urbit/v/main.c
2015-06-09 01:54:43 -07:00

404 lines
8.5 KiB
C

/* v/main.c
**
*/
#include <stdio.h>
#include <stdlib.h>
#include <fcntl.h>
#include <sys/ioctl.h>
#include <sys/stat.h>
#include <unistd.h>
#include <setjmp.h>
#include <signal.h>
#include <gmp.h>
#include <stdint.h>
#include <uv.h>
#include <sigsegv.h>
#include <curses.h>
#include <termios.h>
#include <term.h>
#include <dirent.h>
#define U3_GLOBAL
#define C3_GLOBAL
#include "all.h"
#include "v/vere.h"
/* _main_readw(): parse a word from a string.
*/
static u3_noun
_main_readw(const c3_c* str_c, c3_w max_w, c3_w* out_w)
{
c3_c* end_c;
c3_w par_w = strtoul(str_c, &end_c, 0);
if ( *str_c != '\0' && *end_c == '\0' && par_w < max_w ) {
*out_w = par_w;
return c3y;
}
else return c3n;
}
static c3_c hostbuf[2048]; // kill me
/* _main_presig(): prefix optional sig.
*/
c3_c*
_main_presig(c3_c* txt_c)
{
c3_c* new_c = malloc(2 + strlen(txt_c));
if ( '~' == *txt_c ) {
strcpy(new_c, txt_c);
} else {
new_c[0] = '~';
strcpy(new_c + 1, txt_c);
}
return new_c;
}
/* _main_getopt(): extract option map from command line.
*/
static u3_noun
_main_getopt(c3_i argc, c3_c** argv)
{
c3_i ch_i;
c3_w arg_w;
u3_Host.ops_u.abo = c3n;
u3_Host.ops_u.bat = c3n;
u3_Host.ops_u.gab = c3n;
u3_Host.ops_u.loh = c3n;
u3_Host.ops_u.dem = c3n;
u3_Host.ops_u.fog = c3n;
u3_Host.ops_u.fak = c3n;
u3_Host.ops_u.pro = c3n;
u3_Host.ops_u.dry = c3n;
u3_Host.ops_u.veb = c3n;
u3_Host.ops_u.qui = c3n;
u3_Host.ops_u.nuu = c3n;
u3_Host.ops_u.mem = c3n;
u3_Host.ops_u.kno_w = DefaultKernel;
while ( (ch_i = getopt(argc, argv, "I:w:t:X:f:k:l:n:p:r:LabcdgqvFMPD")) != -1 ) {
switch ( ch_i ) {
case 'M': {
u3_Host.ops_u.mem = c3y;
break;
}
case 'I': {
u3_Host.ops_u.imp_c = strdup(optarg);
break;
}
case 'w': {
u3_Host.ops_u.who_c = _main_presig(optarg);
u3_Host.ops_u.nuu = c3y;
u3_Host.dir_c = strdup(1 + u3_Host.ops_u.who_c);
break;
}
case 't': {
u3_Host.ops_u.tic_c = _main_presig(optarg);
break;
}
case 'X': {
if ( 0 != strcmp("wtf", optarg) ) {
return c3n;
} else u3_Host.ops_u.fog = c3y;
break;
}
case 'f': {
if ( c3n == _main_readw(optarg, 100, &u3_Host.ops_u.fuz_w) ) {
return c3n;
}
break;
}
case 'k': {
if ( c3n == _main_readw(optarg, 256, &u3_Host.ops_u.kno_w) ) {
return c3n;
}
break;
}
case 'l': {
if ( c3n == _main_readw(optarg, 65536, &arg_w) ) {
return c3n;
} else u3_Host.ops_u.rop_s = arg_w;
break;
}
case 'n': {
u3_Host.ops_u.nam_c = strdup(optarg);
break;
}
case 'p': {
if ( c3n == _main_readw(optarg, 65536, &arg_w) ) {
return c3n;
} else u3_Host.ops_u.por_s = arg_w;
break;
}
case 'r': {
u3_Host.ops_u.raf_c = strdup(optarg);
break;
}
case 'L': { u3_Host.ops_u.loh = c3y; break; }
case 'F': {
u3_Host.ops_u.loh = c3y;
u3_Host.ops_u.fak = c3y;
break;
}
case 'a': { u3_Host.ops_u.abo = c3y; break; }
case 'b': { u3_Host.ops_u.bat = c3y; break; }
case 'c': { u3_Host.ops_u.nuu = c3y; break; }
case 'd': { u3_Host.ops_u.dem = c3y; break; }
case 'g': { u3_Host.ops_u.gab = c3y; break; }
case 'P': { u3_Host.ops_u.pro = c3y; break; }
case 'D': { u3_Host.ops_u.dry = c3y; break; }
case 'q': { u3_Host.ops_u.qui = c3y; break; }
case 'v': { u3_Host.ops_u.veb = c3y; break; }
case '?': default: {
return c3n;
}
}
}
if ( u3_Host.ops_u.rop_s == 0 && u3_Host.ops_u.raf_c != 0 ) {
fprintf(stderr, "The -r flag requires -l.\n");
return c3n;
}
if ( c3y == u3_Host.ops_u.bat ) {
u3_Host.ops_u.dem = c3y;
u3_Host.ops_u.nuu = c3y;
}
if ( u3_Host.ops_u.nam_c == 0 ) {
u3_Host.ops_u.nam_c = getenv("HOSTNAME");
if ( u3_Host.ops_u.nam_c == 0 ) {
c3_w len_w = sysconf(_SC_HOST_NAME_MAX) + 1;
u3_Host.ops_u.nam_c = hostbuf;
if ( 0 != gethostname(u3_Host.ops_u.nam_c, len_w) ) {
perror("gethostname");
exit(1);
}
}
}
if ( argc != (optind + 1) ) {
return u3_Host.dir_c ? c3y : c3n;
} else {
{
c3_c* ash_c;
if ( (ash_c = strrchr(argv[optind], '/')) && (ash_c[1] == 0) ) {
*ash_c = 0;
}
}
u3_Host.dir_c = strdup(argv[optind]);
return c3y;
}
}
/* u3_ve_usage(): print usage and exit.
*/
static void
u3_ve_usage(c3_i argc, c3_c** argv)
{
fprintf(stderr, "%s: usage: [-v] [-k stage] [-p ames_port] computer\n",
argv[0]);
exit(1);
}
#if 0
/* u3_ve_panic(): panic and exit.
*/
static void
u3_ve_panic(c3_i argc, c3_c** argv)
{
fprintf(stderr, "%s: gross system failure\n", argv[0]);
exit(1);
}
#endif
/* u3_ve_sysopt(): apply option map to system state.
*/
static void
u3_ve_sysopt()
{
u3_Local = strdup(u3_Host.dir_c);
u3_System = U3_LIB;
}
#if 0
static jmp_buf Signal_buf;
#ifndef SIGSTKSZ
# define SIGSTKSZ 16384
#endif
static uint8_t Sigstk[SIGSTKSZ];
volatile enum { sig_none, sig_overflow, sig_interrupt } Sigcause;
static void _main_cont(void *arg1, void *arg2, void *arg3)
{
(void)(arg1);
(void)(arg2);
(void)(arg3);
siglongjmp(Signal_buf, 1);
}
static void
overflow_handler(int emergency, stackoverflow_context_t scp)
{
if ( 1 == emergency ) {
write(2, "stack emergency\n", strlen("stack emergency" + 2));
exit(1);
} else {
Sigcause = sig_overflow;
sigsegv_leave_handler(_main_cont, NULL, NULL, NULL);
}
}
// Install signal handlers and set buffers.
//
// Note that we use the sigmask-restoring variant. Essentially, when
// we get a signal, we force the system back into the just-booted state.
// If anything goes wrong during boot (above), it's curtains.
{
if ( 0 != sigsetjmp(Signal_buf, 1) ) {
switch ( Sigcause ) {
case sig_overflow: printf("[stack overflow]\r\n"); break;
case sig_interrupt: printf("[interrupt]\r\n"); break;
default: printf("[signal error!]\r\n"); break;
}
Sigcause = sig_none;
signal(SIGINT, SIG_DFL);
stackoverflow_deinstall_handler();
// Print the trace, do a GC, etc.
//
// This is half-assed at present, so we exit.
//
u3_lo_sway(0, u3k(u3_wire_tax(u3_Wire)));
u3_lo_bail(u3A);
exit(1);
}
if ( -1 == stackoverflow_install_handler
(overflow_handler, Sigstk, SIGSTKSZ) )
{
fprintf(stderr, "overflow_handler: install failed\n");
exit(1);
}
signal(SIGINT, interrupt_handler);
signal(SIGIO, SIG_IGN);
}
static void
interrupt_handler(int x)
{
Sigcause = sig_interrupt;
longjmp(Signal_buf, 1);
}
#endif
#define GRAB
c3_i
main(c3_i argc,
c3_c** argv)
{
// Parse options.
//
if ( c3n == _main_getopt(argc, argv) ) {
u3_ve_usage(argc, argv);
return 1;
}
u3_ve_sysopt();
printf("~\n");
// printf("welcome.\n");
printf("urbit: home is %s\n", u3_Host.dir_c);
// printf("vere: hostname is %s\n", u3_Host.ops_u.nam_c);
if ( c3y == u3_Host.ops_u.dem && c3n == u3_Host.ops_u.bat ) {
printf("urbit: running as daemon\n");
}
// Seed prng. Don't panic -- just for fuzz testing.
//
srand(getpid());
// Instantiate process globals.
{
/* Boot the image and checkpoint. Set flags.
*/
{
/* Set pier directory.
*/
u3C.dir_c = u3_Host.dir_c;
/* Set GC flag.
*/
if ( _(u3_Host.ops_u.gab) ) {
u3C.wag_w |= u3o_debug_ram;
}
/* Set profile flag.
*/
if ( _(u3_Host.ops_u.pro) ) {
u3C.wag_w |= u3o_debug_cpu;
}
/* Set verbose flag.
*/
if ( _(u3_Host.ops_u.veb) ) {
u3C.wag_w |= u3o_verbose;
}
/* Set quiet flag.
*/
if ( _(u3_Host.ops_u.qui) ) {
u3C.wag_w |= u3o_quiet;
}
/* Set dry-run flag.
*/
if ( _(u3_Host.ops_u.dry) ) {
u3C.wag_w |= u3o_dryrun;
}
}
u3m_boot(u3_Host.ops_u.nuu, u3_Host.ops_u.gab, u3_Host.dir_c);
/* Start Arvo.
*/
#if 1
{
struct timeval tim_tv;
u3_noun now;
gettimeofday(&tim_tv, 0);
now = u3_time_in_tv(&tim_tv);
u3v_start(now);
}
#endif
#if 0
/* Initial checkpoint.
*/
if ( _(u3_Host.ops_u.nuu) ) {
printf("about to save.\r\n");
u3e_save();
printf("saved.\r\n");
}
#endif
}
// u3e_grab("main", u3_none);
//
u3_lo_loop();
return 0;
}