#include "pxt.h" #include MicroBit uBit; namespace pxt { int incr(uint32_t e) { if (e) { if (hasVTable(e)) ((RefObject*)e)->ref(); else ((RefCounted*)e)->incr(); } return e; } void decr(uint32_t e) { if (e) { if (hasVTable(e)) ((RefObject*)e)->unref(); else ((RefCounted*)e)->decr(); } } Action mkAction(int reflen, int totallen, int startptr) { check(0 <= reflen && reflen <= totallen, ERR_SIZE, 1); check(reflen <= totallen && totallen <= 255, ERR_SIZE, 2); check(bytecode[startptr] == 0xffff, ERR_INVALID_BINARY_HEADER, 3); check(bytecode[startptr + 1] == 0, ERR_INVALID_BINARY_HEADER, 4); uint32_t tmp = (uint32_t)&bytecode[startptr]; if (totallen == 0) { return tmp; // no closure needed } void *ptr = ::operator new(sizeof(RefAction) + totallen * sizeof(uint32_t)); RefAction *r = new (ptr) RefAction(); r->len = totallen; r->reflen = reflen; r->func = (ActionCB)((tmp + 4) | 1); memset(r->fields, 0, r->len * sizeof(uint32_t)); return (Action)r; } uint32_t runAction3(Action a, int arg0, int arg1, int arg2) { if (hasVTable(a)) return ((RefAction*)a)->runCore(arg0, arg1, arg2); else { check(*(uint16_t*)a == 0xffff, ERR_INVALID_BINARY_HEADER, 4); return ((ActionCB)((a + 4) | 1))(NULL, arg0, arg1, arg2); } } uint32_t runAction2(Action a, int arg0, int arg1) { return runAction3(a, arg0, arg1, 0); } uint32_t runAction1(Action a, int arg0) { return runAction3(a, arg0, 0, 0); } uint32_t runAction0(Action a) { return runAction3(a, 0, 0, 0); } RefRecord* mkClassInstance(int vtableOffset) { VTable *vtable = (VTable*)&bytecode[vtableOffset]; intcheck(vtable->methods[0] == &RefRecord_destroy, ERR_SIZE, 3); intcheck(vtable->methods[1] == &RefRecord_print, ERR_SIZE, 4); void *ptr = ::operator new(vtable->numbytes); RefRecord *r = new (ptr) RefRecord(PXT_VTABLE_TO_INT(vtable)); memset(r->fields, 0, vtable->numbytes - sizeof(RefRecord)); return r; } uint32_t RefRecord::ld(int idx) { //intcheck((reflen == 255 ? 0 : reflen) <= idx && idx < len, ERR_OUT_OF_BOUNDS, 1); return fields[idx]; } uint32_t RefRecord::ldref(int idx) { //printf("LD %p len=%d reflen=%d idx=%d\n", this, len, reflen, idx); //intcheck(0 <= idx && idx < reflen, ERR_OUT_OF_BOUNDS, 2); uint32_t tmp = fields[idx]; incr(tmp); return tmp; } void RefRecord::st(int idx, uint32_t v) { //intcheck((reflen == 255 ? 0 : reflen) <= idx && idx < len, ERR_OUT_OF_BOUNDS, 3); fields[idx] = v; } void RefRecord::stref(int idx, uint32_t v) { //printf("ST %p len=%d reflen=%d idx=%d\n", this, len, reflen, idx); //intcheck(0 <= idx && idx < reflen, ERR_OUT_OF_BOUNDS, 4); decr(fields[idx]); fields[idx] = v; } void RefObject::destroy() { ((RefObjectMethod)getVTable()->methods[0])(this); } void RefObject::print() { ((RefObjectMethod)getVTable()->methods[1])(this); } void RefRecord_destroy(RefRecord *r) { auto tbl = r->getVTable(); uint8_t *refmask = (uint8_t*)&tbl->methods[tbl->userdata & 0xff]; int len = (tbl->numbytes >> 2) - 1; for (int i = 0; i < len; ++i) { if (refmask[i]) decr(r->fields[i]); r->fields[i] = 0; } //RefRecord is allocated using placement new r->~RefRecord(); ::operator delete(r); } void RefRecord_print(RefRecord *r) { printf("RefRecord %p r=%d size=%d bytes\n", r, r->refcnt, r->getVTable()->numbytes); } uint32_t Segment::get(uint32_t i) { #ifdef DEBUG_BUILD printf("In Segment::get index:%u\n", i); this->print(); #endif if (i < length) { return data[i]; } return Segment::DefaultValue; } void Segment::set(uint32_t i, uint32_t value) { if (i < size) { data[i] = value; } else if (i < Segment::MaxSize) { growByMin(i + 1); data[i] = value; } if (length <= i) { length = i + 1; } #ifdef DEBUG_BUILD printf("In Segment::set\n"); this->print(); #endif return; } uint16_t Segment::growthFactor(uint16_t size) { if (size == 0) { return 4; } if (size < 64) { return size * 2; // Double } if (size < 512) { return size * 5/3; //Grow by 1.66 rate } return size + 256; //Grow by constant rate } void Segment::growByMin(uint16_t minSize) { growBy(max(minSize, growthFactor(size))); } void Segment::growBy(uint16_t newSize) { #ifdef DEBUG_BUILD printf("growBy: %d\n", newSize); this->print(); #endif if (size < newSize) { //this will throw if unable to allocate uint32_t *tmp = (uint32_t*)(::operator new(newSize * sizeof(uint32_t))); //Copy existing data if (size) { memcpy(tmp, data, size * sizeof(uint32_t)); } //fill the rest with default value memset(tmp + size, Segment::DefaultValue, (newSize - size) * sizeof(uint32_t)); //free older segment; ::operator delete(data); data = tmp; size = newSize; #ifdef DEBUG_BUILD printf("growBy - after reallocation\n"); this->print(); #endif } //else { no shrinking yet; } return; } void Segment::ensure(uint16_t newSize) { if (newSize < size) { return; } growByMin(newSize); } void Segment::setLength(uint32_t newLength) { if (newLength > size) { ensure(length); } length = newLength; return; } void Segment::push(uint32_t value) { this->set(length, value); } uint32_t Segment::pop() { #ifdef DEBUG_BUILD printf("In Segment::pop\n"); this->print(); #endif if (length > 0) { --length; uint32_t value = data[length]; data[length] = Segment::DefaultValue; return value; } return Segment::DefaultValue; } //this function removes an element at index i and shifts the rest of the elements to //left to fill the gap uint32_t Segment::remove(uint32_t i) { #ifdef DEBUG_BUILD printf("In Segment::remove index:%u\n", i); this->print(); #endif if (i < length) { //value to return uint32_t ret = data[i]; if (i + 1 < length) { //Move the rest of the elements to fill in the gap. memmove(data + i, data + i + 1, (length - i - 1) * sizeof(uint32_t)); } length--; data[length] = Segment::DefaultValue; #ifdef DEBUG_BUILD printf("After Segment::remove index:%u\n", i); this->print(); #endif return ret; } return Segment::DefaultValue; } //this function inserts element value at index i by shifting the rest of the elements right. void Segment::insert(uint32_t i, uint32_t value) { #ifdef DEBUG_BUILD printf("In Segment::insert index:%u value:%u\n", i, value); this->print(); #endif if (i < length) { ensure(length + 1); if (i + 1 < length) { //Move the rest of the elements to fill in the gap. memmove(data + i + 1, data + i, (length - i) * sizeof(uint32_t)); } data[i] = value; length++; } else { //This is insert beyond the length, just call set which will adjust the length set(i, value); } #ifdef DEBUG_BUILD printf("After Segment::insert index:%u\n", i); this->print(); #endif } void Segment::print() { printf("Segment: %x, length: %u, size: %u\n", data, (uint32_t)length, (uint32_t)size); for(uint32_t i = 0; i < size; i++) { printf("%d ",(uint32_t)data[i]); } printf("\n"); } bool Segment::isValidIndex(uint32_t i) { if (i > length) { return false; } return true; } void Segment::destroy() { #ifdef DEBUG_BUILD printf("In Segment::destroy\n"); this->print(); #endif length = size = 0; ::operator delete(data); data = nullptr; } void RefCollection::push(uint32_t x) { if (isRef()) incr(x); head.push(x); } uint32_t RefCollection::pop() { uint32_t ret = head.pop(); if (isRef()) { incr(ret); } return ret; } uint32_t RefCollection::getAt(int i) { uint32_t tmp = head.get(i); if (isRef()) { incr(tmp); } return tmp; } uint32_t RefCollection::removeAt(int i) { // no decr() - we return the result return head.remove(i); } void RefCollection::insertAt(int i, uint32_t value) { head.insert(i, value); if (isRef()) { incr(value); } } void RefCollection::setAt(int i, uint32_t value) { if (isRef()) { if (head.isValidIndex((uint32_t)i)) { decr(head.get(i)); } incr(value); } head.set(i, value); } int RefCollection::indexOf(uint32_t x, int start) { if (isString()) { StringData *xx = (StringData*)x; uint32_t i = start; while(head.isValidIndex(i)) { StringData *ee = (StringData*)head.get(i); if (ee == xx) { //handles ee being null return (int) i; } if (ee && xx->len == ee->len && memcmp(xx->data, ee->data, xx->len) == 0) { return (int)i; } i++; } } else { uint32_t i = start; while(head.isValidIndex(i)) { if (head.get(i) == x) { return (int)i; } i++; } } return -1; } int RefCollection::removeElement(uint32_t x) { int idx = indexOf(x, 0); if (idx >= 0) { uint32_t elt = removeAt(idx); if (isRef()) decr(elt); return 1; } return 0; } namespace Coll0 { PXT_VTABLE_BEGIN(RefCollection, 0, 0) PXT_VTABLE_END } namespace Coll1 { PXT_VTABLE_BEGIN(RefCollection, 1, 0) PXT_VTABLE_END } namespace Coll3 { PXT_VTABLE_BEGIN(RefCollection, 3, 0) PXT_VTABLE_END } RefCollection::RefCollection(uint16_t flags) : RefObject(0) { switch (flags) { case 0: vtable = PXT_VTABLE_TO_INT(&Coll0::RefCollection_vtable); break; case 1: vtable = PXT_VTABLE_TO_INT(&Coll1::RefCollection_vtable); break; case 3: vtable = PXT_VTABLE_TO_INT(&Coll3::RefCollection_vtable); break; default: error(ERR_SIZE); break; } } void RefCollection::destroy() { if (this->isRef()) { for(uint32_t i = 0; i < this->head.getLength(); i++) { decr(this->head.get(i)); } } this->head.destroy(); delete this; } void RefCollection::print() { printf("RefCollection %p r=%d flags=%d size=%d\n", this, refcnt, getFlags(), head.getLength()); head.print(); } PXT_VTABLE_CTOR(RefAction) {} // fields[] contain captured locals void RefAction::destroy() { for (int i = 0; i < this->reflen; ++i) { decr(fields[i]); fields[i] = 0; } //RefAction is allocated using placement new this->~RefAction(); ::operator delete(this); } void RefAction::print() { printf("RefAction %p r=%d pc=0x%lx size=%d (%d refs)\n", this, refcnt, (const uint8_t*)func - (const uint8_t*)bytecode, len, reflen); } void RefLocal::print() { printf("RefLocal %p r=%d v=%d\n", this, refcnt, v); } void RefLocal::destroy() { delete this; } PXT_VTABLE_CTOR(RefLocal) { v = 0; } PXT_VTABLE_CTOR(RefRefLocal) { v = 0; } void RefRefLocal::print() { printf("RefRefLocal %p r=%d v=%p\n", this, refcnt, (void*)v); } void RefRefLocal::destroy() { decr(v); delete this; } PXT_VTABLE_BEGIN(RefMap, 0, RefMapMarker) PXT_VTABLE_END RefMap::RefMap() : PXT_VTABLE_INIT(RefMap) {} void RefMap::destroy() { for (unsigned i = 0; i < data.size(); ++i) { if (data[i].key & 1) { decr(data[i].val); } data[i].val = 0; } data.resize(0); delete this; } int RefMap::findIdx(uint32_t key) { for (unsigned i = 0; i < data.size(); ++i) { if (data[i].key >> 1 == key) return i; } return -1; } void RefMap::print() { printf("RefMap %p r=%d size=%d\n", this, refcnt, data.size()); } #ifdef DEBUG_MEMLEAKS std::set allptrs; void debugMemLeaks() { printf("LIVE POINTERS:\n"); for(std::set::iterator itr = allptrs.begin();itr!=allptrs.end();itr++) { (*itr)->print(); } printf("\n"); } #else void debugMemLeaks() {} #endif // --------------------------------------------------------------------------- // An adapter for the API expected by the run-time. // --------------------------------------------------------------------------- map, Action> handlersMap; MicroBitEvent lastEvent; // 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; Action curr = handlersMap[{ e.source, e.value }]; if (curr) runAction1(curr, e.value); curr = handlersMap[{ e.source, MICROBIT_EVT_ANY }]; if (curr) runAction1(curr, e.value); } void registerWithDal(int id, int event, Action a) { Action prev = handlersMap[{ id, event }]; if (prev) decr(prev); else uBit.messageBus.listen(id, event, dispatchEvent); incr(a); handlersMap[{ id, event }] = a; } void fiberDone(void *a) { decr((Action)a); release_fiber(); } void runInBackground(Action a) { if (a != 0) { incr(a); create_fiber((void(*)(void*))runAction0, (void*)a, fiberDone); } } void error(ERROR code, int subcode) { printf("Error: %d [%d]\n", code, subcode); uBit.panic(42); } uint16_t *bytecode; uint32_t *globals; int numGlobals; uint32_t *allocate(uint16_t sz) { uint32_t *arr = new uint32_t[sz]; memset(arr, 0, sz * 4); return arr; } void checkStr(bool cond, const char *msg) { if (!cond) { while (true) { uBit.display.scroll(msg, 100); uBit.sleep(100); } } } int templateHash() { return ((int*)bytecode)[4]; } int programHash() { return ((int*)bytecode)[6]; } int getNumGlobals() { return bytecode[16]; } void exec_binary(int32_t *pc) { // XXX re-enable once the calibration code is fixed and [editor/embedded.ts] // properly prepends a call to [internal_main]. // ::touch_develop::internal_main(); // unique group for radio based on source hash // ::touch_develop::micro_bit::radioDefaultGroup = programHash(); // repeat error 4 times and restart as needed microbit_panic_timeout(4); int32_t ver = *pc++; checkStr(ver == 0x4209, ":( Bad runtime version"); bytecode = *((uint16_t**)pc++); // the actual bytecode is here globals = allocate(getNumGlobals()); // just compare the first word checkStr(((uint32_t*)bytecode)[0] == 0x923B8E70 && templateHash() == *pc, ":( Failed partial flash"); uint32_t startptr = (uint32_t)bytecode; startptr += 48; // header startptr |= 1; // Thumb state ((uint32_t (*)())startptr)(); #ifdef DEBUG_MEMLEAKS pxt::debugMemLeaks(); #endif return; } void start() { exec_binary((int32_t*)functionsAndBytecode); } } // vim: ts=2 sw=2 expandtab