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\section{Related Work}
Czech, Havas and Majewski~\cite{chm97} provide a
comprehensive survey of the most important theoretical results
on perfect hashing.
In the following, we review some of those results.
Fredman, Koml\'os and Szemer\'edi~\cite{FKS84} showed that it is possible to
construct space efficient perfect hash functions that can be evaluated in
constant time with table sizes that are linear in the number of keys:
$m=O(n)$. In their model of computation, an element of the universe~$U$ fits
into one machine word, and arithmetic operations and memory accesses have unit
cost. Randomized algorithms in the FKS model can construct a perfect hash
function in expected time~$O(n)$:
this is the case of our algorithm and the works in~\cite{chm92,p99}.
Many methods for generating minimal perfect hash functions use a
{\em mapping}, {\em ordering} and {\em searching}
(MOS) approach,
a description coined by Fox, Chen and Heath~\cite{fch92}.
In the MOS approach, the construction of a minimal perfect hash function
is accomplished in three steps.
First, the mapping step transforms the key set from the original universe
to a new universe.
Second, the ordering step places the keys in a sequential order that
determines the order in which hash values are assigned to keys.
Third, the searching step attempts to assign hash values to the keys.
Our algorithm and the algorithm presented in~\cite{chm92} use the
MOS approach.
Pagh~\cite{p99} proposed a family of randomized algorithms for
constructing minimal perfect hash functions.
The form of the resulting function is $h(x) = (f(x) + d_{g(x)}) \bmod n$,
where $f$ and $g$ are universal hash functions and $d$ is a set of
displacement values to resolve collisions that are caused by the function $f$.
Pagh identified a set of conditions concerning $f$ and $g$ and showed
that if these conditions are satisfied, then a minimal perfect hash
function can be computed in expected time $O(n)$ and stored in
$(2+\epsilon)n$ computer words.
Dietzfelbinger and Hagerup~\cite{dh01} improved~\cite{p99},
reducing from $(2+\epsilon)n$ to $(1+\epsilon)n$ the number of computer
words required to store the function, but in their approach~$f$ and~$g$ must
be chosen from a class
of hash functions that meet additional requirements.
Differently from the works in~\cite{p99,dh01}, our algorithm uses two
universal hash functions $h_1$ and $h_2$ randomly selected from a class
of universal hash functions that do not need to meet any additional
requirements.
The work in~\cite{chm92} presents an efficient and practical algorithm
for generating order preserving minimal perfect hash functions.
Their method involves the generation of acyclic random graphs
$G = (V, E)$ with~$|V|=cn$ and $|E|=n$, with $c \ge 2.09$.
They showed that an order preserving minimal perfect hash function
can be found in optimal time if~$G$ is acyclic.
To generate an acyclic graph, two vertices $h_1(x)$ and $h_2(x)$ are
computed for each key $x \in S$.
Thus, each set~$S$ has a corresponding graph~$G=(V,E)$, where $V=\{0,1,
\ldots,t\}$ and $E=\big\{\{h_1(x),h_2(x)\}:x \in S\big\}$.
In order to guarantee the acyclicity of~$G$, the algorithm repeatedly selects
$h_1$ and $h_2$ from a family of universal hash functions
until the corresponding graph is acyclic.
Havas et al.~\cite{hmwc93} proved that if $|V(G)|=cn$ and $c>2$,
then the probability that~$G$ is acyclic is $p=e^{1/c}\sqrt{(c-2)/c}$.
For $c=2.09$, this probability is
$p \simeq 0.342$, and
the expected number of iterations to obtain an acyclic graph
is~$1/p \simeq 2.92$.