let X1, X2, X3 be set ; :: thesis: X1 /\ (X2 /\ X3) = (X1 /\ X2) /\ (X1 /\ X3)
thus X1 /\ (X2 /\ X3) = ((X1 /\ X1) /\ X2) /\ X3 by XBOOLE_1:16
.= (X1 /\ (X1 /\ X2)) /\ X3 by XBOOLE_1:16
.= (X1 /\ X2) /\ (X1 /\ X3) by XBOOLE_1:16 ; :: thesis: verum

let Y be functional set ;
coherence
union { (dom f) where f is Element of Y : verum } is set ;

let X be set ;

let X be set ;

let X be set ;

let X be set ;

let X be set ;

let X be set ;

coherence
for b₁ being set st b₁ is natural-functions-membered holds
b₁ is integer-functions-membered coherence
for b₁ being set st b₁ is integer-functions-membered holds
b₁ is rational-functions-membered coherence
for b₁ being set st b₁ is rational-functions-membered holds
b₁ is real-functions-membered ;
coherence
for b₁ being set st b₁ is real-functions-membered holds
b₁ is complex-functions-membered ;
coherence
for b₁ being set st b₁ is real-functions-membered holds
b₁ is ext-real-functions-membered ;

coherence
for b₁ being set st b₁ is empty holds
b₁ is natural-functions-membered ;

let f be complex-valued Function;
coherence
{f} is complex-functions-membered by TARSKI:def 1;

coherence
for b₁ being set st b₁ is complex-functions-membered holds
b₁ is functional coherence
for b₁ being set st b₁ is ext-real-functions-membered holds
b₁ is functional

existence
ex b₁ being set st
( b₁ is natural-functions-membered & not b₁ is empty )

let X be complex-functions-membered set ;
coherence
for b₁ being Subset of X holds b₁ is complex-functions-membered by Def2;

let X be ext-real-functions-membered set ;
coherence
for b₁ being Subset of X holds b₁ is ext-real-functions-membered by Def3;

let X be real-functions-membered set ;
coherence
for b₁ being Subset of X holds b₁ is real-functions-membered by Def4;

let X be rational-functions-membered set ;
coherence
for b₁ being Subset of X holds b₁ is rational-functions-membered by Def5;

let X be integer-functions-membered set ;
coherence
for b₁ being Subset of X holds b₁ is integer-functions-membered by Def6;

let X be natural-functions-membered set ;
coherence
for b₁ being Subset of X holds b₁ is natural-functions-membered by Def7;

set A = COMPLEX ;
let D be set ;
defpred S₁[ object ] means $1 is PartFunc of D,COMPLEX;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is PartFunc of D,COMPLEX ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is PartFunc of D,COMPLEX ) ) & ( for f being object holds
( f in b₂ iff f is PartFunc of D,COMPLEX ) ) holds
b₁ = b₂

set A = COMPLEX ;
let D be set ;
defpred S₁[ object ] means $1 is Function of D,COMPLEX;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is Function of D,COMPLEX ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is Function of D,COMPLEX ) ) & ( for f being object holds
( f in b₂ iff f is Function of D,COMPLEX ) ) holds
b₁ = b₂

set A = ExtREAL ;
let D be set ;
defpred S₁[ object ] means $1 is PartFunc of D,ExtREAL;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is PartFunc of D,ExtREAL ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is PartFunc of D,ExtREAL ) ) & ( for f being object holds
( f in b₂ iff f is PartFunc of D,ExtREAL ) ) holds
b₁ = b₂

set A = ExtREAL ;
let D be set ;
defpred S₁[ object ] means $1 is Function of D,ExtREAL;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is Function of D,ExtREAL ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is Function of D,ExtREAL ) ) & ( for f being object holds
( f in b₂ iff f is Function of D,ExtREAL ) ) holds
b₁ = b₂

set A = REAL ;
let D be set ;
defpred S₁[ object ] means $1 is PartFunc of D,REAL;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is PartFunc of D,REAL ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is PartFunc of D,REAL ) ) & ( for f being object holds
( f in b₂ iff f is PartFunc of D,REAL ) ) holds
b₁ = b₂

set A = REAL ;
let D be set ;
defpred S₁[ object ] means $1 is Function of D,REAL;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is Function of D,REAL ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is Function of D,REAL ) ) & ( for f being object holds
( f in b₂ iff f is Function of D,REAL ) ) holds
b₁ = b₂

set A = RAT ;
let D be set ;
defpred S₁[ object ] means $1 is PartFunc of D,RAT;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is PartFunc of D,RAT ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is PartFunc of D,RAT ) ) & ( for f being object holds
( f in b₂ iff f is PartFunc of D,RAT ) ) holds
b₁ = b₂

set A = RAT ;
let D be set ;
defpred S₁[ object ] means $1 is Function of D,RAT;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is Function of D,RAT ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is Function of D,RAT ) ) & ( for f being object holds
( f in b₂ iff f is Function of D,RAT ) ) holds
b₁ = b₂

set A = INT ;
let D be set ;
defpred S₁[ object ] means $1 is PartFunc of D,INT;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is PartFunc of D,INT ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is PartFunc of D,INT ) ) & ( for f being object holds
( f in b₂ iff f is PartFunc of D,INT ) ) holds
b₁ = b₂

set A = INT ;
let D be set ;
defpred S₁[ object ] means $1 is Function of D,INT;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is Function of D,INT ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is Function of D,INT ) ) & ( for f being object holds
( f in b₂ iff f is Function of D,INT ) ) holds
b₁ = b₂

set A = NAT ;
let D be set ;
defpred S₁[ object ] means $1 is PartFunc of D,NAT;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is PartFunc of D,NAT ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is PartFunc of D,NAT ) ) & ( for f being object holds
( f in b₂ iff f is PartFunc of D,NAT ) ) holds
b₁ = b₂

set A = NAT ;
let D be set ;
defpred S₁[ object ] means $1 is Function of D,NAT;
existence
ex b₁ being set st
for f being object holds
( f in b₁ iff f is Function of D,NAT ) uniqueness
for b₁, b₂ being set st ( for f being object holds
( f in b₁ iff f is Function of D,NAT ) ) & ( for f being object holds
( f in b₂ iff f is Function of D,NAT ) ) holds
b₁ = b₂

for X being set holds C_Funcs X is Subset of (C_PFuncs X)

for X being set holds E_Funcs X is Subset of (E_PFuncs X)

for X being set holds R_Funcs X is Subset of (R_PFuncs X)

for X being set holds Q_Funcs X is Subset of (Q_PFuncs X)

for X being set holds I_Funcs X is Subset of (I_PFuncs X)

for X being set holds N_Funcs X is Subset of (N_PFuncs X)

let X be set ;
coherence
C_PFuncs X is complex-functions-membered by Def8;
coherence
C_Funcs X is complex-functions-membered coherence
E_PFuncs X is ext-real-functions-membered by Def10;
coherence
E_Funcs X is ext-real-functions-membered coherence
R_PFuncs X is real-functions-membered by Def12;
coherence
R_Funcs X is real-functions-membered coherence
Q_PFuncs X is rational-functions-membered by Def14;
coherence
Q_Funcs X is rational-functions-membered coherence
I_PFuncs X is integer-functions-membered by Def16;
coherence
I_Funcs X is integer-functions-membered coherence
N_PFuncs X is natural-functions-membered by Def18;
coherence
N_Funcs X is natural-functions-membered

let X be complex-functions-membered set ;
coherence
for b₁ being Element of X holds b₁ is complex-valued

let X be ext-real-functions-membered set ;
coherence
for b₁ being Element of X holds b₁ is ext-real-valued

let X be real-functions-membered set ;
coherence
for b₁ being Element of X holds b₁ is real-valued

let X be rational-functions-membered set ;
coherence
for b₁ being Element of X holds b₁ is RAT -valued

let X be integer-functions-membered set ;
coherence
for b₁ being Element of X holds b₁ is INT -valued

let X be natural-functions-membered set ;
coherence
for b₁ being Element of X holds b₁ is natural-valued

let X be set ;
let x be object ;
let Y be complex-functions-membered set ;
let f be PartFunc of X,Y;
coherence
( f . x is Function-like & f . x is Relation-like ) ;

let X be set ;
let x be object ;
let Y be ext-real-functions-membered set ;
let f be PartFunc of X,Y;
coherence
( f . x is Function-like & f . x is Relation-like ) ;

let X be set ;
let x be object ;
let Y be complex-functions-membered set ;
let f be PartFunc of X,Y;
coherence
f . x is complex-valued

let X be set ;
let x be object ;
let Y be ext-real-functions-membered set ;
let f be PartFunc of X,Y;
coherence
f . x is ext-real-valued

let X be set ;
let x be object ;
let Y be real-functions-membered set ;
let f be PartFunc of X,Y;
coherence
f . x is real-valued

let X be set ;
let x be object ;
let Y be rational-functions-membered set ;
let f be PartFunc of X,Y;
coherence
f . x is RAT -valued

let X be set ;
let x be object ;
let Y be integer-functions-membered set ;
let f be PartFunc of X,Y;
coherence
f . x is INT -valued

let X be set ;
let x be object ;
let Y be natural-functions-membered set ;
let f be PartFunc of X,Y;
coherence
f . x is natural-valued

let X be set ;
let Y be complex-membered set ;
coherence
PFuncs (X,Y) is complex-functions-membered

let X be set ;
let Y be ext-real-membered set ;
coherence
PFuncs (X,Y) is ext-real-functions-membered

let X be set ;
let Y be real-membered set ;
coherence
PFuncs (X,Y) is real-functions-membered

let X be set ;
let Y be rational-membered set ;
coherence
PFuncs (X,Y) is rational-functions-membered

let X be set ;
let Y be integer-membered set ;
coherence
PFuncs (X,Y) is integer-functions-membered

let X be set ;
let Y be natural-membered set ;
coherence
PFuncs (X,Y) is natural-functions-membered

let X be set ;
let Y be complex-membered set ;
coherence
Funcs (X,Y) is complex-functions-membered

let X be set ;
let Y be ext-real-membered set ;
coherence
Funcs (X,Y) is ext-real-functions-membered

let X be set ;
let Y be real-membered set ;
coherence
Funcs (X,Y) is real-functions-membered

let X be set ;
let Y be rational-membered set ;
coherence
Funcs (X,Y) is rational-functions-membered

let X be set ;
let Y be integer-membered set ;
coherence
Funcs (X,Y) is integer-functions-membered

let X be set ;
let Y be natural-membered set ;
coherence
Funcs (X,Y) is natural-functions-membered

let R be Relation;

let Y be complex-functions-membered set ;
coherence
for b₁ being Y -valued Function holds b₁ is complex-functions-valued

let f be Function;
compatibility
( f is complex-functions-valued iff for x being object st x in dom f holds
f . x is complex-valued Function ) compatibility
( f is ext-real-functions-valued iff for x being object st x in dom f holds
f . x is ext-real-valued Function ) compatibility
( f is real-functions-valued iff for x being object st x in dom f holds
f . x is real-valued Function ) compatibility
( f is rational-functions-valued iff for x being object st x in dom f holds
f . x is RAT -valued Function ) compatibility
( f is integer-functions-valued iff for x being object st x in dom f holds
f . x is INT -valued Function ) compatibility
( f is natural-functions-valued iff for x being object st x in dom f holds
f . x is natural-valued Function )

coherence
for b₁ being Relation st b₁ is natural-functions-valued holds
b₁ is integer-functions-valued ;
coherence
for b₁ being Relation st b₁ is integer-functions-valued holds
b₁ is rational-functions-valued ;
coherence
for b₁ being Relation st b₁ is rational-functions-valued holds
b₁ is real-functions-valued ;
coherence
for b₁ being Relation st b₁ is real-functions-valued holds
b₁ is ext-real-functions-valued ;
coherence
for b₁ being Relation st b₁ is real-functions-valued holds
b₁ is complex-functions-valued ;

coherence
for b₁ being Relation st b₁ is empty holds
b₁ is natural-functions-valued ;

existence
ex b₁ being Function st b₁ is natural-functions-valued

let R be complex-functions-valued Relation;
coherence
rng R is complex-functions-membered by Def20;

let R be ext-real-functions-valued Relation;
coherence
rng R is ext-real-functions-membered by Def21;

let R be real-functions-valued Relation;
coherence
rng R is real-functions-membered by Def22;

let R be rational-functions-valued Relation;
coherence
rng R is rational-functions-membered by Def23;

let R be integer-functions-valued Relation;
coherence
rng R is integer-functions-membered by Def24;

let R be natural-functions-valued Relation;
coherence
rng R is natural-functions-membered by Def25;

let X be set ;
let Y be complex-functions-membered set ;
coherence
for b₁ being PartFunc of X,Y holds b₁ is complex-functions-valued ;

let X be set ;
let Y be ext-real-functions-membered set ;
coherence
for b₁ being PartFunc of X,Y holds b₁ is ext-real-functions-valued ;

let X be set ;
let Y be real-functions-membered set ;
coherence
for b₁ being PartFunc of X,Y holds b₁ is real-functions-valued ;

let X be set ;
let Y be rational-functions-membered set ;
coherence
for b₁ being PartFunc of X,Y holds b₁ is rational-functions-valued ;

let X be set ;
let Y be integer-functions-membered set ;
coherence
for b₁ being PartFunc of X,Y holds b₁ is integer-functions-valued ;

let X be set ;
let Y be natural-functions-membered set ;
coherence
for b₁ being PartFunc of X,Y holds b₁ is natural-functions-valued ;

coherence
for b₁ being Function st b₁ is complex-functions-valued holds
b₁ is Function-yielding coherence
for b₁ being Function st b₁ is real-functions-valued holds
b₁ is Function-yielding ;
coherence
for b₁ being Function st b₁ is ext-real-functions-valued holds
b₁ is Function-yielding

let f be complex-functions-valued Function;
let x be object ;
coherence
( f . x is Function-like & f . x is Relation-like )

let f be ext-real-functions-valued Function;
let x be object ;
coherence
( f . x is Function-like & f . x is Relation-like )

let f be complex-functions-valued Function;
let x be object ;
coherence
f . x is complex-valued

let f be ext-real-functions-valued Function;
let x be object ;
coherence
f . x is ext-real-valued

let f be real-functions-valued Function;
let x be object ;
coherence
f . x is real-valued

let f be rational-functions-valued Function;
let x be object ;
coherence
f . x is RAT -valued

let f be integer-functions-valued Function;
let x be object ;
coherence
f . x is INT -valued

let f be natural-functions-valued Function;
let x be object ;
coherence
f . x is natural-valued

let f be real-functions-valued Function;
let x, y be object ;
coherence
for b₁ being Function st b₁ = f . (x,y) holds
b₁ is real-valued ;

for c1, c2 being Complex
for g being complex-valued Function st g <> {} & g + c1 = g + c2 holds
c1 = c2

for c1, c2 being Complex
for g being complex-valued Function st g <> {} & g - c1 = g - c2 holds
c1 = c2

for c1, c2 being Complex
for g being complex-valued Function st g <> {} & g is non-empty & g (#) c1 = g (#) c2 holds
c1 = c2

for c being Complex
for g being complex-valued Function holds - (g + c) = (- g) - c

for c being Complex
for g being complex-valued Function holds - (g - c) = (- g) + c

for c1, c2 being Complex
for g being complex-valued Function holds (g + c1) + c2 = g + (c1 + c2)

for c1, c2 being Complex
for g being complex-valued Function holds (g + c1) - c2 = g + (c1 - c2)

for c1, c2 being Complex
for g being complex-valued Function holds (g - c1) + c2 = g - (c1 - c2)

for c1, c2 being Complex
for g being complex-valued Function holds (g - c1) - c2 = g - (c1 + c2)

for c1, c2 being Complex
for g being complex-valued Function holds (g (#) c1) (#) c2 = g (#) (c1 * c2)

for g, h being complex-valued Function holds - (g + h) = (- g) - h

for g, h being complex-valued Function holds g - h = - (h - g)

for g, h, k being complex-valued Function holds (g (#) h) /" k = g (#) (h /" k)

for g, h, k being complex-valued Function holds (g /" h) (#) k = (g (#) k) /" h

for g, h, k being complex-valued Function holds (g /" h) /" k = g /" (h (#) k)

for c being Complex
for g being complex-valued Function holds c (#) (- g) = (- c) (#) g

for c being Complex
for g being complex-valued Function holds c (#) (- g) = - (c (#) g)

for c being Complex
for g being complex-valued Function holds (- c) (#) g = - (c (#) g)

for g, h being complex-valued Function holds - (g (#) h) = (- g) (#) h

for g, h being complex-valued Function holds - (g /" h) = (- g) /" h

for g, h being complex-valued Function holds - (g /" h) = g /" (- h)

let f be complex-valued Function;
let c be Complex;
coherence
(1 / c) (#) f is Function ;

let f be complex-valued Function;
let c be Complex;
coherence
f (/) c is complex-valued ;

let f be real-valued Function;
let r be Real;
coherence
f (/) r is real-valued ;

let f be RAT -valued Function;
let r be Rational;
coherence
f (/) r is RAT -valued ;

let f be complex-valued FinSequence;
let c be Complex;
coherence
f (/) c is FinSequence-like ;

for c being Complex
for g being complex-valued Function holds dom (g (/) c) = dom g by VALUED_1:def 5;

for c being Complex
for g being complex-valued Function
for x being object holds (g (/) c) . x = (g . x) / c by VALUED_1:6;

for c being Complex
for g being complex-valued Function holds (- g) (/) c = - (g (/) c)

for c being Complex
for g being complex-valued Function holds g (/) (- c) = - (g (/) c)

for c being Complex
for g being complex-valued Function holds g (/) (- c) = (- g) (/) c

for c1, c2 being Complex
for g being complex-valued Function st g <> {} & g is non-empty & g (/) c1 = g (/) c2 holds
c1 = c2

for c1, c2 being Complex
for g being complex-valued Function holds (g (#) c1) (/) c2 = g (#) (c1 / c2)

for c1, c2 being Complex
for g being complex-valued Function holds (g (/) c1) (#) c2 = (g (#) c2) (/) c1

for c1, c2 being Complex
for g being complex-valued Function holds (g (/) c1) (/) c2 = g (/) (c1 * c2)

for c being Complex
for g, h being complex-valued Function holds (g + h) (/) c = (g (/) c) + (h (/) c)

for c being Complex
for g, h being complex-valued Function holds (g - h) (/) c = (g (/) c) - (h (/) c)

for c being Complex
for g, h being complex-valued Function holds (g (#) h) (/) c = g (#) (h (/) c)

for c being Complex
for g, h being complex-valued Function holds (g /" h) (/) c = g /" (h (#) c)

let f be complex-functions-valued Function;
deffunc H₁( object ) -> set = - (f . $1);
existence
ex b₁ being Function st
( dom b₁ = dom f & ( for x being object st x in dom b₁ holds
b₁ . x = - (f . x) ) ) uniqueness
for b₁, b₂ being Function st dom b₁ = dom f & ( for x being object st x in dom b₁ holds
b₁ . x = - (f . x) ) & dom b₂ = dom f & ( for x being object st x in dom b₂ holds
b₂ . x = - (f . x) ) holds
b₁ = b₂

let X be set ;
let Y be complex-functions-membered set ;
let f be PartFunc of X,Y;
:: original: <->
redefine func <-> f -> PartFunc of X,(C_PFuncs (DOMS Y));
coherence
<-> f is PartFunc of X,(C_PFuncs (DOMS Y))

let X be set ;
let Y be real-functions-membered set ;
let f be PartFunc of X,Y;
:: original: <->
redefine func <-> f -> PartFunc of X,(R_PFuncs (DOMS Y));
coherence
<-> f is PartFunc of X,(R_PFuncs (DOMS Y))

let X be set ;
let Y be rational-functions-membered set ;
let f be PartFunc of X,Y;
:: original: <->
redefine func <-> f -> PartFunc of X,(Q_PFuncs (DOMS Y));
coherence
<-> f is PartFunc of X,(Q_PFuncs (DOMS Y))

let X be set ;
let Y be integer-functions-membered set ;
let f be PartFunc of X,Y;
:: original: <->
redefine func <-> f -> PartFunc of X,(I_PFuncs (DOMS Y));
coherence
<-> f is PartFunc of X,(I_PFuncs (DOMS Y))

let Y be complex-functions-membered set ;
let f be FinSequence of Y;
coherence
<-> f is FinSequence-like

for X being set
for Y being complex-functions-membered set
for f being PartFunc of X,Y holds <-> (<-> f) = f

for X1, X2 being set
for Y1, Y2 being complex-functions-membered set
for f1 being PartFunc of X1,Y1
for f2 being PartFunc of X2,Y2 st <-> f1 = <-> f2 holds
f1 = f2