// Pairing-Based Calculator. // TODO: Garbage collection. // TODO: Recursion (stack frames), anonymous functions. #include // For getopt. #include "pbc.h" #include "pbc_fp.h" #include "pbc_z.h" #include "pbc_multiz.h" #include "pbc_poly.h" #include "misc/darray.h" #include "misc/symtab.h" #include "pbc_tree.h" #include "lex.yy.h" #include "parser.tab.h" int option_easy = 0; const char *option_prompt; char *pbc_getline(const char *prompt); void yyerror(char *s) { fprintf(stderr, "%s\n", s); } int yyparse(void); // Symbol table holding built-in functions and variables. static symtab_t reserved; // Symbol table holding user-defined variable and function names. static symtab_t tab; static field_t M; static field_t Z; static pairing_t pairing; struct val_s; typedef struct val_s *val_ptr; struct fun_s; typedef struct fun_s *fun_ptr; // Syntax tree node. struct tree_s { // Evaluates this node. val_ptr (*eval)(tree_ptr); union { const char *id; element_ptr elem; // Built-in function. fun_ptr fun; // Child nodes. darray_ptr child; }; }; enum { ARITY_VARIABLE = -1, }; // The interface of a val_ptr shared amongst many val_ptr objects. // Analog of C++ class. struct val_type_s { // One of element, field, function, error. char *name; // Print out current value. void (*out_str)(FILE *, val_ptr); // Called when a variable is evaluated, e.g. "foo;". val_ptr (*eval)(val_ptr); // Called when a variable is used as a function, e.g. "foo();". val_ptr (*funcall)(val_ptr, tree_ptr); }; // Functions plus type checking data. struct fun_s { const char *name; val_ptr (*run)(val_ptr[]); int arity; const struct val_type_s **sig; }; typedef struct fun_s fun_t[1]; // When interpreting, each node of the syntax tree recursively evaluates // its children then returns a val_ptr. struct val_s { struct val_type_s *type; union { element_ptr elem; // User-defined function. tree_ptr def; // Built-in function. fun_ptr fun; field_ptr field; const char *msg; }; }; static val_ptr val_new_element(element_ptr e); static val_ptr val_new_field(field_ptr e); static val_ptr val_new_error(const char *msg, ...); // Evaluates syntax tree node. static val_ptr tree_eval(tree_ptr t) { return t->eval(t); } static void v_elem_out(FILE* stream, val_ptr v) { element_out_str(stream, 0, v->elem); } static val_ptr v_elem_eval(val_ptr v) { element_ptr e = pbc_malloc(sizeof(*e)); element_init_same_as(e, v->elem); element_set(e, v->elem); return val_new_element(e); } static void v_builtin_out(FILE* stream, val_ptr v) { // TODO: Print types of arguments. fprintf(stream, "built-in function %s, arity %d", v->fun->name, v->fun->arity); } static void v_define_out(FILE* stream, val_ptr v) { fprintf(stream, "user-defined function %s", ((tree_ptr) darray_at(v->def->child, 0))->id); } static val_ptr v_builtin(val_ptr v, tree_ptr t) { fun_ptr fun = v->fun; int n = fun->arity; if (1 + n != darray_count(t->child)) { return val_new_error("%s: wrong number of arguments", fun->name); } val_ptr arg[n]; int i; for(i = 0; i < n; i++) { arg[i] = tree_eval(darray_at(t->child, i)); if (fun->sig[i] && arg[i]->type != fun->sig[i]) { return val_new_error("%s: argument %d type mismatch", fun->name, i + 1); } } return fun->run(arg); } static void eval_stmt(void *ptr) { tree_eval(ptr); } static val_ptr v_def_call(val_ptr v, tree_ptr t) { int i; const char* name = ((tree_ptr) darray_at(v->def->child, 0))->id; darray_ptr parm = ((tree_ptr) darray_at(v->def->child, 1))->child; int n = darray_count(parm); if (1 + n != darray_count(t->child)) { return val_new_error("%s: wrong number of arguments", name); } for(i = 0; i < n; i++) { const char *id = ((tree_ptr) darray_at(parm, i))->id; val_ptr v1 = tree_eval(darray_at(t->child, i)); // TODO: Stack frames for recursion. symtab_put(tab, v1, id); } // Evaluate function body. darray_ptr a = ((tree_ptr) darray_at(v->def->child, 2))->child; darray_forall(a, eval_stmt); return NULL; } static val_ptr v_field_cast(val_ptr v, tree_ptr t) { // TODO: Check args, x is an element. val_ptr x = tree_eval(darray_at(t->child, 0)); element_ptr e = x->elem; if (e->field == M) { if (v->field == M) return x; element_ptr e2 = element_new(v->field); if (element_is0(e)) // if 'set0' is not 'set1' in base field of GT, but we hope 'GT(0)' calls 'set1', we may directly call 'element_set0' here element_set0(e2); else if (element_is1(e)) // reason is same as above element_set1(e2); else element_set_multiz(e2, e->data); x->elem = e2; return x; } if (v->field == M) { // Map to/from integer. TODO: Map to/from multiz instead. mpz_t z; mpz_init(z); element_to_mpz(z, e); element_clear(e); element_init(e, v->field); element_set_mpz(e, z); mpz_clear(z); } return x; } static void v_field_out(FILE* stream, val_ptr v) { field_out_info(stream, v->field); } static val_ptr v_self(val_ptr v) { return v; } static void v_err_out(FILE* stream, val_ptr v) { fprintf(stream, "%s", v->msg); } static val_ptr v_errcall(val_ptr v, tree_ptr t) { UNUSED_VAR(t); return v; } static struct val_type_s // TODO: Replace NULL with get_coeff. v_elem[1] = {{ "element", v_elem_out, v_elem_eval, NULL }}, v_field[1] = {{ "field", v_field_out, v_self, v_field_cast }}, v_fun[1] = {{ "builtin", v_builtin_out, v_self, v_builtin }}, v_def[1] = {{ "function", v_define_out, v_self, v_def_call }}, v_error[1] = {{ "error", v_err_out, v_self, v_errcall }}; // Function signature constants for type checking. const struct val_type_s *sig_field[] = { v_field }; const struct val_type_s *sig_elem[] = { v_elem }; const struct val_type_s *sig_any[] = { NULL }; const struct val_type_s *sig_elem_elem[] = { v_elem, v_elem }; const struct val_type_s *sig_field_elem[] = { v_field, v_elem }; static val_ptr val_new_element(element_ptr e) { val_ptr v = pbc_malloc(sizeof(*v)); v->type = v_elem; v->elem = e; return v; } static val_ptr val_new_field(field_ptr f) { val_ptr v = pbc_malloc(sizeof(*v)); v->type = v_field; v->field = f; return v; } static val_ptr val_new_error(const char *msg, ...) { va_list params; char buf[80]; va_start(params, msg); vsnprintf(buf, 80, msg, params); va_end(params); val_ptr v = pbc_malloc(sizeof(*v)); v->type = v_error; v->msg = pbc_strdup(buf); return v; } static val_ptr val_new_fun(fun_ptr fun) { val_ptr v = pbc_malloc(sizeof(*v)); v->type = v_fun; v->fun = fun; return v; } static val_ptr fun_bin( void (*binop)(element_ptr, element_ptr, element_ptr), val_ptr v[]) { binop(v[0]->elem, v[0]->elem, v[1]->elem); return v[0]; } static val_ptr run_add(val_ptr v[]) { return fun_bin(element_add, v); } static val_ptr run_sub(val_ptr v[]) { return fun_bin(element_sub, v); } static val_ptr run_mul(val_ptr v[]) { return fun_bin(element_mul, v); } static val_ptr run_div(val_ptr v[]) { return fun_bin(element_div, v); } static val_ptr run_pow(val_ptr v[]) { return fun_bin(element_pow_zn, v); } static fun_t fun_add = {{ "add", run_add, 2, sig_elem_elem }}; static fun_t fun_sub = {{ "sub", run_sub, 2, sig_elem_elem }}; static fun_t fun_mul = {{ "mul", run_mul, 2, sig_elem_elem }}; static fun_t fun_div = {{ "div", run_div, 2, sig_elem_elem }}; static fun_t fun_pow = {{ "pow", run_pow, 2, sig_elem_elem }}; static val_ptr fun_cmp(val_ptr v[], int (*fun)(int)) { int i = element_cmp(v[0]->elem, v[1]->elem); element_ptr e = pbc_malloc(sizeof(*e)); element_init(e, M); element_set_si(e, fun(i)); v[0]->elem = e; return v[0]; } static int is0(int i) { return i == 0; } static int isnot0(int i) { return i != 0; } static int isle(int i) { return i <= 0; } static int isge(int i) { return i >= 0; } static int islt(int i) { return i < 0; } static int isgt(int i) { return i > 0; } static val_ptr run_eq(val_ptr v[]) { return fun_cmp(v, is0); } static val_ptr run_ne(val_ptr v[]) { return fun_cmp(v, isnot0); } static val_ptr run_le(val_ptr v[]) { return fun_cmp(v, isle); } static val_ptr run_ge(val_ptr v[]) { return fun_cmp(v, isge); } static val_ptr run_lt(val_ptr v[]) { return fun_cmp(v, islt); } static val_ptr run_gt(val_ptr v[]) { return fun_cmp(v, isgt); } static fun_t fun_eq = {{ "==", run_eq, 2, sig_elem_elem }}; static fun_t fun_ne = {{ "!=", run_ne, 2, sig_elem_elem }}; static fun_t fun_le = {{ "<=", run_le, 2, sig_elem_elem }}; static fun_t fun_ge = {{ ">=", run_ge, 2, sig_elem_elem }}; static fun_t fun_lt = {{ "<", run_lt, 2, sig_elem_elem }}; static fun_t fun_gt = {{ ">", run_gt, 2, sig_elem_elem }}; static val_ptr eval_elem(tree_ptr t) { // TODO: Write element_clone(), or at least element_new(). element_ptr e = pbc_malloc(sizeof(*e)); element_init_same_as(e, t->elem); element_set(e, t->elem); return val_new_element(e); } static val_ptr eval_list(tree_ptr t) { element_ptr e = NULL; int n = darray_count(t->child); int i; for(i = 0; i < n; i++) { val_ptr x = tree_eval(darray_at(t->child, i)); // TODO: Also check x is a multiz. if (v_error == x->type) { return x; } if (v_elem != x->type) { return val_new_error("element expected in list"); } if (!i) e = multiz_new_list(x->elem); else multiz_append(e, x->elem); } return val_new_element(e); } static val_ptr eval_ternary(tree_ptr t) { val_ptr x = tree_eval(darray_at(t->child, 0)); if (v_error == x->type) { return x; } if (x->type != v_elem) { return val_new_error("element expected in ternary operator"); } if (!element_is0(x->elem)) { return tree_eval(darray_at(t->child, 1)); } return tree_eval(darray_at(t->child, 2)); } static val_ptr eval_id(tree_ptr t) { val_ptr x = symtab_at(reserved, t->id); if (!x) x = symtab_at(tab, t->id); if (!x) { return val_new_error("undefined variable %s", t->id); } return x->type->eval(x); } static val_ptr eval_funcall(tree_ptr t) { val_ptr x = tree_eval(darray_last(t->child)); return x->type->funcall(x, t); } static val_ptr eval_fun(tree_ptr t) { return val_new_fun(t->fun); } static val_ptr run_neg(val_ptr v[]) { element_neg(v[0]->elem, v[0]->elem); return v[0]; } static fun_t fun_neg = {{ "neg", run_neg, 1, sig_elem }}; static val_ptr eval_assign(tree_ptr t) { tree_ptr tid = darray_at(t->child, 0); val_ptr v = tree_eval(darray_at(t->child, 1)); if (symtab_at(reserved, tid->id)) { return val_new_error("%s is reserved", tid->id); } symtab_put(tab, v, tid->id); return v; } static void assign_field(field_ptr f, const char* s) { symtab_put(tab, val_new_field(f), s); } tree_ptr tree_new(val_ptr (*eval)(tree_ptr)) { tree_ptr res = pbc_malloc(sizeof(*res)); res->eval = eval; return res; } tree_ptr tree_new_z(const char* s) { element_ptr e = pbc_malloc(sizeof(*e)); element_init(e, M); element_set_str(e, s, 0); tree_ptr t = tree_new(eval_elem); t->elem = e; return t; } static val_ptr eval_err(tree_ptr t) { UNUSED_VAR(t); pbc_die("BUG: shouldn't reach here!"); } tree_ptr tree_new_empty_stmt_list() { tree_ptr t = tree_new(eval_err); t->child = darray_new(); return t; } tree_ptr tree_new_empty_parms() { tree_ptr t = tree_new(eval_err); t->child = darray_new(); return t; } static val_ptr eval_define(tree_ptr t) { val_ptr v = pbc_malloc(sizeof(*v)); v->type = v_def; v->def = t; symtab_put(tab, v, ((tree_ptr) darray_at(t->child, 0))->id); return v; } tree_ptr tree_new_define(tree_ptr id, tree_ptr parm, tree_ptr body) { tree_ptr t = tree_new(eval_define); t->child = darray_new(); darray_append(t->child, id); darray_append(t->child, parm); darray_append(t->child, body); return t; } tree_ptr tree_new_list(tree_ptr first) { tree_ptr t = tree_new(eval_list); t->child = darray_new(); darray_append(t->child, first); return t; } tree_ptr tree_new_ternary(tree_ptr cond, tree_ptr t1, tree_ptr t2) { tree_ptr t = tree_new(eval_ternary); t->child = darray_new(); darray_append(t->child, cond); darray_append(t->child, t1); darray_append(t->child, t2); return t; } tree_ptr tree_new_id(const char* s) { tree_ptr t = tree_new(eval_id); t->id = pbc_strdup(s); return t; } tree_ptr tree_new_funcall(void) { tree_ptr t = tree_new(eval_funcall); t->child = darray_new(); return t; } static tree_ptr tree_new_fun(fun_ptr fun) { tree_ptr t = tree_new(eval_fun); t->fun = fun; return t; } void tree_set_fun(tree_ptr f, tree_ptr src) { darray_append(f->child, src); } void tree_append(tree_ptr f, tree_ptr p) { darray_append(f->child, p); } tree_ptr tree_new_binary(fun_ptr fun, tree_ptr x, tree_ptr y) { tree_ptr t = tree_new_funcall(); tree_append(t, x); tree_append(t, y); tree_set_fun(t, tree_new_fun(fun)); return t; } static tree_ptr tree_new_unary(fun_ptr fun, tree_ptr x) { tree_ptr t = tree_new_funcall(); tree_append(t, x); tree_set_fun(t, tree_new_fun(fun)); return t; } tree_ptr tree_new_neg(tree_ptr t) { return tree_new_unary(fun_neg, t); } tree_ptr tree_new_add(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_add, x, y); } tree_ptr tree_new_sub(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_sub, x, y); } tree_ptr tree_new_mul(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_mul, x, y); } tree_ptr tree_new_div(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_div, x, y); } tree_ptr tree_new_pow(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_pow, x, y); } tree_ptr tree_new_eq(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_eq, x, y); } tree_ptr tree_new_ne(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_ne, x, y); } tree_ptr tree_new_le(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_le, x, y); } tree_ptr tree_new_ge(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_ge, x, y); } tree_ptr tree_new_lt(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_lt, x, y); } tree_ptr tree_new_gt(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_gt, x, y); } static val_ptr run_item(val_ptr v[]) { mpz_t z; mpz_init(z); element_to_mpz(z, v[1]->elem); int i = mpz_get_si(z); mpz_clear(z); element_ptr a = element_item(v[0]->elem, i); element_ptr e = pbc_malloc(sizeof(*e)); element_init_same_as(e, a); element_set(e, a); return val_new_element(e); } static fun_t fun_item = {{ "item", run_item, 2, sig_elem_elem }}; tree_ptr tree_new_item(tree_ptr x, tree_ptr y) { return tree_new_binary(fun_item, x, y); } tree_ptr tree_new_assign(tree_ptr l, tree_ptr r) { // TODO: Check l's type. tree_ptr t = tree_new(eval_assign); t->child = darray_new(); darray_append(t->child, l); darray_append(t->child, r); return t; } // Evaluate statement. void tree_eval_stmt(tree_ptr stmt) { val_ptr v = tree_eval(stmt); if (v && v_error == v->type) { v->type->out_str(stdout, v); putchar('\n'); } else if (stmt->eval != eval_assign && v) { v->type->out_str(stdout, v); putchar('\n'); } } static val_ptr run_nextprime(val_ptr v[]) { element_ptr e = v[0]->elem; mpz_t z; mpz_init(z); element_to_mpz(z, e); mpz_nextprime(z, z); element_set_mpz(e, z); return v[0]; } static fun_t fun_nextprime = {{ "nextprime", run_nextprime, 1, sig_elem }}; static val_ptr run_order(val_ptr v[]) { field_ptr f = v[0]->field; element_ptr e = pbc_malloc(sizeof(*e)); element_init(e, M); element_set_mpz(e, f->order); return val_new_element(e); } static fun_t fun_ord = {{ "ord", run_order, 1, sig_field }}; static fun_t fun_order = {{ "order", run_order, 1, sig_field }}; static val_ptr run_random(val_ptr v[]) { element_ptr e = pbc_malloc(sizeof(*e)); element_init(e, v[0]->field); element_random(e); return val_new_element(e); } static fun_t fun_rnd = {{ "rnd", run_random, 1, sig_field }}; static fun_t fun_random = {{ "random", run_random, 1, sig_field }}; static val_ptr run_sqrt(val_ptr v[]) { // TODO: Check v[0] is square. element_sqrt(v[0]->elem, v[0]->elem); return v[0]; } static fun_t fun_sqrt = {{ "sqrt", run_sqrt, 1, sig_elem }}; static val_ptr run_invert(val_ptr v[]) { // TODO: Check v[0] is invertible. element_invert(v[0]->elem, v[0]->elem); return v[0]; } static fun_t fun_inv = {{ "inv", run_invert, 1, sig_elem }}; static val_ptr run_type(val_ptr v[]) { puts(v[0]->type->name); return v[0]; } static fun_t fun_type = {{ "type", run_type, 1, sig_any }}; static val_ptr run_pairing(val_ptr v[]) { element_ptr x = v[0]->elem; element_ptr e = element_new(x->field->pairing->GT); element_pairing(e, x, v[1]->elem); return val_new_element(e); } static fun_t fun_pairing = {{ "pairing", run_pairing, 2, sig_elem_elem }}; static val_ptr run_zmod(val_ptr v[]) { element_ptr e = v[0]->elem; mpz_t z; mpz_init(z); element_to_mpz(z, e); field_ptr f = pbc_malloc(sizeof(*f)); field_init_fp(f, z); mpz_clear(z); return val_new_field(f); } static fun_t fun_zmod = {{ "zmod", run_zmod, 1, sig_elem }}; static val_ptr run_poly(val_ptr v[]) { field_ptr f = pbc_malloc(sizeof(*f)); field_init_poly(f, v[0]->field); return val_new_field(f); } static fun_t fun_poly = {{ "poly", run_poly, 1, sig_field }}; static val_ptr run_polymod(val_ptr v[]) { // TODO: Check v[0] is a poly. field_ptr f = pbc_malloc(sizeof(*f)); field_init_polymod(f, v[0]->elem); return val_new_field(f); } static fun_t fun_polymod = {{ "polymod", run_polymod, 1, sig_elem }}; static val_ptr run_extend(val_ptr v[]) { // TODO: Check v[1] is multiz poly. field_ptr fx = pbc_malloc(sizeof(*fx)); field_init_poly(fx, v[0]->field); element_ptr poly = element_new(fx); element_set_multiz(poly, v[1]->elem->data); field_ptr f = pbc_malloc(sizeof(*f)); field_init_polymod(f, poly); element_free(poly); return val_new_field(f); } static fun_t fun_extend = {{ "extend", run_extend, 1, sig_field_elem }}; static void init_pairing(const char *s) { pairing_init_set_str(pairing, s); assign_field(pairing->G1, "G1"); assign_field(pairing->G2, "G2"); assign_field(pairing->GT, "GT"); assign_field(pairing->Zr, "Zr"); } static val_ptr run_exit(val_ptr v[]) { mpz_t z; mpz_init(z); element_to_mpz(z, v[0]->elem); exit(mpz_get_si(z)); } static fun_t fun_exit = {{ "exit", run_exit, 1, sig_elem }}; static val_ptr run_CHECK(val_ptr v[]) { if (element_is0(v[0]->elem)) { pbc_die("CHECK failed"); } return v[0]; } static fun_t fun_CHECK = {{ "CHECK", run_CHECK, 1, sig_elem }}; static char *aparam = "type a\n" "q 8780710799663312522437781984754049815806883199414208211028653399266475630880222957078625179422662221423155858769582317459277713367317481324925129998224791\n" "h 12016012264891146079388821366740534204802954401251311822919615131047207289359704531102844802183906537786776\n" "r 730750818665451621361119245571504901405976559617\n" "exp2 159\n" "exp1 107\n" "sign1 1\n" "sign0 1\n"; static char *dparam = "type d\n" "q 625852803282871856053922297323874661378036491717\n" "n 625852803282871856053923088432465995634661283063\n" "h 3\n" "r 208617601094290618684641029477488665211553761021\n" "a 581595782028432961150765424293919699975513269268\n" "b 517921465817243828776542439081147840953753552322\n" "k 6\n" "nk 60094290356408407130984161127310078516360031868417968262992864809623507269833854678414046779817844853757026858774966331434198257512457993293271849043664655146443229029069463392046837830267994222789160047337432075266619082657640364986415435746294498140589844832666082434658532589211525696\n" "hk 1380801711862212484403205699005242141541629761433899149236405232528956996854655261075303661691995273080620762287276051361446528504633283152278831183711301329765591450680250000592437612973269056\n" "coeff0 472731500571015189154958232321864199355792223347\n" "coeff1 352243926696145937581894994871017455453604730246\n" "coeff2 289113341693870057212775990719504267185772707305\n" "nqr 431211441436589568382088865288592347194866189652\n"; static char *eparam = "type e\n" "q 7245986106510086080714203333362098431608853335867425877960916928496629182991629664903654100214900946450053872786629995869445693724001299041657434948257845644905153122838458864000479326695430719258600053239930483226650953770354174712511646273516974069245462534034085895319225452125649979474047163305307830001\n" "r 730750862221594424981965739670091261094297337857\n" "h 13569343110918781839835249021482970252603216587988030044836106948825516930173270978617489032334001006615524543925753725725046733884363846960470444404747241287743773746682188521738728797153760275116924829183670000\n" "a 7130970454025799000067946137594446075551569949583815943390108723282396973737794273397246892274981883807989525599540630855644968426794929215599380425269625872763801485968007136000471718335185787206876242871042697778608875139078711621836858237429403052273312335081163896980825048123655535355411494046493419999\n" "b 7169309004853894693616698536183663527570664411678352588247044791687141043489072737232715961588288238022010974661903752526911876859197052490952065266265699130144252031591491045333807587788600764557450846327338626261289568016170532652061787582791926724597362401398804563093625182790987016728290050466098223333\n" "exp2 159\n" "exp1 135\n" "sign1 1\n" "sign0 1\n"; static char *fparam = "type f\n" "q 205523667896953300194896352429254920972540065223\n" "r 205523667896953300194895899082072403858390252929\n" "b 40218105156867728698573668525883168222119515413\n" "beta 115334401956802802075595682801335644058796914268\n" "alpha0 191079354656274778837764015557338301375963168470\n" "alpha1 71445317903696340296199556072836940741717506375\n"; static char *gparam = "type g\n" "q 503189899097385532598615948567975432740967203\n" "n 503189899097385532598571084778608176410973351\n" "h 1\n" "r 503189899097385532598571084778608176410973351\n" "a 465197998498440909244782433627180757481058321\n" "b 463074517126110479409374670871346701448503064\n" "k 10\n" "nk 1040684643531490707494989587381629956832530311976146077888095795458709511789670022388326295177424065807612879371896982185473788988016190582073591316127396374860265835641044035656044524481121528846249501655527462202999638159773731830375673076317719519977183373353791119388388468745670818193868532404392452816602538968163226713846951514831917487400267590451867746120591750902040267826351982737642689423713163967384383105678367875981348397359466338807\n" "hk 4110127713690841149713310614420858884651261781185442551927080083178682965171097172366598236129731931693425629387502221804555636704708008882811353539555915064049685663790355716130262332064327767695339422323460458479884756000782939428852120522712008037615051139080628734566850259704397643028017435446110322024094259858170303605703280329322675124728639532674407\n" "coeff0 67343110967802947677845897216565803152319250\n" "coeff1 115936772834120270862756636148166314916823221\n" "coeff2 87387877425076080433559927080662339215696505\n" "coeff3 433223145899090928132052677121692683015058909\n" "coeff4 405367866213598664862417230702935310328613596\n" "nqr 22204504160560785687198080413579021865783099\n"; static char *iparam = "type i\n" "m 97\n" "t 12\n" "n 2726865189058261010774960798134976187171462721\n" "n2 7\n"; static val_ptr run_init_pairing_a(val_ptr v[]) { UNUSED_VAR(v); init_pairing(aparam); return NULL; } static fun_t fun_init_pairing_a = {{ "init_pairing_a", run_init_pairing_a, 0, NULL }}; static val_ptr run_init_pairing_d(val_ptr v[]) { UNUSED_VAR(v); init_pairing(dparam); return NULL; } static fun_t fun_init_pairing_d = {{ "init_pairing_d", run_init_pairing_d, 0, NULL }}; static val_ptr run_init_pairing_e(val_ptr v[]) { UNUSED_VAR(v); init_pairing(eparam); return NULL; } static fun_t fun_init_pairing_e = {{ "init_pairing_e", run_init_pairing_e, 0, NULL }}; static val_ptr run_init_pairing_f(val_ptr v[]) { UNUSED_VAR(v); init_pairing(fparam); return NULL; } static fun_t fun_init_pairing_f = {{ "init_pairing_f", run_init_pairing_f, 0, NULL }}; static val_ptr run_init_pairing_g(val_ptr v[]) { UNUSED_VAR(v); init_pairing(gparam); return NULL; } static fun_t fun_init_pairing_g = {{ "init_pairing_g", run_init_pairing_g, 0, NULL }}; static val_ptr run_init_pairing_i(val_ptr v[]) { UNUSED_VAR(v); init_pairing(iparam); return NULL; } static fun_t fun_init_pairing_i = {{ "init_pairing_i", run_init_pairing_i, 0, NULL }}; static void builtin(fun_ptr fun) { symtab_put(reserved, val_new_fun(fun), fun->name); } int end_of_input; int yywrap_return1(void) { return 1; } int yywrap_readline(void) { static char *currentline; static YY_BUFFER_STATE st; yy_delete_buffer(st); free(currentline); currentline = pbc_getline(option_prompt); if (!currentline) { end_of_input = 1; return 1; } int n = strlen(currentline); currentline = realloc(currentline, n + 2); currentline[n] = '\n'; currentline[n + 1] = '\0'; st = yy_scan_string(currentline); //if (option_echo) puts(currentline); return 0; } static int (*yywrapfun)(void); int yywrap(void) { return yywrapfun(); } int main(int argc, char **argv) { for (;;) { int c = getopt(argc, argv, "y"); if (c == -1) break; switch (c) { case 'y': option_easy = 1; option_prompt = "> "; break; default: fprintf(stderr, "unrecognized option: %c\n", c); break; } } field_init_z(Z); field_init_multiz(M); symtab_init(tab); builtin(fun_rnd); builtin(fun_random); builtin(fun_ord); builtin(fun_order); builtin(fun_nextprime); builtin(fun_sqrt); builtin(fun_inv); builtin(fun_type); builtin(fun_pairing); builtin(fun_zmod); builtin(fun_poly); builtin(fun_polymod); builtin(fun_extend); builtin(fun_exit); builtin(fun_CHECK); builtin(fun_init_pairing_a); builtin(fun_init_pairing_d); builtin(fun_init_pairing_e); builtin(fun_init_pairing_f); builtin(fun_init_pairing_g); builtin(fun_init_pairing_i); run_init_pairing_a(NULL); symtab_put(reserved, val_new_field(M), "M"); symtab_put(reserved, val_new_field(Z), "Z"); if (argc > optind) { FILE *fp = fopen(argv[optind], "r"); if (!fp) pbc_die("fopen failed on %s", argv[optind]); YY_BUFFER_STATE st = yy_create_buffer(fp, YY_BUF_SIZE); yy_switch_to_buffer(st); yywrapfun = yywrap_return1; yyparse(); yy_delete_buffer(st); } else { yywrapfun = yywrap_readline; yywrap(); while (!end_of_input) { if (2 == yyparse()) pbc_die("parser out of memory"); } putchar('\n'); } symtab_clear(tab); field_clear(M); return 0; }