/* -*-comment-start: "//";comment-end:""-*- * GNU Mes --- Maxwell Equations of Software * Copyright © 2016,2017,2018 Jan (janneke) Nieuwenhuizen * * This file is part of GNU Mes. * * GNU Mes 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 3 of the License, or (at * your option) any later version. * * GNU Mes 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 GNU Mes. If not, see . */ #if SYSTEM_LIBC #error "SYSTEM_LIBC not supported" #endif #include #include #include #include #include char arena[2000]; typedef int SCM; int g_debug = 0; int g_free = 0; SCM g_continuations = 0; SCM g_symbols = 0; SCM g_stack = 0; SCM r0 = 0; // a/env SCM r1 = 0; // param 1 SCM r2 = 0; // save 2+load/dump SCM r3 = 0; // continuation enum type_t { TCHAR, TCLOSURE, TCONTINUATION, TFUNCTION, TKEYWORD, TMACRO, TNUMBER, TPAIR, TREF, TSPECIAL, TSTRING, TSYMBOL, TVALUES, TVECTOR, TBROKEN_HEART }; struct scm { enum type_t type; SCM car; SCM cdr; }; struct function { int (*function) (void); int arity; char *name; }; #if __MESC__ struct scm *g_cells = arena; #else struct scm *g_cells = (struct scm *) arena; #endif #define cell_nil 1 #define cell_f 2 #define cell_t 3 #define cell_dot 4 // #define cell_arrow 5 #define cell_undefined 6 #define cell_unspecified 7 #define cell_closure 8 #define cell_circular 9 #define cell_begin 10 #define cell_symbol_dot 11 #define cell_symbol_lambda 12 #define cell_symbol_begin 13 #define cell_symbol_if 14 #define cell_symbol_quote 15 #define cell_symbol_set_x 16 #define cell_vm_apply 45 #define cell_vm_apply2 46 #define cell_vm_eval 47 #define cell_vm_begin 56 //#define cell_vm_begin_read_input_file 57 #define cell_vm_begin2 58 #define cell_vm_return 63 SCM tmp; SCM tmp_num; SCM tmp_num2; int ARENA_SIZE = 200; struct function g_functions[5]; int g_function = 0; SCM make_cell_ (SCM type, SCM car, SCM cdr); struct function fun_make_cell_ = { &make_cell_, 3, "core:make-cell" }; struct scm scm_make_cell_ = { TFUNCTION, 0, 0 }; //, "core:make-cell", 0}; SCM cell_make_cell_; SCM cons (SCM x, SCM y); struct function fun_cons = { &cons, 2, "cons" }; struct scm scm_cons = { TFUNCTION, 0, 0 }; // "cons", 0}; SCM cell_cons; SCM car (SCM x); struct function fun_car = { &car, 1, "car" }; struct scm scm_car = { TFUNCTION, 0, 0 }; // "car", 0}; SCM cell_car; SCM cdr (SCM x); struct function fun_cdr = { &cdr, 1, "cdr" }; struct scm scm_cdr = { TFUNCTION, 0, 0 }; // "cdr", 0}; SCM cell_cdr; // SCM eq_p (SCM x, SCM y); // struct function fun_eq_p = {&eq_p,2,"eq?"}; // scm scm_eq_p = {TFUNCTION,0,0}; // SCM cell_eq_p; #define TYPE(x) (g_cells[x].type) #define CAR(x) g_cells[x].car #define LENGTH(x) g_cells[x].car #define STRING(x) g_cells[x].car #define CDR(x) g_cells[x].cdr #define CONTINUATION(x) g_cells[x].cdr #define FUNCTION(x) g_functions[g_cells[x].cdr] #define VALUE(x) g_cells[x].cdr #define VECTOR(x) g_cells[x].cdr #define MAKE_CHAR(n) make_cell_ (tmp_num_ (TCHAR), 0, tmp_num2_ (n)) #define MAKE_NUMBER(n) make_cell_ (tmp_num_ (TNUMBER), 0, tmp_num2_ (n)) #define CAAR(x) CAR (CAR (x)) #define CADAR(x) CAR (CDR (CAR (x))) #define CDADAR(x) CAR (CDR (CAR (CDR (x)))) #define CADR(x) CAR (CDR (x)) #define MAKE_STRING(x) make_cell_ (tmp_num_ (TSTRING), x, 0) SCM alloc (int n) { assert (g_free + n < ARENA_SIZE); SCM x = g_free; g_free += n; return x; } SCM make_cell_ (SCM type, SCM car, SCM cdr) { SCM x = alloc (1); assert (TYPE (type) == TNUMBER); TYPE (x) = VALUE (type); if (VALUE (type) == TCHAR || VALUE (type) == TNUMBER) { if (car) CAR (x) = CAR (car); if (cdr) CDR (x) = CDR (cdr); } else if (VALUE (type) == TFUNCTION) { if (car) CAR (x) = car; if (cdr) CDR (x) = CDR (cdr); } else { CAR (x) = car; CDR (x) = cdr; } return x; } SCM tmp_num_ (int x) { VALUE (tmp_num) = x; return tmp_num; } SCM tmp_num2_ (int x) { VALUE (tmp_num2) = x; return tmp_num2; } SCM cons (SCM x, SCM y) { VALUE (tmp_num) = TPAIR; return make_cell_ (tmp_num, x, y); } SCM car (SCM x) { return CAR (x); } SCM cdr (SCM x) { return CDR (x); } SCM gc_push_frame () { SCM frame = cons (r1, cons (r2, cons (r3, cons (r0, cell_nil)))); g_stack = cons (frame, g_stack); return g_stack; } SCM append2 (SCM x, SCM y) { if (x == cell_nil) return y; assert (TYPE (x) == TPAIR); return cons (car (x), append2 (cdr (x), y)); } SCM pairlis (SCM x, SCM y, SCM a) { if (x == cell_nil) return a; if (TYPE (x) != TPAIR) return cons (cons (x, y), a); return cons (cons (car (x), car (y)), pairlis (cdr (x), cdr (y), a)); } SCM assq (SCM x, SCM a) { while (a != cell_nil && x == CAAR (a)) a = CDR (a); return a != cell_nil ? car (a) : cell_f; } SCM push_cc (SCM p1, SCM p2, SCM a, SCM c) ///((internal)) { puts ("push cc\n"); SCM x = r3; r3 = c; r2 = p2; gc_push_frame (); r1 = p1; r0 = a; r3 = x; return cell_unspecified; } SCM caar (SCM x) { return car (car (x)); } SCM cadr (SCM x) { return car (cdr (x)); } SCM cdar (SCM x) { return cdr (car (x)); } SCM cddr (SCM x) { return cdr (cdr (x)); } #if __GNUC__ //FIXME SCM call (SCM, SCM); SCM gc_pop_frame (); #endif SCM eval_apply () { eval_apply: switch (r3) { case cell_vm_apply: { goto apply; } case cell_unspecified: { return r1; } } SCM x = cell_nil; SCM y = cell_nil; apply: switch (TYPE (car (r1))) { case TFUNCTION: { puts ("apply.function\n"); r1 = call (car (r1), cdr (r1)); goto vm_return; } } vm_return: x = r1; gc_pop_frame (); r1 = x; goto eval_apply; } SCM call (SCM fn, SCM x) { puts ("call\n"); if ((FUNCTION (fn).arity > 0 || FUNCTION (fn).arity == -1) && x != cell_nil && TYPE (CAR (x)) == TVALUES) x = cons (CADAR (x), CDR (x)); if ((FUNCTION (fn).arity > 1 || FUNCTION (fn).arity == -1) && x != cell_nil && TYPE (CDR (x)) == TPAIR && TYPE (CADR (x)) == TVALUES) x = cons (CAR (x), cons (CDADAR (x), CDR (x))); switch (FUNCTION (fn).arity) { case 0: { return (FUNCTION (fn).function) (); } case 1: { return ((SCM (*)(SCM)) (FUNCTION (fn).function)) (car (x)); } case 2: { return ((SCM (*)(SCM, SCM)) (FUNCTION (fn).function)) (car (x), cadr (x)); } case 3: { return ((SCM (*)(SCM, SCM, SCM)) (FUNCTION (fn).function)) (car (x), cadr (x), car (cddr (x))); } case -1: { return ((SCM (*)(SCM)) (FUNCTION (fn).function)) (x); } } return cell_unspecified; } SCM gc_peek_frame () { SCM frame = car (g_stack); r1 = car (frame); r2 = cadr (frame); r3 = car (cddr (frame)); r0 = cadr (cddr (frame)); return frame; } SCM gc_pop_frame () { SCM frame = gc_peek_frame (g_stack); g_stack = cdr (g_stack); return frame; } SCM mes_g_stack (SCM a) ///((internal)) { r0 = a; r1 = MAKE_CHAR (0); r2 = MAKE_CHAR (0); r3 = MAKE_CHAR (0); g_stack = cons (cell_nil, cell_nil); return r0; } // Environment setup SCM make_tmps (struct scm * cells) { tmp = g_free++; cells[tmp].type = TCHAR; tmp_num = g_free++; cells[tmp_num].type = TNUMBER; tmp_num2 = g_free++; cells[tmp_num2].type = TNUMBER; return 0; } SCM make_symbol_ (SCM s) { VALUE (tmp_num) = TSYMBOL; SCM x = make_cell_ (tmp_num, s, 0); g_symbols = cons (x, g_symbols); return x; } SCM make_symbol (SCM s) { SCM x = 0; return x ? x : make_symbol_ (s); } SCM acons (SCM key, SCM value, SCM alist) { return cons (cons (key, value), alist); } // Jam Collector SCM g_symbol_max; SCM gc_init_cells () { return 0; } // INIT NEWS SCM mes_symbols () ///((internal)) { gc_init_cells (); // gc_init_news (); #if __GNUC__ && 0 //#include "mes.symbols.i" #else g_free++; // g_cells[cell_nil] = scm_nil; g_free++; // g_cells[cell_f] = scm_f; g_free++; // g_cells[cell_t] = scm_t; g_free++; // g_cells[cell_dot] = scm_dot; g_free++; // g_cells[cell_arrow] = scm_arrow; g_free++; // g_cells[cell_undefined] = scm_undefined; g_free++; // g_cells[cell_unspecified] = scm_unspecified; g_free++; // g_cells[cell_closure] = scm_closure; g_free++; // g_cells[cell_circular] = scm_circular; g_free++; // g_cells[cell_begin] = scm_begin; /// g_free = 44; g_free++; // g_cells[cell_vm_apply] = scm_vm_apply; g_free++; // g_cells[cell_vm_apply2] = scm_vm_apply2; g_free++; // g_cells[cell_vm_eval] = scm_vm_eval; /// g_free = 55; g_free++; // g_cells[cell_vm_begin] = scm_vm_begin; g_free++; // g_cells[cell_vm_begin_read_input_file] = scm_vm_begin_read_input_file; g_free++; // g_cells[cell_vm_begin2] = scm_vm_begin2; /// g_free = 62; g_free++; // g_cells[cell_vm_return] = scm_vm_return; #endif g_symbol_max = g_free; make_tmps (g_cells); g_symbols = 0; for (int i = 1; i < g_symbol_max; i++) g_symbols = cons (i, g_symbols); SCM a = cell_nil; a = acons (cell_symbol_dot, cell_dot, a); a = acons (cell_symbol_begin, cell_begin, a); a = acons (cell_closure, a, a); return a; } SCM make_closure (SCM args, SCM body, SCM a) { return make_cell_ (tmp_num_ (TCLOSURE), cell_f, cons (cons (cell_circular, a), cons (args, body))); } SCM mes_environment () ///((internal)) { SCM a = 0; a = mes_symbols (); a = mes_g_stack (a); return a; } SCM mes_builtins (SCM a) { #if 0 //__GNUC__ //#include "mes.i" // #include "lib.i" // #include "math.i" // #include "posix.i" // #include "reader.i" // #include "lib.environment.i" // #include "math.environment.i" // #include "mes.environment.i" // #include "posix.environment.i" // #include "reader.environment.i" #else scm_make_cell_.cdr = g_function; g_functions[g_function++] = fun_make_cell_; cell_make_cell_ = g_free++; g_cells[cell_make_cell_] = scm_make_cell_; scm_cons.cdr = g_function; g_functions[g_function++] = fun_cons; cell_cons = g_free++; g_cells[cell_cons] = scm_cons; scm_car.cdr = g_function; g_functions[g_function++] = fun_car; cell_car = g_free++; g_cells[cell_car] = scm_car; scm_cdr.cdr = g_function; g_functions[g_function++] = fun_cdr; cell_cdr = g_free++; g_cells[cell_cdr] = scm_cdr; #endif return a; } SCM bload_env (SCM a) ///((internal)) { __stdin = open ("module/mes/read-0.mo", 0); char *p = (char *) g_cells; assert (getchar () == 'M'); assert (getchar () == 'E'); assert (getchar () == 'S'); g_stack = getchar () << 8; g_stack += getchar (); int c = getchar (); while (c != EOF) { *p++ = c; c = getchar (); } g_free = (p - (char *) g_cells) / sizeof (struct scm); gc_peek_frame (); g_symbols = r1; __stdin = STDIN; r0 = mes_builtins (r0); return r2; } SCM fill () { TYPE (0) = 0x6c6c6168; CAR (0) = 0x6a746f6f; CDR (0) = 0x00002165; TYPE (1) = TSYMBOL; CAR (1) = 0x2d2d2d2d; CDR (1) = 0x3e3e3e3e; TYPE (9) = 0x2d2d2d2d; CAR (9) = 0x2d2d2d2d; CDR (9) = 0x3e3e3e3e; // (cons 0 1) TYPE (10) = TPAIR; CAR (10) = 11; CDR (10) = 12; TYPE (11) = TFUNCTION; CAR (11) = 0x58585858; // 0 = make_cell_ // 1 = cons // 2 = car CDR (11) = 1; TYPE (12) = TPAIR; CAR (12) = 13; //CDR (12) = 1; CDR (12) = 14; TYPE (13) = TNUMBER; CAR (13) = 0x58585858; CDR (13) = 0; TYPE (14) = TPAIR; CAR (14) = 15; CDR (14) = 1; TYPE (15) = TNUMBER; CAR (15) = 0x58585858; CDR (15) = 1; return 0; } SCM display_ (SCM x) { //puts ("\n"); switch (TYPE (x)) { case TCHAR: { //puts ("\n"); puts ("#\\"); putchar (VALUE (x)); break; } case TFUNCTION: { //puts ("\n"); if (VALUE (x) == 0) puts ("core:make-cell"); if (VALUE (x) == 1) puts ("cons"); if (VALUE (x) == 2) puts ("car"); if (VALUE (x) == 3) puts ("cdr"); break; } case TNUMBER: { //puts ("\n"); #if __GNUC__ puts (itoa (VALUE (x))); #else int i; i = VALUE (x); i = i + 48; putchar (i); #endif break; } case TPAIR: { //puts ("\n"); //if (cont != cell_f) puts "("); puts ("("); if (x && x != cell_nil) display_ (CAR (x)); if (CDR (x) && CDR (x) != cell_nil) { #if __GNUC__ if (TYPE (CDR (x)) != TPAIR) puts (" . "); #else int c; c = CDR (x); c = TYPE (c); if (c != TPAIR) puts (" . "); #endif display_ (CDR (x)); } //if (cont != cell_f) puts (")"); puts (")"); break; } case TSPECIAL: { switch (x) { case 1: { puts ("()"); break; } case 2: { puts ("#f"); break; } case 3: { puts ("#t"); break; } default: { #if __GNUC__ puts (""); #else puts (""); #endif } } break; } case TSYMBOL: { switch (x) { case 11: { puts (" . "); break; } case 12: { puts ("lambda"); break; } case 13: { puts ("begin"); break; } case 14: { puts ("if"); break; } case 15: { puts ("quote"); break; } case 37: { puts ("car"); break; } case 38: { puts ("cdr"); break; } case 39: { puts ("null?"); break; } case 40: { puts ("eq?"); break; } case 41: { puts ("cons"); break; } default: { #if __GNUC__ puts (""); #else puts (""); #endif } } break; } default: { //puts ("\n"); #if __GNUC__ puts ("<"); puts (itoa (TYPE (x))); puts (":"); puts (itoa (x)); puts (">"); #else puts ("_"); #endif break; } } return 0; } SCM simple_bload_env (SCM a) ///((internal)) { puts ("reading: "); char *mo = "module/mes/tiny-0-32.mo"; puts (mo); puts ("\n"); __stdin = open (mo, 0); if (__stdin < 0) { eputs ("no such file: module/mes/tiny-0-32.mo\n"); return 1; } char *p = (char *) g_cells; int c; assert (getchar () == 'M'); assert (getchar () == 'E'); assert (getchar () == 'S'); puts (" *GOT MES*\n"); g_stack = getchar () << 8; g_stack += getchar (); puts ("stack: "); puts (itoa (g_stack)); puts ("\n"); c = getchar (); while (c != -1) { *p++ = c; c = getchar (); } puts ("read done\n"); g_free = (p - (char *) g_cells) / sizeof (struct scm); if (g_free != 15) exit (33); g_symbols = 1; __stdin = STDIN; r0 = mes_builtins (r0); if (g_free != 19) exit (34); puts ("cells read: "); puts (itoa (g_free)); puts ("\n"); puts ("symbols: "); puts (itoa (g_symbols)); puts ("\n"); // display_ (g_symbols); // puts ("\n"); display_ (10); puts ("\n"); fill (); r2 = 10; if (TYPE (12) != TPAIR) exit (33); puts ("program["); puts (itoa (r2)); puts ("]: "); display_ (r2); //display_ (14); puts ("\n"); r0 = 1; //r2 = 10; return r2; } int main (int argc, char *argv[]) { puts ("Hello cons-mes!\n"); if (argc > 1 && !strcmp (argv[1], "--help")) return eputs ("Usage: mes [--dump|--load] < FILE"); #if __GNUC__ if (argc > 1 && !strcmp (argv[1], "--version")) { eputs ("Mes "); return eputs (MES_VERSION); }; #else if (argc > 1 && !strcmp (argv[1], "--version")) { eputs ("Mes "); return eputs ("0.4"); }; #endif __stdin = STDIN; r0 = mes_environment (); SCM program = simple_bload_env (r0); puts ("g_free="); puts (itoa (g_free)); puts ("\n"); push_cc (r2, cell_unspecified, r0, cell_unspecified); puts ("g_free="); puts (itoa (g_free)); puts ("\n"); puts ("g_stack="); puts (itoa (g_stack)); puts ("\n"); puts ("r0="); puts (itoa (r0)); puts ("\n"); puts ("r1="); puts (itoa (r1)); puts ("\n"); puts ("r2="); puts (itoa (r2)); puts ("\n"); puts ("r3="); puts (itoa (r3)); puts ("\n"); r3 = cell_vm_apply; r1 = eval_apply (); display_ (r1); eputs ("\n"); return 0; }