Sequences, Series, and Special Functions 567Proof L'et M be the set of such zeros. We have f(M) = {O} and M =
f-^1 {O} n D. Since {O} is closed and f is continuous, it follows that the
set M is closed in D (Theorem 3.7).
Theorem 8.19 Let f: D -t C ,he continuous with D open. If f(z)
vanishes in a set everywhere dense in D, then f(z) = 0 for all z ED.Proof The continuity of f implies that A = D is the set of zeros of f
whenever f(A) = {O} and A is everywhere dense in D.
Corollary 8.9 Let f: D -t C and g: D -t C be continuous with D open,
and let A be a set everywhere dense in D. If f(z) = g(z) for all z E A,
then f(z) = g(z) for all z ED; i.e., a continuous function is determined by
its values on a set everywhere dense in its domain of definition.
Proof The function F(z) = f(z)-g(z) is continuous on D and vanishes in
a set everywhere dense in D. Hence F(z) = 0 or f(z) = g(z) for all z ED.
Remarks I. We have shown in Theorem 8.18 that the set M of zeros
of finite order of a continuous function in an open set D is closed in D.
Conversely,· if M C D is closed, there is always a continuous function f
such that f(z) = 0 if z E M and f(z) =f. 0 if z E D - M.
Example Let
f(z) = d(z, M) = glb(EM lz - Cl
Then f(z) = 0 iff z EM. Clearly, f is continuous on M. To show that f is
also continuous at any point zo ED -M, first we note that glbCEM lzo -Cl
is attained at some point C' E M. From
z - C' = ( z - zo) + ( zo -(')
we obtain
Jz -('J::; Jz - zol + lzo - ('J
= lz -zoJ + glb(EM lzo - Cland for some other z E D - M,
glhceM lz -Cl::; Jz - C'I::; Jz -zol + glhceM lzo -CJ
so that
f(z) - f(zo)::; Jz - zoJ
Similarly,