/* This file is part of tgl-libary/generate Tgl-library/generate is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 2 of the License, or (at your option) any later version. Tgl-library/generate is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this tgl-library/generate. If not, see . Copyright Vitaly Valtman 2014 It is derivative work of VK/KittenPHP-DB-Engine (https://github.com/vk-com/kphp-kdb/) Copyright 2012-2013 Vkontakte Ltd 2012-2013 Vitaliy Valtman */ #include #include #include #include #include #include #include #include #include #include #include "tl-tl.h" #include "generate.h" #include "tree.h" #include "config.h" int header; #define tl_type_name_cmp(a,b) (a->name > b->name ? 1 : a->name < b->name ? -1 : 0) DEFINE_TREE (tl_type, struct tl_type *, tl_type_name_cmp, 0) DEFINE_TREE (tl_combinator, struct tl_combinator *, tl_type_name_cmp, 0) struct tree_tl_type *type_tree; struct tree_tl_combinator *function_tree; void tl_function_insert_by_name (struct tl_combinator *c) { function_tree = tree_insert_tl_combinator (function_tree, c, lrand48 ()); } struct tl_type *tl_type_get_by_name (int name) { static struct tl_type t; t.name = name; return tree_lookup_tl_type (type_tree, &t); } void tl_type_insert_by_name (struct tl_type *t) { type_tree = tree_insert_tl_type (type_tree, t, lrand48 ()); } static char buf[1 << 20]; int buf_size; int *buf_ptr = (int *)buf; int *buf_end; int verbosity; int get_int (void) { assert (buf_ptr < buf_end); return *(buf_ptr ++); } long long get_long (void) { assert (buf_ptr + 1 < buf_end); long long r = *(long long *)buf_ptr; buf_ptr += 2; return r; } static void *malloc0 (int size) { void *r = malloc (size); memset (r, 0, size); return r; } char *get_string (void) { int l = *(unsigned char *)buf_ptr; assert (l != 0xff); char *res; int tlen = 0; if (l == 0xfe) { l = ((unsigned)get_int ()) >> 8; res = (char *)buf_ptr; tlen = l; } else { res = ((char *)buf_ptr) + 1; tlen = 1 + l; } int len = l; tlen += ((-tlen) & 3); assert (!(tlen & 3)); buf_ptr += tlen / 4; assert (buf_ptr <= buf_end); return strndup (res, len); } int tn, fn, cn; struct tl_type **tps; struct tl_combinator **fns; struct tl_tree *read_tree (int *var_num); struct tl_tree *read_nat_expr (int *var_num); struct tl_tree *read_type_expr (int *var_num); int read_args_list (struct arg **args, int args_num, int *var_num); #define use_var_nat_full_form(x) 0 void *int_to_var_nat_const_init (long long x) { if (use_var_nat_full_form (x)) { struct tl_tree_nat_const *T = malloc (sizeof (*T)); T->self.flags = 0; T->self.methods = &tl_pnat_const_full_methods; T->value = x; return T; } else { return (void *)(long)(x * 2 - 0x80000001l); } } long long var_nat_const_to_int (void *x) { if (((long)x) & 1) { return (((long)x) + 0x80000001l) / 2; } else { return ((struct tl_tree_nat_const *)x)->value; } } int tl_tree_type_type (struct tl_tree *x) { return NODE_TYPE_TYPE; } int tl_tree_type_array (struct tl_tree *x) { return NODE_TYPE_ARRAY; } int tl_tree_type_nat_const (struct tl_tree *x) { return NODE_TYPE_NAT_CONST; } int tl_tree_type_var_num (struct tl_tree *x) { return NODE_TYPE_VAR_NUM; } int tl_tree_type_var_type (struct tl_tree *x) { return NODE_TYPE_VAR_TYPE; } struct tl_tree_methods tl_var_num_methods = { .type = tl_tree_type_var_num }; struct tl_tree_methods tl_var_type_methods = { .type = tl_tree_type_var_type }; struct tl_tree_methods tl_type_methods = { .type = tl_tree_type_type }; struct tl_tree_methods tl_nat_const_methods = { .type = tl_tree_type_nat_const }; struct tl_tree_methods tl_array_methods = { .type = tl_tree_type_array }; struct tl_tree_methods tl_ptype_methods = { .type = tl_tree_type_type }; struct tl_tree_methods tl_parray_methods = { .type = tl_tree_type_array }; struct tl_tree_methods tl_pvar_num_methods = { .type = tl_tree_type_var_num }; struct tl_tree_methods tl_pvar_type_methods = { .type = tl_tree_type_var_type }; struct tl_tree_methods tl_nat_const_full_methods = { .type = tl_tree_type_nat_const }; struct tl_tree_methods tl_pnat_const_full_methods = { .type = tl_tree_type_nat_const }; struct tl_tree *read_num_const (int *var_num) { return (void *)int_to_var_nat_const_init (get_int ()); } int gen_uni (struct tl_tree *t, char *cur_name, int *vars, int first) { assert (t); int x = TL_TREE_METHODS (t)->type (t); int l = 0; int i; int j; struct tl_tree_type *t1; struct tl_tree_array *t2; int y; int L = strlen (cur_name); switch (x) { case NODE_TYPE_TYPE: t1 = (void *)t; if (!first) { printf (" if (ODDP(%s) || %s->type->name != 0x%08x) { return -1; }\n", cur_name, cur_name, t1->type->name); } else { printf (" if (ODDP(%s) || (%s->type->name != 0x%08x && %s->type->name != 0x%08x)) { return -1; }\n", cur_name, cur_name, t1->type->name, cur_name, ~t1->type->name); } for (i = 0; i < t1->children_num; i++) { sprintf (cur_name + L, "->params[%d]", i); gen_uni (t1->children[i], cur_name, vars, 0); cur_name[L] = 0; } return 0; case NODE_TYPE_NAT_CONST: printf (" if (EVENP(%s) || ((long)%s) != %lld) { return -1; }\n", cur_name, cur_name, var_nat_const_to_int (t) * 2 + 1); return 0; case NODE_TYPE_ARRAY: printf (" if (ODDP(%s) || %s->type->name != TL_TYPE_ARRAY) { return -1; }\n", cur_name, cur_name); t2 = (void *)t; sprintf (cur_name + L, "->params[0]"); y = gen_uni (t2->multiplicity, cur_name, vars, 0); cur_name[L] = 0; sprintf (cur_name + L, "->params[1]"); y += gen_uni (t2->args[0]->type, cur_name, vars, 0); cur_name[L] = 0; return 0; case NODE_TYPE_VAR_TYPE: printf (" if (ODDP(%s)) { return -1; }\n", cur_name); i = ((struct tl_tree_var_type *)t)->var_num; if (!vars[i]) { printf (" struct paramed_type *var%d = %s; assert (var%d);\n", i, cur_name, i); vars[i] = 1; } else if (vars[i] == 1) { printf (" if (compare_types (var%d, %s) < 0) { return -1; }\n", i, cur_name); } else { assert (0); return -1; } return l; case NODE_TYPE_VAR_NUM: printf (" if (EVENP(%s)) { return -1; }\n", cur_name); i = ((struct tl_tree_var_num *)t)->var_num; j = ((struct tl_tree_var_num *)t)->dif; if (!vars[i]) { printf (" struct paramed_type *var%d = ((void *)%s) + %d; assert (var%d);\n", i, cur_name, 2 * j, i); vars[i] = 2; } else if (vars[i] == 2) { printf (" if (var%d != ((void *)%s) + %d) { return -1; }\n", i, cur_name, 2 * j); } else { assert (0); return -1; } return 0; default: assert (0); return -1; } } void print_offset (int len) { int i; for (i = 0; i < len; i++) { printf (" "); } } int gen_create (struct tl_tree *t, int *vars, int offset) { int x = TL_TREE_METHODS (t)->type (t); int i; struct tl_tree_type *t1; struct tl_tree_array *t2; switch (x) { case NODE_TYPE_TYPE: print_offset (offset); printf ("&(struct paramed_type){\n"); print_offset (offset + 2); t1 = (void *)t; if (t1->self.flags & FLAG_BARE) { printf (".type = &(struct tl_type) {.name = 0x%08x, .id = \"Bare_%s\"},\n", ~t1->type->name, t1->type->id); } else { printf (".type = &(struct tl_type) {.name = 0x%08x, .id = \"%s\"},\n", t1->type->name, t1->type->id); } if (t1->children_num) { print_offset (offset + 2); printf (".params = (struct paramed_type *[]){\n"); for (i = 0; i < t1->children_num; i++) { assert (gen_create (t1->children[i], vars, offset + 4) >= 0); printf (",\n"); } print_offset (offset + 2); printf ("}\n"); } else { print_offset (offset + 2); printf (".params = 0,\n"); } print_offset (offset); printf ("}"); return 0; case NODE_TYPE_NAT_CONST: print_offset (offset); printf ("INT2PTR (%d)", (int)var_nat_const_to_int (t)); return 0; case NODE_TYPE_ARRAY: print_offset (offset); printf ("&(struct paramed_type){\n"); print_offset (offset + 2); t2 = (void *)t; printf (".type = &(struct tl_type) {.name = NAME_ARRAY, .id = \"array\"},\n"); print_offset (offset + 2); printf (".params = (struct paramed_type **){\n"); gen_create (t2->multiplicity, vars, offset + 4); printf (",\n"); gen_create (t2->args[0]->type, vars, offset + 4); printf (",\n"); print_offset (offset + 2); printf ("}\n"); print_offset (offset); printf ("}"); return 0; case NODE_TYPE_VAR_TYPE: print_offset (offset); printf ("var%d", ((struct tl_tree_var_type *)t)->var_num); return 0; case NODE_TYPE_VAR_NUM: print_offset (offset); printf ("((void *)var%d) + %d", ((struct tl_tree_var_type *)t)->var_num, 2 * ((struct tl_tree_var_num *)t)->dif); return 0; default: assert (0); return -1; } } int gen_field_fetch (struct arg *arg, int *vars, int num) { assert (arg); char *offset = " "; int o = 0; if (arg->exist_var_num >= 0) { printf (" if (PTR2INT (var%d) & (1 << %d)) {\n", arg->exist_var_num, arg->exist_var_bit); offset = " "; o = 2; } if (arg->var_num >= 0) { assert (TL_TREE_METHODS (arg->type)->type (arg->type) == NODE_TYPE_TYPE); int t = ((struct tl_tree_type *)arg->type)->type->name; if (t == NAME_VAR_TYPE) { fprintf (stderr, "Not supported yet\n"); assert (0); } else { assert (t == NAME_VAR_NUM); if (vars[arg->var_num] == 0) { printf ("%sstruct paramed_type *var%d = INT2PTR (*in_ptr);\n", offset, arg->var_num); printf ("%sif (skip_int () < 0) { return -1;}\n", offset); vars[arg->var_num] = 2; } else if (vars[arg->var_num] == 2) { printf ("%sif (vars%d != INT2PTR (*in_ptr)) { return -1; }\n", offset, arg->var_num); printf ("%sif (skip_int () < 0) { return -1;}\n", offset); } else { assert (0); return -1; } } } else { int t = TL_TREE_METHODS (arg->type)->type (arg->type); if (t == NODE_TYPE_TYPE || t == NODE_TYPE_VAR_TYPE) { printf ("%sstruct paramed_type *field%d = \n", offset, num); assert (gen_create (arg->type, vars, 2 + o) >= 0); printf (";\n"); int bare = arg->flags & FLAG_BARE; if (!bare && t == NODE_TYPE_TYPE) { bare = ((struct tl_tree_type *)arg->type)->self.flags & FLAG_BARE; } if (!bare) { printf ("%sif (skip_type_%s (field%d) < 0) { return -1;}\n", offset, t == NODE_TYPE_VAR_TYPE ? "any" : ((struct tl_tree_type *)arg->type)->type->print_id, num); } else { printf ("%sif (skip_type_bare_%s (field%d) < 0) { return -1;}\n", offset, t == NODE_TYPE_VAR_TYPE ? "any" : ((struct tl_tree_type *)arg->type)->type->print_id, num); } } else { assert (t == NODE_TYPE_ARRAY); printf ("%sint multiplicity%d = PTR2INT (\n", offset, num); assert (gen_create (((struct tl_tree_array *)arg->type)->multiplicity, vars, 2 + o) >= 0); printf ("%s);\n", offset); printf ("%sstruct paramed_type *field%d = \n", offset, num); assert (gen_create (((struct tl_tree_array *)arg->type)->args[0]->type, vars, 2 + o) >= 0); printf (";\n"); printf ("%swhile (multiplicity%d -- > 0) {\n", offset, num); printf ("%s if (skip_type_%s (field%d) < 0) { return -1;}\n", offset, "any", num); printf ("%s}\n", offset); } } if (arg->exist_var_num >= 0) { printf (" }\n"); } return 0; } void gen_constructor_fetch (struct tl_combinator *c) { printf ("int skip_constructor_%s (struct paramed_type *T) {\n", c->print_id); static char s[10000]; sprintf (s, "T"); int *vars = malloc0 (c->var_num * 4);; gen_uni (c->result, s, vars, 1); if (c->name == NAME_INT) { printf (" if (skip_int () < 0) { return -1; }\n"); printf (" return 0;\n"); printf ("}\n"); return; } else if (c->name == NAME_LONG) { printf (" if (skip_long () < 0) { return -1; }\n"); printf (" return 0;\n"); printf ("}\n"); return; } else if (c->name == NAME_STRING) { printf (" if (skip_string () < 0) { return -1; }\n"); printf (" return 0;\n"); printf ("}\n"); return; } else if (c->name == NAME_DOUBLE) { printf (" if (skip_double () < 0) { return -1; }\n"); printf (" return 0;\n"); printf ("}\n"); return; } int i; for (i = 0; i < c->args_num; i++) if (!(c->args[i]->flags & FLAG_OPT_VAR)) { assert (gen_field_fetch (c->args[i], vars, i + 1) >= 0); } free (vars); printf (" return 0;\n"); printf ("}\n"); } void gen_type_fetch (struct tl_type *t) { printf ("int skip_type_%s (struct paramed_type *T) {\n", t->print_id); printf (" int magic = *in_ptr;\n"); printf (" if (skip_int () < 0) { return -1; }\n"); printf (" switch (magic) {\n"); int i; for (i = 0; i < t->constructors_num; i++) { printf (" case 0x%08x: return skip_constructor_%s (T);\n", t->constructors[i]->name, t->constructors[i]->print_id); } printf (" default: return -1;\n"); printf (" }\n"); printf ("}\n"); printf ("int skip_type_bare_%s (struct paramed_type *T) {\n", t->print_id); printf (" int *save = in_ptr;\n"); for (i = 0; i < t->constructors_num; i++) { printf (" if (skip_constructor_%s (T) >= 0) { return 0; }\n", t->constructors[i]->print_id); printf (" in_ptr = save;\n"); } printf (" return -1;\n"); printf ("}\n"); } struct tl_tree *read_num_var (int *var_num) { struct tl_tree_var_num *T = malloc0 (sizeof (*T)); T->self.flags = 0; T->self.methods = &tl_pvar_num_methods;; T->dif = get_int (); T->var_num = get_int (); if (T->var_num >= *var_num) { *var_num = T->var_num + 1; } assert (!(T->self.flags & FLAG_NOVAR)); return (void *)T; } struct tl_tree *read_type_var (int *var_num) { struct tl_tree_var_type *T = malloc0 (sizeof (*T)); T->self.methods = &tl_pvar_type_methods; T->var_num = get_int (); T->self.flags = get_int (); if (T->var_num >= *var_num) { *var_num = T->var_num + 1; } assert (!(T->self.flags & (FLAG_NOVAR | FLAG_BARE))); return (void *)T; } struct tl_tree *read_array (int *var_num) { struct tl_tree_array *T = malloc0 (sizeof (*T)); T->self.methods = &tl_parray_methods; T->self.flags = 0; T->multiplicity = read_nat_expr (var_num); assert (T->multiplicity); T->args_num = get_int (); assert (T->args_num >= 0 && T->args_num <= 1000); T->args = malloc0 (sizeof (void *) * T->args_num); assert (read_args_list (T->args, T->args_num, var_num) >= 0); T->self.flags |= FLAG_NOVAR; int i; for (i = 0; i < T->args_num; i++) { if (!(T->args[i]->flags & FLAG_NOVAR)) { T->self.flags &= ~FLAG_NOVAR; } } return (void *)T; } struct tl_tree *read_type (int *var_num) { struct tl_tree_type *T = malloc0 (sizeof (*T)); T->self.methods = &tl_ptype_methods; T->type = tl_type_get_by_name (get_int ()); assert (T->type); T->self.flags = get_int (); T->children_num = get_int (); assert (T->type->arity == T->children_num); T->children = malloc0 (sizeof (void *) * T->children_num); int i; T->self.flags |= FLAG_NOVAR; for (i = 0; i < T->children_num; i++) { int t = get_int (); if (t == (int)TLS_EXPR_NAT) { assert ((T->type->params_types & (1 << i))); T->children[i] = read_nat_expr (var_num); } else if (t == (int)TLS_EXPR_TYPE) { assert (!(T->type->params_types & (1 << i))); T->children[i] = read_type_expr (var_num); } else { assert (0); } if (!TL_IS_NAT_VAR (T->children[i]) && !(T->children[i]->flags & FLAG_NOVAR)) { T->self.flags &= ~FLAG_NOVAR; } } return (void *)T; } struct tl_tree *read_tree (int *var_num) { int x = get_int (); if (verbosity >= 2) { fprintf (stderr, "read_tree: constructor = 0x%08x\n", x); } switch (x) { case TLS_TREE_NAT_CONST: return read_num_const (var_num); case TLS_TREE_NAT_VAR: return read_num_var (var_num); case TLS_TREE_TYPE_VAR: return read_type_var (var_num); case TLS_TREE_TYPE: return read_type (var_num); case TLS_TREE_ARRAY: return read_array (var_num); default: if (verbosity) { fprintf (stderr, "x = %d\n", x); } assert (0); return 0; } } struct tl_tree *read_type_expr (int *var_num) { int x = get_int (); if (verbosity >= 2) { fprintf (stderr, "read_type_expr: constructor = 0x%08x\n", x); } switch (x) { case TLS_TYPE_VAR: return read_type_var (var_num); case TLS_TYPE_EXPR: return read_type (var_num); case TLS_ARRAY: return read_array (var_num); default: if (verbosity) { fprintf (stderr, "x = %d\n", x); } assert (0); return 0; } } struct tl_tree *read_nat_expr (int *var_num) { int x = get_int (); if (verbosity >= 2) { fprintf (stderr, "read_nat_expr: constructor = 0x%08x\n", x); } switch (x) { case TLS_NAT_CONST: return read_num_const (var_num); case TLS_NAT_VAR: return read_num_var (var_num); default: if (verbosity) { fprintf (stderr, "x = %d\n", x); } assert (0); return 0; } } struct tl_tree *read_expr (int *var_num) { int x = get_int (); if (verbosity >= 2) { fprintf (stderr, "read_nat_expr: constructor = 0x%08x\n", x); } switch (x) { case TLS_EXPR_NAT: return read_nat_expr (var_num); case TLS_EXPR_TYPE: return read_type_expr (var_num); default: if (verbosity) { fprintf (stderr, "x = %d\n", x); } assert (0); return 0; } } int read_args_list (struct arg **args, int args_num, int *var_num) { int i; for (i = 0; i < args_num; i++) { args[i] = malloc0 (sizeof (struct arg)); args[i]->exist_var_num = -1; args[i]->exist_var_bit = 0; assert (get_int () == TLS_ARG_V2); args[i]->id = get_string (); args[i]->flags = get_int (); if (args[i]->flags & 2) { args[i]->flags &= ~2; args[i]->flags |= (1 << 20); } if (args[i]->flags & 4) { args[i]->flags &= ~4; args[i]->var_num = get_int (); } else { args[i]->var_num = -1; } if (args[i]->var_num >= *var_num) { *var_num = args[i]->var_num + 1; } if (args[i]->flags & FLAG_OPT_FIELD) { args[i]->exist_var_num = get_int (); args[i]->exist_var_bit = get_int (); } args[i]->type = read_type_expr (var_num); assert (args[i]->type); if (args[i]->var_num < 0 && args[i]->exist_var_num < 0 && (TL_IS_NAT_VAR(args[i]->type) || (args[i]->type->flags & FLAG_NOVAR))) { args[i]->flags |= FLAG_NOVAR; } } return 1; } int read_combinator_args_list (struct tl_combinator *c) { c->args_num = get_int (); if (verbosity >= 2) { fprintf (stderr, "c->id = %s, c->args_num = %d\n", c->id, c->args_num); } assert (c->args_num >= 0 && c->args_num <= 1000); c->args = malloc0 (sizeof (void *) * c->args_num); c->var_num = 0; return read_args_list (c->args, c->args_num, &c->var_num); } int read_combinator_right (struct tl_combinator *c) { assert (get_int () == TLS_COMBINATOR_RIGHT_V2); c->result = read_type_expr (&c->var_num); assert (c->result); return 1; } int read_combinator_left (struct tl_combinator *c) { int x = get_int (); if (x == (int)TLS_COMBINATOR_LEFT_BUILTIN) { c->args_num = 0; c->var_num = 0; c->args = 0; return 1; } else if (x == TLS_COMBINATOR_LEFT) { return read_combinator_args_list (c); } else { assert (0); return -1; } } char *gen_print_id (const char *id) { static char s[1000]; char *ptr = s; int first = 1; while (*id) { if (*id == '.') { *(ptr ++) = '_'; } else if (*id >= 'A' && *id <= 'Z') { if (!first && *(ptr - 1) != '_') { *(ptr ++) = '_'; } *(ptr ++) = *id - 'A' + 'a'; } else { *(ptr ++) = *id; } id ++; first = 0; } *ptr = 0; return s; } struct tl_combinator *read_combinators (int v) { struct tl_combinator *c = malloc0 (sizeof (*c)); c->name = get_int (); c->id = get_string (); c->print_id = strdup (gen_print_id (c->id)); //char *s = c->id; //while (*s) { if (*s == '.') { *s = '_'; } ; s ++;} int x = get_int (); struct tl_type *t = tl_type_get_by_name (x); assert (t || (!x && v == 3)); if (v == 2) { assert (t->extra < t->constructors_num); t->constructors[t->extra ++] = c; c->is_fun = 0; } else { assert (v == 3); tl_function_insert_by_name (c); c->is_fun = 1; } assert (read_combinator_left (c) >= 0); assert (read_combinator_right (c) >= 0); return c; } struct tl_type *read_types (void) { struct tl_type *t = malloc0 (sizeof (*t)); t->name = get_int (); t->id = get_string (); t->print_id = strdup (gen_print_id (t->id)); t->constructors_num = get_int (); assert (t->constructors_num >= 0 && t->constructors_num <= 1000); t->constructors = malloc0 (sizeof (void *) * t->constructors_num); t->flags = get_int (); t->arity = get_int (); t->params_types = get_long (); // params_types t->extra = 0; tl_type_insert_by_name (t); return t; } int parse_tlo_file (void) { buf_end = buf_ptr + (buf_size / 4); assert (get_int () == TLS_SCHEMA_V2); get_int (); // version get_int (); // date tn = 0; fn = 0; cn = 0; int i; tn = get_int (); assert (tn >= 0 && tn < 10000); tps = malloc0 (sizeof (void *) * tn); if (verbosity >= 2) { fprintf (stderr, "Found %d types\n", tn); } for (i = 0; i < tn; i++) { assert (get_int () == TLS_TYPE); tps[i] = read_types (); assert (tps[i]); } cn = get_int (); assert (cn >= 0); if (verbosity >= 2) { fprintf (stderr, "Found %d constructors\n", cn); } for (i = 0; i < cn; i++) { assert (get_int () == TLS_COMBINATOR); assert (read_combinators (2)); } fn = get_int (); assert (fn >= 0 && fn < 10000); fns = malloc0 (sizeof (void *) * fn); if (verbosity >= 2) { fprintf (stderr, "Found %d functions\n", fn); } for (i = 0; i < fn; i++) { assert (get_int () == TLS_COMBINATOR); fns[i] = read_combinators (3); assert (fns[i]); } assert (buf_ptr == buf_end); /* static void *IP[10000]; if (gen_function_fetch (IP, 100) < 0) { return -2; } for (i = 0; i < tn; i++) { if (tps[i]->extra < tps[i]->constructors_num) { tl_config_back (); return -1; } } int j; for (i = 0; i < tn; i++) { for (j = 0; j < tps[i]->constructors_num; j ++) { if (gen_constructor_store (tps[i]->constructors[j], IP, 10000) < 0) { return -2; } if (gen_constructor_fetch (tps[i]->constructors[j], IP, 10000) < 0) { return -2; } } } for (i = 0; i < fn; i++) { if (gen_function_store (fns[i], IP, 10000) < 0) { return -2; } } if (tl_config_name) { ADD_PFREE (strlen (tl_config_name)); zzstrfree (tl_config_name); } tl_config_name = 0; config_crc64 = new_crc64; tl_config_version = new_tl_config_version ; tl_config_date = new_tl_config_date; int i; int types_num = get_int (); for (i = 0; i < types_num; i++) { if (parse_type () < 0) { return -1; } }*/ int j; for (i = 0; i < tn; i++) if (tps[i]->id[0] != '#' && strcmp (tps[i]->id, "Type")) { tps[i]->name = 0; for (j = 0; j < tps[i]->constructors_num; j ++) { tps[i]->name ^= tps[i]->constructors[j]->name; } } if (!header) { printf ("#include \"auto.h\"\n"); printf ("#include \n"); printf ("extern int *tgl_in_ptr, *tgl_in_end;\n"); printf ("#define in_ptr tgl_in_ptr\n"); printf ("#define in_end tgl_in_end\n"); printf ("#include \"auto-static.c\"\n"); for (i = 0; i < tn; i++) { for (j = 0; j < tps[i]->constructors_num; j ++) { gen_constructor_fetch (tps[i]->constructors[j]); } } for (i = 0; i < tn; i++) if (tps[i]->id[0] != '#' && strcmp (tps[i]->id, "Type")) { gen_type_fetch (tps[i]); } /*for (i = 0; i < tn; i++) if (tps[i]->id[0] != '#') { printf ("struct tl_type tl_type_%s = {\n", tps[i]->id); printf (" .name = 0x%08x,\n", tps[i]->name); printf (" .id = \"%s\"\n", tps[i]->id); printf ("};\n"); }*/ printf ("int skip_type_any (struct paramed_type *T) {\n"); printf (" switch (T->type->name) {\n"); for (i = 0; i < tn; i++) if (tps[i]->id[0] != '#' && strcmp (tps[i]->id, "Type")) { printf (" case 0x%08x: return skip_type_%s (T);\n", tps[i]->name, tps[i]->print_id); printf (" case 0x%08x: return skip_type_bare_%s (T);\n", ~tps[i]->name, tps[i]->print_id); } printf (" default: return -1; }\n"); printf ("}\n"); } else { for (i = 0; i < tn; i++) { for (j = 0; j < tps[i]->constructors_num; j ++) { printf ("int skip_constructor_%s (struct paramed_type *T);\n", tps[i]->constructors[j]->print_id); } } for (i = 0; i < tn; i++) if (tps[i]->id[0] != '#' && strcmp (tps[i]->id, "Type")) { printf ("int skip_type_%s (struct paramed_type *T);\n", tps[i]->print_id); printf ("int skip_type_bare_%s (struct paramed_type *T);\n", tps[i]->print_id); } printf ("int skip_type_any (struct paramed_type *T);\n"); /*for (i = 0; i < tn; i++) if (tps[i]->id[0] != '#') { printf ("extern struct tl_type tl_type_%s;\n", tps[i]->id); }*/ for (i = 0; i < tn; i++) if (tps[i]->id[0] != '#' && strcmp (tps[i]->id, "Type")) { printf ("static struct tl_type tl_type_%s __attribute__ ((unused));\n", tps[i]->print_id); printf ("static struct tl_type tl_type_%s = {\n", tps[i]->print_id); printf (" .name = 0x%08x,\n", tps[i]->name); printf (" .id = \"%s\"\n", tps[i]->id); printf ("};\n"); printf ("static struct tl_type tl_type_bare_%s __attribute__ ((unused));\n", tps[i]->print_id); printf ("static struct tl_type tl_type_bare_%s = {\n", tps[i]->print_id); printf (" .name = 0x%08x,\n", ~tps[i]->name); printf (" .id = \"Bare_%s\"\n", tps[i]->id); printf ("};\n"); } } return 0; } void usage (void) { printf ("usage: generate [-v] [-h] \n" ); exit (2); } void logprintf (const char *format, ...) __attribute__ ((format (printf, 1, 2))); void logprintf (const char *format __attribute__ ((unused)), ...) { } /* void hexdump (int *in_ptr, int *in_end) { int *ptr = in_ptr; while (ptr < in_end) { printf (" %08x", *(ptr ++)); } printf ("\n"); }*/ #ifdef HAVE_EXECINFO_H void print_backtrace (void) { void *buffer[255]; const int calls = backtrace (buffer, sizeof (buffer) / sizeof (void *)); backtrace_symbols_fd (buffer, calls, 1); } #else void print_backtrace (void) { if (write (1, "No libexec. Backtrace disabled\n", 32) < 0) { // Sad thing } } #endif void sig_segv_handler (int signum __attribute__ ((unused))) { if (write (1, "SIGSEGV received\n", 18) < 0) { // Sad thing } print_backtrace (); exit (EXIT_FAILURE); } void sig_abrt_handler (int signum __attribute__ ((unused))) { if (write (1, "SIGABRT received\n", 18) < 0) { // Sad thing } print_backtrace (); exit (EXIT_FAILURE); } int main (int argc, char **argv) { signal (SIGSEGV, sig_segv_handler); signal (SIGABRT, sig_abrt_handler); int i; while ((i = getopt (argc, argv, "vhH")) != -1) { switch (i) { case 'h': usage (); return 2; case 'v': verbosity++; break; case 'H': header ++; break; } } if (argc != optind + 1) { usage (); } int fd = open (argv[optind], O_RDONLY); if (fd < 0) { fprintf (stderr, "Can not open file '%s'. Error %m\n", argv[optind]); exit (1); } buf_size = read (fd, buf, (1 << 20)); if (fd == (1 << 20)) { fprintf (stderr, "Too big tlo file\n"); exit (2); } return parse_tlo_file (); }