Theorem conventions-labels 27812

Description:

The following gives conventions used in the Metamath Proof Explorer (MPE, set.mm) regarding labels. For other conventions, see conventions 27811 and links therein.

Every statement has a unique identifying label, which serves the same purpose as an equation number in a book. We use various label naming conventions to provide easy-to-remember hints about their contents. Labels are not a 1-to-1 mapping, because that would create long names that would be difficult to remember and tedious to type. Instead, label names are relatively short while suggesting their purpose. Names are occasionally changed to make them more consistent or as we find better ways to name them. Here are a few of the label naming conventions:

• Axioms, definitions, and wff syntax. As noted earlier, axioms are named "ax-NAME", proofs of proven axioms are named "axNAME", and definitions are named "df-NAME". Wff syntax declarations have labels beginning with "w" followed by short fragment suggesting its purpose.
• Hypotheses. Hypotheses have the name of the final axiom or theorem, followed by ".", followed by a unique id (these ids are usually consecutive integers starting with 1, e.g. for rgen 3131"rgen.1 $e |- ( x e. A -> ph ) $." or letters corresponding to the (main) class variable used in the hypothesis, e.g. for mdet0 20787: "mdet0.d $e |- D = ( N maDet R ) $.").
• Common names. If a theorem has a well-known name, that name (or a short version of it) is sometimes used directly. Examples include barbara 2746 and stirling 41098.
• Principia Mathematica. Proofs of theorems from Principia Mathematica often use a special naming convention: "pm" followed by its identifier. For example, Theorem *2.27 of [WhiteheadRussell] p. 104 is named pm2.27 42.
• 19.x series of theorems. Similar to the conventions for the theorems from Principia Mathematica, theorems from Section 19 of [Margaris] p. 90 often use a special naming convention: "19." resp. "r19." (for corresponding restricted quantifier versions) followed by its identifier. For example, Theorem 38 from Section 19 of [Margaris] p. 90 is labeled 19.38 1937, and the restricted quantifier version of Theorem 21 from Section 19 of [Margaris] p. 90 is labeled r19.21 3165.
• Characters to be used for labels. Although the specification of Metamath allows for dots/periods "." in any label, it is usually used only in labels for hypotheses (see above). Exceptions are the labels of theorems from Principia Mathematica and the 19.x series of theorems from Section 19 of [Margaris] p. 90 (see above) and 0.999... 14993. Furthermore, the underscore "_" should not be used. Finally, only lower case characters should be used (except the special suffixes OLD, ALT and ALTV mentioned in bullet point "Suffixes"), at least in main set.mm (exceptions are tolerated in mathboxes).
• Syntax label fragments. Most theorems are named using a concatenation of syntax label fragments (omitting variables) that represent the important part of the theorem's main conclusion. Almost every syntactic construct has a definition labeled "df-NAME", and normally NAME is the syntax label fragment. For example, the class difference construct (𝐴 ∖ 𝐵) is defined in df-dif 3801, and thus its syntax label fragment is "dif". Similarly, the subclass relation 𝐴 ⊆ 𝐵 has syntax label fragment "ss" because it is defined in df-ss 3812. Most theorem names follow from these fragments, for example, the theorem proving (𝐴 ∖ 𝐵) ⊆ 𝐴 involves a class difference ("dif") of a subset ("ss"), and thus is labeled difss 3966. There are many other syntax label fragments, e.g., singleton construct {𝐴} has syntax label fragment "sn" (because it is defined in df-sn 4400), and the pair construct {𝐴, 𝐵} has fragment "pr" ( from df-pr 4402). Digits are used to represent themselves. Suffixes (e.g., with numbers) are sometimes used to distinguish multiple theorems that would otherwise produce the same label.
• Phantom definitions. In some cases there are common label fragments for something that could be in a definition, but for technical reasons is not. The is-element-of (is member of) construct 𝐴 ∈ 𝐵 does not have a df-NAME definition; in this case its syntax label fragment is "el". Thus, because the theorem beginning with (𝐴 ∈ (𝐵 ∖ {𝐶}) uses is-element-of ("el") of a class difference ("dif") of a singleton ("sn"), it is labeled eldifsn 4538. An "n" is often used for negation (¬), e.g., nan 864.
• Exceptions. Sometimes there is a definition df-NAME but the label fragment is not the NAME part. The definition should note this exception as part of its definition. In addition, the table below attempts to list all such cases and marks them in bold. For example, the label fragment "cn" represents complex numbers ℂ (even though its definition is in df-c 10265) and "re" represents real numbers ℝ ( definition df-r 10269). The empty set ∅ often uses fragment 0, even though it is defined in df-nul 4147. The syntax construct (𝐴 + 𝐵) usually uses the fragment "add" (which is consistent with df-add 10270), but "p" is used as the fragment for constant theorems. Equality (𝐴 = 𝐵) often uses "e" as the fragment. As a result, "two plus two equals four" is labeled 2p2e4 11500.
• Other markings. In labels we sometimes use "com" for "commutative", "ass" for "associative", "rot" for "rotation", and "di" for "distributive".
• Focus on the important part of the conclusion. Typically the conclusion is the part the user is most interested in. So, a rough guideline is that a label typically provides a hint about only the conclusion; a label rarely says anything about the hypotheses or antecedents. If there are multiple theorems with the same conclusion but different hypotheses/antecedents, then the labels will need to differ; those label differences should emphasize what is different. There is no need to always fully describe the conclusion; just identify the important part. For example, cos0 15259 is the theorem that provides the value for the cosine of 0; we would need to look at the theorem itself to see what that value is. The label "cos0" is concise and we use it instead of "cos0eq1". There is no need to add the "eq1", because there will never be a case where we have to disambiguate between different values produced by the cosine of zero, and we generally prefer shorter labels if they are unambiguous.
• Closures and values. As noted above, if a function df-NAME is defined, there is typically a proof of its value labeled "NAMEval" and of its closure labeld "NAMEcl". E.g., for cosine (df-cos 15180) we have value cosval 15232 and closure coscl 15236.
• Special cases. Sometimes, syntax and related markings are insufficient to distinguish different theorems. For example, there are over a hundred different implication-only theorems. They are grouped in a more ad-hoc way that attempts to make their distinctions clearer. These often use abbreviations such as "mp" for "modus ponens", "syl" for syllogism, and "id" for "identity". It is especially hard to give good names in the propositional calculus section because there are so few primitives. However, in most cases this is not a serious problem. There are a few very common theorems like ax-mp 5 and syl 17 that you will have no trouble remembering, a few theorem series like syl*anc and simp* that you can use parametrically, and a few other useful glue things for destructuring 'and's and 'or's (see natded 27814 for a list), and that is about all you need for most things. As for the rest, you can just assume that if it involves at most three connectives, then it is probably already proved in set.mm, and searching for it will give you the label.
• Suffixes. Suffixes are used to indicate the form of a theorem (see above). Additionally, we sometimes suffix with "v" the label of a theorem eliminating a hypothesis such as Ⅎ𝑥𝜑 in 19.21 2249 via the use of disjoint variable conditions combined with nfv 2013. If two (or three) such hypotheses are eliminated, the suffix "vv" resp. "vvv" is used, e.g. exlimivv 2031. Conversely, we sometimes suffix with "f" the label of a theorem introducing such a hypothesis to eliminate the need for the disjoint variable condition; e.g. euf 2648 derived from eu6 2645. The "f" stands for "not free in" which is less restrictive than "does not occur in." The suffix "b" often means "biconditional" (↔, "iff" , "if and only if"), e.g. sspwb 5140. We sometimes suffix with "s" the label of an inference that manipulates an antecedent, leaving the consequent unchanged. The "s" means that the inference eliminates the need for a syllogism (syl 17) -type inference in a proof. A theorem label is suffixed with "ALT" if it provides an alternate less-preferred proof of a theorem (e.g., the proof is clearer but uses more axioms than the preferred version). The "ALT" may be further suffixed with a number if there is more than one alternate theorem. Furthermore, a theorem label is suffixed with "OLD" if there is a new version of it and the OLD version is obsolete (and will be removed within one year). Finally, it should be mentioned that suffixes can be combined, for example in cbvaldva 2431 (cbval 2423 in deduction form "d" with a not free variable replaced by a disjoint variable condition "v" with a conjunction as antecedent "a"). As a general rule, the suffixes for the theorem forms ("i", "d" or "g") should be the first of multiple suffixes, as for example in vtocldf 3472 or rabeqif 3404. Here is a non-exhaustive list of common suffixes:
  • a : theorem having a conjunction as antecedent
  • b : theorem expressing a logical equivalence
  • c : contraction (e.g., sylc 65, syl2anc 579), commutes (e.g., biimpac 472)
  • d : theorem in deduction form
  • f : theorem with a hypothesis such as Ⅎ𝑥𝜑
  • g : theorem in closed form having an "is a set" antecedent
  • i : theorem in inference form
  • l : theorem concerning something at the left
  • r : theorem concerning something at the right
  • r : theorem with something reversed (e.g., a biconditional)
  • s : inference that manipulates an antecedent ("s" refers to an application of syl 17 that is eliminated)
  • v : theorem with one (main) disjoint variable condition
  • vv : theorem with two (main) disjoint variable conditions
  • w : weak(er) form of a theorem
  • ALT : alternate proof of a theorem
  • ALTV : alternate version of a theorem or definition
  • OLD : old/obsolete version of a theorem/definition/proof
• Reuse. When creating a new theorem or axiom, try to reuse abbreviations used elsewhere. A comment should explain the first use of an abbreviation.

The following table shows some commonly used abbreviations in labels, in alphabetical order. For each abbreviation we provide a mnenomic, the source theorem or the assumption defining it, an expression showing what it looks like, whether or not it is a "syntax fragment" (an abbreviation that indicates a particular kind of syntax), and hyperlinks to label examples that use the abbreviation. The abbreviation is bolded if there is a df-NAME definition but the label fragment is not NAME. This is not a complete list of abbreviations, though we do want this to eventually be a complete list of exceptions.

Abbreviation	Mnenomic	Source	Expression	Syntax?	Example(s)
a	and (suffix)			No	biimpa 470, rexlimiva 3237
abl	Abelian group	df-abl 18556	Abel	Yes	ablgrp 18558, zringabl 20189
abs	absorption			No	ressabs 16310
abs	absolute value (of a complex number)	df-abs 14360	(abs‘𝐴)	Yes	absval 14362, absneg 14401, abs1 14421
ad	adding			No	adantr 474, ad2antlr 718
add	add (see "p")	df-add 10270	(𝐴 + 𝐵)	Yes	addcl 10341, addcom 10548, addass 10346
al	"for all"		∀𝑥𝜑	No	alim 1909, alex 1924
ALT	alternative/less preferred (suffix)			No	idALT 23
an	and	df-an 387	(𝜑 ∧ 𝜓)	Yes	anor 1010, iman 392, imnan 390
ant	antecedent			No	adantr 474
ass	associative			No	biass 376, orass 950, mulass 10347
asym	asymmetric, antisymmetric			No	intasym 5757, asymref 5758, posasymb 17312
ax	axiom			No	ax6dgen 2179, ax1cn 10293
bas, base	base (set of an extensible structure)	df-base 16235	(Base‘𝑆)	Yes	baseval 16288, ressbas 16300, cnfldbas 20117
b, bi	biconditional ("iff", "if and only if")	df-bi 199	(𝜑 ↔ 𝜓)	Yes	impbid 204, sspwb 5140
br	binary relation	df-br 4876	𝐴𝑅𝐵	Yes	brab1 4923, brun 4926
cbv	change bound variable			No	cbvalivw 2111, cbvrex 3380
cl	closure			No	ifclda 4342, ovrcl 6950, zaddcl 11752
cn	complex numbers	df-c 10265	ℂ	Yes	nnsscn 11362, nncn 11366
cnfld	field of complex numbers	df-cnfld 20114	ℂfld	Yes	cnfldbas 20117, cnfldinv 20144
cntz	centralizer	df-cntz 18107	(Cntz‘𝑀)	Yes	cntzfval 18110, dprdfcntz 18775
cnv	converse	df-cnv 5354	◡𝐴	Yes	opelcnvg 5539, f1ocnv 6394
co	composition	df-co 5355	(𝐴 ∘ 𝐵)	Yes	cnvco 5544, fmptco 6651
com	commutative			No	orcom 901, bicomi 216, eqcomi 2834
con	contradiction, contraposition			No	condan 852, con2d 132
csb	class substitution	df-csb 3758	⦋𝐴 / 𝑥⦌𝐵	Yes	csbid 3765, csbie2g 3788
cyg	cyclic group	df-cyg 18640	CycGrp	Yes	iscyg 18641, zringcyg 20206
d	deduction form (suffix)			No	idd 24, impbid 204
df	(alternate) definition (prefix)			No	dfrel2 5828, dffn2 6284
di, distr	distributive			No	andi 1035, imdi 381, ordi 1033, difindi 4113, ndmovdistr 7088
dif	class difference	df-dif 3801	(𝐴 ∖ 𝐵)	Yes	difss 3966, difindi 4113
div	division	df-div 11017	(𝐴 / 𝐵)	Yes	divcl 11023, divval 11019, divmul 11020
dm	domain	df-dm 5356	dom 𝐴	Yes	dmmpt 5875, iswrddm0 13605
e, eq, equ	equals	df-cleq 2818	𝐴 = 𝐵	Yes	2p2e4 11500, uneqri 3984, equtr 2125
edg	edge	df-edg 26353	(Edg‘𝐺)	Yes	edgopval 26356, usgredgppr 26499
el	element of		𝐴 ∈ 𝐵	Yes	eldif 3808, eldifsn 4538, elssuni 4691
en	equinumerous	df-en	𝐴 ≈ 𝐵	Yes	domen 8241, enfi 8451
eu	"there exists exactly one"	eu6 2645	∃!𝑥𝜑	Yes	euex 2650, euabsn 4481
ex	exists (i.e. is a set)		∈ V	No	brrelex1 5394, 0ex 5016
ex	"there exists (at least one)"	df-ex 1879	∃𝑥𝜑	Yes	exim 1932, alex 1924
exp	export			No	expt 170, expcom 404
f	"not free in" (suffix)			No	equs45f 2480, sbf 2511
f	function	df-f 6131	𝐹:𝐴⟶𝐵	Yes	fssxp 6301, opelf 6306
fal	false	df-fal 1670	⊥	Yes	bifal 1673, falantru 1692
fi	finite intersection	df-fi 8592	(fi‘𝐵)	Yes	fival 8593, inelfi 8599
fi, fin	finite	df-fin 8232	Fin	Yes	isfi 8252, snfi 8313, onfin 8426
fld	field (Note: there is an alternative definition Fld of a field, see df-fld 34332)	df-field 19113	Field	Yes	isfld 19119, fldidom 19673
fn	function with domain	df-fn 6130	𝐴 Fn 𝐵	Yes	ffn 6282, fndm 6227
frgp	free group	df-frgp 18481	(freeGrp‘𝐼)	Yes	frgpval 18531, frgpadd 18536
fsupp	finitely supported function	df-fsupp 8551	𝑅 finSupp 𝑍	Yes	isfsupp 8554, fdmfisuppfi 8559, fsuppco 8582
fun	function	df-fun 6129	Fun 𝐹	Yes	funrel 6144, ffun 6285
fv	function value	df-fv 6135	(𝐹‘𝐴)	Yes	fvres 6456, swrdfv 13717
fz	finite set of sequential integers	df-fz 12627	(𝑀...𝑁)	Yes	fzval 12628, eluzfz 12637
fz0	finite set of sequential nonnegative integers		(0...𝑁)	Yes	nn0fz0 12739, fz0tp 12742
fzo	half-open integer range	df-fzo 12768	(𝑀..^𝑁)	Yes	elfzo 12774, elfzofz 12787
g	more general (suffix); eliminates "is a set" hypotheses			No	uniexg 7220
gr	graph			No	uhgrf 26367, isumgr 26400, usgrres1 26619
grp	group	df-grp 17786	Grp	Yes	isgrp 17789, tgpgrp 22259
gsum	group sum	df-gsum 16463	(𝐺 Σg 𝐹)	Yes	gsumval 17631, gsumwrev 18153
hash	size (of a set)	df-hash 13418	(♯‘𝐴)	Yes	hashgval 13420, hashfz1 13433, hashcl 13444
hb	hypothesis builder (prefix)			No	hbxfrbi 1923, hbald 2218, hbequid 34983
hm	(monoid, group, ring) homomorphism			No	ismhm 17697, isghm 18018, isrhm 19084
i	inference (suffix)			No	eleq1i 2897, tcsni 8903
i	implication (suffix)			No	brwdomi 8749, infeq5i 8817
id	identity			No	biid 253
iedg	indexed edge	df-iedg 26304	(iEdg‘𝐺)	Yes	iedgval0 26345, edgiedgb 26359
idm	idempotent			No	anidm 560, tpidm13 4511
im, imp	implication (label often omitted)	df-im 14225	(𝐴 → 𝐵)	Yes	iman 392, imnan 390, impbidd 202
ima	image	df-ima 5359	(𝐴 “ 𝐵)	Yes	resima 5671, imaundi 5790
imp	import			No	biimpa 470, impcom 398
in	intersection	df-in 3805	(𝐴 ∩ 𝐵)	Yes	elin 4025, incom 4034
inf	infimum	df-inf 8624	inf(ℝ+, ℝ*, < )	Yes	fiinfcl 8682, infiso 8689
is...	is (something a) ...?			No	isring 18912
j	joining, disjoining			No	jc 161, jaoi 888
l	left			No	olcd 905, simpl 476
map	mapping operation or set exponentiation	df-map 8129	(𝐴 ↑𝑚 𝐵)	Yes	mapvalg 8137, elmapex 8148
mat	matrix	df-mat 20588	(𝑁 Mat 𝑅)	Yes	matval 20591, matring 20623
mdet	determinant (of a square matrix)	df-mdet 20766	(𝑁 maDet 𝑅)	Yes	mdetleib 20768, mdetrlin 20783
mgm	magma	df-mgm 17602	Magma	Yes	mgmidmo 17619, mgmlrid 17626, ismgm 17603
mgp	multiplicative group	df-mgp 18851	(mulGrp‘𝑅)	Yes	mgpress 18861, ringmgp 18914
mnd	monoid	df-mnd 17655	Mnd	Yes	mndass 17662, mndodcong 18319
mo	"there exists at most one"	df-mo 2605	∃*𝑥𝜑	Yes	eumo 2651, moim 2610
mp	modus ponens	ax-mp 5		No	mpd 15, mpi 20
mpt	modus ponendo tollens			No	mptnan 1867, mptxor 1868
mpt	maps-to notation for a function	df-mpt 4955	(𝑥 ∈ 𝐴 ↦ 𝐵)	Yes	fconstmpt 5402, resmpt 5690
mpt2	maps-to notation for an operation	df-mpt2 6915	(𝑥 ∈ 𝐴, 𝑦 ∈ 𝐵 ↦ 𝐶)	Yes	mpt2mpt 7017, resmpt2 7023
mul	multiplication (see "t")	df-mul 10271	(𝐴 · 𝐵)	Yes	mulcl 10343, divmul 11020, mulcom 10345, mulass 10347
n, not	not		¬ 𝜑	Yes	nan 864, notnotr 128
ne	not equal	df-ne	𝐴 ≠ 𝐵	Yes	exmidne 3009, neeqtrd 3068
nel	not element of	df-nel	𝐴 ∉ 𝐵	Yes	neli 3104, nnel 3111
ne0	not equal to zero (see n0)		≠ 0	No	negne0d 10718, ine0 10796, gt0ne0 10824
nf	"not free in" (prefix)			No	nfnd 1958
ngp	normed group	df-ngp 22765	NrmGrp	Yes	isngp 22777, ngptps 22783
nm	norm (on a group or ring)	df-nm 22764	(norm‘𝑊)	Yes	nmval 22771, subgnm 22814
nn	positive integers	df-nn 11358	ℕ	Yes	nnsscn 11362, nncn 11366
nn0	nonnegative integers	df-n0 11626	ℕ0	Yes	nnnn0 11633, nn0cn 11636
n0	not the empty set (see ne0)		≠ ∅	No	n0i 4151, vn0 4156, ssn0 4203
OLD	old, obsolete (to be removed soon)			No	19.43OLD 1986
on	ordinal number	df-on 5971	𝐴 ∈ On	Yes	elon 5976, 1on 7838 onelon 5992
op	ordered pair	df-op 4406	⟨𝐴, 𝐵⟩	Yes	dfopif 4622, opth 5167
or	or	df-or 879	(𝜑 ∨ 𝜓)	Yes	orcom 901, anor 1010
ot	ordered triple	df-ot 4408	⟨𝐴, 𝐵, 𝐶⟩	Yes	euotd 5201, fnotovb 6959
ov	operation value	df-ov 6913	(𝐴𝐹𝐵)	Yes	fnotovb 6959, fnovrn 7074
p	plus (see "add"), for all-constant theorems	df-add 10270	(3 + 2) = 5	Yes	3p2e5 11516
pfx	prefix	df-pfx 13757	(𝑊 prefix 𝐿)	Yes	pfxlen 13769, ccatpfx 13787
pm	Principia Mathematica			No	pm2.27 42
pm	partial mapping (operation)	df-pm 8130	(𝐴 ↑pm 𝐵)	Yes	elpmi 8146, pmsspw 8162
pr	pair	df-pr 4402	{𝐴, 𝐵}	Yes	elpr 4422, prcom 4487, prid1g 4515, prnz 4531
prm, prime	prime (number)	df-prm 15765	ℙ	Yes	1nprm 15771, dvdsprime 15779
pss	proper subset	df-pss 3814	𝐴 ⊊ 𝐵	Yes	pssss 3930, sspsstri 3937
q	rational numbers ("quotients")	df-q 12079	ℚ	Yes	elq 12080
r	right			No	orcd 904, simprl 787
rab	restricted class abstraction	df-rab 3126	{𝑥 ∈ 𝐴 ∣ 𝜑}	Yes	rabswap 3332, df-oprab 6914
ral	restricted universal quantification	df-ral 3122	∀𝑥 ∈ 𝐴𝜑	Yes	ralnex 3201, ralrnmpt2 7040
rcl	reverse closure			No	ndmfvrcl 6468, nnarcl 7968
re	real numbers	df-r 10269	ℝ	Yes	recn 10349, 0re 10365
rel	relation	df-rel 5353	Rel 𝐴	Yes	brrelex1 5394, relmpt2opab 7528
res	restriction	df-res 5358	(𝐴 ↾ 𝐵)	Yes	opelres 5639, f1ores 6396
reu	restricted existential uniqueness	df-reu 3124	∃!𝑥 ∈ 𝐴𝜑	Yes	nfreud 3322, reurex 3372
rex	restricted existential quantification	df-rex 3123	∃𝑥 ∈ 𝐴𝜑	Yes	rexnal 3203, rexrnmpt2 7041
rmo	restricted "at most one"	df-rmo 3125	∃*𝑥 ∈ 𝐴𝜑	Yes	nfrmod 3323, nrexrmo 3375
rn	range	df-rn 5357	ran 𝐴	Yes	elrng 5550, rncnvcnv 5585
rng	(unital) ring	df-ring 18910	Ring	Yes	ringidval 18864, isring 18912, ringgrp 18913
rot	rotation			No	3anrot 1126, 3orrot 1116
s	eliminates need for syllogism (suffix)			No	ancoms 452
sb	(proper) substitution (of a set)	df-sb 2068	[𝑦 / 𝑥]𝜑	Yes	spsbe 2071, sbimi 2073
sbc	(proper) substitution of a class	df-sbc 3663	[𝐴 / 𝑥]𝜑	Yes	sbc2or 3671, sbcth 3677
sca	scalar	df-sca 16328	(Scalar‘𝐻)	Yes	resssca 16397, mgpsca 18857
simp	simple, simplification			No	simpl 476, simp3r3 1386
sn	singleton	df-sn 4400	{𝐴}	Yes	eldifsn 4538
sp	specialization			No	spsbe 2071, spei 2414
ss	subset	df-ss 3812	𝐴 ⊆ 𝐵	Yes	difss 3966
struct	structure	df-struct 16231	Struct	Yes	brstruct 16238, structfn 16246
sub	subtract	df-sub 10594	(𝐴 − 𝐵)	Yes	subval 10599, subaddi 10696
sup	supremum	df-sup 8623	sup(𝐴, 𝐵, < )	Yes	fisupcl 8650, supmo 8633
supp	support (of a function)	df-supp 7565	(𝐹 supp 𝑍)	Yes	ressuppfi 8576, mptsuppd 7587
swap	swap (two parts within a theorem)			No	rabswap 3332, 2reuswap 3637
syl	syllogism	syl 17		No	3syl 18
sym	symmetric			No	df-symdif 4072, cnvsym 5756
symg	symmetric group	df-symg 18155	(SymGrp‘𝐴)	Yes	symghash 18162, pgrpsubgsymg 18185
t	times (see "mul"), for all-constant theorems	df-mul 10271	(3 · 2) = 6	Yes	3t2e6 11531
th	theorem			No	nfth 1900, sbcth 3677, weth 9639
tp	triple	df-tp 4404	{𝐴, 𝐵, 𝐶}	Yes	eltpi 4450, tpeq1 4497
tr	transitive			No	bitrd 271, biantr 840
tru	true	df-tru 1660	⊤	Yes	bitru 1666, truanfal 1691
un	union	df-un 3803	(𝐴 ∪ 𝐵)	Yes	uneqri 3984, uncom 3986
unit	unit (in a ring)	df-unit 19003	(Unit‘𝑅)	Yes	isunit 19018, nzrunit 19635
v	disjoint variable conditions used when a not-free hypothesis (suffix)			No	spimv 2410
vtx	vertex	df-vtx 26303	(Vtx‘𝐺)	Yes	vtxval0 26344, opvtxov 26310
vv	2 disjoint variables (in a not-free hypothesis) (suffix)			No	19.23vv 2042
w	weak (version of a theorem) (suffix)			No	ax11w 2181, spnfw 2104
wrd	word	df-word 13582	Word 𝑆	Yes	iswrdb 13587, wrdfn 13595, ffz0iswrd 13608
xp	cross product (Cartesian product)	df-xp 5352	(𝐴 × 𝐵)	Yes	elxp 5369, opelxpi 5383, xpundi 5408
xr	eXtended reals	df-xr 10402	ℝ*	Yes	ressxr 10407, rexr 10409, 0xr 10410
z	integers (from German "Zahlen")	df-z 11712	ℤ	Yes	elz 11713, zcn 11716
zn	ring of integers mod 𝑁	df-zn 20222	(ℤ/nℤ‘𝑁)	Yes	znval 20250, zncrng 20259, znhash 20273
zring	ring of integers	df-zring 20186	ℤring	Yes	zringbas 20191, zringcrng 20187
0, z	slashed zero (empty set)	df-nul 4147	∅	Yes	n0i 4151, vn0 4156; snnz 4530, prnz 4531

(Contributed by the Metamath team, 27-Dec-2016.) Date of last revision. (Revised by the Metamath team, 22-Sep-2022.) (Proof modification is discouraged.) (New usage is discouraged.)

Hypothesis

Ref	Expression
conventions-labels.1	⊢ 𝜑

Assertion

Ref	Expression
conventions-labels	⊢ 𝜑

Proof of Theorem conventions-labels

Step	Hyp	Ref	Expression
1		conventions-labels.1	1 ⊢ 𝜑

This theorem is referenced by: (None)