#include /* for INT_MAX */ #include /* for fprintf etc */ #include /* for free etc */ #include /* for strlen */ #include "header.h" /* Define this to get warning messages when optimisations can't be used. */ /* #define OPTIMISATION_WARNINGS */ /* recursive use: */ static void generate(struct generator * g, struct node * p); static int new_label(struct generator * g) { return g->next_label++; } /* Write routines for simple entities */ /* Write a space if the preceding character was not whitespace */ static void ws_opt_space(struct generator * g, const char * s) { int ch = str_back(g->outbuf); if (ch != ' ' && ch != '\n' && ch != '\t' && ch != -1) write_char(g, ' '); write_string(g, s); } static void wi3(struct generator * g, int i) { if (i < 100) write_char(g, ' '); if (i < 10) write_char(g, ' '); write_int(g, i); /* integer (width 3) */ } /* Write routines for items from the syntax tree */ static void write_varname(struct generator * g, struct name * p) { int ch = "SIIrxg"[p->type]; switch (p->type) { case t_external: write_string(g, g->options->externals_prefix); break; case t_string: case t_boolean: case t_integer: { int count = p->count; if (count < 0) { fprintf(stderr, "Reference to optimised out variable "); report_b(stderr, p->b); fprintf(stderr, " attempted\n"); exit(1); } if (p->type == t_boolean) { /* We use a single array for booleans and integers, with the * integers first. */ count += g->analyser->name_count[t_integer]; } write_char(g, ch); write_char(g, '['); write_int(g, count); write_char(g, ']'); return; } default: write_char(g, ch); write_char(g, '_'); } write_b(g, p->b); } static void write_varref(struct generator * g, struct name * p) { /* reference to variable */ if (p->type < t_routine) write_string(g, "z->"); write_varname(g, p); } static void write_hexdigit(struct generator * g, int i) { str_append_ch(g->outbuf, "0123456789ABCDEF"[i & 0xF]); /* hexchar */ } static void write_hex(struct generator * g, int i) { if (i >> 4) write_hex(g, i >> 4); write_hexdigit(g, i); /* hex integer */ } /* write character literal */ static void wlitch(struct generator * g, int ch) { if (32 <= ch && ch < 127) { write_char(g, '\''); if (ch == '\'' || ch == '\\') { write_char(g, '\\'); } write_char(g, ch); write_char(g, '\''); } else { write_string(g, "0x"); write_hex(g, ch); } } static void wlitarray(struct generator * g, symbol * p) { /* write literal array */ write_string(g, "{ "); { int i; for (i = 0; i < SIZE(p); i++) { wlitch(g, p[i]); if (i < SIZE(p) - 1) write_string(g, ", "); } } write_string(g, " }"); } static void wlitref(struct generator * g, symbol * p) { /* write ref to literal array */ if (SIZE(p) == 0) { write_char(g, '0'); } else { struct str * s = g->outbuf; g->outbuf = g->declarations; write_string(g, "static const symbol s_"); write_int(g, g->literalstring_count); write_string(g, "[] = "); wlitarray(g, p); write_string(g, ";\n"); g->outbuf = s; write_string(g, "s_"); write_int(g, g->literalstring_count); g->literalstring_count++; } } static void write_margin(struct generator * g) { int i; for (i = 0; i < g->margin; i++) write_string(g, " "); } void write_comment_content(struct generator * g, struct node * p) { switch (p->type) { case c_mathassign: case c_plusassign: case c_minusassign: case c_multiplyassign: case c_divideassign: if (p->name) { write_char(g, '$'); write_b(g, p->name->b); write_char(g, ' '); } write_string(g, name_of_token(p->type)); write_string(g, " "); break; case c_eq: case c_ne: case c_gr: case c_ge: case c_ls: case c_le: write_string(g, "$( "); write_string(g, name_of_token(p->type)); write_string(g, " )"); break; default: write_string(g, name_of_token(p->type)); if (p->name) { write_char(g, ' '); write_b(g, p->name->b); } } write_string(g, ", line "); write_int(g, p->line_number); } static void write_comment(struct generator * g, struct node * p) { if (g->options->comments) { ws_opt_space(g, "/* "); write_comment_content(g, p); write_string(g, " */"); } write_newline(g); } static void wms(struct generator * g, const char * s) { write_margin(g); write_string(g, s); } /* margin + string */ static void write_block_start(struct generator * g) { /* block start */ wms(g, "{ "); g->margin++; } static void write_block_end(struct generator * g) { /* block end */ if (g->line_labelled == g->line_count) { wms(g, ";"); write_newline(g); } g->margin--; wms(g, "}"); write_newline(g); } static void w(struct generator * g, const char * s); /* keep c */ static void wk(struct generator * g, struct node * p, int keep_limit) { ++g->keep_count; if (p->mode == m_forward) { write_string(g, "int c"); write_int(g, g->keep_count); write_string(g, " = z->c"); if (keep_limit) { write_string(g, ", mlimit"); write_int(g, g->keep_count); } write_char(g, ';'); } else { write_string(g, "int m"); write_int(g, g->keep_count); write_string(g, " = z->l - z->c"); if (keep_limit) { write_string(g, ", mlimit"); write_int(g, g->keep_count); } write_string(g, "; (void)m"); write_int(g, g->keep_count); write_char(g, ';'); } } static void wrestore(struct generator * g, struct node * p, int keep_token) { /* restore c */ if (p->mode == m_forward) { write_string(g, "z->c = c"); } else { write_string(g, "z->c = z->l - m"); } write_int(g, keep_token); write_char(g, ';'); } static void wrestorelimit(struct generator * g, struct node * p, int keep_token) { /* restore limit */ if (p->mode == m_forward) { w(g, "z->l += mlimit"); } else { w(g, "z->lb = mlimit"); } write_int(g, keep_token); write_string(g, ";"); } static void winc(struct generator * g, struct node * p) { /* increment c */ write_string(g, p->mode == m_forward ? "z->c++;" : "z->c--;"); } static void wsetl(struct generator * g, int n) { g->margin--; wms(g, "lab"); write_int(g, n); write_char(g, ':'); write_newline(g); g->line_labelled = g->line_count; g->margin++; } static void wgotol(struct generator * g, int n) { wms(g, "goto lab"); write_int(g, n); write_char(g, ';'); write_newline(g); } static void write_failure(struct generator * g, struct node * p) { /* fail */ if (g->failure_keep_count != 0) { write_string(g, "{ "); if (g->failure_keep_count > 0) { wrestore(g, p, g->failure_keep_count); } else { wrestorelimit(g, p, -g->failure_keep_count); } write_char(g, ' '); } switch (g->failure_label) { case x_return: write_string(g, "return 0;"); break; default: write_string(g, "goto lab"); write_int(g, g->failure_label); write_char(g, ';'); g->label_used = 1; } if (g->failure_keep_count != 0) write_string(g, " }"); } /* if at limit fail */ static void write_check_limit(struct generator * g, struct node * p) { write_string(g, p->mode == m_forward ? "if (z->c >= z->l) " : "if (z->c <= z->lb) "); write_failure(g, p); } static void write_data_address(struct generator * g, struct node * p) { symbol * b = p->literalstring; if (b != 0) { write_int(g, SIZE(b)); w(g, ", "); wlitref(g, b); } else { write_varref(g, p->name); } } /* Formatted write. */ static void writef(struct generator * g, const char * input, struct node * p) { int i = 0; int l = strlen(input); while (i < l) { int ch = input[i++]; if (ch != '~') { write_char(g, ch); continue; } switch (input[i++]) { default: write_char(g, input[i - 1]); continue; case 'C': write_comment(g, p); continue; case 'k': wk(g, p, false); continue; case 'K': wk(g, p, true); continue; case 'i': winc(g, p); continue; case 'l': write_check_limit(g, p); continue; case 'f': write_failure(g, p); continue; case 'M': write_margin(g); continue; case 'N': write_newline(g); continue; case '{': write_block_start(g); continue; case '}': write_block_end(g); continue; case 'S': write_string(g, g->S[input[i++] - '0']); continue; case 'I': write_int(g, g->I[input[i++] - '0']); continue; case 'J': wi3(g, g->I[input[i++] - '0']); continue; case 'V': write_varref(g, g->V[input[i++] - '0']); continue; case 'W': write_varname(g, g->V[input[i++] - '0']); continue; case 'L': wlitref(g, g->L[input[i++] - '0']); continue; case 'A': wlitarray(g, g->L[input[i++] - '0']); continue; case 'c': wlitch(g, g->I[input[i++] - '0']); continue; case 'a': write_data_address(g, p); continue; case '+': g->margin++; continue; case '-': g->margin--; continue; case '$': /* insert_s, insert_v etc */ write_char(g, p->literalstring == 0 ? 'v' : 's'); continue; case 'p': write_string(g, g->options->externals_prefix); continue; } } } static void w(struct generator * g, const char * s) { writef(g, s, 0); } static void generate_AE(struct generator * g, struct node * p) { const char * s; switch (p->type) { case c_name: write_varref(g, p->name); break; case c_number: write_int(g, p->number); break; case c_maxint: write_string(g, "MAXINT"); break; case c_minint: write_string(g, "MININT"); break; case c_neg: write_char(g, '-'); generate_AE(g, p->right); break; case c_multiply: s = " * "; goto label0; case c_plus: s = " + "; goto label0; case c_minus: s = " - "; goto label0; case c_divide: s = " / "; label0: write_char(g, '('); generate_AE(g, p->left); write_string(g, s); generate_AE(g, p->right); write_char(g, ')'); break; case c_cursor: w(g, "z->c"); break; case c_limit: w(g, p->mode == m_forward ? "z->l" : "z->lb"); break; case c_len: if (g->options->encoding == ENC_UTF8) { w(g, "len_utf8(z->p)"); break; } /* FALLTHRU */ case c_size: w(g, "SIZE(z->p)"); break; case c_lenof: if (g->options->encoding == ENC_UTF8) { g->V[0] = p->name; w(g, "len_utf8(~V0)"); break; } /* FALLTHRU */ case c_sizeof: g->V[0] = p->name; w(g, "SIZE(~V0)"); break; } } /* K_needed() tests to see if we really need to keep c. Not true when the command does not touch the cursor. This and repeat_score() could be elaborated almost indefinitely. */ static int K_needed_(struct generator * g, struct node * p, int call_depth) { while (p) { switch (p->type) { case c_atlimit: case c_do: case c_dollar: case c_leftslice: case c_rightslice: case c_mathassign: case c_plusassign: case c_minusassign: case c_multiplyassign: case c_divideassign: case c_eq: case c_ne: case c_gr: case c_ge: case c_ls: case c_le: case c_sliceto: case c_booltest: case c_set: case c_unset: case c_true: case c_false: case c_debug: break; case c_call: /* Recursive functions aren't typical in snowball programs, so * make the pessimistic assumption that keep is needed if we * hit a generous limit on recursion. It's not likely to make * a difference to any real world program, but means we won't * recurse until we run out of stack for pathological cases. */ if (call_depth >= 100) return true; if (K_needed_(g, p->name->definition, call_depth + 1)) return true; break; case c_bra: if (K_needed_(g, p->left, call_depth)) return true; break; default: return true; } p = p->right; } return false; } extern int K_needed(struct generator * g, struct node * p) { return K_needed_(g, p, 0); } static int repeat_score(struct generator * g, struct node * p, int call_depth) { int score = 0; while (p) { switch (p->type) { case c_dollar: case c_leftslice: case c_rightslice: case c_mathassign: case c_plusassign: case c_minusassign: case c_multiplyassign: case c_divideassign: case c_eq: case c_ne: case c_gr: case c_ge: case c_ls: case c_le: case c_sliceto: /* case c_not: must not be included here! */ case c_debug: break; case c_call: /* Recursive functions aren't typical in snowball programs, so * make the pessimistic assumption that repeat requires cursor * reinstatement if we hit a generous limit on recursion. It's * not likely to make a difference to any real world program, * but means we won't recurse until we run out of stack for * pathological cases. */ if (call_depth >= 100) { return 2; } score += repeat_score(g, p->name->definition, call_depth + 1); if (score >= 2) return score; break; case c_bra: score += repeat_score(g, p->left, call_depth); if (score >= 2) return score; break; case c_name: case c_literalstring: case c_next: case c_grouping: case c_non: case c_hop: if (++score >= 2) return score; break; default: return 2; } p = p->right; } return score; } /* tests if an expression requires cursor reinstatement in a repeat */ extern int repeat_restore(struct generator * g, struct node * p) { return repeat_score(g, p, 0) >= 2; } static void generate_bra(struct generator * g, struct node * p) { p = p->left; while (p) { generate(g, p); p = p->right; } } static void generate_and(struct generator * g, struct node * p) { int keep_c = 0; if (K_needed(g, p->left)) { writef(g, "~{~k~C", p); keep_c = g->keep_count; } else { writef(g, "~M~C", p); } p = p->left; while (p) { generate(g, p); if (keep_c && p->right != 0) { w(g, "~M"); wrestore(g, p, keep_c); w(g, "~N"); } p = p->right; } if (keep_c) w(g, "~}"); } static void generate_or(struct generator * g, struct node * p) { int keep_c = 0; int used = g->label_used; int a0 = g->failure_label; int a1 = g->failure_keep_count; int out_lab = new_label(g); if (K_needed(g, p->left)) { writef(g, "~{~k~C", p); keep_c = g->keep_count; } else { writef(g, "~M~C", p); } p = p->left; g->failure_keep_count = 0; while (p->right) { g->failure_label = new_label(g); g->label_used = 0; generate(g, p); wgotol(g, out_lab); if (g->label_used) wsetl(g, g->failure_label); if (keep_c) { w(g, "~M"); wrestore(g, p, keep_c); w(g, "~N"); } p = p->right; } g->label_used = used; g->failure_label = a0; g->failure_keep_count = a1; generate(g, p); if (keep_c) w(g, "~}"); wsetl(g, out_lab); } static void generate_backwards(struct generator * g, struct node * p) { writef(g, "~Mz->lb = z->c; z->c = z->l;~C~N", p); generate(g, p->left); w(g, "~Mz->c = z->lb;~N"); } static void generate_not(struct generator * g, struct node * p) { int keep_c = 0; int used = g->label_used; int a0 = g->failure_label; int a1 = g->failure_keep_count; if (K_needed(g, p->left)) { writef(g, "~{~k~C", p); keep_c = g->keep_count; } else { writef(g, "~M~C", p); } g->failure_label = new_label(g); g->label_used = 0; g->failure_keep_count = 0; generate(g, p->left); { int l = g->failure_label; int u = g->label_used; g->label_used = used; g->failure_label = a0; g->failure_keep_count = a1; writef(g, "~M~f~N", p); if (u) wsetl(g, l); } if (keep_c) { w(g, "~M"); wrestore(g, p, keep_c); w(g, "~N~}"); } } static void generate_try(struct generator * g, struct node * p) { int keep_c = 0; if (K_needed(g, p->left)) { writef(g, "~{~k~C", p); keep_c = g->keep_count; } else { writef(g, "~M~C", p); } g->failure_keep_count = keep_c; g->failure_label = new_label(g); g->label_used = 0; generate(g, p->left); if (g->label_used) wsetl(g, g->failure_label); if (keep_c) w(g, "~}"); } static void generate_set(struct generator * g, struct node * p) { g->V[0] = p->name; writef(g, "~M~V0 = 1;~C", p); } static void generate_unset(struct generator * g, struct node * p) { g->V[0] = p->name; writef(g, "~M~V0 = 0;~C", p); } static void generate_fail(struct generator * g, struct node * p) { generate(g, p->left); writef(g, "~M~f~C", p); } /* generate_test() also implements 'reverse' */ static void generate_test(struct generator * g, struct node * p) { int keep_c = 0; if (K_needed(g, p->left)) { keep_c = ++g->keep_count; w(g, p->mode == m_forward ? "~{int c_test" : "~{int m_test"); write_int(g, keep_c); w(g, p->mode == m_forward ? " = z->c;" : " = z->l - z->c;"); writef(g, "~C", p); } else writef(g, "~M~C", p); generate(g, p->left); if (keep_c) { w(g, p->mode == m_forward ? "~Mz->c = c_test" : "~Mz->c = z->l - m_test"); write_int(g, keep_c); writef(g, ";~N~}", p); } } static void generate_do(struct generator * g, struct node * p) { int keep_c = 0; if (K_needed(g, p->left)) { writef(g, "~{~k~C", p); keep_c = g->keep_count; } else { writef(g, "~M~C", p); } if (p->left->type == c_call) { /* Optimise do */ g->V[0] = p->left->name; writef(g, "~{int ret = ~V0(z);~C", p->left); w(g, "~Mif (ret < 0) return ret;~N~}"); } else { g->failure_label = new_label(g); g->label_used = 0; g->failure_keep_count = 0; generate(g, p->left); if (g->label_used) wsetl(g, g->failure_label); } if (keep_c) { w(g, "~M"); wrestore(g, p, keep_c); w(g, "~N~}"); } } static void generate_next(struct generator * g, struct node * p) { if (g->options->encoding == ENC_UTF8) { if (p->mode == m_forward) w(g, "~{int ret = skip_utf8(z->p, z->c, 0, z->l, 1"); else w(g, "~{int ret = skip_utf8(z->p, z->c, z->lb, 0, -1"); writef(g, ");~N" "~Mif (ret < 0) ~f~N" "~Mz->c = ret;~C" "~}", p); } else writef(g, "~M~l~N" "~M~i~C", p); } static void generate_GO_grouping(struct generator * g, struct node * p, int is_goto, int complement) { struct grouping * q = p->name->grouping; g->S[0] = p->mode == m_forward ? "" : "_b"; g->S[1] = complement ? "in" : "out"; g->S[2] = g->options->encoding == ENC_UTF8 ? "_U" : ""; g->V[0] = p->name; g->I[0] = q->smallest_ch; g->I[1] = q->largest_ch; if (is_goto) { writef(g, "~Mif (~S1_grouping~S0~S2(z, ~V0, ~I0, ~I1, 1) < 0) ~f~C", p); } else { writef(g, "~{~C" "~Mint ret = ~S1_grouping~S0~S2(z, ~V0, ~I0, ~I1, 1);~N" "~Mif (ret < 0) ~f~N", p); if (p->mode == m_forward) w(g, "~Mz->c += ret;~N"); else w(g, "~Mz->c -= ret;~N"); w(g, "~}"); } } static void generate_GO(struct generator * g, struct node * p, int style) { int keep_c = 0; int used = g->label_used; int a0 = g->failure_label; int a1 = g->failure_keep_count; if (p->left->type == c_grouping || p->left->type == c_non) { /* Special case for "goto" or "gopast" when used on a grouping or an * inverted grouping - the movement of c by the matching action is * exactly what we want! */ #ifdef OPTIMISATION_WARNINGS printf("Optimising %s %s\n", style ? "goto" : "gopast", p->left->type == c_non ? "non" : "grouping"); #endif if (g->options->comments) { writef(g, "~M~C", p); } generate_GO_grouping(g, p->left, style, p->left->type == c_non); return; } w(g, "~Mwhile(1) {"); writef(g, "~C~+", p); if (style == 1 || repeat_restore(g, p->left)) { writef(g, "~M~k~N", p); keep_c = g->keep_count; } g->failure_label = new_label(g); g->label_used = 0; generate(g, p->left); if (style == 1) { /* include for goto; omit for gopast */ w(g, "~M"); wrestore(g, p, keep_c); w(g, "~N"); } w(g, "~Mbreak;~N"); if (g->label_used) wsetl(g, g->failure_label); if (keep_c) { w(g, "~M"); wrestore(g, p, keep_c); w(g, "~N"); } g->label_used = used; g->failure_label = a0; g->failure_keep_count = a1; /* writef(g, "~M~l~N" "~M~i~N", p); */ generate_next(g, p); w(g, "~}"); } static void generate_loop(struct generator * g, struct node * p) { w(g, "~{int i; for (i = "); generate_AE(g, p->AE); writef(g, "; i > 0; i--)~C" "~{", p); generate(g, p->left); w(g, "~}" "~}"); } static void generate_repeat_or_atleast(struct generator * g, struct node * p, int atleast_case) { int keep_c = 0; if (atleast_case) { writef(g, "~Mwhile(1) {~+~N", p); } else { writef(g, "~Mwhile(1) {~+~C", p); } if (repeat_restore(g, p->left)) { writef(g, "~M~k~N", p); keep_c = g->keep_count; } g->failure_label = new_label(g); g->label_used = 0; g->failure_keep_count = 0; generate(g, p->left); if (atleast_case) w(g, "~Mi--;~N"); w(g, "~Mcontinue;~N"); if (g->label_used) wsetl(g, g->failure_label); if (keep_c) { w(g, "~M"); wrestore(g, p, keep_c); w(g, "~N"); } w(g, "~Mbreak;~N" "~}"); } static void generate_repeat(struct generator * g, struct node * p) { generate_repeat_or_atleast(g, p, false); } static void generate_atleast(struct generator * g, struct node * p) { w(g, "~{int i = "); generate_AE(g, p->AE); w(g, ";~C"); { int used = g->label_used; int a0 = g->failure_label; int a1 = g->failure_keep_count; generate_repeat_or_atleast(g, p, true); g->label_used = used; g->failure_label = a0; g->failure_keep_count = a1; } writef(g, "~Mif (i > 0) ~f~N" "~}", p); } static void generate_setmark(struct generator * g, struct node * p) { g->V[0] = p->name; writef(g, "~M~V0 = z->c;~C", p); } static void generate_tomark(struct generator * g, struct node * p) { g->S[0] = p->mode == m_forward ? ">" : "<"; w(g, "~Mif (z->c ~S0 "); generate_AE(g, p->AE); writef(g, ") ~f~N", p); w(g, "~Mz->c = "); generate_AE(g, p->AE); writef(g, ";~C", p); } static void generate_atmark(struct generator * g, struct node * p) { w(g, "~Mif (z->c != "); generate_AE(g, p->AE); writef(g, ") ~f~C", p); } static void generate_hop(struct generator * g, struct node * p) { g->S[0] = p->mode == m_forward ? "+" : "-"; g->S[1] = p->mode == m_forward ? "0" : "z->lb"; if (g->options->encoding == ENC_UTF8) { w(g, "~{int ret = skip_utf8(z->p, z->c, ~S1, z->l, ~S0 "); generate_AE(g, p->AE); writef(g, ");~C", p); writef(g, "~Mif (ret < 0) ~f~N", p); } else { w(g, "~{int ret = z->c ~S0 "); generate_AE(g, p->AE); writef(g, ";~C", p); writef(g, "~Mif (~S1 > ret || ret > z->l) ~f~N", p); } writef(g, "~Mz->c = ret;~N" "~}", p); } static void generate_delete(struct generator * g, struct node * p) { writef(g, "~{int ret = slice_del(z);~C", p); writef(g, "~Mif (ret < 0) return ret;~N" "~}", p); } static void generate_tolimit(struct generator * g, struct node * p) { g->S[0] = p->mode == m_forward ? "" : "b"; writef(g, "~Mz->c = z->l~S0;~C", p); } static void generate_atlimit(struct generator * g, struct node * p) { g->S[0] = p->mode == m_forward ? "" : "b"; g->S[1] = p->mode == m_forward ? "<" : ">"; writef(g, "~Mif (z->c ~S1 z->l~S0) ~f~C", p); } static void generate_leftslice(struct generator * g, struct node * p) { g->S[0] = p->mode == m_forward ? "bra" : "ket"; writef(g, "~Mz->~S0 = z->c;~C", p); } static void generate_rightslice(struct generator * g, struct node * p) { g->S[0] = p->mode == m_forward ? "ket" : "bra"; writef(g, "~Mz->~S0 = z->c;~C", p); } static void generate_assignto(struct generator * g, struct node * p) { g->V[0] = p->name; writef(g, "~M~V0 = assign_to(z, ~V0);~C" "~Mif (~V0 == 0) return -1;~C", p); } static void generate_sliceto(struct generator * g, struct node * p) { g->V[0] = p->name; writef(g, "~M~V0 = slice_to(z, ~V0);~C" "~Mif (~V0 == 0) return -1;~N", p); } static void generate_insert(struct generator * g, struct node * p, int style) { int keep_c = style == c_attach; if (p->mode == m_backward) keep_c = !keep_c; writef(g, "~{int ret;~N", p); if (keep_c) w(g, "~{int saved_c = z->c;~N"); writef(g, "~Mret = insert_~$(z, z->c, z->c, ~a);~C", p); if (keep_c) w(g, "~Mz->c = saved_c;~N~}"); writef(g, "~Mif (ret < 0) return ret;~N" "~}", p); } static void generate_assignfrom(struct generator * g, struct node * p) { int keep_c = p->mode == m_forward; /* like 'attach' */ writef(g, "~{int ret;~N", p); if (keep_c) writef(g, "~{int saved_c = z->c;~N", p); w(g, "~Mret = "); writef(g, keep_c ? "insert_~$(z, z->c, z->l, ~a);~C" : "insert_~$(z, z->lb, z->c, ~a);~C", p); if (keep_c) w(g, "~Mz->c = saved_c;~N~}"); writef(g, "~Mif (ret < 0) return ret;~N" "~}", p); } /* bugs marked <======= fixed 22/7/02. Similar fixes required for Java */ static void generate_slicefrom(struct generator * g, struct node * p) { /* w(g, "~Mslice_from_s(z, "); <============= bug! should be: */ writef(g, "~{int ret = slice_from_~$(z, ~a);~C", p); writef(g, "~Mif (ret < 0) return ret;~N" "~}", p); } static void generate_setlimit(struct generator * g, struct node * p) { int keep_c; if (p->left && p->left->type == c_tomark) { /* Special case for: * * setlimit tomark AE for C * * All uses of setlimit in the current stemmers we ship follow this * pattern, and by special-casing we can avoid having to save and * restore c. */ struct node * q = p->left; ++g->keep_count; writef(g, "~N~{int mlimit", p); write_int(g, g->keep_count); writef(g, ";~C", p); keep_c = g->keep_count; g->S[0] = q->mode == m_forward ? ">" : "<"; w(g, "~Mif (z->c ~S0 "); generate_AE(g, q->AE); writef(g, ") ~f~N", q); w(g, "~Mmlimit"); write_int(g, keep_c); if (p->mode == m_forward) { w(g, " = z->l - z->c; z->l = "); } else { w(g, " = z->lb; z->lb = "); } generate_AE(g, q->AE); w(g, ";~N"); } else { writef(g, "~{~K~C", p); keep_c = g->keep_count; generate(g, p->left); w(g, "~Mmlimit"); write_int(g, keep_c); if (p->mode == m_forward) w(g, " = z->l - z->c; z->l = z->c;~N"); else w(g, " = z->lb; z->lb = z->c;~N"); w(g, "~M"); wrestore(g, p, keep_c); w(g, "~N"); } g->failure_keep_count = -keep_c; generate(g, p->aux); w(g, "~M"); wrestorelimit(g, p, -g->failure_keep_count); w(g, "~N" "~}"); } /* dollar sets snowball up to operate on a string variable as if it were the * current string */ static void generate_dollar(struct generator * g, struct node * p) { int used = g->label_used; int a0 = g->failure_label; int a1 = g->failure_keep_count; int keep_token; g->failure_label = new_label(g); g->label_used = 0; g->failure_keep_count = 0; keep_token = ++g->keep_count; g->I[0] = keep_token; writef(g, "~{struct SN_env env~I0 = * z;~C", p); g->V[0] = p->name; /* Assume failure. */ writef(g, "~Mint failure = 1;~N" "~Mz->p = ~V0;~N" "~Mz->lb = z->c = 0;~N" "~Mz->l = SIZE(z->p);~N", p); generate(g, p->left); /* Mark success. */ w(g, "~Mfailure = 0;~N"); if (g->label_used) wsetl(g, g->failure_label); g->V[0] = p->name; /* necessary */ g->label_used = used; g->failure_label = a0; g->failure_keep_count = a1; g->I[0] = keep_token; writef(g, "~M~V0 = z->p;~N" "~M* z = env~I0;~N" "~Mif (failure) ~f~N~}", p); } static void generate_integer_assign(struct generator * g, struct node * p, char * s) { g->V[0] = p->name; g->S[0] = s; w(g, "~M~V0 ~S0 "); generate_AE(g, p->AE); writef(g, ";~C", p); } static void generate_integer_test(struct generator * g, struct node * p, char * s) { w(g, "~Mif (!("); generate_AE(g, p->left); write_char(g, ' '); write_string(g, s); write_char(g, ' '); generate_AE(g, p->AE); writef(g, ")) ~f~C", p); } static void generate_call(struct generator * g, struct node * p) { g->V[0] = p->name; writef(g, "~{int ret = ~V0(z);~C", p); if (g->failure_keep_count == 0 && g->failure_label == x_return) { /* Combine the two tests in this special case for better optimisation * and clearer generated code. */ writef(g, "~Mif (ret <= 0) return ret;~N~}", p); } else { writef(g, "~Mif (ret == 0) ~f~N" "~Mif (ret < 0) return ret;~N~}", p); } } static void generate_grouping(struct generator * g, struct node * p, int complement) { struct grouping * q = p->name->grouping; g->S[0] = p->mode == m_forward ? "" : "_b"; g->S[1] = complement ? "out" : "in"; g->S[2] = g->options->encoding == ENC_UTF8 ? "_U" : ""; g->V[0] = p->name; g->I[0] = q->smallest_ch; g->I[1] = q->largest_ch; writef(g, "~Mif (~S1_grouping~S0~S2(z, ~V0, ~I0, ~I1, 0)) ~f~C", p); } static void generate_namedstring(struct generator * g, struct node * p) { g->S[0] = p->mode == m_forward ? "" : "_b"; g->V[0] = p->name; writef(g, "~Mif (!(eq_v~S0(z, ~V0))) ~f~C", p); } static void generate_literalstring(struct generator * g, struct node * p) { symbol * b = p->literalstring; if (SIZE(b) == 1) { /* It's quite common to compare with a single character literal string, * so just inline the simpler code for this case rather than making a * function call. In UTF-8 mode, only do this for the ASCII subset, * since multi-byte characters are more complex to test against. */ if (g->options->encoding == ENC_UTF8 && *b >= 128) { printf("single byte %d\n", *b); exit(1); } g->I[0] = *b; if (p->mode == m_forward) { writef(g, "~Mif (z->c == z->l || z->p[z->c] != ~c0) ~f~C" "~Mz->c++;~N", p); } else { writef(g, "~Mif (z->c <= z->lb || z->p[z->c - 1] != ~c0) ~f~C" "~Mz->c--;~N", p); } } else { g->S[0] = p->mode == m_forward ? "" : "_b"; g->I[0] = SIZE(b); g->L[0] = b; writef(g, "~Mif (!(eq_s~S0(z, ~I0, ~L0))) ~f~C", p); } } static void generate_define(struct generator * g, struct node * p) { struct name * q = p->name; g->next_label = 0; g->S[0] = q->type == t_routine ? "static" : "extern"; g->V[0] = q; w(g, "~N~S0 int ~V0(struct SN_env * z) {"); if (g->options->comments) { write_string(g, p->mode == m_forward ? " /* forwardmode */" : " /* backwardmode */"); } w(g, "~N~+"); if (p->amongvar_needed) w(g, "~Mint among_var;~N"); g->failure_keep_count = 0; g->failure_label = x_return; g->label_used = 0; g->keep_count = 0; generate(g, p->left); w(g, "~Mreturn 1;~N~}"); } static void generate_substring(struct generator * g, struct node * p) { struct among * x = p->among; int block = -1; unsigned int bitmap = 0; struct amongvec * among_cases = x->b; int c; int empty_case = -1; int n_cases = 0; symbol cases[2]; int shortest_size = INT_MAX; int shown_comment = 0; g->S[0] = p->mode == m_forward ? "" : "_b"; g->I[0] = x->number; g->I[1] = x->literalstring_count; /* In forward mode with non-ASCII UTF-8 characters, the first character * of the string will often be the same, so instead look at the last * common character position. * * In backward mode, we can't match if there are fewer characters before * the current position than the minimum length. */ for (c = 0; c < x->literalstring_count; ++c) { int size = among_cases[c].size; if (size != 0 && size < shortest_size) { shortest_size = size; } } for (c = 0; c < x->literalstring_count; ++c) { symbol ch; if (among_cases[c].size == 0) { empty_case = c; continue; } if (p->mode == m_forward) { ch = among_cases[c].b[shortest_size - 1]; } else { ch = among_cases[c].b[among_cases[c].size - 1]; } if (n_cases == 0) { block = ch >> 5; } else if (ch >> 5 != block) { block = -1; if (n_cases > 2) break; } if (block == -1) { if (n_cases > 0 && ch == cases[0]) continue; if (n_cases < 2) { cases[n_cases++] = ch; } else if (ch != cases[1]) { ++n_cases; break; } } else { if ((bitmap & (1u << (ch & 0x1f))) == 0) { bitmap |= 1u << (ch & 0x1f); if (n_cases < 2) cases[n_cases] = ch; ++n_cases; } } } if (block != -1 || n_cases <= 2) { char buf[64]; g->I[2] = block; g->I[3] = bitmap; g->I[4] = shortest_size - 1; if (p->mode == m_forward) { sprintf(buf, "z->p[z->c + %d]", shortest_size - 1); g->S[1] = buf; if (shortest_size == 1) { writef(g, "~Mif (z->c >= z->l", p); } else { writef(g, "~Mif (z->c + ~I4 >= z->l", p); } } else { g->S[1] = "z->p[z->c - 1]"; if (shortest_size == 1) { writef(g, "~Mif (z->c <= z->lb", p); } else { writef(g, "~Mif (z->c - ~I4 <= z->lb", p); } } if (n_cases == 0) { /* We get this for the degenerate case: among { '' } * This doesn't seem to be a useful construct, but it is * syntactically valid. */ } else if (n_cases == 1) { g->I[4] = cases[0]; writef(g, " || ~S1 != ~I4", p); } else if (n_cases == 2) { g->I[4] = cases[0]; g->I[5] = cases[1]; writef(g, " || (~S1 != ~I4 && ~S1 != ~I5)", p); } else { writef(g, " || ~S1 >> 5 != ~I2 || !((~I3 >> (~S1 & 0x1f)) & 1)", p); } write_string(g, ") "); if (empty_case != -1) { /* If the among includes the empty string, it can never fail * so not matching the bitmap means we match the empty string. */ g->I[4] = among_cases[empty_case].result; writef(g, "among_var = ~I4; else~C", p); } else { writef(g, "~f~C", p); } shown_comment = 1; } else { #ifdef OPTIMISATION_WARNINGS printf("Couldn't shortcut among %d\n", x->number); #endif } if (!x->amongvar_needed) { writef(g, "~Mif (!(find_among~S0(z, a_~I0, ~I1))) ~f", p); writef(g, shown_comment ? "~N" : "~C", p); } else { writef(g, "~Mamong_var = find_among~S0(z, a_~I0, ~I1);", p); writef(g, shown_comment ? "~N" : "~C", p); writef(g, "~Mif (!(among_var)) ~f~N", p); } } static void generate_among(struct generator * g, struct node * p) { struct among * x = p->among; if (x->substring == 0) generate_substring(g, p); if (x->starter != 0) generate(g, x->starter); if (x->command_count == 1 && x->nocommand_count == 0) { /* Only one outcome ("no match" already handled). */ generate(g, x->commands[0]); } else if (x->command_count > 0) { int i; writef(g, "~Mswitch (among_var) {~C~+", p); for (i = 1; i <= x->command_count; i++) { g->I[0] = i; w(g, "~Mcase ~I0:~N~+"); generate(g, x->commands[i - 1]); w(g, "~Mbreak;~N~-"); } w(g, "~}"); } } static void generate_booltest(struct generator * g, struct node * p) { g->V[0] = p->name; writef(g, "~Mif (!(~V0)) ~f~C", p); } static void generate_false(struct generator * g, struct node * p) { writef(g, "~M~f~C", p); } static void generate_debug(struct generator * g, struct node * p) { g->I[0] = g->debug_count++; g->I[1] = p->line_number; writef(g, "~Mdebug(z, ~I0, ~I1);~C", p); } static void generate(struct generator * g, struct node * p) { int used = g->label_used; int a0 = g->failure_label; int a1 = g->failure_keep_count; switch (p->type) { case c_define: generate_define(g, p); break; case c_bra: generate_bra(g, p); break; case c_and: generate_and(g, p); break; case c_or: generate_or(g, p); break; case c_backwards: generate_backwards(g, p); break; case c_not: generate_not(g, p); break; case c_set: generate_set(g, p); break; case c_unset: generate_unset(g, p); break; case c_try: generate_try(g, p); break; case c_fail: generate_fail(g, p); break; case c_reverse: case c_test: generate_test(g, p); break; case c_do: generate_do(g, p); break; case c_goto: generate_GO(g, p, 1); break; case c_gopast: generate_GO(g, p, 0); break; case c_repeat: generate_repeat(g, p); break; case c_loop: generate_loop(g, p); break; case c_atleast: generate_atleast(g, p); break; case c_setmark: generate_setmark(g, p); break; case c_tomark: generate_tomark(g, p); break; case c_atmark: generate_atmark(g, p); break; case c_hop: generate_hop(g, p); break; case c_delete: generate_delete(g, p); break; case c_next: generate_next(g, p); break; case c_tolimit: generate_tolimit(g, p); break; case c_atlimit: generate_atlimit(g, p); break; case c_leftslice: generate_leftslice(g, p); break; case c_rightslice: generate_rightslice(g, p); break; case c_assignto: generate_assignto(g, p); break; case c_sliceto: generate_sliceto(g, p); break; case c_assign: generate_assignfrom(g, p); break; case c_insert: case c_attach: generate_insert(g, p, p->type); break; case c_slicefrom: generate_slicefrom(g, p); break; case c_setlimit: generate_setlimit(g, p); break; case c_dollar: generate_dollar(g, p); break; case c_mathassign: generate_integer_assign(g, p, "="); break; case c_plusassign: generate_integer_assign(g, p, "+="); break; case c_minusassign: generate_integer_assign(g, p, "-="); break; case c_multiplyassign:generate_integer_assign(g, p, "*="); break; case c_divideassign: generate_integer_assign(g, p, "/="); break; case c_eq: generate_integer_test(g, p, "=="); break; case c_ne: generate_integer_test(g, p, "!="); break; case c_gr: generate_integer_test(g, p, ">"); break; case c_ge: generate_integer_test(g, p, ">="); break; case c_ls: generate_integer_test(g, p, "<"); break; case c_le: generate_integer_test(g, p, "<="); break; case c_call: generate_call(g, p); break; case c_grouping: generate_grouping(g, p, false); break; case c_non: generate_grouping(g, p, true); break; case c_name: generate_namedstring(g, p); break; case c_literalstring: generate_literalstring(g, p); break; case c_among: generate_among(g, p); break; case c_substring: generate_substring(g, p); break; case c_booltest: generate_booltest(g, p); break; case c_false: generate_false(g, p); break; case c_true: break; case c_debug: generate_debug(g, p); break; default: fprintf(stderr, "%d encountered\n", p->type); exit(1); } if (g->failure_label != a0) g->label_used = used; g->failure_label = a0; g->failure_keep_count = a1; } void write_generated_comment_content(struct generator * g) { w(g, "Generated by Snowball " SNOWBALL_VERSION " - https://snowballstem.org/"); } void write_start_comment(struct generator * g, const char * comment_start, const char * comment_end) { write_margin(g); w(g, comment_start); write_generated_comment_content(g); if (comment_end) { w(g, comment_end); } w(g, "~N~N"); } static void generate_head(struct generator * g) { w(g, "#include \""); if (g->options->runtime_path) { write_string(g, g->options->runtime_path); if (g->options->runtime_path[strlen(g->options->runtime_path) - 1] != '/') write_char(g, '/'); } w(g, "header.h\"~N~N"); } static void generate_routine_headers(struct generator * g) { struct name * q; for (q = g->analyser->names; q; q = q->next) { g->V[0] = q; switch (q->type) { case t_routine: w(g, "static int ~W0(struct SN_env * z);~N"); break; case t_external: w(g, "#ifdef __cplusplus~N" "extern \"C\" {~N" "#endif~N" "extern int ~W0(struct SN_env * z);~N" "#ifdef __cplusplus~N" "}~N" "#endif~N" ); break; } } } static void generate_among_table(struct generator * g, struct among * x) { struct amongvec * v = x->b; g->I[0] = x->number; { int i; for (i = 0; i < x->literalstring_count; i++) { g->I[1] = i; g->I[2] = v->size; g->L[0] = v->b; if (v->size) w(g, "static const symbol s_~I0_~I1[~I2] = ~A0;~N"); v++; } } g->I[1] = x->literalstring_count; w(g, "~N~Mstatic const struct among a_~I0[~I1] =~N{~N"); v = x->b; { int i; for (i = 0; i < x->literalstring_count; i++) { g->I[1] = i; g->I[2] = v->size; g->I[3] = v->i; g->I[4] = v->result; g->S[0] = i < x->literalstring_count - 1 ? "," : ""; if (g->options->comments) { w(g, "/*~J1 */ "); } w(g, "{ ~I2, "); if (v->size == 0) { w(g, "0,"); } else { w(g, "s_~I0_~I1,"); } w(g, " ~I3, ~I4, "); if (v->function == 0) { write_char(g, '0'); } else { write_varname(g, v->function); } w(g, "}~S0~N"); v++; } } w(g, "};~N~N"); } static void generate_amongs(struct generator * g) { struct among * x; for (x = g->analyser->amongs; x; x = x->next) { generate_among_table(g, x); } } static void set_bit(symbol * b, int i) { b[i/8] |= 1 << i%8; } static void generate_grouping_table(struct generator * g, struct grouping * q) { int range = q->largest_ch - q->smallest_ch + 1; int size = (range + 7)/ 8; /* assume 8 bits per symbol */ symbol * b = q->b; symbol * map = create_b(size); int i; for (i = 0; i < size; i++) map[i] = 0; for (i = 0; i < SIZE(b); i++) set_bit(map, b[i] - q->smallest_ch); g->V[0] = q->name; w(g, "static const unsigned char ~V0[] = { "); for (i = 0; i < size; i++) { write_int(g, map[i]); if (i < size - 1) w(g, ", "); } w(g, " };~N~N"); lose_b(map); } static void generate_groupings(struct generator * g) { struct grouping * q; for (q = g->analyser->groupings; q; q = q->next) { if (q->name->used) generate_grouping_table(g, q); } } static void generate_create(struct generator * g) { int * p = g->analyser->name_count; g->I[0] = p[t_string]; g->I[1] = p[t_integer] + p[t_boolean]; w(g, "~N" "extern struct SN_env * ~pcreate_env(void) { return SN_create_env(~I0, ~I1); }" "~N"); } static void generate_close(struct generator * g) { int * p = g->analyser->name_count; g->I[0] = p[t_string]; w(g, "~Nextern void ~pclose_env(struct SN_env * z) { SN_close_env(z, ~I0); }~N~N"); } static void generate_create_and_close_templates(struct generator * g) { w(g, "~N" "extern struct SN_env * ~pcreate_env(void);~N" "extern void ~pclose_env(struct SN_env * z);~N" "~N"); } static void generate_header_file(struct generator * g) { struct name * q; const char * vp = g->options->variables_prefix; g->S[0] = vp; w(g, "#ifdef __cplusplus~N" "extern \"C\" {~N" "#endif~N"); /* for C++ */ generate_create_and_close_templates(g); for (q = g->analyser->names; q; q = q->next) { g->V[0] = q; switch (q->type) { case t_external: w(g, "extern int ~W0(struct SN_env * z);~N"); break; case t_string: case t_integer: case t_boolean: if (vp) { int count = q->count; if (count < 0) { /* Unused variables should get removed from `names`. */ fprintf(stderr, "Optimised out variable "); report_b(stderr, q->b); fprintf(stderr, " still in names list\n"); exit(1); } if (q->type == t_boolean) { /* We use a single array for booleans and integers, * with the integers first. */ count += g->analyser->name_count[t_integer]; } g->I[0] = count; g->I[1] = "SIIrxg"[q->type]; w(g, "#define ~S0"); write_b(g, q->b); w(g, " (~c1[~I0])~N"); } break; } } w(g, "~N" "#ifdef __cplusplus~N" "}~N" "#endif~N"); /* for C++ */ w(g, "~N"); } extern void generate_program_c(struct generator * g) { g->outbuf = str_new(); write_start_comment(g, "/* ", " */"); generate_head(g); generate_routine_headers(g); w(g, "#ifdef __cplusplus~N" "extern \"C\" {~N" "#endif~N" "~N"); generate_create_and_close_templates(g); w(g, "~N" "#ifdef __cplusplus~N" "}~N" "#endif~N"); generate_amongs(g); generate_groupings(g); g->declarations = g->outbuf; g->outbuf = str_new(); g->literalstring_count = 0; { struct node * p = g->analyser->program; while (p) { generate(g, p); p = p->right; } } generate_create(g); generate_close(g); output_str(g->options->output_src, g->declarations); str_delete(g->declarations); output_str(g->options->output_src, g->outbuf); str_clear(g->outbuf); write_start_comment(g, "/* ", " */"); generate_header_file(g); output_str(g->options->output_h, g->outbuf); str_delete(g->outbuf); } /* Generator functions common to multiple languages. */ extern struct generator * create_generator(struct analyser * a, struct options * o) { NEW(generator, g); g->analyser = a; g->options = o; g->margin = 0; g->debug_count = 0; g->copy_from_count = 0; g->line_count = 0; g->line_labelled = 0; g->failure_label = -1; g->unreachable = false; #ifndef DISABLE_PYTHON g->max_label = 0; #endif return g; } extern void close_generator(struct generator * g) { FREE(g); } /* Write routines for simple entities */ extern void write_char(struct generator * g, int ch) { str_append_ch(g->outbuf, ch); /* character */ } extern void write_newline(struct generator * g) { str_append_ch(g->outbuf, '\n'); /* newline */ g->line_count++; } extern void write_string(struct generator * g, const char * s) { str_append_string(g->outbuf, s); } extern void write_int(struct generator * g, int i) { str_append_int(g->outbuf, i); } extern void write_b(struct generator * g, symbol * b) { str_append_b(g->outbuf, b); } extern void write_str(struct generator * g, struct str * str) { str_append(g->outbuf, str); }