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How to Share a Secret
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How to Share a Secret
Adi Shamir
Massachusetts Institute of Technology
In this paper we show how to divide data D into n pieces in such a way that D
is easily reconstructable from any k pieces, but even complete knowledge of
k - 1 pieces reveals absolutely no information about D. This technique enables
the construction of robust key management schemes or cryptographic schemes that
can function securely and reliably even when misfortunes destroy half the
pieces and security breaches expose all but one of the remaining pieces.
Key Words and phrases: cryptography, key management, interpolation.
CR Categories: 5:39, 5.6
1. Introduction
In [4], Liu considers the following problem:
Eleven scientists are working on a secret project. They wish to lock up
the documents in a cabinet so that the cabinet can be opened if and only if
six or more of the scientists are present. What is the smallest number of
locks needed? What is the smallest number of keys to the locks each
scientist must carry?
It is not hard to show that the minimal solution uses 462 locks and 252 keys
per scientist. These numbers are clearly impractical, and they become
exponentially worse when the number of scientists increases.
In this paper we generalize the problem to one in which the secret is some data
D (e.g., the safe combination) and in which nonmechanical solutions (which
manipulate this data) are also allowed. Our goal is to divide D into n pieces
D1, ..., Dn in such a way that:
(1) knowledge of any k or more Di pieces makes D easily computable;
(2) knowledge of any k - 1 or fewer Di pieces leaves D completely undetermined
(in the sense that all its possible values are equally likely).
Such a scheme is called a (k, n) threshold scheme.
Efficient threshold schemes can be very helpful in the management of
cryptographic keys. In order to protect data we can encrypt it, but in order
to protect the encryption key we need a different method (further encryptions
change the problem rather than solve it). The most secure key management
scheme keeps the key in a single, well-guarded location (a computer, a human
brain, or a safe). This scheme is highly unreliable since a single misfortune
(a computer breakdown, sudden death, or sabotage) can make the information
inaccessible. An obvious solution is to store multiple copies of the key at
different locations, but this increases the danger of security breaches
(computer penetration, betrayal, or human errors). By using a (k, n) threshold
scheme with n = 2k - 1 we get a very robust key management scheme: We can
recover the original key even when floor(n/2) = k - 1 of the n pieces are
destroyed, but our opponents cannot reconstruct the key even when security
breaches expose floor(n/2) = k - 1 of the remaining k pieces.
In other applications the tradeoff is not between secrecy and reliability, but
between safety and convenience of use. Consider, for example, a company that
digitally signs all its checks (see RSA [5]). If each executive is given a
copy of the company's secret signature key, the system is convenient but easy
to misuse. If the cooperation of all the company's executives is necessary in
order to sign each check, the system is safe but inconvenient. The standard
solution requires at least three signatures per check, and it is easy to
implement with a (3, n) threshold scheme. Each executive is given a small
magnetic card with one Di piece, and the company's signature generating device
accepts any three of them in order to generate (and later destroy) a temporary
copy of the actual signature key D. The device does not contain any secret
information and thus it need not be protected against inspection. An
unfaithful executive must have at least two accomplices in order to forge the
company's signature in this scheme.
Threshold schemes are ideally suited to applications in which a group of
mutually suspicious individuals with conflicting interests must cooperate.
Ideally we would like the cooperation to be based on mutual consent, but the
veto power this mechanism gives to each member can paralyze the activities of
the group. By properly choosing the k and n parameters we can give any
sufficiently large majority the authority to take some action while giving any
sufficiently large minority the power to block it.
2. A Simple (k, n) Threshold Scheme
Our scheme is based on polynomial (*) interpolation: given k points in the
2-dimensional plane (x1, y1), ... (xk, yk) with distinct xi's, there is one and
only one polynomial q(x) of degree k - i such that q(xi) = yi for all i.
--------
(*) The polynomials can be replaced by any other collection of functions which
are easy to evaluate and to interpolate.
--------
Without loss of generality, we can assume that the data D is (or can be made) a
number. To divide it into pieces Di, we pick a random k - 1 degree polynomial
q(x) = a[0] + a[1] * x + ... a[k-1] * x^(k-1) in which a[0] = D, and
evaluate:
D1 = q(1), ..., Di = q(i), ..., Dn = q(n).
Given any subset of k of these Di values (together with their identifying
indices), we can find the coefficients of q(x) by interpolation, and then
evaluate D = q(O). Knowledge of just k - 1 of these values, on the other hand,
does not suffice in order to calculate D.
To make this claim more precise, we use modular arithmetic instead of real
arithmetic. The set of integers modulo a prime number p forms a field in which
interpolation is possible. Given an integer valued data D, we pick a prime p
which is bigger than both D and n. The coefficients a[1], ..., a[k-1], in q(x)
are randomly chosen from a uniform distribution over the integers in [0, p),
and the values D1, ..., Dn are computed modulo p.
Let us now assume that k - 1 of these n pieces are revealed to an opponent.
For each candidate value D' in [O, p) he can construct one and only one
polynomial q'(x) of degree k - 1 such that q'(0) = D' and q'(i) = Di for the
k - 1 given arguments. By construction, these p possible polynomials are
equally likely, and thus there is absolutely nothing the opponent can deduce
about the real value of D.
Efficient O(n log^2 n) algorithms for polynomial evaluation and interpolation
are discussed in [11 and [3], but even the straightforward quadratic algorithms
are fast enough for practical key management schemes. If the number D is long,
it is advisable to break it into shorter blocks of bits (which are handled
separately) in order to avoid multiprecision arithmetic operations. The blocks
cannot be arbitrarily short, since the smallest usable value of p is n + 1
(there must be at least n + 1 distinct arguments in [0, p) to evaluate q(x)
at). However, this is not a severe limitation since sixteen bit modulus (which
can be handled by a cheap sixteen bit arithmetic unit) suffices for
applications with up to 64,000 Di pieces.
Some of the useful properties of this (k, n) threshold scheme (when compared to
the mechanical locks and keys solutions) are:
(1) The size of each piece does not exceed the size of the original data.
(2) When k is kept fixed, Di pieces can be dynamically added or deleted (e.g.,
when executives join or leave the company) without affecting the other D,
pieces. (A piece is deleted only when a leaving executive makes it
completely inaccessible, even to himself.)
(3) It is easy to change the Di pieces without changing the original data D --
all we need is a new polynomial q(x) with the same free term. A frequent
change of this type can greatly enhance security since the pieces exposed
by security breaches cannot be accumulated unless all of them are values of
the same edition of the q(x) polynomial.
(4) By using tuples of polynomial values as Di pieces, we can get a
hierarchical scheme in which the number of pieces needed to determine D
depends on their importance. For example, if we give the company's
president three values of q(x), each vice-president two values of q(x), and
each executive one value of q(x), then a (3, n) threshold scheme enables
checks to be signed either by any three executives, or by any two
executives one of whom is a vice-president, or by the president alone.
A different (and somewhat less efficient) threshold scheme was recently
developed by G.R. Blakley [2].
References
1. Aho, A., Hopcroft, J., and Ullman, J. The Design and Analysis of Computer
Algorithms. Addison-Wesley, Reading, Mass., 1974.
2. Blakley, G.R. Safeguarding cryptographic keys. Proc. AFIPS 1979 NCC,
Vol. 48, Arlington, Va., June 1979, pp. 313-317.
3. Knuth, D. The Art of Computer Programming, Vol. 2: Seminumerical
Algorithms. Addison-Wesley, Reading, Mass., 1969.
4. Liu, C.L. Introduction to Combinatorial Mathematics. McGraw-Hill, New
York, 1968.
5. Rivest, R., Shamir. A., and Adleman, L. A method for obtaining digital
signatures and public key cryptosystems. Comm. ACM 21, 2 (Feb. 1978),
120-126.
Communications of the ACM
November 1979
Volume 22
Number 11
Permission to copy without fee all or part of this material is granted provided
that the copies are not made or distributed for direct commercial advantage,
the ACM copyright notice and the title of the publication and its date appear,
and notice is given that copying is by permission of the Association for
Computing Machinery. To copy otherwise, or to republish, requires a fee and/or
specific permission.
Author's present address: A. Shamir, Laboratory for Computer Science,
Massachusetts Institute of Technology, Cambridge, MA 02139.
This research was supported by the Office of Naval Research under contract no
N00014-76-C-0366.
Received April 1979; revised September 1979.
(c) 1979 ACM 0001-0782/79/1100-0612 $00.75.
Brought to you by the Information Liberation Front, and
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