pxt-calliope/libs/core/codal.cpp

281 lines
6.2 KiB
C++

#include "pxt.h"
#include <stdarg.h>
PXT_ABI(__aeabi_dadd)
PXT_ABI(__aeabi_dcmplt)
PXT_ABI(__aeabi_dcmpgt)
PXT_ABI(__aeabi_dsub)
PXT_ABI(__aeabi_ddiv)
PXT_ABI(__aeabi_dmul)
extern "C" void target_panic(int error_code) {
// wait for serial to flush
wait_us(300000);
microbit_panic(error_code);
}
extern "C" void target_reset() {
microbit_reset();
}
uint32_t device_heap_size(uint8_t heap_index); // defined in microbit-dal
namespace pxt {
MicroBit uBit;
MicroBitEvent lastEvent;
void platform_init() {
microbit_seed_random();
seedRandom(microbit_random(0x7fffffff));
}
void initMicrobitGC() {
if (device_heap_size(1) > NON_GC_HEAP_RESERVATION + 4)
gcPreAllocateBlock(device_heap_size(1) - NON_GC_HEAP_RESERVATION);
}
void platform_init();
void usb_init();
struct FreeList {
FreeList *next;
};
static void initCodal() {
uBit.init();
// repeat error 4 times and restart as needed
microbit_panic_timeout(4);
}
void dumpDmesg() {}
// ---------------------------------------------------------------------------
// An adapter for the API expected by the run-time.
// ---------------------------------------------------------------------------
// We have the invariant that if [dispatchEvent] is registered against the DAL
// for a given event, then [handlersMap] contains a valid entry for that
// event.
void dispatchEvent(MicroBitEvent e) {
lastEvent = e;
auto curr = findBinding(e.source, e.value);
auto value = fromInt(e.value);
if (curr)
runAction1(curr->action, value);
curr = findBinding(e.source, DEVICE_EVT_ANY);
if (curr)
runAction1(curr->action, value);
}
void registerWithDal(int id, int event, Action a, int flags) {
// first time?
if (!findBinding(id, event))
uBit.messageBus.listen(id, event, dispatchEvent, flags);
setBinding(id, event, a);
}
void fiberDone(void *a) {
decr((Action)a);
unregisterGCPtr((Action)a);
release_fiber();
}
void releaseFiber() {
release_fiber();
}
void sleep_ms(unsigned ms) {
fiber_sleep(ms);
}
void sleep_us(uint64_t us) {
wait_us(us);
}
void forever_stub(void *a) {
while (true) {
runAction0((Action)a);
fiber_sleep(20);
}
}
void runForever(Action a) {
if (a != 0) {
incr(a);
registerGCPtr(a);
create_fiber(forever_stub, (void *)a);
}
}
void runInParallel(Action a) {
if (a != 0) {
incr(a);
registerGCPtr(a);
create_fiber((void (*)(void *))runAction0, (void *)a, fiberDone);
}
}
void waitForEvent(int id, int event) {
fiber_wait_for_event(id, event);
}
void initRuntime() {
initCodal();
platform_init();
}
//%
unsigned afterProgramPage() {
unsigned ptr = (unsigned)&bytecode[0];
ptr += programSize();
ptr = (ptr + (PAGE_SIZE - 1)) & ~(PAGE_SIZE - 1);
return ptr;
}
int current_time_ms() {
return system_timer_current_time();
}
static void logwriten(const char *msg, int l) {
uBit.serial.send((uint8_t *)msg, l);
}
static void logwrite(const char *msg) {
logwriten(msg, strlen(msg));
}
static void writeNum(char *buf, uint32_t n, bool full) {
int i = 0;
int sh = 28;
while (sh >= 0) {
int d = (n >> sh) & 0xf;
if (full || d || sh == 0 || i) {
buf[i++] = d > 9 ? 'A' + d - 10 : '0' + d;
}
sh -= 4;
}
buf[i] = 0;
}
static void logwritenum(uint32_t n, bool full, bool hex) {
char buff[20];
if (hex) {
writeNum(buff, n, full);
logwrite("0x");
} else {
itoa(n, buff);
}
logwrite(buff);
}
void vdebuglog(const char *format, va_list ap) {
const char *end = format;
while (*end) {
if (*end++ == '%') {
logwriten(format, end - format - 1);
uint32_t val = va_arg(ap, uint32_t);
switch (*end++) {
case 'c':
logwriten((const char *)&val, 1);
break;
case 'd':
logwritenum(val, false, false);
break;
case 'x':
logwritenum(val, false, true);
break;
case 'p':
case 'X':
logwritenum(val, true, true);
break;
case 's':
logwrite((char *)(void *)val);
break;
case '%':
logwrite("%");
break;
default:
logwrite("???");
break;
}
format = end;
}
}
logwriten(format, end - format);
logwrite("\n");
}
void debuglog(const char *format, ...) {
va_list arg;
va_start(arg, format);
vdebuglog(format, arg);
va_end(arg);
}
void sendSerial(const char *data, int len) {
logwriten(data, len);
}
#ifdef PXT_GC
ThreadContext *getThreadContext() {
if (!currentFiber)
return NULL;
return (ThreadContext *)currentFiber->user_data;
}
void setThreadContext(ThreadContext *ctx) {
currentFiber->user_data = ctx;
}
static void *threadAddressFor(Fiber *fib, void *sp) {
if (fib == currentFiber)
return sp;
return (uint8_t *)sp + ((uint8_t *)fib->stack_top - (uint8_t *)fib->tcb.stack_base);
}
void gcProcessStacks(int flags) {
// check scheduler is initialized
if (!currentFiber) {
// make sure we allocate something to at least initalize the memory allocator
void * volatile p = xmalloc(1);
xfree(p);
return;
}
int numFibers = list_fibers(NULL);
Fiber **fibers = (Fiber **)xmalloc(sizeof(Fiber *) * numFibers);
int num2 = list_fibers(fibers);
if (numFibers != num2)
oops(12);
int cnt = 0;
for (int i = 0; i < numFibers; ++i) {
auto fib = fibers[i];
auto ctx = (ThreadContext *)fib->user_data;
if (!ctx)
continue;
for (auto seg = &ctx->stack; seg; seg = seg->next) {
auto ptr = (TValue *)threadAddressFor(fib, seg->top);
auto end = (TValue *)threadAddressFor(fib, seg->bottom);
if (flags & 2)
DMESG("RS%d:%p/%d", cnt++, ptr, end - ptr);
// VLOG("mark: %p - %p", ptr, end);
while (ptr < end) {
gcProcess(*ptr++);
}
}
}
xfree(fibers);
}
#endif
} // namespace pxt