 e. ZZ
20		fveq2	\|- ( x = -u 1 -> ( abs ` x ) = ( abs ` -u 1 ) )
21		ax-1cn	\|- 1 e. CC
22	21	absnegi	\|- ( abs ` -u 1 ) = ( abs ` 1 )
23	22 14	eqtri	\|- ( abs ` -u 1 ) = 1
24	20 23	eqtrdi	\|- ( x = -u 1 -> ( abs ` x ) = 1 )
25	24	breq1d	\|- ( x = -u 1 -> ( ( abs ` x ) <_ 1 <-> 1 <_ 1 ) )
26	25 2	elrab2	\|- ( -u 1 e. Z <-> ( -u 1 e. ZZ /\ 1 <_ 1 ) )
27	19 12 26	mpbir2an	\|- -u 1 e. Z
28	18 27	ifcli	\|- if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) e. Z
29	10 28	ifcli	\|- if ( 2 \|\| A , 0 , if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) ) e. Z
30	29	a1i	\|- ( ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) /\ n = 2 ) -> if ( 2 \|\| A , 0 , if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) ) e. Z )
31		simpl1	\|- ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) -> A e. ZZ )
32	31	ad2antrr	\|- ( ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) /\ -. n = 2 ) -> A e. ZZ )
33		simplr	\|- ( ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) /\ -. n = 2 ) -> n e. Prime )
34		simpr	\|- ( ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) /\ -. n = 2 ) -> -. n = 2 )
35	34	neqned	\|- ( ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) /\ -. n = 2 ) -> n =/= 2 )
36		eldifsn	\|- ( n e. ( Prime \ { 2 } ) <-> ( n e. Prime /\ n =/= 2 ) )
37	33 35 36	sylanbrc	\|- ( ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) /\ -. n = 2 ) -> n e. ( Prime \ { 2 } ) )
38	2	lgslem4	\|- ( ( A e. ZZ /\ n e. ( Prime \ { 2 } ) ) -> ( ( ( ( A ^ ( ( n - 1 ) / 2 ) ) + 1 ) mod n ) - 1 ) e. Z )
39	32 37 38	syl2anc	\|- ( ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) /\ -. n = 2 ) -> ( ( ( ( A ^ ( ( n - 1 ) / 2 ) ) + 1 ) mod n ) - 1 ) e. Z )
40	30 39	ifclda	\|- ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) -> if ( n = 2 , if ( 2 \|\| A , 0 , if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) ) , ( ( ( ( A ^ ( ( n - 1 ) / 2 ) ) + 1 ) mod n ) - 1 ) ) e. Z )
41		simpr	\|- ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) -> n e. Prime )
42		simpll2	\|- ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) -> N e. ZZ )
43		simpll3	\|- ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) -> N =/= 0 )
44		pczcl	\|- ( ( n e. Prime /\ ( N e. ZZ /\ N =/= 0 ) ) -> ( n pCnt N ) e. NN0 )
45	41 42 43 44	syl12anc	\|- ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) -> ( n pCnt N ) e. NN0 )
46	2	ssrab3	\|- Z C_ ZZ
47		zsscn	\|- ZZ C_ CC
48	46 47	sstri	\|- Z C_ CC
49	2	lgslem3	\|- ( ( a e. Z /\ b e. Z ) -> ( a x. b ) e. Z )
50	48 49 18	expcllem	\|- ( ( if ( n = 2 , if ( 2 \|\| A , 0 , if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) ) , ( ( ( ( A ^ ( ( n - 1 ) / 2 ) ) + 1 ) mod n ) - 1 ) ) e. Z /\ ( n pCnt N ) e. NN0 ) -> ( if ( n = 2 , if ( 2 \|\| A , 0 , if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) ) , ( ( ( ( A ^ ( ( n - 1 ) / 2 ) ) + 1 ) mod n ) - 1 ) ) ^ ( n pCnt N ) ) e. Z )
51	40 45 50	syl2anc	\|- ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ n e. Prime ) -> ( if ( n = 2 , if ( 2 \|\| A , 0 , if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) ) , ( ( ( ( A ^ ( ( n - 1 ) / 2 ) ) + 1 ) mod n ) - 1 ) ) ^ ( n pCnt N ) ) e. Z )
52	18	a1i	\|- ( ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) /\ -. n e. Prime ) -> 1 e. Z )
53	51 52	ifclda	\|- ( ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) /\ n e. NN ) -> if ( n e. Prime , ( if ( n = 2 , if ( 2 \|\| A , 0 , if ( ( A mod 8 ) e. { 1 , 7 } , 1 , -u 1 ) ) , ( ( ( ( A ^ ( ( n - 1 ) / 2 ) ) + 1 ) mod n ) - 1 ) ) ^ ( n pCnt N ) ) , 1 ) e. Z )
54	53 1	fmptd	\|- ( ( A e. ZZ /\ N e. ZZ /\ N =/= 0 ) -> F : NN --> Z )

Metamath Proof Explorer

Theorem lgsfcl2

Proof