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-== PBC internals ==
-
-The source code is organized by subdirectories:
-
-*`include`*: Headers describing the official API. Headers in other places
-are for internal use only.
-
-*`arith`*: Finite fields: modular arithmetic, polynomial rings, and polynomial
-rings modulo a polynomial. Finite fields of low characteristic are unsupported.
-
-*`ecc`*: Elliptic curve generation, elliptic curve groups and pairings. One
-source file is dedicated to each type of pairing, containing specialized
-optimizations. Some of the code requires arbitrary precision complex numbers,
-which also live here but should be moved elsewhere one day.
-
-*`misc`*: Dynamic arrays, symbol tables, benchmarking, logging, debugging,
-other utilities.
-
-*`gen`*: Programs that generate pairing parameters and list Hilbert
-polynomials. These were used to prepare the samples in the `param` directory.
-
-*`example`*: Example programs showing how to use the library.
-
-*`guru`*: Tests, experimental code.
-
-=== Groups, rings, fields ===
-
-Algebraic structures are represented in the +field_t+ data type, which mostly
-contains pointers to functions written to perform operations such as addition
-and multiplication in that particular group, ring or field:
-
-  struct field_s {
-    ...
-    void (*init)(element_ptr);
-    void (*clear)(element_ptr);
-    ...
-    void (*add)(element_ptr, element_ptr, element_ptr);
-    void (*sub)(element_ptr, element_ptr, element_ptr);
-    void (*mul)(element_ptr, element_ptr, element_ptr);
-    ...
-  };
-  typedef struct field_s *field_ptr;
-  typedef struct field_s field_t[1];
-
-The name +algebraic_structure_t+ is arguably more accurate, but far too
-cumbersome.  It may help if one views groups and rings as handicapped fields.
-
-The last two lines of the above code excerpt show how GMP and PBC define data
-types: they are arrays of length one so that when a variable is
-declared, space is automatically allocated for it on the stack.
-Yet when used as a argument to a function, a pointer is passed, thus there is
-no need to explicitly allocate and deallocate memory, nor reference and
-dereference variables.
-
-Each +element_t+ contains a field named +field+ to such a +field_t+ variable.
-The only other field is +data+, which stores any data needed for the
-implementation of the particular algebraic structure the element resides in.
-
-  struct element_s {
-    struct field_s *field;
-    void *data;
-  };
-
-When an +element_t+ variable is initialized, +field+ is set appropriately, and
-then the initialization specific to that field is called to complete the
-initialization. Here, a line of code is worth a thousand words:
-
-  void element_init(element_t e, field_ptr f) {
-    e->field = f;
-    f->init(e);
-  }
-
-Thus during a call to one of the `element_` functions, the +field+ pointer is
-followed then the appropriate routine is executed. For example, modular addition
-results when the input element is an element of a finite field, while
-polynomial addition is performed for elements of a polynomial ring and so on.
-
-  void element_add(element_t n, element_t a, element_t b) {
-    n->field->add(n, a, b);
-  }
-
-My design may seem dangerous because if a programmer inadvertently attempts
-to add a polynomial and a point on an elliptic curve, say, the code
-will compile without warnings since they have the same data type.
-
-However I settled on having a catch-all ``glorified +void *+'' +element_t+
-because I wanted to
-
-- extend a field an arbitrary number of times (though in practice, currently I
-  only need to extend a field twice at most),
-- switch fields easily, so for example a program that benchmarks addition in
-  polynomial rings can be trivially modified to benchmark addition in a group,
-  and
-- interchange different implementations of the same algebraic structure, for
-  example, compare Montgomery representation versus a naive implementation of
-  integer modulo rings.
-
-Additionally, defining `PBC_DEBUG` catches many type mismatches.
-
-In mathematics, groups, rings and fields should be distinguished, but for
-implmentation, it is simplest lump them together under the same heading.
-In any event, distinct data types may lead to a false sense of security.
-Fields of prime order with different moduli would still fall under the same
-data type, with unpleasant results if their elements are mistakenly mixed.
-
-I have vague plans to add flags to +field_t+ describing the capabilities of a
-particular +field_t+.  These flags would be set during initialization, and
-would indicate for example whether one can invert every nonzero element,
-whether there are one or two operations (that is, group versus ring), whether
-the field is an integer mod ring, polynomial ring, or polynomial mod ring, and
-so on. Once in place, more runtime checks can be performed to avoid illegal
-inversion and similar problems.
-
-Another option is to introduce data types for each of the four pairing-related
-algebraic structures, namely G1, G2, GT and Zr, as these are the only ones
-needed for implementing pairing-based cryptosystems.
-
-An alternative was to simply use +void *+ instead of +element_t+ and require
-the programmer to pass the field as a parameter, e.g. +element_add(a, b, c,
-F_13)+, but I decided the added annoyance of having to type this extra variable
-every time negated any benefits, such as obviating the need for the
-+field+ pointer in +struct element_s+, even if one ignores
-the more serious problem that runtime type checking is considerably harder, if
-not impossible.
-
-I suppose one could write a preprocessor to convert one type of notation
-to the other, but I would like the code to be standard C.  (On the other hand,
-as Hovav Shacham suggested, it may be nice to eventually have a converter that
-takes human-friendly infix operator expressions like `a = (b + c) *
-d` and outputs the assembly-like `element_` equivalents.)
-
-=== Internal randomness ===
-
-Some algorithms require a quadratic nonresidue in a given field. These
-are computed lazily: The first time a quadratic nonresidue is requested, one is
-generated at random, using the same source of random bits as other PBC random
-functions. [Which reminds me, should I get rid of the +nqr+ field and instead
-have it as part of the +data+ field in struct field_s?]
-
-In `fieldquadratic.c`, a quadratic field extension is constructed with a square
-root of this randomly generated quadratic nonresidue in the base field.  Thus
-for a nondeterminstic source of random bits, the same field may be constructed
-differently on different runs.
-
-To construct the same field the same way every time, one must record the
-quadratic nonresidue generated from one run, and call `field_set_nqr()` every
-time this particular construction of a quadratic field extension is desired.
-Another use for this function is to save time by setting the quadratic
-nonresidue to some precomputed value.
-
-Similarly, for higher degree extensions, a random irreducible polynomial
-may be chosen to construct it, but this must be recorded if the same
-construction is later required.
-
-This happens behind the scenes in PBC.
-
-=== Type A internals ===
-
-Type A pairings are constructed on the curve y^2^ = x^3^ + x over the field F_q
-for some prime q = 3 mod 4.
-Both G1 and G2 are the group of points E(F_q), so this
-pairing is symmetric.  It turns out #E(F_q) = q + 1 and
-#E(F_q^2^) = (q + 1)^2^. Thus the embedding degree k is 2,
-and hence GT is a subgroup of F_q^2.  The order r is some prime
-factor of q + 1.
-
-Write q + 1 = r * h. For efficiency, r is picked to be a Solinas prime,
-that is, r has the form 2^a^ +- 2^b^ +- 1 for some integers 0 < b < a.
-
-Also, we choose q = -1 mod 12 so F_q^2^ can be implemented as F_q[i]
-(where i = sqrt(-1)) and since q = -1 mod 3, cube roots in F_q
-are easy to compute. This latter feature may be removed because I have
-not found a use for it yet (in which case we only need q = -1 mod 4).
-
-+a_param+ struct fields:
-
-  exp2, exp1, sign1, sign0, r:
-    r = 2^exp2 + sign1 * 2^exp1 + sign0 * 1 (Solinas prime)
-  q, h:
-    r * h = q + 1
-    q is a prime, h is a multiple of 12 (thus q = -1 mod 12)
-
-Type A1 uses the same equation, but have different fields since the library
-is given r and cannot choose it.
-
-+a1_param+ struct fields:
-
-  p, n, l:
-    p + 1 = n * l
-    p is prime, same as the q in a_param, n is the order of the group.
-
-=== Type B internals ===
-
-Unimplemented. Similar to type A. The curve y^2^ = x^3^ + 1 over the field F_q
-for some prime q = 2 mod 3, which implies cube roots in F_q are easy to
-compute, though we can achieve this for type A pairings by constraining q
-appropriately. I recommend requiring q = 3 mod 4 as well, so that -1 is
-a quadratic nonresidue.
-
-The lack of an x term simplifies some routines such as point doubling.
-
-It turns out we must choose between symmetry or efficiency due to the nature of
-a certain optimization.
-
-=== Type C internals ===
-
-Unimplemented. The supersingular curves y^2^ = x^3^ + 2x + 1 and
-y^2^ = x^3^ + 2x - 1 over a field of characteristic 3. Discussed at length
-by Boneh, Lynn, and Shacham, "Short signatures from the Weil pairing".
-Many optimizations can be applied to speed up these pairings; see
-Barreto et al., "Efficient algorithms for pairing-based cryptosystems", but
-sadly, an attack due to Coppersmith makes these curves less attractive.
-
-=== Type D internals ===
-
-These are ordinary curves of with embedding degree 6, whose orders are prime
-or a prime multiplied by a small constant.
-
-A type D curve is defined over some field F_q and has order h * r where
-r is a prime and h is a small constant. Over the field F_q^6^ its order is
-a multiple of r^2^.
-
-Typically the order of the curve E is around 170 bits, as is F_q, the base
-field, thus q^k^ is around the 1024-bit mark which is commonly considered
-good enough.
-
-+d_param+ struct fields:
-
-  q   F_q is the base field
-  n   # of points in E(F_q)
-  r   large prime dividing n
-  h   n = h * r
-  a   E: y^2 = x^3 + ax + b
-  b
-  nk  # of points in E(F_q^k)
-  hk  nk = hk * r * r
-  coeff0 coefficients of a monic cubic irreducible over F_q
-  coeff1
-  coeff2
-  nqr quadratic nonresidue in F_q
-
-These were discovered by Miyaji, Nakabayashi and Takano,
-"New explicit conditions of elliptic curve traces for FR-reduction".
-
-=== Type E Internals ===
-
-The CM (Complex Multiplication) method of constructing elliptic curves
-starts with the Diophantine equation
-
-    DV^2 = 4q - t^2
-
-If t = 2 and q = D r^2^ h^2^ + 1 for some prime r (which we choose to
-be a Solinas prime) and some integer h, we find that this equation is easily
-solved with V = 2rh.
-
-Thus it is easy to find a curve (over the field F_q) with order q - 1.
-Note r^2^ divides q - 1, thus we have an embedding degree of 1.
-
-Hence all computations necessary for the pairing can be done in F_q alone.
-There is never any need to extend F_q.
-
-As q is typically 1024 bits, group elements take a lot of space to represent.
-Moreover, many optimizations do not apply to this type, resulting in a slower
-pairing.
-
-+e_param+ struct fields:
-
-  exp2, exp1, sign1, sign0, r:
-    r = 2^exp2 + sign1 * 2^exp1 + sign0 * 1 (Solinas prime)
-  q, h
-    q = h r^2 + 1 where r is prime, and h is 28 times a perfect square
-  a, b
-    E: y^2 = x^3 + ax + b
-
-=== Type F internals ===
-
-Using carefully crafted polynomials, k = 12 pairings can be constructed.
-Only 160 bits are needed to represent elements of one group, and 320 bits
-for the other.
-
-Also, embedding degree k = 12 allows higher security short signatures.
-(k = 6 curves cannot
-be used to scale security from 160-bits to say 256-bits because finite
-field attacks are subexponential.)
-
-+f_param+ struct fields:
-
-  q:
-    The curve is defined over Fq
-  r:
-    The order of the curve.
-  b:
-    E: y^2= x^3 + b
-  beta:
-    A quadratic nonresidue in Fq: used in quadratic extension.
-  alpha0, alpha1:
-    x^6 + alpha0 + alpha1 sqrt(beta) is irreducible: used in sextic extension.
-
-Discovered by Barreto and Naehrig, "Pairing-friendly elliptic curves of prime order".
-
-=== Type G Internals ===
-
-Another construction based on the CM method.
-
-+g_param+ struct fields:
-
-  q, n, h, r:
-    h * r = n is the order of E(F_q)
-  a, b:
-    E: y^2 = x^3 + ax + b
-  nk:
-    #E(F_q^10)
-  hk:
-    hk * r^2 = nk
-  coeff:
-    array of coefficients of polynomial used for quintic extension.
-  nqr:
-    a quadratic nonresidue
-
-+g_param+ struct fields:
-
-Discovered by Freeman, "Constructing pairing-friendly elliptic curves with embedding degree 10."
-
-=== Type I Internals ===
-
-Type I pairings is symmetric, constructed on a supersingular curve
-y^2^ = x^3^ - x + 1 over a ternary extension field F_{3^m^}.
-The embedding degree k is 6.
-Both G1 and G2 are the group of points E(F_{3^m^}).
-GT is a subgroup of F_{3^6*m^}. The group order is a prime number.
-
-parameters:
-
-  m, t:
-    The ternary extension field is F(3)[x]/(x^m^ + x^t^ + 2).
-  n:
-    the order of G1
-  n2:
-    n * n2 = number of points in E(F_{3^m^})
-
-Introduced by Barreto et al, "Efficient Pairing Computation on Supersingular
-Abelian Varieties", Designs, Codes and Cryptography, vol. 42, no. 3, pp. 239-271,
-Mar. 2007.
-
-=== Testing functions ===
-
-For testing, debugging, demonstrations and benchmarks.
-Declared in +pbc_test.h+:
-
-include::gen/test.txt[]
-
-=== Dynamic arrays ===
-
-The +darray_t+ data type manages an array of pointers of type +void \*+,
-allocating more memory when necessary.
-Declared in +pbc_darray.h+.
-
-include::gen/darray.txt[]
-
-=== Symbol tables ===
-
-The +symtab_t+ data type manages symbol tables where the keys are strings of
-type +char \*+ and the values are pointers of type +void \*+.
-
-At present, they are implemented inefficiently using dynamic arrays, but this
-will change if the need arises. They are only used when reading a +pbc_param_t+
-from a string. Declared in +pbc_symtab.h+.
-
-include::gen/symtab.txt[]
-
-=== Religious stances ===
-
-I chose C because:
-
-- GMP, which PBC requires and is also modeled on, is also written in C.
-- PBC is intended to be a low-level portable cryptographic library.  C is the
-  least common denominator. It should not be difficult to wrap PBC for other
-  languages.
-- Despite its drawbacks (I would appreciate operator overloading and
-  genericity, and to a lesser extent garbage collection), I've found few
-  languages I like better.  To quote Rob Pike, C is the desert island language.
-  (I also agree with his statement that OO languages conceptually provide
-  little extra over judicious use of function pointers in C.)
-
-With respect to indentation, I'm migrating the code to follow
-http://google-styleguide.googlecode.com/svn/trunk/cppguide.xml[Google C++
-Style Guide] to avoid having to switch styles all the time.
-The code was originally written using my old style: 4-space indent with 1TBS
-(One True Brace Style).
-
-I'd like to have no library dependencies (except standard C libraries),
-but then I'd have to write a large integer library. Furthermore, I'd have to
-write it in assembly, and then port it.
-
-To avoid this, I use an existing library. I selected GMP because the library's
-focus is on multiprecision arithmetic and nothing else, and it aims to be as
-fast as possible on many platforms.  Another important factor is that GMP is
-released under a free license.
-
-On the other hand, GMP is written to deal with extremely large numbers, while I
-mostly only need integers that are roughly between 160 and 2048 bits. It is
-possible a library specializing in numbers of these sizes would be better for
-PBC.
-
-I'm fond of GMP's method for eliminating the need for the +&amp;+ and +*+
-operators most of the time by declaring a typedef on arrays of size 1.  I try
-to do the same with PBC for consistency, though this trick does have drawbacks.
-
-I would like to have GMP as the only library dependency, though I do not mind
-using other libraries so long as they are optional. For example, one of the
-test programs is much easier to use if compiled with the GNU readline library,
-but by default compiles without it and is still functional.
-
-I dislike the C preprocessor. I like to place platform-specific code in
-separate files and let the build system work out which one to use.  Integer
-constants can be defined with enum instead.  I intend to minimize the number of
-+#include+ statements in header files for PBC's internal use as much as
-possible (they should be in the `.c` files instead), and later perhaps even
-remove those annoying +#ifndef+ statements too.
-I grudgingly accept some macros for PBC's debugging features.
-
-I liberally use nested functions, a GNU C extension. I find their expressiveness so indispensable that I'm willing to sacrifice portability for them.
-
-The
-http://www.gnu.org/software/libc/manual/html_node/Reserved-Names.html[GNU libc manual]
-states that data types ending in +_t+ should not be used because they are
-reserved for future additions to C or POSIX.  On the other hand, I want to stay
-consistent with GMP, and ending data types with +_t+ is common practice.