1 Many approaches have been developed to solve the problem of building
2 a Gray code in a $\mathsf{N}$ cube~\cite{Robinson:1981:CS,DBLP:journals/combinatorics/BhatS96,ZanSup04,Bykov2016}, according to properties
3 the produced code has to verify.
4 For instance,~\cite{DBLP:journals/combinatorics/BhatS96,ZanSup04} focus on
5 balanced Gray codes. In the transition sequence of these codes,
6 the number of transitions of each element must differ
8 This uniformity is a global property on the cycle, \textit{i.e.}
9 a property that is established while traversing the whole cycle.
10 On the opposite side, when the objective is to follow a subpart
11 of the Gray code and to switch each element approximately the
13 local properties are wished.
14 For instance, the locally balanced property is studied in~\cite{Bykov2016}
15 and an algorithm that establishes locally balanced Gray codes is given.
17 The current context is to provide a function
18 $f:\Bool^{\mathsf{N}} \rightarrow \Bool^{\mathsf{N}}$ by removing a Hamiltonian
19 cycle in the $\mathsf{N}$ cube. Such a function is going to be iterated
20 $b$ time to produce a pseudo random number, \textit{i.e.} a vertex in the
22 Obviously, the number of iterations $b$ has to be sufficiently large
23 to provide a uniform output distribution.
24 To reduced the number of iterations, the provided Gray code
25 should ideally possess the both balanced and locally balanced properties.
26 However, none of the two algorithms is compatible with the second one:
27 balanced Gray codes that are generated by state of the art works~\cite{ZanSup04,DBLP:journals/combinatorics/BhatS96} are not locally balanced. Conversely,
28 locally balanced Gray codes yielded by Igor Bykov approach~\cite{Bykov2016}
29 are not globally balanced.
30 This section thus shows how the non deterministic approach
31 presented in~\cite{ZanSup04} has been automatized to provide balanced
32 Hamiltonian paths such that, for each subpart,
33 the number of switches of each element is as uniform as possible.
35 \subsection{Analysis of the Robinson-Cohn extension algorithm}
36 As far as we know three works,
37 namely~\cite{Robinson:1981:CS},~\cite{DBLP:journals/combinatorics/BhatS96},
38 and~\cite{ZanSup04} have adressed the probem of providing an approach
39 to produce balanced gray code.
40 The authors of~\cite{Robinson:1981:CS} introduced an inductive approach
41 aiming at producing balanced Gray codes, provided the user gives
42 a special subsequence of the transition sequence at each induction step.
43 This work have been strengthened in~\cite{DBLP:journals/combinatorics/BhatS96}
44 where the authors have explicitely shown how to construct such a subsequence.
45 Finally the authors of~\cite{ZanSup04} have presented
46 the \emph{Robinson-Cohn extension}
47 algorithm. There rigourous presentation of this one
48 have mainly allowed them to prove two properties.
49 The former states that if
50 $\mathsf{N}$ is a 2-power, a balanced Gray code is always totally balanced.
51 The latter states that for every $\mathsf{N}$ there
52 exists a Gray code such that all transition count numbers are
53 are 2-powers whose exponents are either equal
54 or differ from each other by 1.
55 However, the authors do not prove that the approach allows to build
56 (totally balanced) Gray code.
57 What follows shows that this fact is established and first recalls the approach.
60 Let be given a $\mathsf{N}-2$-bit Gray code whose transition sequence is
61 $S_{\mathsf{N}-2}$. What follows is the
62 \emph{Robinson-Cohn extension} method~\cite{ZanSup04}
63 which produces a $n$-bits Gray code.
66 \item \label{item:nondet}Let $l$ be an even positive integer. Find
67 $u_1, u_2, \dots , u_{l-2}, v$ (maybe empty) subsequences of $S_{\mathsf{N}-2}$
68 such that $S_{\mathsf{N}-2}$ is the concatenation of
70 s_{i_1}, u_0, s_{i_2}, u_1, s_{i_3}, u_2, . . . , s_{i_l-1}, u_{l-2}, s_{i_l}, v
72 where $i_1 = 1$, $i_2 = 2$, and $u_0 = \emptyset$ (the empty sequence).
73 \item Replace in $S_{\mathsf{N}-2}$ the sequences $u_0, u_1, u_2, \ldots, u_{l-2}$
75 $\mathsf{N} - 1, u'(u_1,\mathsf{N} - 1, \mathsf{N}) , u'(u_2,\mathsf{N}, \mathsf{N} - 1), u'(u_3,\mathsf{N} - 1,\mathsf{N}), \dots, u'(u_{l-2},\mathsf{N}, \mathsf{N} - 1)$
76 respectively, where $u'(u,x,y)$ is the sequence $u,x,u^R,y,u$ such that
77 $u^R$ is $u$ in reversed order.
78 The obtained sequence is further denoted as $U$.
79 \item Construct the sequences $V=v^R,\mathsf{N},v$, $W=\mathsf{N}-1,S_{\mathsf{N}-2},\mathsf{N}$, and let $W'$ be $W$ where the first
80 two elements have been exchanged.
81 \item The transition sequence $S_{\mathsf{N}}$ is thus the concatenation $U^R, V, W'$.
84 It has been proven in~\cite{ZanSup04} that
85 $S_{\mathsf{N}}$ is transition sequence of a cyclic $\mathsf{N}$-bits Gray code
86 if $S_{\mathsf{N}-2}$ is.
87 However, the step~(\ref{item:nondet}) is not a constructive
88 step that precises how to select the subsequences which ensures that
89 yielded Gray code is balanced.
90 Next section shows how to choose the sequence $l$ to have the balancy property.
92 \subsection{Balanced Codes}
93 Let us first recall how to formalize the balancy property of a Gray code.
94 Let $L = w_1, w_2, \dots, w_{2^\mathsf{N}}$ be the sequence
95 of a $\mathsf{N}$-bits cyclic Gray code.
96 The transition sequence
97 $S = s_1, s_2, \dots, s_{2^n}$, $s_i$, $1 \le i \le 2^\mathsf{N}$,
98 indicates which bit position changes between
99 codewords at index $i$ and $i+1$ modulo $2^\mathsf{N}$.
100 The \emph{transition count} function
101 $\textit{TC}_{\mathsf{N}} : \{1,\dots, \mathsf{N}\} \rightarrow \{0, \ldots, 2^{\mathsf{N}}\}$
102 gives the number of times $i$ occurs in $S$,
103 \textit{i.e.}, the number of times
104 the bit $i$ has been switched in $L$.
106 The Gray code is \emph{totally balanced} if $\textit{TC}_{\mathsf{N}}$
107 is constant (and equal to $\frac{2^{\mathsf{N}}}{\mathsf{N}}$).
108 It is \emph{balanced} if for any two bit indices $i$ and $j$,
109 $|\textit{TC}_{\mathsf{N}}(i) - \textit{TC}_{\mathsf{N}}(j)| \le 2$.
114 Let $L^*=000,100,101,001,011,111,110,010$ be the Gray code that corresponds to
115 the Hamiltonian cycle that has been removed in $f^*$.
116 Its transition sequence is $S=3,1,3,2,3,1,3,2$ and its transition count function is
117 $\textit{TC}_3(1)= \textit{TC}_3(2)=2$ and $\textit{TC}_3(3)=4$. Such a Gray code is balanced.
120 $L^4=0000, 0010, 0110, 1110, 1111, 0111, 0011, 0001, 0101,$
121 $0100, 1100, 1101, 1001, 1011, 1010, 1000$
122 be a cyclic Gray code. Since $S=2,3,4,1,4,3,2,3,1,4,1,3,2,1,2,4$ $\textit{TC}_4$ is equal to 4 everywhere, this code
123 is thus totally balanced.
125 On the contrary, for the standard $4$-bits Gray code
126 $L^{\textit{st}}=0000,0001,0011,0010,0110,0111,0101,0100,1100,$
127 $1101,1111,1110,1010,1011,1001,1000$,
128 we have $\textit{TC}_4(1)=8$ $\textit{TC}_4(2)=4$ $\textit{TC}_4(3)=\textit{TC}_4(4)=2$ and
129 the code is neither balanced nor totally balanced.
133 \begin{thrm}\label{prop:balanced}
134 Let $\mathsf{N}$ in $\Nats$, and $a_{\mathsf{N}}$ be defined by
135 $a_{\mathsf{N}}= 2 \lfloor \dfrac{2^{\mathsf{N}}}{2\mathsf{N}} \rfloor$.
136 There exists then a sequence $l$ in
137 step~(\ref{item:nondet}) of the \emph{Robinson-Cohn extension} algorithm
138 such that all the transition counts $\textit{TC}_{\mathsf{N}}(i)$
139 are $a_{\mathsf{N}}$ or $a_{\mathsf{N}}+2$
140 for any $i$, $1 \le i \le \mathsf{N}$.
147 The proof is done by induction on $\mathsf{N}$. Let us imadialty verify
148 that it is established for both odd and even smallest values, \textit{i.e.}
150 For the initial case where $\mathsf{N}=3$, \textit{i.e.} $\mathsf{N-2}=1$ we successively have: $S_1=1,1$, $l=2$, $u_0 = \emptyset$, and $v=\emptyset$.
151 Thus again the algorithm successively produces
152 $U= 1,2,1$, $V = 3$, $W= 2, 1, 1,3$, and $W' = 1,2,1,3$.
153 Finally, $S_3$ is $1,2,1,3,1,2,1,3$ which obviously verifies the theorem.
154 For the initial case where $\mathsf{N}=4$, \textit{i.e.} $\mathsf{N-2}=2$
155 we successively have: $S_1=1,2,1,2$, $l=4$,
156 $u_0,u_1,u_2 = \emptyset,\emptyset,\emptyset$, and $v=\emptyset$.
157 Thus again the algorithm successively produces
158 $U= 1,3,2,3,4,1,4,3,2$, $V = 4$, $W= 3, 1, 2, 1,2, 4$, and $W' = 1, 3, 2, 1,2, 4 $.
161 2,3,4,1,4,3,2,3,1,4,1,3,2,1,2,4
163 such that $\textit{TC}_4(i) = 4$ and the theorem is established for
164 odd and even initial values.
167 For the inductive case, let us first define some variables.
168 Let $c_{\mathsf{N}}$ (resp. $d_{\mathsf{N}}$) be the number of elements
169 whose transistion count is exactly $a_{\mathsf{N}}$ (resp $a_{\mathsf{N}} +2$).
170 These two variables are defined by the system
175 c_{\mathsf{N}} + d_{\mathsf{N}} & = & \mathsf{N} \\
176 c_{\mathsf{N}}a_{\mathsf{N}} + d_{\mathsf{N}}(a_{\mathsf{N}}+2) & = & 2^{\mathsf{N}}
184 d_{\mathsf{N}} & = & \dfrac{2^{\mathsf{N}} -n.a_{\mathsf{N}}}{2} \\
185 c_{\mathsf{N}} &= &\mathsf{N} - d_{\mathsf{N}}
190 Since $a_{\mathsf{N}$ is even, $d_{\mathsf{N}}$ is defined.
191 Moreover, both $c_{\mathsf{N}}$ and $d_{\mathsf{N}}$ are obviously positves.
194 \subsection{Toward a local uniform distribution of switches}