/*int main(void){*/
void kmain(void){
// vga_init();
// puts((uint8_t*)"Hello kernel world!\n");
/*do some work here, like initialize timer or paging*/
kinit1(end, P2V(4*1024*1024)); // phys page allocator
kvmalloc(); // kernel page table
mpinit(); // collect info about this machine
lapicinit();
// gdt_descriptor();
// puts((uint8_t*)"GDT initialized...\n");
// idt_descriptor();
// puts((uint8_t*)"IDT initialized...\n");
// cprintf("IDT initialized...\n");
seginit(); // set up segments
cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
picinit(); // interrupt controller
ioapicinit(); // another interrupt controller
consoleinit(); // I/O devices & their interrupts
uartinit(); // serial port
pinit(); // process table
tvinit(); // trap vectors
binit(); // buffer cache
fileinit(); // file table
ideinit(); // disk
if(!ismp)
timerinit(); // uniprocessor timer
startothers(); // start other processors
kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
userinit(); // first user process
// Finish setting up this processor in mpmain.
mpmain();
}
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
kinit1(end, P2V(4*1024*1024)); // phys page allocator
kvmalloc(); // kernel page table
mpinit(); // collect info about this machine
lapicinit();
seginit(); // set up segments
cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
picinit(); // interrupt controller
ioapicinit(); // another interrupt controller
consoleinit(); // I/O devices & their interrupts
uartinit(); // serial port
pinit(); // process table
tvinit(); // trap vectors
binit(); // buffer cache
fileinit(); // file table
ideinit(); // disk
if(!ismp)
timerinit(); // uniprocessor timer
startothers(); // start other processors
kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
userinit(); // first user process
mpmain();
}
void HL1606stripPWM::setSPIdivider(uint8_t spispeed) {
SPIspeedDiv = spispeed;
switch (spispeed) {
case 2:
SPSR |= _BV(SPI2X);
break;
case 4:
// no bits set
break;
case 8:
SPCR |= _BV(SPR0);
SPSR |= _BV(SPI2X);
break;
case 16:
SPCR |= _BV(SPR0);
break;
case 32:
SPCR |= _BV(SPR1);
SPSR |= _BV(SPI2X);
break;
case 64:
SPCR |= _BV(SPR1);
break;
default: // slowest
case 128:
SPCR |= _BV(SPR1);
SPCR |= _BV(SPR0);
}
timerinit();
}
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
kinit1(end, P2V(4*1024*1024)); // phys page allocator
kvmalloc(); // kernel page table
mpinit(); // detect other processors
lapicinit(); // interrupt controller
seginit(); // segment descriptors
cprintf("\ncpu%d: starting xv6\n\n", cpunum());
picinit(); // another interrupt controller
ioapicinit(); // another interrupt controller
consoleinit(); // console hardware
uartinit(); // serial port
pinit(); // process table
tvinit(); // trap vectors
binit(); // buffer cache
fileinit(); // file table
ideinit(); // disk
if(!ismp)
timerinit(); // uniprocessor timer
startothers(); // start other processors
kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
userinit(); // first user process
mpmain(); // finish this processor's setup
init_semaphores_on_boot();
}
// Bootstrap processor starts running C code here.
int
main(int memsize)
{
mpinit(); // collect info about this machine
lapicinit(mpbcpu());
ksegment();
picinit(); // interrupt controller
ioapicinit(); // another interrupt controller
consoleinit(); // I/O devices & their interrupts
uartinit(); // serial port
cprintf("cpus %p cpu %p\n", cpus, cpu);
cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
cprintf("mem: %d kb\n", memsize);
kinit(memsize); // physical memory allocator
pinit(); // process table
tvinit(); // trap vectors
binit(); // buffer cache
fileinit(); // file table
iinit(); // inode cache
ideinit(); // disk
if(!ismp)
timerinit(); // uniprocessor timer
pageinit(); // enable paging
userinit(); // first user process
bootothers(); // start other processors
// Finish setting up this processor in mpmain.
mpmain();
}
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
kinit1(end, P2V(4*1024*1024)); // phys page allocator // kmem. freelist added
cprintf("%x \n", end);
kvmalloc(); // kernel page table
#ifdef CONFIG_MULTI_PROCESS
mpinit(); // collect info about this machine
#endif
lapicinit();
seginit(); // set up segments
picinit(); // interrupt controller: Programmable Interrupt Controller
#ifdef CONFIG_MULTI_PROCESS
ioapicinit(); // another interrupt controller
#endif
consoleinit(); // I/O devices & their interrupts
uartinit(); // serial port
pinit(); // process table
tvinit(); // trap vectors
binit(); // buffer cache
fileinit(); // file table
iinit(); // inode cache
ideinit(); // disk
if(!ismp)
timerinit(); // uniprocessor timer
#ifdef CONFIG_MULTI_PROCESS
startothers(); // start other processors
kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
#endif
userinit(); // first user process
// Finish setting up this processor in mpmain.
mpmain();
}
void
main(void)
{
memset(edata, 0, (ulong)end-(ulong)edata);
conf.nmach = 1;
machinit();
confinit();
xinit();
trapinit();
mmuinit();
plan9iniinit();
hwintrinit();
clockinit();
timerinit();
console();
quotefmtinstall();
printinit();
cpuidprint();
print("\nPlan 9 from Bell Labs\n");
procinit0();
initseg();
timersinit();
links();
chandevreset();
pageinit();
swapinit();
sharedseginit();
fpsave(&initfp);
initfp.fpscr = 0;
userinit();
schedinit();
}
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
kvmalloc(); // kernel page table
mpinit(); // collect info about this machine
lapicinit(mpbcpu());
seginit(); // set up segments
cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
picinit(); // interrupt controller
ioapicinit(); // another interrupt controller
consoleinit(); // I/O devices & their interrupts
uartinit(); // serial port
pinit(); // process table
tvinit(); // trap vectors
binit(); // buffer cache
fileinit(); // file table
iinit(); // inode cache
ideinit(); // disk
if(!ismp)
timerinit(); // uniprocessor timer
startothers(); // start other processors (must come before kinit)
kinit(); // initialize memory allocator
userinit(); // first user process (must come after kinit)
// Finish setting up this processor in mpmain.
mpmain();
}
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
unsigned char FB[]="MESSAGE WRITTEN THROUGH FRAMEBUFFER!!";
fb_init(); // initialize framebuffer device (2015.11.02)
cprintf("\nUsing Framebuffer still presents some problems :(\n\n");
cprintf("\nSuggestion: review the way it is used in console.c\n\n");
fb_write(FB, sizeof(FB)); // Framebuffer maybe could be used before this moment (2015.11.02)
see_mylock(MYLOCK);
kinit1(end, P2V(4*1024*1024)); // phys page allocator
kvmalloc(); // kernel page table
mpinit(); // collect info about this machine
lapicinit();
seginit(); // set up segments
cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
picinit(); // interrupt controller
ioapicinit(); // another interrupt controller
consoleinit(); // I/O devices & their interrupts
uartinit(); // serial port
pinit(); // process table
tvinit(); // trap vectors
binit(); // buffer cache
fileinit(); // file table
ideinit(); // disk
if(!ismp)
timerinit(); // uniprocessor timer
startothers(); // start other processors
kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
userinit(); // first user process
// Finish setting up this processor in mpmain.
mpmain();
}
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
monitor_clear ();
// Print basic system information.
cprintf ("Ensidia\n\n");
cprintf ("Copyright (c) 2013-2014 Fotis Koutoulakis\n");
cprintf ("Based on xv6 by Russ Cox et al, at MIT CSAIL\n");
kinit1(end, P2V(4*1024*1024)); // phys page allocator
kvmalloc(); // kernel page table
mpinit(); // collect info about this machine
lapicinit();
seginit(); // set up segments
cprintf("\ncpu%d: starting xng kernel\n\n", cpu->id);
picinit(); // interrupt controller
ioapicinit(); // another interrupt controller
consoleinit(); // I/O devices & their interrupts
uartinit(); // serial port
pinit(); // process table
tvinit(); // trap vectors
binit(); // buffer cache
fileinit(); // file table
iinit(); // inode cache
ideinit(); // disk
if(!ismp)
timerinit(); // uniprocessor timer
startothers(); // start other processors
kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
userinit(); // first user process
// Finish setting up this processor in mpmain.
mpmain();
}
void HL1606stripPWM::begin(void) {
SPIinit();
timerinit();
// go!
#if defined(__AVR_ATmega32U4__)
TIMSK3 = _BV(OCIE3A);
#else
TIMSK2 = _BV(OCIE2A); // run our strip-writing interrupt
#endif
}
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
kinit1(end, P2V(4*1024*1024)); // phys page allocator
kvmalloc(); // kernel page table
mpinit(); // collect info about this machine
lapicinit();
seginit(); // set up segments
cprintf("\ncpu%d: starting xv6\n\n", cpu->id);
picinit(); // interrupt controller
ioapicinit(); // another interrupt controller
consoleinit(); // I/O devices & their interrupts
uartinit(); // serial port
initGraphMode();
initDom();
tryOnce();
toggleOn();
pinit(); // process table
toggleOn();
tvinit(); // trap vectors
toggleOn();
binit(); // buffer cache
toggleOn();
fileinit(); // file table
toggleOn();
iinit(); // inode cache
toggleOn();
ideinit(); // disk
toggleOn();
if(!ismp)
timerinit(); // uniprocessor timer
toggleOn();
startothers(); // start other processors
toggleOn();
kinit2(P2V(4*1024*1024), P2V(PHYSTOP)); // must come after startothers()
toggleOn();
txt_initLock();
mouseEnable();
initProcessMsgMap();
userinit(); // first user process
toggleOn();
endToggle();
// Finish setting up this processor in mpmain.
mpmain();
}
void
threadmain(int argc, char *argv[])
{
int i;
char *p, *loadfile;
Column *c;
int ncol;
Display *d;
rfork(RFENVG|RFNAMEG);
ncol = -1;
loadfile = nil;
ARGBEGIN{
case 'D':
{extern int _threaddebuglevel;
_threaddebuglevel = ~0;
}
break;
case 'a':
globalautoindent = TRUE;
break;
case 'b':
bartflag = TRUE;
break;
case 'c':
p = ARGF();
if(p == nil)
goto Usage;
ncol = atoi(p);
if(ncol <= 0)
goto Usage;
break;
case 'f':
fontnames[0] = ARGF();
if(fontnames[0] == nil)
goto Usage;
break;
case 'F':
fontnames[1] = ARGF();
if(fontnames[1] == nil)
goto Usage;
break;
case 'l':
loadfile = ARGF();
if(loadfile == nil)
goto Usage;
break;
case 'm':
mtpt = ARGF();
if(mtpt == nil)
goto Usage;
break;
case 'r':
swapscrollbuttons = TRUE;
break;
case 'W':
winsize = ARGF();
if(winsize == nil)
goto Usage;
break;
default:
Usage:
fprint(2, "usage: acme -a -c ncol -f fontname -F fixedwidthfontname -l loadfile -W winsize\n");
threadexitsall("usage");
}ARGEND
fontnames[0] = estrdup(fontnames[0]);
fontnames[1] = estrdup(fontnames[1]);
quotefmtinstall();
fmtinstall('t', timefmt);
cputype = getenv("cputype");
objtype = getenv("objtype");
home = getenv("HOME");
acmeshell = getenv("acmeshell");
if(acmeshell && *acmeshell == '\0')
acmeshell = nil;
p = getenv("tabstop");
if(p != nil){
maxtab = strtoul(p, nil, 0);
free(p);
}
if(maxtab == 0)
maxtab = 4;
if(loadfile)
rowloadfonts(loadfile);
putenv("font", fontnames[0]);
snarffd = open("/dev/snarf", OREAD|OCEXEC);
/*
if(cputype){
sprint(buf, "/acme/bin/%s", cputype);
bind(buf, "/bin", MBEFORE);
}
bind("/acme/bin", "/bin", MBEFORE);
*/
getwd(wdir, sizeof wdir);
/*
if(geninitdraw(nil, derror, fontnames[0], "acme", nil, Refnone) < 0){
fprint(2, "acme: can't open display: %r\n");
threadexitsall("geninitdraw");
}
*/
if(initdraw(derror, fontnames[0], "acme") < 0){
fprint(2, "acme: can't open display: %r\n");
threadexitsall("initdraw");
}
d = display;
font = d->defaultfont;
/*assert(font); */
reffont.f = font;
reffonts[0] = &reffont;
incref(&reffont.ref); /* one to hold up 'font' variable */
incref(&reffont.ref); /* one to hold up reffonts[0] */
fontcache = emalloc(sizeof(Reffont*));
nfontcache = 1;
fontcache[0] = &reffont;
iconinit();
timerinit();
rxinit();
cwait = threadwaitchan();
ccommand = chancreate(sizeof(Command**), 0);
ckill = chancreate(sizeof(Rune*), 0);
cxfidalloc = chancreate(sizeof(Xfid*), 0);
cxfidfree = chancreate(sizeof(Xfid*), 0);
cnewwindow = chancreate(sizeof(Channel*), 0);
cerr = chancreate(sizeof(char*), 0);
cedit = chancreate(sizeof(int), 0);
cexit = chancreate(sizeof(int), 0);
cwarn = chancreate(sizeof(void*), 1);
if(cwait==nil || ccommand==nil || ckill==nil || cxfidalloc==nil || cxfidfree==nil || cerr==nil || cexit==nil || cwarn==nil){
fprint(2, "acme: can't create initial channels: %r\n");
threadexitsall("channels");
}
chansetname(ccommand, "ccommand");
chansetname(ckill, "ckill");
chansetname(cxfidalloc, "cxfidalloc");
chansetname(cxfidfree, "cxfidfree");
chansetname(cnewwindow, "cnewwindow");
chansetname(cerr, "cerr");
chansetname(cedit, "cedit");
chansetname(cexit, "cexit");
chansetname(cwarn, "cwarn");
mousectl = initmouse(nil, screen);
if(mousectl == nil){
fprint(2, "acme: can't initialize mouse: %r\n");
threadexitsall("mouse");
}
mouse = &mousectl->m;
keyboardctl = initkeyboard(nil);
if(keyboardctl == nil){
fprint(2, "acme: can't initialize keyboard: %r\n");
threadexitsall("keyboard");
}
mainpid = getpid();
startplumbing();
/*
plumbeditfd = plumbopen("edit", OREAD|OCEXEC);
if(plumbeditfd < 0)
fprint(2, "acme: can't initialize plumber: %r\n");
else{
cplumb = chancreate(sizeof(Plumbmsg*), 0);
threadcreate(plumbproc, nil, STACK);
}
plumbsendfd = plumbopen("send", OWRITE|OCEXEC);
*/
fsysinit();
#define WPERCOL 8
disk = diskinit();
if(!loadfile || !rowload(&row, loadfile, TRUE)){
rowinit(&row, screen->clipr);
if(ncol < 0){
if(argc == 0)
ncol = 2;
else{
ncol = (argc+(WPERCOL-1))/WPERCOL;
if(ncol < 2)
ncol = 2;
}
}
if(ncol == 0)
ncol = 2;
for(i=0; i<ncol; i++){
c = rowadd(&row, nil, -1);
if(c==nil && i==0)
error("initializing columns");
}
c = row.col[row.ncol-1];
if(argc == 0)
readfile(c, wdir);
else
for(i=0; i<argc; i++){
p = utfrrune(argv[i], '/');
if((p!=nil && strcmp(p, "/guide")==0) || i/WPERCOL>=row.ncol)
readfile(c, argv[i]);
else
readfile(row.col[i/WPERCOL], argv[i]);
}
}
flushimage(display, 1);
acmeerrorinit();
threadcreate(keyboardthread, nil, STACK);
threadcreate(mousethread, nil, STACK);
threadcreate(waitthread, nil, STACK);
threadcreate(xfidallocthread, nil, STACK);
threadcreate(newwindowthread, nil, STACK);
/* threadcreate(shutdownthread, nil, STACK); */
threadnotify(shutdown, 1);
recvul(cexit);
killprocs();
threadexitsall(nil);
}
int main(void)
{
//LEDs
uint16_t hue = 0, brightness = BRI_LIMIT - 1, lastBrightness = brightness;
//motion
int16_t oldaccel[3], rawoldaccel[3], accel[3] = {0}, rawaccel[3] = {0};
int32_t dotp[3];
double flt_div, flt_acos;
int8_t int_acos;
//microphone
uint32_t histPower[HIST_SIZE] = {0}, histPowerIndex = 0;
uint32_t currentPower, avgPower = 0;
double scale;
//idle
uint16_t idleIters = 0, idleActivity = 0;
uint8_t idleMinutes = 0;
// Initialize io ports
ioinit();
// Initialize serial
serialinit();
stdout = &mystdout;
// print banner/battery check
banner();
// Initialize the timer
timerinit();
// Initialize audio capture
audioinit();
// Initialize accelerometer
accelinit();
// Enable interrupts
sei();
while(1)
{
// Wait until audio sample is ready
while(!curAudioPowerReady) {}
curAudioPowerReady = 0;
// Grab the current audio power
currentPower = curAudioPower;
//Read accelerometer, determine hue
oldaccel[0] = accel[0]; oldaccel[1] = accel[1]; oldaccel[2] = accel[2];
rawoldaccel[0] = rawaccel[0]; rawoldaccel[1] = rawaccel[1]; rawoldaccel[2] = rawaccel[2];
adxl345_getxyz(&rawaccel[0], &rawaccel[1], &rawaccel[2]);
//(lowpass filter the accelerometer data)
accel[0] = (rawoldaccel[0] + rawaccel[0]) / 2;
accel[1] = (rawoldaccel[1] + rawaccel[1]) / 2;
accel[2] = (rawoldaccel[2] + rawaccel[2]) / 2;
//theta = acos(a.b / |a||b|)
dotp[0] = accel[0] * oldaccel[0] + accel[1] * oldaccel[1] + accel[2] * oldaccel[2];
dotp[1] = accel[0] * accel[0] + accel[1] * accel[1] + accel[2] * accel[2];
dotp[2] = oldaccel[0] * oldaccel[0] + oldaccel[1] * oldaccel[1] + oldaccel[2] * oldaccel[2];
if(dotp[1] == 0) dotp[1] = 1;
if(dotp[2] == 0) dotp[2] = 1;
flt_div = dotp[0] / (sqrt(dotp[1]) * sqrt(dotp[2]));
flt_acos = acos(flt_div);
int_acos = (int8_t)(flt_acos * 180 / M_PI);
//the amount of motion varies pretty widely; it seems like the best
//aesthetic results are from motion-triggering
if(int_acos > 15)
{
hue += 15;
idleActivity++;
}
if(hue >= HUE_LIMIT) hue -= HUE_LIMIT;
//determine intensity (sliding scale)
avgPower -= histPower[histPowerIndex];
histPower[histPowerIndex] = currentPower;
avgPower += histPower[histPowerIndex];
histPowerIndex++;
if(histPowerIndex >= HIST_SIZE) histPowerIndex = 0;
//scale should vary between 0.5ish and 1.5ish... clamp to [0,1]
scale = (float)(currentPower * HIST_SIZE) / avgPower;
scale -= 0.5;
if(scale > 1.0) scale = 1.0;
if(scale < 0.0) scale = 0.0;
//perception mapping: y=x^4 to give it a concave shape
scale = scale*scale*scale*scale;
brightness = BRI_MIN + (BRI_MAX-BRI_MIN) * scale;
if(brightness < lastBrightness)
brightness = (brightness + lastBrightness) / 2;
lastBrightness = brightness;
//Update LED colors
send_hsb(hue, SATURATION, brightness);
//Handle console
dispatch_console();
// Idle check
idleIters++;
if(idleIters >= ITERS_PER_MINUTE) {
if(idleActivity >= IDLE_ACTIVITY_THRESHOLD) {
// Activity!!! Reset idle minutes
idleMinutes = 0;
} else {
// Not enough activity, mark minute as idle
idleMinutes++;
}
// Shutdown if idle for too long
if(idleMinutes >= IDLE_MINUTES_UNTIL_SHUTDOWN) {
shutdown(0);
}
// Reset iteration counts
idleIters = 0;
idleActivity = 0;
}
// Idle backstop check
if(get_ticks() >= MINUTES_UNTIL_SHUTDOWN * 60) {
shutdown(0);
}
}
}
void HL1606stripPWM::setCPUmax(uint8_t cpumax) {
CPUmaxpercent = cpumax;
timerinit();
}
// Bootstrap processor starts running C code here.
// Allocate a real stack and switch to it, first
// doing some setup required for memory allocator to work.
int
main(void)
{
monitor_clear();
xylos_logo();
kinit1(end, P2V(4 * 1024 * 1024)); // phys page allocator, 16MB for kernel
kvmalloc(); // kernel page table
mpinit(); // collect info about this machine
lapicinit();
seginit(); // set up segments
cprintf("Initializing interrupts... ");
init_generic_irq_table();
picinit(); // interrupt controller
ioapicinit(); // another interrupt controller
cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
cprintf("Initializing console and serial... ");
consoleinit(); // I/O devices & their interrupts
uartinit(); // serial port
cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
cprintf("Setting up swap space disk... ");
swapinit();
cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
cprintf("Initializing tasking... ");
pinit(); // process table
tvinit(); // trap vectors
binit(); // buffer cache
cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
cprintf("Initializing pipe IPC... ");
init_pipe_ipc_system();
if(pipe_ipc_sanitycheck() == 0) {
cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
}
cprintf("Initializing direct IPC... ");
init_direct_ipc_table();
if(direct_ipc_sanitycheck() == 0) {
cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
}
cprintf("Mounting root filesystem... ");
fileinit(); // file table
ideinit(); // disk
cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
if(!ismp) {
cprintf("Starting up uniprocessor CPU... ");
timerinit(); // uniprocessor timer
cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
}
if(ismp) {
if(ncpu > 1) {
cprintf("Starting up %d CPU cores... ", ncpu);
} else {
cprintf("Starting up %d CPU core... ", ncpu);
}
}
startothers(); // start other processors
kinit2(P2V(4 * 1024 * 1024), P2V(PHYSTOP)); // 16MB to PHYSTOP [234MB]
if(ismp) {
cprintf_color(COLOR_BLACK, COLOR_LIGHT_GREEN, false, "done\n");
}
// detects and starts km drivers
auto_enable_nic();
// first user process
userinit();
// Finish setting up this processor in mpmain.
mpmain();
}
void
threadmain(int argc, char *argv[])
{
Column *c;
char buf[256];
int i, ncol;
rfork(RFENVG|RFNAMEG);
ncol = 1;
ARGBEGIN{
case 'c':
ncol = atoi(EARGF(usage()));
if(ncol <= 0)
usage();
break;
case 'm':
webmountpt = EARGF(usage());
break;
case 'p':
procstderr++;
break;
case 't':
charset = EARGF(usage());
break;
default:
usage();
break;
}ARGEND
snprint(buf, sizeof(buf), "%s/ctl", webmountpt);
webctlfd = open(buf, ORDWR);
if(webctlfd < 0)
sysfatal("can't initialize webfs: %r");
snarffd = open("/dev/snarf", OREAD|OCEXEC);
if(initdraw(derror, fontnames[0], "abaco") < 0)
sysfatal("can't open display: %r");
memimageinit();
iconinit();
timerinit();
initfontpaths();
cexit = chancreate(sizeof(int), 0);
crefresh = chancreate(sizeof(Page *), 0);
if(cexit==nil || crefresh==nil)
sysfatal("can't create initial channels: %r");
mousectl = initmouse(nil, screen);
if(mousectl == nil)
sysfatal("can't initialize mouse: %r");
mouse = mousectl;
keyboardctl = initkeyboard(nil);
if(keyboardctl == nil)
sysfatal("can't initialize keyboard: %r");
mainpid = getpid();
plumbwebfd = plumbopen("web", OREAD|OCEXEC);
if(plumbwebfd >= 0){
cplumb = chancreate(sizeof(Plumbmsg*), 0);
proccreate(plumbproc, nil, STACK);
}
plumbsendfd = plumbopen("send", OWRITE|OCEXEC);
rowinit(&row, screen->clipr);
for(i=0; i<ncol; i++){
c = rowadd(&row, nil, -1);
if(c==nil && i==0)
error("initializing columns");
}
c = row.col[row.ncol-1];
for(i=0; i<argc; i++)
if(i/WPERCOL >= row.ncol)
readpage(c, argv[i]);
else
readpage(row.col[i/WPERCOL], argv[i]);
flushimage(display, 1);
threadcreate(keyboardthread, nil, STACK);
threadcreate(mousethread, nil, STACK);
threadnotify(shutdown, 1);
recvul(cexit);
threadexitsall(nil);
}
void
threadmain(int argc, char *argv[])
{
int i;
char *p, *loadfile;
char buf[256];
Column *c;
int ncol;
Display *d;
static void *arg[1];
rfork(RFENVG|RFNAMEG);
ncol = -1;
loadfile = nil;
ARGBEGIN{
case 'a':
globalautoindent = TRUE;
break;
case 'b':
bartflag = TRUE;
break;
case 'c':
p = ARGF();
if(p == nil)
goto Usage;
ncol = atoi(p);
if(ncol <= 0)
goto Usage;
break;
case 'f':
fontnames[0] = ARGF();
if(fontnames[0] == nil)
goto Usage;
break;
case 'F':
fontnames[1] = ARGF();
if(fontnames[1] == nil)
goto Usage;
break;
case 'l':
loadfile = ARGF();
if(loadfile == nil)
goto Usage;
break;
default:
Usage:
fprint(2, "usage: acme [-ab] [-c ncol] [-f font] [-F fixedfont] [-l loadfile | file...]\n");
exits("usage");
}ARGEND
if(fontnames[0] == nil)
fontnames[0] = getenv("font");
if(fontnames[0] == nil)
fontnames[0] = "/lib/font/bit/vga/unicode.font";
if(access(fontnames[0], 0) < 0){
fprint(2, "acme: can't access %s: %r\n", fontnames[0]);
exits("font open");
}
if(fontnames[1] == nil)
fontnames[1] = fontnames[0];
fontnames[0] = estrdup(fontnames[0]);
fontnames[1] = estrdup(fontnames[1]);
quotefmtinstall();
cputype = getenv("cputype");
objtype = getenv("objtype");
home = getenv("home");
p = getenv("tabstop");
if(p != nil){
maxtab = strtoul(p, nil, 0);
free(p);
}
if(maxtab == 0)
maxtab = 4;
if(loadfile)
rowloadfonts(loadfile);
putenv("font", fontnames[0]);
snarffd = open("/dev/snarf", OREAD|OCEXEC);
if(cputype){
sprint(buf, "/acme/bin/%s", cputype);
bind(buf, "/bin", MBEFORE);
}
bind("/acme/bin", "/bin", MBEFORE);
getwd(wdir, sizeof wdir);
if(geninitdraw(nil, derror, fontnames[0], "acme", nil, Refnone) < 0){
fprint(2, "acme: can't open display: %r\n");
exits("geninitdraw");
}
d = display;
font = d->defaultfont;
reffont.f = font;
reffonts[0] = &reffont;
incref(&reffont); /* one to hold up 'font' variable */
incref(&reffont); /* one to hold up reffonts[0] */
fontcache = emalloc(sizeof(Reffont*));
nfontcache = 1;
fontcache[0] = &reffont;
iconinit();
timerinit();
rxinit();
cwait = threadwaitchan();
ccommand = chancreate(sizeof(Command**), 0);
ckill = chancreate(sizeof(Rune*), 0);
cxfidalloc = chancreate(sizeof(Xfid*), 0);
cxfidfree = chancreate(sizeof(Xfid*), 0);
cnewwindow = chancreate(sizeof(Channel*), 0);
cerr = chancreate(sizeof(char*), 0);
cedit = chancreate(sizeof(int), 0);
cexit = chancreate(sizeof(int), 0);
cwarn = chancreate(sizeof(void*), 1);
if(cwait==nil || ccommand==nil || ckill==nil || cxfidalloc==nil || cxfidfree==nil || cerr==nil || cexit==nil || cwarn==nil){
fprint(2, "acme: can't create initial channels: %r\n");
threadexitsall("channels");
}
mousectl = initmouse(nil, screen);
if(mousectl == nil){
fprint(2, "acme: can't initialize mouse: %r\n");
threadexitsall("mouse");
}
mouse = mousectl;
keyboardctl = initkeyboard(nil);
if(keyboardctl == nil){
fprint(2, "acme: can't initialize keyboard: %r\n");
threadexitsall("keyboard");
}
mainpid = getpid();
plumbeditfd = plumbopen("edit", OREAD|OCEXEC);
if(plumbeditfd >= 0){
cplumb = chancreate(sizeof(Plumbmsg*), 0);
proccreate(plumbproc, nil, STACK);
}
plumbsendfd = plumbopen("send", OWRITE|OCEXEC);
fsysinit();
#define WPERCOL 8
disk = diskinit();
if(!loadfile || !rowload(&row, loadfile, TRUE)){
rowinit(&row, screen->clipr);
if(ncol < 0){
if(argc == 0)
ncol = 2;
else{
ncol = (argc+(WPERCOL-1))/WPERCOL;
if(ncol < 2)
ncol = 2;
}
}
if(ncol == 0)
ncol = 2;
for(i=0; i<ncol; i++){
c = rowadd(&row, nil, -1);
if(c==nil && i==0)
error("initializing columns");
}
c = row.col[row.ncol-1];
if(argc == 0)
readfile(c, wdir);
else
for(i=0; i<argc; i++){
p = utfrrune(argv[i], '/');
if((p!=nil && strcmp(p, "/guide")==0) || i/WPERCOL>=row.ncol)
readfile(c, argv[i]);
else
readfile(row.col[i/WPERCOL], argv[i]);
}
}
flushimage(display, 1);
acmeerrorinit();
threadcreate(keyboardthread, nil, STACK);
threadcreate(mousethread, nil, STACK);
threadcreate(waitthread, nil, STACK);
threadcreate(xfidallocthread, nil, STACK);
threadcreate(newwindowthread, nil, STACK);
threadnotify(shutdown, 1);
recvul(cexit);
killprocs();
threadexitsall(nil);
}
