Patent Grant
10074293
The present invention relates to a secret calculation technique, and especially relates to a technique for performing secret sorting.
Secret calculation is a technique in which data processing is performed while concealing data by secret sharing. The secret sharing is a technique in which data is converted into a plurality of distributed values so that original data can be restored by using a certain number or more number of pieces of distributed values, while original data cannot be restored by using distributed values of which the number of pieces is smaller than the certain number. The secret sharing can be categorized into several kinds. Examples of the secret sharing include (k,n)-secret sharing, permutation data secret sharing, and the like.
The (k,n)-secret sharing is secret sharing in which a plain text which is inputted is divided into n pieces of shares so as to be distributed to n pieces of parties P=(p0, . . . , pn−1) in advance. The plain text can be restored when arbitrary k pieces of shares are provided. Any information on the plain text cannot be obtained from shares of which the number is smaller than k. Specific examples of types of the (k,n)-secret sharing include Shamir secret sharing, reproduction secret sharing, and the like.
The permutation data secret sharing is secret sharing performed while concealing permutation data. The permutation data is data representing the rearrangement way in rearrangement of data columns. When m pieces of data columns are rearranged, permutation data π having the volume m is data representing a bijective map π:Nm→Nm. Here, Nm represents a collection of non-negative integers which are smaller than an arbitrary integer m. For example, data of which elements in vectors x→∈(Nm)m are different from each other can be assumed as random permutation data having the volume m.
More specifically, a vector x→=(3,0,2,1) can be assumed as random permutation data having the volume 4. For example, it is assumed to rearrange the data column y→=(1,5,7,10) by the vector x→. 1 which is the 0th element of the data column y→ is moved to the third position represented by the 0th element of the vector x→. 5 which is the first element of the data column y→ is moved to the 0th position represented by the first element of the vector x→. In a similar manner, 7 is moved to the second position and 10 is moved to the first position. As a result, the post-permutation data column z→=(5,10,7,1) is obtained.
In the permutation data secret sharing, permutation data is concealed by the following procedure. It is assumed that there are N pieces of k party groups of columns P=ρ0, . . . , ρN−1. For example, when k=2, each k party group ρi is a set (p0,p1) of the party p0 and the party p1, a set (p0,p2) of the party p0 and the party p2, or the like. It is assumed that all parties in each k party group ρi mutually share the permutation data πρi and the permutation data πρi is not informed to a complement ρ−i. Further, a corresponding plain text is assumed to be π0(π1( . . . (πN−1(I)) . . . )). Here, I represents permutation in which output is performed in the same arrangement as that of input, that is, identical permutation. In this case, if the k party groups of columns P=ρ0, . . . , ρN−1 is set so that “(condition 1) any complement ρ−i satisfies ρρ−i with respect to an arbitrary k−1 party group ρ”, any permutation data πρi is unknown in any coupling of the k−1 party.
For example, when the number n of parties satisfies n≥2k−1, the above-mentioned condition 1 is satisfied if the column P of the k party groups is set as a collection including all the k party groups. Further, when the number n of parties satisfies n>2k−1, the above-mentioned condition 1 is sometimes satisfied even if not all the k party groups are included. For example, when k=2 and n=4, the condition 1 is satisfied though {(p0,p1),(p2,p3)} does not include all the k party groups.
Secret sorting is processing for rearranging values in accordance with a certain rule based on a key order relation while concealing keys and values which are subjected to secret sharing. As a related art for performing the secret sorting, a technique described in Non-patent Literature 1 is disclosed.
In the secret sorting described in Non-patent Literature 1, a secret sharing value [v→] of the value column v→ and secret sharing values [k→L−1], . . . , [k→0] of the key column k→ are inputted and a secret sharing value [σv→] of the value column σv→ which is subjected to alignment is outputted. Here, σ is a permutation function representing sorting. (1) The permutation function σ0 is first set as identical mapping on Zm. Here, Zm is a collection of integers which are equal to or larger than 0 and smaller than m. (2) The random ID column [h→]:=[I] is set. Here, I represents identical permutation. (3) Processing from (4) to (14) described below is executed with respect to i=0, . . . , L−1. (4) The permutation data <π0>, <π1>, and <π2> are generated. (5) [σi−1k→i] is stably sorted by 1 bit so as to generate the order table [s→]. (6) Secret random permutation of ([σih→],[s→]) is performed with the permutation data <π0> so as to generate ([π0σih→],[π0s→]). (7) If i=L, the process goes to (15) described below. (8) Secret random permutation of ([h→],[k→i+1]) is performed with the permutation data <π1> so as to generate ([π1h→],[π1k→i+1]). (9) [π1h→] and [π0σih→] are restored. (10) [π0σik→i+1]:=π0σih→(π1h→)−1[π1k→i+1] is calculated. (11) Secret random permutation of ([π0σih→],[π0s→],[π0σik→i+1]) is performed with the permutation data <π2> so as to generate ([π20σih→],[π20s→],[π20σik→i+1]). Here, π20=π2π0 holds. (12) [π20s→] is restored. (13) ([s→−1σih→],[s→−1σik→i+1]):=(π20s→)−1([π20σi→],[π20σik→i+1]) is calculated. (14) Permutation function σi+1:=s→−1σi is set. (15) [π0s→] and [s→−1σih→] are restored. (16) Permutation function σL:=s→−1σL−1 is set. (17) The permutation data <π3> is generated. (18) Permutation of [h→] and [v→] is performed with the permutation data <π3> so as to generate ([π3h→],[π3v→]). (19) [π3h→] and [σLh→] are restored so as to output [σv→]:=σLh→(π3h→)−1[π3v→]. Here, permutation function σ=σL.
In the secret sorting technique described in Non-patent Literature 1, production of random ID columns and secret random permutation are repeatedly executed in sequence. Thus, there is a problem in which the number of communication stages is large.
An object of the present invention is to reduce the number of communication stages required for secret sorting and perform secret calculation including secret sorting at high speed.
In order to solve the above-described problems, a secret calculation method according to one aspect of the present invention is a secret calculation method in which sort permutation σπ−1L for performing alignment of a value column v→ is generated by inputting a set composed of a secret sharing value [k→] of a column k→ including in pieces of keys k0, . . . , km−1 having L bits and a secret sharing value [v→] of the column v→ including in pieces of values v0, . . . , vm−1, and which includes a permutation data generation step in which a permutation data generation unit generates permutation data <πi> and <π′i> so as to generate permutation data <πL> with respect to i=1, . . . , L−1, a random ID column generation step in which a random ID column generation unit generates a random ID column [r→i] which does not include mutually-overlapped values so as to generate a random ID column [r→L] which does not include mutually-overlapped values with respect to i=1, . . . , L−1, a secret random permutation step in which a secret random permutation unit performs secret random permutation of a set composed of a random ID column [r→i−1], a key column [k→i], and the random ID column [r→i] with the permutation data <πi> so as to generate a set composed of a post-permutation random ID column πir→i−1, a post-permutation key column [πik→i], and a post-permutation random ID column [πir→i] and performs secret random permutation of a random ID column [r→L−1] with the permutation data <πL> so as to generate a post-permutation random ID column πLr→L−1 with respect to i=1, . . . , L−1, a flag creation step in which a flag creation unit determines whether or not kj=h is satisfied with respect to a key [kj]=([kj,0], . . . , [kj,L−1]) in cases of j=0, . . . , m−1 and h=0, . . . , L−1 so as to set a flag [fj,h], an order table creation step in which an order table creation unit creates an order table [s→:=(s0, . . . , sm−1)], in which an order of each of the keys k0, . . . , km−1 in an ascending order is set, by using the flag [fj,h], and a sort permutation generation step in which a sort permutation generation unit performs permutation of the random ID column [r→i] by a permutation function σi so as to generate a post-permutation random ID column [σir→i] with respect to i=0, . . . , L−1, performs secret random permutation of an order table [s→] and the post-permutation random ID column [σir→i] with the permutation data <π′i> so as to generate a post-permutation order table π′is→ and a post-permutation random ID column π′iσir→i, performs alignment of the post-permutation random ID column π′iσir→i based on the post-permutation order table π′is→ so as to generate a post-alignment random ID column σi+1r→i, sets a permutation function σi+1=s→−1σi, equally couples a set composed of a post-permutation random ID column πi+1r→i, a post-permutation key column [πi+1k→i+1], and a post-permutation random ID column [πi+1r→i+1] with the post-alignment random ID column σi+1r→i by using the post-permutation random ID column πi+1r→i as a key with respect to i=0, . . . , L−2, generates a set composed of the post-alignment random ID column σi+1r→i, a post-alignment key column [σi+1k→i+1], and a post-alignment random ID column [σi+1r→i+1], and equally couples the post-permutation random ID column πLr→L−1 with a post-alignment random ID column σLr→L−1 so as to generate sort permutation σπ−1L.
A secret calculation method according to another aspect of the present invention is a secret calculation method in which a post-alignment value column [σv→]V is generated by inputting a set composed of a secret sharing value [k→] of a column k→ including in pieces of keys k0, . . . , km−1 having L bits and a secret sharing value [v→] of the column v→ including in pieces of values v0, . . . , vm−1, and which includes a permutation data generation step in which a permutation data generation unit generates permutation data <πi> and <π′i> so as to generate permutation data <πL> with respect to i=1, . . . , L−1, a random ID column generation step in which a random ID column generation unit generates a random ID column [r→i] which does not include mutually-overlapped values so as to generate a random ID column [r→L] which does not include mutually-overlapped values with respect to i=1, . . . , L−1, a secret random permutation step in which a secret random permutation unit performs secret random permutation of a set composed of a random ID column [r→i−1], a key column [k→i], and the random ID column [r→i] with the permutation data <πi> so as to generate a set composed of a post-permutation random ID column πir→i−1, a post-permutation key column [πik→i], and a post-permutation random ID column [πir→i] and performs secret random permutation of a random ID column [r→L−1] and a value column [v→]V with the permutation data <πL> so as to generate a post-permutation random ID column πLr→L−1 and a post-permutation value column [πLv→]V with respect to i=1, . . . , L−1, a flag creation step in which a flag creation unit determines whether or not kj=h is satisfied with respect to a key [kj]=([kj,0], . . . , [kj,L−1]) in cases of j=0, . . . , m−1 and h=0, . . . , L−1 so as to set a flag [fj,h], an order table creation step in which an order table creation unit creates an order table [s→:=(s0, . . . , sm−1], in which an order of each of the keys k0, . . . , km−1 in an ascending order is set, by using the flag [fj,h], and an alignment step in which an alignment unit performs permutation of the random ID column [r→i] by a permutation function σi so as to generate a post-permutation random ID column [σir→i] with respect to i=0, . . . , L−1, performs secret random permutation of an order table [s→] and the post-permutation random ID column [σir→i] with the permutation data <π′i> so as to generate a post-permutation order table π′is→ and a post-permutation random ID column π′iσir→i, performs alignment of the post-permutation random ID column π′iσir→i based on the post-permutation order table π′is→ so as to generate a post-alignment random ID column σi+1r→i, sets a permutation function σi+1=s→−1σi, equally couples a set composed of a post-permutation random ID column πi+1r→i, a post-permutation key column [πi+1k→i+1], and a post-permutation random ID column [πi+1r→i+1] with the post-alignment random ID column σi+1r→i by using the post-permutation random ID column πi+1r→i as a key with respect to i=0, . . . , L−2, generates a set composed of the post-alignment random ID column σi+1r→i, a post-alignment key column [σi+1k→i+1], and a post-alignment random ID column [σi+1r→i+1], and equally couples a set composed of the post-permutation random ID column πLr→L−1 and the post-permutation value column [πLv→]V with a post-alignment random ID column σLr→L−1 by using the post-permutation random ID column πLr→L−1 as a key so as to generate the post-alignment value column [σv→]V.
According to the secret calculation technique of the present invention, the number of communication stages in performing of secret sorting can be reduced. Accordingly, secret calculation including secret sorting can be executed at high speed.
Before provision of the description of embodiments, notation and terms used in this specification are defined.
[Notation]
p represents a party possessing shares.
P=(p0, . . . , pn−1) represents a collection of the whole of n parties possessing shares.
ρ=(p0, . . . , pk−1) represents a collection of k party groups executing permutation processing.
[x] represents a (k,n)-secret sharing value of the plane text x∈G. Here, G represents a commutative group. The (k,n)-secret sharing value represents a set obtained by collecting all shares which are obtained by distributing the plain text x by the (k,n)-secret sharing. Secret sharing values [x] are normally possessed in a manner to be distributed in n party collection P, so that all secret sharing values [x] are not possessed at one place and therefore, secret sharing values [x] are virtual.
[x]ID represents a secret sharing value, which can express in kinds of IDs, in a space.
[x]O represents a secret sharing value, which can express m kinds of order collections, in a space.
[x]B represents a secret sharing value of a bit.
[x]V represents a secret sharing value, which can express a value of a sorting object, in a space.
[x]K represents a secret sharing value, which can express a part of keys for determining a sorting order, in a space. The whole key space is expressed by a combination of L pieces of [x]K (a case where [x]K is a secret sharing value in a bit column and the key has L bits, for example).
x
ρ represents an additive secret sharing value of the plain text x∈G. The additive secret sharing value represents a set obtained by collecting all shares which are obtained by distributing the plain text x by additive secret sharing.
x
ρp represents a share possessed by the party p∈ρ in the additive secret sharing value
x
ρ.
x→
ρ represents a column of additive secret sharing values by which a column of a plain text becomes x→.
G
ρ represents a collection of the whole of additive secret sharing values in the commutative group G.
<π> represents a permutation data secret sharing value of permutation data π.
Embodiments of the present invention will be described in detail below. Here, it should be noted that constituent portions mutually having the same functions are given the same reference numerals in the drawings and duplicate description thereof is omitted.
Referring to
A configuration example of the sorting device 1 included in the secret calculation system is described with reference to
Referring to
The sorting device 1 inputs a set ([k→]K,[v→]V) composed of the secret sharing value [k→]K of the key column k→ and the secret sharing value [v→]V of the value column v→ and outputs the secret sharing value [σv→]V of the post-alignment value column σv→. Here, σ represents a permutation function representing sorting. The key column k→ is a column including in pieces of keys k0, . . . , km−1. The bit length of each key ki is L. That is, each key ki can be expressed as ki=(ki,0, . . . , ki,L−1). Columns of distributed values of respective bits of the key column k→ are expressed as [k→0]K, . . . , [k→L−1]K. The value column v→ represents a column including m pieces of values v0, . . . , vm−1. Each value vi is at least one value or may be a combination of a plurality of values. The key column k→ and the value column v→ may be identical to each other.
In step S10, the permutation data generation unit 10 parallelly and simultaneously generates permutation data <πi> and <π′i> with respect to i=0, . . . , L−1. Subsequently, permutation data <πL> is generated.
In step S12, the random ID column generation unit 12 parallelly and simultaneously generates the random ID column [r→i]ID which does not include mutually-overlapped values with respect to i=0, . . . , L−1. Subsequently, the random ID column [r→]ID which does not mutually include overlapped values.
In step S14, the secret random permutation unit 14 parallelly and simultaneously performs secret random permutation of the set ([r→i−1]ID,[k→i]K,[r→i]ID) composed of the random ID column [r→i−1]ID, the key column [k→i]K, and the random ID column [r→i]ID by the permutation data <πi> with respect to i=1, . . . , L−1 so as to generate the set (πir→i−1, [πik→i]K,[πir→i]ID) composed of the post-permutation random ID column πir→i−1, the post-permutation key column [πik→i]K, and the post-permutation random ID column [πir→i]ID. Subsequently, secret random permutation of the random ID column [r→L−1]ID is performed with the permutation data <πL> so as to generate the post-permutation random ID column πLr→L−1.
As the method of the secret random permutation, arbitrary secret random permutation can be employed. For example, the method described in Reference Literature 1 below can be employed. Further, permutation performed by a permutation circuit is applicable as well.
Further, the secret random permutation can be also performed by using 1-additive re-sharing protocol described below. The 1-additive re-sharing protocol is secret random permutation in which data processing is performed in accordance with the following procedures with an input of secret sharing values a
ρ∈
G
ρ which are possessed by the k party group ρ=p0, . . . , pk−1 so as to output secret sharing values
a
ρ′∈
G
ρ′ which are possessed by another k party group ρ′=p1, . . . , pk. In the 1-additive re-sharing protocol, only one party is different between the k party group ρ and the k party group ρ′, so that the communication volume and the number of communication stages can be reduced and thus, the secret random permutation can be performed effectively. However, it should be noted that roles of the parties are appropriately changed.
First, the party p0 shares the random number ri∈G with the party pi with respect to i=1, . . . , k−1. Then, the party p0 calculates the secret sharing value a
ρ′pk with the following formula so as to send the
a
ρ′pk to the party pk.
The party pk outputs the received a
ρ′pk. The party pi (i=1, . . . , k−1) calculates the secret sharing value
a
ρ′pi with the following formula so as to output the secret sharing value
a
ρ′pi.
a
p
a
p
In step S16, the flag creation unit 16 determines whether or not kj=h is satisfied with respect to the key [kj]K=([kj,0]B, . . . , [kj,L−1]B) in the cases of j=0, . . . , m−1 and h=0, . . . , L−1 so as to parallelly and simultaneously set the flag [fj,h]. Specifically, in the case of kj=h, the flag [fj,h]B=[1]B is set. In the case of kj≠h, the flag [fj,h]B=[0]B is set. An equal sign determination circuit may be used for setting of a flag.
Subsequently, the flag creation unit 16 converts the flag [fj,h]B into the flag [fj,h]O. As a method for converting the secret sharing value [a]B of the value a into the secret sharing value [a]O, the conversion may be performed as follows in the case of secret sharing in which [a]B includes Z2 as a partial group (for example, reproduction secret sharing of mod 2, Shamir secret sharing on an extension field of 2, or the like). First, the party pi generates the random number ri so as to generate the secret sharing values [ri]B and [ri]O by two types of secret sharing. Then, the following formulas are calculated by secret calculation so as to generate the secret sharing values [r]B and [r]O of the random number r.
[r]B:=⊕i<n[ri]B,
[r]O:=⊕i<n[ri]O
Subsequently, the exclusive OR [a′=a XOR r]B of the value a and the value r is calculated by using the secret sharing value [a]B and the secret sharing value [r]B so as to restore the value a′. Then, the exclusive OR [a]O=a′ XOR [r]O of the value a′ and the secret sharing value [r]O is calculated. That is, in the case of a XOR r=0, [a]O:=[r]O is obtained. In the case of a XOR r=1, [a]O:=1−[r]O is obtained.
In step S18, the order table creation unit 18 creates the order table [s→]O by using the flag [fj,h]O. [S]O=[0]O is first set. Then, [sj,h]O=[Sj,h−1]O+[fj,h]O (here, each integer satisfying 0≤h<2L) is set with respect to j=0, . . . , m−1. Subsequently, the following formula is parallelly and simultaneously calculated with respect to j=0, . . . , m−1 so as to set the order table [s→:=(s0, . . . , sm−1)]O. The created order table [s→]O becomes a vector in which an order of each element of the key column k→=k0, . . . , km−1 in an ascending order is set.
In step S20, the sort permutation generation unit 20 generates the sort permutation σπ−1L by using the order table [s→]O, the random ID column [r→i], the permutation data <π′i>, the post-permutation key column [πik→i]K, and the post-permutation random ID column [σir→i]ID. The permutation function σ0=I is first set. Here, I represents identical permutation. Then, permutation of the random ID column [r→i]ID is performed by the permutation function σi with respect to i=0, . . . , L−1 so as to generate the post-permutation random ID column [σir→i]ID. Subsequently, secret random permutation of the order table [s→]O and the post-permutation random ID column [σir→i]ID performed with the permutation data <π′i> so as to generate the post-permutation order table π′is→ and the post-permutation random ID column π′iσir→i. Then, alignment of the post-permutation random ID column π′iσir→i is performed based on the post-permutation order table π′is→ so as to generate the post-alignment random ID column σi+1r→i. Here, the permutation function is expressed as σi+1=s→−1σi. Further, the set (πi+1r→i,[πi+1k→i+1]K,[πi+1r→i+1]ID) composed of the post-permutation random ID column πi+1r→i, the post-permutation key column [πi+1k→i+1]K, and the post-permutation random ID column [πi+1r→i+1]ID and the post-alignment random ID column σi+1r→i are equally coupled with each other by using the post-permutation random ID column πi+1r→i as a key with respect to i=0, . . . , L−2 so as to generate the set (σi+1r→i,[σi+1k→i+1]K,[σi+1r→i+1]ID) composed of the post-alignment random ID column σi+1r→i, the post-alignment key column [σi+1k→i+1]K, and the post-alignment random ID column [σi+1r→i+1]ID. Subsequently, the post-permutation random ID column πLr→L−1 and the post-alignment random ID column σLr→L−1 are equally coupled with each other so as to generate the sort permutation σπ−L. Here, a permutation function is expressed as σ=σL.
In step S22, the value alignment unit 22 performs secret random permutation of the value column [v→]V by the permutation data <πL> so as to generate the post-permutation value column [πLv→]V. Subsequently, alignment of the post-permutation value column [πLv→]V is performed based on the sort permutation σπ−1L so as to generate the post-alignment value column [σv→].
In the conventional secret sorting technique, generation of a random ID column and secret random permutation have been performed in sequence. In the secret calculation system according to the first embodiment, required pieces of random ID columns are first generated so as to be able to parallelly and simultaneously perform the secret random permutation using the random ID columns. Further, flags required for creation of an order table are parallelly and simultaneously created. Accordingly, the number of communication stages in secret sorting can be reduced and secret calculation including secret sorting can be executed at high speed.
A configuration example of a sorting device 2 according to a second embodiment is described with reference to
Referring to
Processing from step S10 to step S12 is same as that in the secret calculation method according to the first embodiment.
In step S24, the secret random permutation unit 24 parallelly and simultaneously performs secret random permutation of the set ([r→i−1]ID,[k→i]K,[r→i]ID) composed of the random ID column [r→i−1]ID, the key column [k→i]K, and the random ID column [r→i]ID with the permutation data <πi> with respect to i=1, . . . , L−1 so as to generate the set (πir→i−1,[πik→i]K,[πir→i]ID) composed of the post-permutation random ID column πir→i−1, the post-permutation key column [πik→i]K, and the post-permutation random ID column [πir→i]ID. Subsequently, secret random permutation of the set ([r→L−1]ID,[v→]V) composed of the random ID column [r→L−1]ID and the value column [v→]V is performed with the permutation data <πL> so as to generate the set (πLr→L−1,[πLv→]V) composed of the post-permutation random ID column πLr→L−1 and the post-permutation value column [πLv→]V.
Processing from step S16 to step S18 is same as that of the secret calculation method according to the first embodiment.
In step S26, the alignment unit 26 generates the post-alignment value column [σv→] by using the order table [s→]O, the random ID column [r→i], the permutation data <π′i>, the post-permutation key column [πik→i]K, the post-permutation random ID column [σir→i]ID, and the post-permutation value column [πLv→]V. The permutation function σ0=I is first set. Here, I represents identical permutation. Then, permutation of the random ID column [r→i]ID is performed by the permutation function σi with respect to i=0, . . . , L−1 so as to generate the post-permutation random ID column [σir→i]ID. Subsequently, secret random permutation of the order table [s→]O and the post-permutation random ID column [σir→i]ID is performed with the permutation data <π′i> so as to generate the post-permutation order table π′is→ and the post-permutation random ID column π′iσir→i. Then, alignment of the post-permutation random ID column π′iσir→i is performed based on the post-permutation order table π′is→ so as to generate the post-alignment random ID column σi+1r→i. Here, the permutation function is expressed as σi+1=s→−1σi. Further, the set (πi+1r→i,[πi+1k→i+1]K,[πi+1r→i+1]ID) composed of the post-permutation random ID column πi+1r→i, the post-permutation key column [πi+1k→i+1]K, and the post-permutation random ID column [πi+1r→i+1]ID and the post-alignment random ID column σi+1r→i are equally coupled with each other by using the post-permutation random ID column πi+1r→i as a key with respect to i=0, . . . , L−2 so as to generate the set (σi+1r→i,[σi+1k→i+1]K,[σi+1r→i+1]ID) composed of the post-alignment random ID column σi+1r→i, the post-alignment key column [σi+1k→i+1]K, and the post-alignment random ID column [σi+1r→i+1]ID. Subsequently, the set (πLr→L−1,[πLv→]V) composed of the post-permutation random ID column πLr→L−1 and the post-permutation value column [πLv→]V and the post-alignment random ID column σLr→L−1 are equally coupled with each other by using the post-permutation random ID column πLr→L−1 as a key so as to generate the post-alignment value column [σv→]V. Here, a permutation function is expressed as σ=σL.
In the secret calculation system according to the first embodiment, the processing for generating the sort permutation σπ−1L based on the key column [k→]K and the processing for obtaining the post-alignment value column [σv→]V based on the sort permutation σπ−1L are separated from each other. According to such configuration, processing by the value alignment unit can be omitted in the case where the key column k→ and the value column v→ are identical to each other and only the key column k→ is desired to be sorted, for example. In the secret calculation system according to the second embodiment, the secret random permutation unit simultaneously performs secret random permutation of the value column [v→]V with the permutation data <πL> which is the same data for the random ID column [r→L−1]ID. Therefore, the number of communication stages can be further reduced in the case where both of the key column k→ and the value column v→ are desired to be sorted.
A configuration example of a sorting device 3 according to a third embodiment is described with reference to
Referring to
In the sorting device 1 according to the first embodiment and the sorting device 2 according to the second embodiment, the secret sharing value [k→]K of the key column k→ to be inputted is a secret sharing value of a bit. That is, the key [kj]K can be expressed as the key [kj]K=([kj,0]B, . . . , [kj,L−1]B) with respect to j=0, . . . , m−1. On the other hand, in the sorting device 3 according to the third embodiment, the secret sharing value [k→]K of the key column k→ to be inputted is a secret sharing value, which can express in kinds of order collections, in a space. That is, the key [kj]K can be expressed as the key [kj]K=([kj,0]O, . . . , [kj,L−1]O) with respect to j=0, . . . , m−1.
Processing from step S10 to step S14 is same as that of the secret calculation method according to the first embodiment.
In step S28, the flag creation unit 28 determines whether or not kj=h is satisfied with respect to the key [kj]K=([kj,0]O, . . . , [kj,L−1]O) in cases of j=0, . . . , m−1 and h=0, . . . , L−1 so as to parallelly and simultaneously set the flag [fj,h]. Specifically, in the case of kj=h, the flag [fj,h]O=[1]O is set. In the case of kj≠h, the flag [fj,h]O=[0]O is set. An equal sign determination circuit may be used for setting of a flag.
Processing from step S18 to step S22 is same as that of the secret calculation method according to the first embodiment.
In the secret calculation system according to the first embodiment, the flag [fj,h]B is set from the secret sharing values [kj,0]B, . . . , [kj,L−1]B which are obtained by performing secret sharing of the key kj for each bit, so that the flag [fj,h]B needs to be converted into the flag [fj,h]O. In the secret calculation system according to the third embodiment, respective bits of the key kj are dealt as the secret sharing values [kj,0]O, . . . [kj,L−1]O in a wider space and the flag [fj,h]O are directly set, so that conversion is not necessary. Accordingly, the configuration is simpler than that in the first embodiment and therefore implementation is easy. However, the calculation amount is larger because the space used for calculation is wider, so that calculation is performed more efficiently in the first embodiment.
A fourth embodiment enables detection of tampering in secret calculation with respect to secret sorting of this invention. As a secret tampering detection method for detecting tampering in secret calculation, a method described in Reference Literature 2 below is proposed. In Reference Literature 2, tampering detection in secret calculation is performed in three phases. In a randomization phase, a distributed value is converted into a randomized distributed value of which correctness can be verified. In a calculation phase, desired secret calculation is executed by using an operation, which is composed of the semi-honest operation, for a randomized distributed value. At this time, the calculation is performed while collecting randomized distributed values which will be required for calculation of a checksum in the following correctness verification phase. In the correctness verification phase, checksums are collectively calculated with respect to the randomized distributed values which are collected in the calculation phase so as to perform correctness verification. When the checksum is correct, a calculation result obtained in the calculation phase is outputted. When the checksum is incorrect, only the fact of incorrectness is outputted without outputting the calculation result.
However, in order to apply the method described in Reference Literature 2, each operation executed in secret calculation needs to be tamper-simulatable (Reference Literature 3).
Therefore, in the fourth embodiment, such configuration example is described that the secret tampering detection method described in Reference Literature 2 is applied to secret sorting of the first embodiment so that the above-mentioned condition is satisfied. Here, an example in which the method is applied to the first embodiment is described below, but the method is applicable to the second embodiment and the third embodiment as well based on a similar concept.
A configuration example of a sorting device 4 according to the fourth embodiment is described with reference to
Referring to
In step S32, the randomization unit 32 converts the set ([k→]K,[v→]V) composed of the distributed value [k→]K of the inputted key k→ and the distributed value [v→]V of the value v→ into a randomized distributed value. The randomized distributed value is the set ([x],[xr]) composed of the distributed value [x] of the value x∈R and the distributed value [xr] of the integrated value xr of the value x∈R and the random number r∈A. Here, R represents a ring and A represents an associative algebra on the ring R. The associative algebra is a joined ring and has a structure in a linear space on a certain field compatible with the ring. The associative algebra can be described such that a value dealt in a vector space may be a ring instead of a field. The 0th component ([x]) of the randomized distributed value is also referred to as the R component and the first component ([xr]) is also referred to as the A component.
A random number used in generation of a randomized distributed value is generated such that a distributed value for one secret sharing is converted into a distributed value for the other secret sharing so as to obtain an identical value of the random number in the case where a plurality of types of secret sharing on one ring are used. In this format conversion as well, tampering detection should be possible or tampering should be impossible. For example, a method which prohibits tampering conversion from replicated secret sharing into linear secret sharing is described in Reference Literature 4 below.
From step S14 to step S18, the secret random permutation unit 14, the flag creation unit 16, and the order table creation unit 18 execute predetermined secret calculation while putting a randomized distributed value which is a calculation object and a randomized distributed value which is a calculation result into a checksum Cj (j=0, . . . , J−1; J represents the number of types of secret sharing) which is prepared for each type of secret sharing.
In step S34, the sort permutation generation unit 34 uses a secret random permutation method by which tampering can be detected when performing secret random permutation of the order table [s→]O and the post-permutation random ID column [σir→i]ID with the permutation data <π′i>. This is because confidentiality may be violated in the case where the order table [s→]O and the post-permutation random ID column [σir→i]ID are tampered. As the random permutation method by which tampering can be detected, in such random permutation method that a (k,n)-secret sharing value is converted into an additive secret sharing value and permutation and re-sharing are repeated, for example, an input is converted into a randomized distributed value, a randomized distributed value is converted from an additive secret sharing value into a (k,n)-secret sharing value so as to be put into a checksum whenever one permutation is ended, and correctness verification similar to step S36 below is performed after the whole repeated permutation is ended. Here, it is possible to repeat the acquisition of a checksum and the correctness verification at arbitrary timing in the random permutation. At this time, it is sufficient to generate a randomized distributed value at least once with respect to an input.
In step S36, the correctness verification unit 36 executes synchronous processing (SYNC) in which an action of waiting is performed until all secret calculations for all secret sharing are ended. When the end of all secret calculations for all secret sharing is detected, the checksums C0, . . . , CJ−1 are verified by using the distributed values [r0], . . . , [rJ−1] of the random values r0, . . . , rJ−1 which are used in the randomization unit 32 so as to verify correctness of the post-alignment value column [σv→]V which is obtained as a result of secret sorting. In the case where it is determined that there is no tempering as a result of the verification of all of J pieces of checksums C0, . . . , CJ−1, the post-alignment value column [σv→]V is outputted. In the case where it is determined that there is tempering, information representing the presence of tampering (for example, “⊥” or the like) is outputted.
In the verification of a checksum, the distributed value [φj] obtained by multiplying a sum of the R components of randomized distributed values included in the checksum Cj by the distributed value [rj] and the distributed value [ψj] which is a sum of the A components of randomized distributed values included in the checksum Cj are calculated and the distributed value [δj]=[φj]−[ψj] obtained by subtracting the distributed value [ψj] from the distributed value [φj] is restored. When all of the values δ0, . . . , δJ−1 are 0, it is determined that there is no tampering in the whole secret sorting. When any value δj is not 0, it is determined that tampering is performed in any operation in the secret sorting.
In the case where there are pieces of secret sharing on one ring among J pieces of secret sharing, if correctness verification is performed collectively to the extent possible, the number of disclosed values is reduced and consequently confidentiality can be further enhanced. For example, in the case where the α-th (α=0, . . . , J−1) secret sharing and the β-th (β=0, . . . , J−1, α≠β) secret sharing are pieces of secret sharing on one ring, the correctness verification is performed as follows. First, the distributed value [φα] which is calculated from the checksum Cα as described above and the distributed value [ψα] which is calculated from the checksum Cα as described above are respectively converted into the β-th secret sharing. Then, the distributed value [δ]=([φα]+[φβ])−([ψα]+[ψβ]) which is obtained by subtracting the distributed value [ψα+ψβ] which is obtained by adding the converted distributed value [ψα] and the distributed value [ψβ] which is calculated from the β-th checksum Cβ in a similar manner from the distributed value [φα+φβ] which is obtained by adding the converted distributed value [φα] and the distributed value [φβ] which is calculated from the checksum Cβ in a similar manner is restored. When the restored value δ is 0, it is determined that there is no tampering. When the restored value δ is other than 0, it is determined that there is tampering. Thus, all combinations of pieces of secret sharing on one ring are verified so as to verify that there is no tampering in the whole secret sorting. The example in which two pieces of secret sharing are secret sharing on one ring is described in the present embodiment. However, correctness verification can be performed by a similar method even in the case where three or more pieces of secret sharing are secret sharing on one ring.
The configuration as that of the present embodiment enables tampering detection and enhances security in the secret sorting of the present invention.
It is obvious that the present invention is not limited to the above-described embodiments and alterations can be made as appropriate within a scope of the idea of the present invention. Various types of processing which are described in the above embodiments may be executed in time series in accordance with the described order and may be executed in parallel or individually in accordance with the processing capacity of the device performing the processing or in accordance with the need.
[Program and Recording Medium]
When various types of processing functions in the devices described in the above embodiments are implemented on a computer, the contents of processing function to be contained in each device is written by a program. With this program executed on the computer, various types of processing functions in the above-described devices are executed on the computer.
This program in which the contents of processing are written can be recorded in a computer-readable recording medium. The computer-readable recording medium may be any medium such as a magnetic recording device, an optical disc, a magneto-optical recording medium, and a semiconductor memory.
Distribution of this program is implemented by sales, transfer, rental, and other transactions of a portable recording medium such as a DVD and a CD-ROM on which the program is recorded, for example. Furthermore, this program may be stored in a storage unit of a server computer and transferred from the server computer to other computers via a network so as to be distributed.
A computer which executes such program first stores the program stored in a portable recording medium or transferred from a server computer once in a storage unit of the computer, for example. When the processing is performed, the computer reads out the program stored in the recording medium of the computer and performs processing in accordance with the program thus read out. As another execution form of this program, the computer may directly read out the program from a portable recording medium and perform processing in accordance with the program. Furthermore, each time the program is transferred to the computer from the server computer, the computer may sequentially perform processing in accordance with the received program. Alternatively, what is called application service provider (ASP) type of services may be used to perform the processing described above, with which the program is not transferred from the server computer to the computer and the processing function is realized only with execution instructions and result acquisition. It should be noted that a program according to the present embodiment includes information provided for processing performed by electronic calculation equipment, which is equivalent to a program (such as data which is not a direct instruction to the computer but has a property specifying the processing performed by the computer).
In the present embodiment, the present device is configured with a predetermined program executed on a computer. However, the present device may be configured with at least part of these processing contents realized in a hardware manner.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2014-006334 | Jan 2014 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2015/050230 | 1/7/2015 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2015/107951 | 7/23/2015 | WO | A |
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| Number | Date | Country | |
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| 20160321958 A1 | Nov 2016 | US |
