sn-addcand

Description: addcand without ax-mulcom . Note how the proof is almost identical to addcan . (Contributed by SN, 5-May-2024)

	Ref	Expression
Hypotheses	sn-addcand.a	\|- ( ph -> A e. CC )
	sn-addcand.b	\|- ( ph -> B e. CC )
	sn-addcand.c	\|- ( ph -> C e. CC )
Assertion	sn-addcand	\|- ( ph -> ( ( A + B ) = ( A + C ) <-> B = C ) )

Proof

Step	Hyp	Ref	Expression
1		sn-addcand.a	\|- ( ph -> A e. CC )
2		sn-addcand.b	\|- ( ph -> B e. CC )
3		sn-addcand.c	\|- ( ph -> C e. CC )
4		sn-negex2	\|- ( A e. CC -> E. x e. CC ( x + A ) = 0 )
5	1 4	syl	\|- ( ph -> E. x e. CC ( x + A ) = 0 )
6		oveq2	\|- ( ( A + B ) = ( A + C ) -> ( x + ( A + B ) ) = ( x + ( A + C ) ) )
7		simprr	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( x + A ) = 0 )
8	7	oveq1d	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( ( x + A ) + B ) = ( 0 + B ) )
9		simprl	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> x e. CC )
10	1	adantr	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> A e. CC )
11	2	adantr	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> B e. CC )
12	9 10 11	addassd	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( ( x + A ) + B ) = ( x + ( A + B ) ) )
13		sn-addlid	\|- ( B e. CC -> ( 0 + B ) = B )
14	11 13	syl	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( 0 + B ) = B )
15	8 12 14	3eqtr3d	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( x + ( A + B ) ) = B )
16	7	oveq1d	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( ( x + A ) + C ) = ( 0 + C ) )
17	3	adantr	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> C e. CC )
18	9 10 17	addassd	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( ( x + A ) + C ) = ( x + ( A + C ) ) )
19		sn-addlid	\|- ( C e. CC -> ( 0 + C ) = C )
20	17 19	syl	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( 0 + C ) = C )
21	16 18 20	3eqtr3d	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( x + ( A + C ) ) = C )
22	15 21	eqeq12d	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( ( x + ( A + B ) ) = ( x + ( A + C ) ) <-> B = C ) )
23	6 22	imbitrid	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( ( A + B ) = ( A + C ) -> B = C ) )
24		oveq2	\|- ( B = C -> ( A + B ) = ( A + C ) )
25	23 24	impbid1	\|- ( ( ph /\ ( x e. CC /\ ( x + A ) = 0 ) ) -> ( ( A + B ) = ( A + C ) <-> B = C ) )
26	5 25	rexlimddv	\|- ( ph -> ( ( A + B ) = ( A + C ) <-> B = C ) )

Metamath Proof Explorer

Theorem sn-addcand

Proof