// ------------------------------------------------------------------------------------------------ #include "Misc/Signal.hpp" // ------------------------------------------------------------------------------------------------ namespace SqMod { // ------------------------------------------------------------------------------------------------ SQMODE_DECL_TYPENAME(Typename, _SC("SqSignalImpl")) // ------------------------------------------------------------------------------------------------ Signal::SignalPool Signal::s_Signals; Signal::FreeSignals Signal::s_FreeSignals; /* ------------------------------------------------------------------------------------------------ * Class used to control the signal emitter. */ struct SignalWrapper { // -------------------------------------------------------------------------------------------- using Slot = Signal::Slot; // -------------------------------------------------------------------------------------------- Signal * mSignal; // A raw pointer to the signal instance. // -------------------------------------------------------------------------------------------- Slot mSlot; // The specified slot. HSQUIRRELVM mVM; // The specified virtual machine. SQInteger mRes; // The result of the operation. bool mOne; // Limit to one slot in the operation. bool mAppend; // Append instead of push when leading or tailing. /* -------------------------------------------------------------------------------------------- * Explicit constructor. */ explicit SignalWrapper(HSQUIRRELVM vm, bool extra = false) : mSignal(nullptr) , mSlot() , mVM(vm) , mRes(Initialize(vm, extra)) , mOne(false), mAppend(false) { //... } /* -------------------------------------------------------------------------------------------- * Extracts the information from the stack of the specified virtual machine. */ SQInteger Initialize(HSQUIRRELVM vm, bool extra) { const SQInteger top = sq_gettop(vm); // See if the minimum amount of arguments were specified if (top <= 1) { return sq_throwerror(vm, "Wrong number of parameters"); } // Attempt to extract the signal instance try { mSignal = Var< Signal * >(vm, 1).value; } catch (const Sqrat::Exception & e) { return sq_throwerror(vm, e.what()); } // Do we have a valid signal instance? if (!mSignal) { return sq_throwerror(vm, "Invalid signal instance"); } // By default, extra parameters start after callback SQInteger extpos = 3; // Is the first parameter a function? if (sq_gettype(vm, 2) & (_RT_CLOSURE | _RT_NATIVECLOSURE)) { // Attempt to grab the callback object SQRESULT res = sq_getstackobj(vm, 2, &mSlot.mFuncRef); // Did we fail to retrieve the callback object? if (SQ_FAILED(res)) { return res; // Propagate the error } else { sq_addref(vm, &mSlot.mFuncRef); } // Grab the hash of the callback object mSlot.mFuncHash = sq_gethash(vm, 2); // Push the root table on the stack sq_pushroottable(vm); // Attempt to grab root table as the environment res = sq_getstackobj(vm, -1, &mSlot.mThisRef); // Did we fail to retrieve the root table? if (SQ_FAILED(res)) { // Pop the root table from the stack sq_pop(vm, 1); // Propagate the error return res; } else { sq_addref(vm, &mSlot.mThisRef); } // Grab the hash of the root table mSlot.mThisHash = sq_gethash(vm, -1); // Pop the root table from the stack sq_pop(vm, 1); } // Should we look for a specific environment? else if (top >= 3 && sq_gettype(vm, 3) & (_RT_CLOSURE | _RT_NATIVECLOSURE)) { // Is the first type at suitable to be an environment at least? if (!(sq_gettype(vm, 2) & (_RT_TABLE | _RT_CLASS | _RT_INSTANCE))) { return sq_throwerror(vm, "Invalid environment object"); } // Attempt to grab the environment object SQRESULT res = sq_getstackobj(vm, 2, &mSlot.mThisRef); // Did we fail to retrieve the environment object? if (SQ_FAILED(res)) { return res; // Propagate the error } else { sq_addref(vm, &mSlot.mThisRef); } // Grab the hash of the environment object mSlot.mThisHash = sq_gethash(vm, 2); // Attempt to grab the callback object res = sq_getstackobj(vm, 3, &mSlot.mFuncRef); // Did we fail to retrieve the callback object? if (SQ_FAILED(res)) { return res; // Propagate the error } else { sq_addref(vm, &mSlot.mFuncRef); } // Grab the hash of the callback object mSlot.mFuncHash = sq_gethash(vm, 3); // The extra parameters start one slot higher ++extpos; } else { return sq_throwerror(vm, "Missing callback function"); } // Should we look for the extra parameters? if (extra && top >= extpos) { SQBool value; // Attempt to retrieve the parameter value sq_tobool(vm, extpos, &value); // Convert the retrieved value mOne = static_cast< bool >(value); // The next extra parameter starts one slot higher ++extpos; } else { mOne = false; } // Should we look for the extra parameters? if (extra && top >= extpos) { SQBool value; // Attempt to retrieve the parameter value sq_tobool(vm, extpos, &value); // Convert the retrieved value mAppend = static_cast< bool >(value); } else { mAppend = true; } // Initialization was successful return SQ_OK; } /* -------------------------------------------------------------------------------------------- * Copy constructor. (disabled) */ SignalWrapper(const SignalWrapper & o) = delete; /* -------------------------------------------------------------------------------------------- * Move constructor. (disabled) */ SignalWrapper(SignalWrapper && o) = delete; /* -------------------------------------------------------------------------------------------- * Copy assignment operator. (disabled) */ SignalWrapper & operator = (const SignalWrapper & o) = delete; /* -------------------------------------------------------------------------------------------- * Move assignment operator. (disabled) */ SignalWrapper & operator = (SignalWrapper && o) = delete; }; /* ------------------------------------------------------------------------------------------------ * Helper functor to locate specific slots. */ template < class Slot > struct MatchSlot { // -------------------------------------------------------------------------------------------- const SQHash mThisHash; // The environment to search for. const SQHash mFuncHash; // The callback to search for. /* -------------------------------------------------------------------------------------------- * Base constructor. */ MatchSlot(SQHash t, SQHash f) : mThisHash(t), mFuncHash(f) { //... } /* -------------------------------------------------------------------------------------------- * Function call operator. */ inline bool operator () (const Slot & s) const { return (mThisHash == s.mThisHash) && (mFuncHash == s.mFuncHash); } }; /* ------------------------------------------------------------------------------------------------ * Helper functor to locate slots with specific environments. */ template < class Slot > struct MatchThis { // -------------------------------------------------------------------------------------------- const SQHash mThisHash; // The environment to search for. /* -------------------------------------------------------------------------------------------- * Base constructor. */ explicit MatchThis(SQHash t) : mThisHash(t) { //... } /* -------------------------------------------------------------------------------------------- * Function call operator. */ inline bool operator () (const Slot & s) const { return (mThisHash == s.mThisHash); } }; /* ------------------------------------------------------------------------------------------------ * Helper functor to locate slots with specific callbacks. */ template < class Slot > struct MatchFunc { // -------------------------------------------------------------------------------------------- const SQHash mFuncHash; // The callback to search for. /* -------------------------------------------------------------------------------------------- * Base constructor. */ explicit MatchFunc(SQHash f) : mFuncHash(f) { //... } /* -------------------------------------------------------------------------------------------- * Function call operator. */ inline bool operator () (const Slot & s) const { return (mFuncHash == s.mFuncHash); } }; /* ------------------------------------------------------------------------------------------------ * See if a certain slot exists using the provided functor. */ template < typename F, class Slot > static bool ExistsIf(F func, Slot * itr, Slot * end) { // Process slots within the given range while (itr != end) { // Does this slot satisfy the functor? if (func(*(itr++))) { return true; } } return false; } /* ------------------------------------------------------------------------------------------------ * Count the number of slots that the provided functor deems worthy. */ template < typename F, class Slot > static Signal::SizeType CountIf(F func, Slot * itr, Slot * end) { Signal::SizeType count = 0; // Process slots within the given range while (itr != end) { // Should we count this slot? if (func(*(itr++))) { ++count; } } // Return the final count return count; } /* ------------------------------------------------------------------------------------------------ * Remove all slot from the specified range if the provided functor demands it. */ template < typename F, class Slot, class Scope > static Signal::SizeType RemoveIf(F func, Slot * itr, Slot * end, Scope * scope) { Slot * dest = itr; // Number of removed slots Signal::SizeType count = 0; // Process slots within the given range while (itr != end) { // Should we remove this slot? if (func(*itr)) { // Release the stored references itr->Release(); // Are we currently signaling? if (scope != nullptr) { scope->Descend(itr); // Update iterators } // Increase the counter ++count; } // Were there any slots removed? else if (itr != dest) { // Offset the current scope *dest = std::move(*itr); // Advance the destination ++dest; } else { ++dest; // We avoided a move assignment } // Advance the iterator ++itr; } // Return the final count return count; } /* ------------------------------------------------------------------------------------------------ * Move to the front all slots that the provided functor demands. */ template < typename F, class Slot, class Scope > static void LeadIf(F func, Slot * front, Slot * end, bool one, bool append, Scope * scope) { Slot * itr = front; // Process slots within the given range while (itr != end) { // Should this slot become a lead? if (!func(*itr)) { ++itr; // Skip it continue; } // Is this slot right behind the current lead? else if ((itr - front) == 1) { // Swap them itr->Swap(*front); // Are we currently signaling? if (scope != nullptr) { scope->Lead(itr); // Update iterators } } // Is this not the current lead? else if (itr != front) { // Backup the values of this slot Slot tmp(std::move(*itr)); // Shift back all the slots before it for (Slot * dest = itr, * src = (itr - 1); dest != front; dest = src, --src) { dest->Swap(*src); // Swap with the one bellow it } // Finally, place the slot into lead *front = std::move(tmp); // Are we currently signaling? if (scope != nullptr) { scope->Lead(itr); // Update iterators } } // Advance the iterator ++itr; // Are we using the append method? if (append) { ++front; // Don't overrule the current lead } // Should we make only one lead? if (one) { break; // Then stop here! } } } /* ------------------------------------------------------------------------------------------------ * Move to the back all slots that the provided functor demands. */ template < typename F, class Slot, class Scope > static void TailIf(F func, Slot * front, Slot * back, bool one, bool append, Scope * scope) { Slot * itr = back; // Process slots within the given range while (itr >= front) { // Should this slot become a tail? if (!func(*itr)) { --itr; // Skip it continue; } // Is this slot right behind the current tail? else if ((back - itr) == 1) { // Swap them itr->Swap(*front); // Are we currently signaling? if (scope != nullptr) { scope->Tail(itr); // Update iterators } } // Is this not the current tail? else if (itr != back) { // Backup the values of this slot Slot tmp(std::move(*itr)); // Shift up all the slots before it for (Slot * dest = itr, * src = (itr + 1); dest != back; dest = src, ++src) { dest->Swap(*src); // Swap with the one above it } // Finally, place the slot into tail *back = std::move(tmp); // Are we currently signaling? if (scope != nullptr) { scope->Tail(itr); // Update iterators } } // Advance the iterator --itr; // Are we using the append method? if (append) { --back; // Don't overrule the current tail } // Should we make only one tail? if (one) { break; // Then stop here! } } } // ------------------------------------------------------------------------------------------------ void Signal::Scope::Descend(Pointer ptr) { // Is the descended pointer withing this scope? if (ptr <= mEnd) { // Is the iterator affected by this? if (ptr < mItr || mItr > mEnd) { --mItr; } // Update the end iterator --mEnd; } // Is this that last scope? if (mChild != nullptr) { mChild->Descend(ptr); // Let the others know as well } } // ------------------------------------------------------------------------------------------------ void Signal::Scope::Lead(Pointer ptr) { // Is the descended pointer in our scope? if (ptr <= mEnd) { // Does it affect our iterator? if (ptr >= mItr && mItr != mEnd) { ++mItr; } } // Is the descended pointer out of our scope? else if (ptr > mEnd) { ++mItr, ++mEnd; } // Is this that last scope? if (mChild != nullptr) { mChild->Lead(ptr); // Let the others know as well } } // ------------------------------------------------------------------------------------------------ void Signal::Scope::Tail(Pointer ptr) { // Is the descended pointer in our scope? if (ptr <= mEnd) { // Did this scope already finish processing? if (mItr != mEnd) { // Does it affect our iterator? if (ptr < mItr) { --mItr; } // Update the end iterator --mEnd; } } // Is this that last scope? if (mChild != nullptr) { mChild->Tail(ptr); // Let the others know as well } } // ------------------------------------------------------------------------------------------------ void Signal::Scope::Finish() { // Forcefully skip all remaining slots mItr = mEnd; // Is this that last scope? if (mChild != nullptr) { mChild->Finish(); // Let the others know as well } } // ------------------------------------------------------------------------------------------------ Signal::Signal() : m_Used(0) , m_Size(SMB_SIZE) , m_Slots(m_SMB) , m_Scope(nullptr) , m_Name() , m_Data() { s_FreeSignals.push_back(this); } // ------------------------------------------------------------------------------------------------ Signal::Signal(String && name) : m_Used(0) , m_Size(SMB_SIZE) , m_Slots(m_SMB) , m_Scope(nullptr) , m_Name(std::forward< String >(name)) , m_Data() { if (m_Name.empty()) { s_FreeSignals.push_back(this); } } // ------------------------------------------------------------------------------------------------ Signal::~Signal() { ClearSlots(); // Should we erase this from the fee signals list? if (m_Name.empty()) { s_FreeSignals.erase(std::remove(s_FreeSignals.begin(), s_FreeSignals.end(), this), s_FreeSignals.end()); } } // ------------------------------------------------------------------------------------------------ bool Signal::AdjustSlots(SizeType capacity) { // Is it necessary to resize? if (capacity <= m_Size) { return true; // Already have that memory available! } // Do not alter the current capacity SizeType size = m_Size; // Calculate the next optimal size of the buffer while (size < capacity) { size += (size + 1u) >> 1u; } // Attempt to allocate a memory buffer of the resulted size auto slots = reinterpret_cast< Pointer >(new uint8_t[size * sizeof(Slot)]); // See if the memory could be allocated if (slots == nullptr) { return false; // Unable to acquire the memory! } // Do not alter the pointer to the new buffer Pointer dest = slots; // Are there any existing slots? if (m_Used) { // Grab the range of slots to be transferred Pointer src = m_Slots, end = (m_Slots + m_Used); // Transfer the existing slots while (src != end) { // Transfer to the new buffer new (dest++) Slot(std::move(*(src))); // Destroy the old instance (src++)->~Slot(); } // Grab the end of the remaining slots end = (m_Slots + m_Size); // Destroy the remaining slots while (src != end) { (src++)->~Slot(); } } // Grab the end of the new buffer Pointer end = (slots + size); // Initialize the remaining slots while (dest != end) { new (dest++) Slot(); } // Update the iterators from current scopes for (Scope * scope = m_Scope; scope != nullptr; scope = scope->mChild) { scope->mItr = slots + (scope->mItr - m_Slots); scope->mEnd = slots + (scope->mEnd - m_Slots); } // Should we delete the current buffer? if (m_Slots != m_SMB) { delete[] reinterpret_cast< uint8_t * >(m_Slots); } // Assign the new buffer m_Slots = slots; // Assign the new capacity m_Size = size; // The buffer was successfully adjusted return true; } // ------------------------------------------------------------------------------------------------ void Signal::ClearSlots() { // Release every connected slot for (Pointer itr = m_Slots, end = m_Slots + m_Used; itr != end; ++itr) { itr->Release(); } // Are we currently signaling? if (m_Scope != nullptr) { m_Scope->Finish(); // Update iterators } } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Connect(SignalWrapper & w) { // Make sure we have enough space to store the slot if ((m_Used < m_Size) || AdjustSlots(m_Used + 1)) { m_Slots[m_Used++].Swap(w.mSlot); // Connect the slot to the signal } else { sq_throwerror(w.mVM, "Unable to acquire enough memory"); } // Specify that we don't return a value return 0; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::ConnectOnce(SignalWrapper & w) { // Disconnect every occurrence of this slot first w.mRes = Eliminate(w); // Did we fail to disconnect it? if (SQ_FAILED(w.mRes)) { return w.mRes; // Propagate the error } // Finally, attempt to connect it again return Connect(w); } // ------------------------------------------------------------------------------------------------ SQInteger Signal:: Disconnect(SignalWrapper & w) { return Eliminate(w); } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Exists(SignalWrapper & w) { // Forward the call to the actual function const bool r = ExistsIf(MatchSlot< Slot >(w.mSlot.mThisHash, w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used); // Push the resulted value on the stack sq_pushbool(w.mVM, static_cast< SQBool >(r)); // Specify that we returned a value return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::ExistsThis(SignalWrapper & w) { // Forward the call to the actual function const bool r = ExistsIf(MatchThis< Slot >(w.mSlot.mThisHash), m_Slots, m_Slots + m_Used); // Push the resulted value on the stack sq_pushbool(w.mVM, static_cast< SQBool >(r)); // Specify that we returned a value return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::ExistsFunc(SignalWrapper & w) { // Forward the call to the actual function const bool r = ExistsIf(MatchFunc< Slot >(w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used); // Push the resulted value on the stack sq_pushbool(w.mVM, static_cast< SQBool >(r)); // Specify that we returned a value return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Count(SignalWrapper & w) { // Forward the call to the actual function const SizeType r = CountIf(MatchSlot< Slot >(w.mSlot.mThisHash, w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used); // Push the resulted value on the stack sq_pushinteger(w.mVM, static_cast< SQInteger >(r)); // Specify that we returned a value return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::CountThis(SignalWrapper & w) { // Forward the call to the actual function const SizeType r = CountIf(MatchThis< Slot >(w.mSlot.mThisHash), m_Slots, m_Slots + m_Used); // Push the resulted value on the stack sq_pushinteger(w.mVM, static_cast< SQInteger >(r)); // Specify that we returned a value return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::CountFunc(SignalWrapper & w) { // Forward the call to the actual function const SizeType r = CountIf(MatchFunc< Slot >(w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used); // Push the resulted value on the stack sq_pushinteger(w.mVM, static_cast< SQInteger >(r)); // Specify that we returned a value return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Lead(SignalWrapper & w) { // Make sure that there's more than one slot connected if (m_Used > 1) { LeadIf(MatchSlot< Slot >(w.mSlot.mThisHash, w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used, w.mOne, w.mAppend, m_Scope); } // Specify that we don't return a value return 0; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::LeadThis(SignalWrapper & w) { // Make sure that there's more than one slot connected if (m_Used > 1) { LeadIf(MatchThis< Slot >(w.mSlot.mThisHash), m_Slots, m_Slots + m_Used, w.mOne, w.mAppend, m_Scope); } // Specify that we don't return a value return 0; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::LeadFunc(SignalWrapper & w) { // Make sure that there's more than one slot connected if (m_Used > 1) { LeadIf(MatchFunc< Slot >(w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used, w.mOne, w.mAppend, m_Scope); } // Specify that we don't return a value return 0; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Tail(SignalWrapper & w) { // Make sure that there's more than one slot connected if (m_Used > 1) { TailIf(MatchSlot< Slot >(w.mSlot.mThisHash, w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used, w.mOne, w.mAppend, m_Scope); } // Specify that we don't return a value return 0; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::TailThis(SignalWrapper & w) { // Make sure that there's more than one slot connected if (m_Used > 1) { TailIf(MatchThis< Slot >(w.mSlot.mThisHash), m_Slots, m_Slots + m_Used, w.mOne, w.mAppend, m_Scope); } // Specify that we don't return a value return 0; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::TailFunc(SignalWrapper & w) { // Make sure that there's more than one slot connected if (m_Used > 1) { TailIf(MatchFunc< Slot >(w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used, w.mOne, w.mAppend, m_Scope); } // Specify that we don't return a value return 0; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Eliminate(SignalWrapper & w) { // Make sure that there's at least one slot connected if (m_Used != 0) { // Backup the current number of used slots const SizeType count = m_Used; // Forward the call to the actual function m_Used -= RemoveIf(MatchSlot< Slot >(w.mSlot.mThisHash, w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used, m_Scope); // Push the number of removed slots sq_pushinteger(w.mVM, static_cast< SQInteger >(count - m_Used)); } else { sq_pushinteger(w.mVM, 0); } // Specify that we returned a value return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::EliminateThis(SignalWrapper & w) { // Make sure that there's at least one slot connected if (m_Used != 0) { // Backup the current number of used slots const SizeType count = m_Used; // Forward the call to the actual function m_Used -= RemoveIf(MatchThis< Slot >(w.mSlot.mThisHash), m_Slots, m_Slots + m_Used, m_Scope); // Push the number of removed slots sq_pushinteger(w.mVM, static_cast< SQInteger >(count - m_Used)); } else { sq_pushinteger(w.mVM, 0); } // Specify that we returned a value return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::EliminateFunc(SignalWrapper & w) { // Make sure that there's at least one slot connected if (m_Used != 0) { // Backup the current number of used slots const SizeType count = m_Used; // Forward the call to the actual function m_Used -= RemoveIf(MatchFunc< Slot >(w.mSlot.mFuncHash), m_Slots, m_Slots + m_Used, m_Scope); // Push the number of removed slots sq_pushinteger(w.mVM, static_cast< SQInteger >(count - m_Used)); } else { sq_pushinteger(w.mVM, 0); } // Specify that we returned a value return 1; } // ------------------------------------------------------------------------------------------------ #define SQMOD_SIGNAL_CONTROL_WRAPPER(_f, _e) /* */ SQInteger Signal::Sq##_f(HSQUIRRELVM vm) { /* */ SignalWrapper w(vm, _e); /* */ if (SQ_FAILED(w.mRes)) return w.mRes; /* */ else return w.mSignal->_f(w); /* */ } /* */ /* */ // ------------------------------------------------------------------------------------------------ SQMOD_SIGNAL_CONTROL_WRAPPER(Connect, false) SQMOD_SIGNAL_CONTROL_WRAPPER(ConnectOnce, false) SQMOD_SIGNAL_CONTROL_WRAPPER(Exists, false) SQMOD_SIGNAL_CONTROL_WRAPPER(Disconnect, false) SQMOD_SIGNAL_CONTROL_WRAPPER(ExistsThis, false) SQMOD_SIGNAL_CONTROL_WRAPPER(ExistsFunc, false) SQMOD_SIGNAL_CONTROL_WRAPPER(Count, false) SQMOD_SIGNAL_CONTROL_WRAPPER(CountThis, false) SQMOD_SIGNAL_CONTROL_WRAPPER(CountFunc, false) SQMOD_SIGNAL_CONTROL_WRAPPER(Lead, true) SQMOD_SIGNAL_CONTROL_WRAPPER(LeadThis, true) SQMOD_SIGNAL_CONTROL_WRAPPER(LeadFunc, true) SQMOD_SIGNAL_CONTROL_WRAPPER(Tail, true) SQMOD_SIGNAL_CONTROL_WRAPPER(TailThis, true) SQMOD_SIGNAL_CONTROL_WRAPPER(TailFunc, true) SQMOD_SIGNAL_CONTROL_WRAPPER(Eliminate, false) SQMOD_SIGNAL_CONTROL_WRAPPER(EliminateThis, false) SQMOD_SIGNAL_CONTROL_WRAPPER(EliminateFunc, false) // ------------------------------------------------------------------------------------------------ SQInteger Signal::Emit(HSQUIRRELVM vm, SQInteger top) { // Are there any slots connected? if (!m_Used) return 0; // Enter a new execution scope Scope scope(m_Scope, m_Slots, m_Slots + m_Used); // Activate the current scope and create a guard to restore it const AutoAssign< Scope * > aa(m_Scope, scope.mParent, &scope); // Contains the last received result SQRESULT res = SQ_OK; // Process the slots from this scope while (scope.mItr != scope.mEnd) { // Grab a reference to the current slot const Slot & slot = *(scope.mItr++); // Push the callback object sq_pushobject(vm, slot.mFuncRef); // Is there an explicit environment? if (slot.mThisHash == 0) { sq_pushroottable(vm); } else { sq_pushobject(vm, slot.mThisRef); } // Are there any parameters to forward? if (top > 1) { for (SQInteger i = 2; i <= top; ++i) { sq_push(vm, i); } } // Make the function call and store the result res = sq_call(vm, top, static_cast< SQBool >(false), static_cast< SQBool >(ErrorHandling::IsEnabled())); // Pop the callback object from the stack sq_pop(vm, 1); // Validate the result if (SQ_FAILED(res)) { break; // Stop emitting signals } } // Return the last result return res; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Query(HSQUIRRELVM vm, SQInteger top) { // Are there any slots connected? if (!m_Used) return 0; // The collector and the specified environment HSQOBJECT cthis, cfunc; // Attempt to grab the collector environment SQRESULT res = sq_getstackobj(vm, 2, &cthis); // Validate the result if (SQ_FAILED(res)) { return res; // Propagate the error } // Was there a valid environment? else if (sq_isnull(cthis)) { // Default to the root table sq_pushroottable(vm); // Try to grab the collector environment again res = sq_getstackobj(vm, -1, &cthis); // Pop the root table from the stack sq_pop(vm, 1); // Validate the result if (SQ_FAILED(res)) { return res; // Propagate the error } } // Grab the collector callback res = sq_getstackobj(vm, 3, &cfunc); // Validate the result if (SQ_FAILED(res)) { return res; // Propagate the error } // Some dummy checks to make sure the collector is a callable object else if (!(sq_type(cfunc) & (_RT_CLOSURE | _RT_NATIVECLOSURE))) { return sq_throwerror(vm, "Invalid collector callback"); } // Enter a new execution scope Scope scope(m_Scope, m_Slots, m_Slots + m_Used); // Activate the current scope and create a guard to restore it const AutoAssign< Scope * > aa(m_Scope, scope.mParent, &scope); // Process the slots from this scope while (scope.mItr != scope.mEnd) { // Grab a reference to the current slot const Slot & slot = *(scope.mItr++); // Push the callback object sq_pushobject(vm, slot.mFuncRef); // Is there an explicit environment? if (slot.mThisHash == 0) { sq_pushroottable(vm); } else { sq_pushobject(vm, slot.mThisRef); } // Are there any parameters to forward? if (top > 3) { for (SQInteger i = 4; i <= top; ++i) { sq_push(vm, i); } } // Make the function call and store the result res = sq_call(vm, top-2, static_cast< SQBool >(true), static_cast< SQBool >(ErrorHandling::IsEnabled())); // Validate the result if (SQ_FAILED(res)) { // Pop the callback object and return value from the stack sq_pop(vm, 2); // Stop emitting signals break; } // Push the collector onto the stack sq_pushobject(vm, cfunc); sq_pushobject(vm, cthis); // Push the returned value sq_push(vm, -3); // Make the function call and store the result res = sq_call(vm, 2, static_cast< SQBool >(false), static_cast< SQBool >(ErrorHandling::IsEnabled())); // Pop the callback object, return value and collector from the stack sq_pop(vm, 3); // Validate the result if (SQ_FAILED(res)) { break; // Stop emitting signals } } // Return the last result return res; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Consume(HSQUIRRELVM vm, SQInteger top) { // Are there any slots connected? if (!m_Used) return 0; // Enter a new execution scope Scope scope(m_Scope, m_Slots, m_Slots + m_Used); // Activate the current scope and create a guard to restore it const AutoAssign< Scope * > aa(m_Scope, scope.mParent, &scope); // Contains the last received result SQRESULT res = SQ_OK; // Default to not consumed SQBool ret = SQFalse; // Process the slots from this scope while (scope.mItr != scope.mEnd) { // Grab a reference to the current slot const Slot & slot = *(scope.mItr++); // Push the callback object sq_pushobject(vm, slot.mFuncRef); // Is there an explicit environment? if (slot.mThisHash == 0) { sq_pushroottable(vm); } else { sq_pushobject(vm, slot.mThisRef); } // Are there any parameters to forward? if (top > 1) { for (SQInteger i = 2; i <= top; ++i) { sq_push(vm, i); } } // Make the function call and store the result res = sq_call(vm, top, static_cast< SQBool >(true), static_cast< SQBool >(ErrorHandling::IsEnabled())); // Validate the result if (SQ_FAILED(res)) { // Pop the callback object and return value from the stack sq_pop(vm, 2); // Stop emitting signals break; } // Is the returned value not null? else if (sq_gettype(vm, -1) != OT_NULL) { // Obtain the returned value sq_tobool(vm, -1, &ret); // Should we proceed to the next slot or stop here? if (ret == SQTrue) { // Pop the callback object and return value from the stack sq_pop(vm, 2); // The slot consumed the signal break; } } // Pop the callback object and return value from the stack sq_pop(vm, 2); } // Did we fail to process slots? if (SQ_FAILED(res)) { return res; // Propagate the error } // Forward the returned value to the invoker sq_pushbool(vm, ret); // Specify that we returned something return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Approve(HSQUIRRELVM vm, SQInteger top) { // Are there any slots connected? if (!m_Used) return 0; // Enter a new execution scope Scope scope(m_Scope, m_Slots, m_Slots + m_Used); // Activate the current scope and create a guard to restore it const AutoAssign< Scope * > aa(m_Scope, scope.mParent, &scope); // Contains the last received result SQRESULT res = SQ_OK; // Default to approved SQBool ret = SQTrue; // Process the slots from this scope while (scope.mItr != scope.mEnd) { // Grab a reference to the current slot const Slot & slot = *(scope.mItr++); // Push the callback object sq_pushobject(vm, slot.mFuncRef); // Is there an explicit environment? if (slot.mThisHash == 0) { sq_pushroottable(vm); } else { sq_pushobject(vm, slot.mThisRef); } // Are there any parameters to forward? if (top > 1) { for (SQInteger i = 2; i <= top; ++i) { sq_push(vm, i); } } // Make the function call and store the result res = sq_call(vm, top, static_cast< SQBool >(true), static_cast< SQBool >(ErrorHandling::IsEnabled())); // Validate the result if (SQ_FAILED(res)) { // Pop the callback object and return value from the stack sq_pop(vm, 2); // Stop emitting signals break; } // Is the returned value not null? else if (sq_gettype(vm, -1) != OT_NULL) { // Obtain the returned value sq_tobool(vm, -1, &ret); // Should we proceed to the next slot or stop here? if (ret == SQFalse) { // Pop the callback object and return value from the stack sq_pop(vm, 2); // The slot did not approve the signal break; } } // Pop the callback object and return value from the stack sq_pop(vm, 2); } // Did we fail to process slots? if (SQ_FAILED(res)) { return res; // Propagate the error } // Forward the returned value to the invoker sq_pushbool(vm, ret); // Specify that we returned something return 1; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::Request(HSQUIRRELVM vm, SQInteger top) { // Are there any slots connected? if (!m_Used) return 0; // Enter a new execution scope Scope scope(m_Scope, m_Slots, m_Slots + m_Used); // Activate the current scope and create a guard to restore it const AutoAssign< Scope * > aa(m_Scope, scope.mParent, &scope); // Contains the last received result SQRESULT res = SQ_OK; // Process the slots from this scope while (scope.mItr != scope.mEnd) { // Grab a reference to the current slot const Slot & slot = *(scope.mItr++); // Push the callback object sq_pushobject(vm, slot.mFuncRef); // Is there an explicit environment? if (slot.mThisHash == 0) { sq_pushroottable(vm); } else { sq_pushobject(vm, slot.mThisRef); } // Are there any parameters to forward? if (top > 1) { for (SQInteger i = 2; i <= top; ++i) { sq_push(vm, i); } } // Make the function call and store the result res = sq_call(vm, top, static_cast< SQBool >(true), static_cast< SQBool >(ErrorHandling::IsEnabled())); // Validate the result if (SQ_FAILED(res)) { // Pop the callback object and return value from the stack sq_pop(vm, 2); // Stop emitting signals break; } // Is the returned value not null? else if (sq_gettype(vm, -1) != OT_NULL) { // Remove the callback object from the stack sq_remove(vm, -2); // Specify that we returned something res = 1; // The slot did not approve the signal break; } // Pop the callback object and return value from the stack sq_pop(vm, 2); } // Return the last result return res; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::SqEmit(HSQUIRRELVM vm) { const SQInteger top = sq_gettop(vm); // Contains the last received result SQRESULT res; // Attempt to forward the call to the signal instance try { // Attempt to grab the signal instance from the stack Signal * signal = Var< Signal * >(vm, 1).value; // Do we have a valid signal instance? if (!signal) { res = sq_throwerror(vm, "Invalid signal instance"); } // Forward the call to the signal instance else { res = signal->Emit(vm, top); } } catch (const Sqrat::Exception & e) { res = sq_throwerror(vm, e.what()); } // The execution was successful return res; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::SqQuery(HSQUIRRELVM vm) { const SQInteger top = sq_gettop(vm); // Do we have the collector environment? if (top <= 1) { return sq_throwerror(vm, "Missing collector environment"); } // Do we have the collector callback? else if (top <= 2) { return sq_throwerror(vm, "Missing collector callback"); } // Contains the last received result SQRESULT res; // Attempt to forward the call to the signal instance try { // Attempt to grab the signal instance from the stack Signal * signal = Var< Signal * >(vm, 1).value; // Do we have a valid signal instance? if (!signal) { res = sq_throwerror(vm, "Invalid signal instance"); } // Forward the call to the signal instance else { res = signal->Query(vm, top); } } catch (const Sqrat::Exception & e) { res = sq_throwerror(vm, e.what()); } // The execution was successful return res; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::SqConsume(HSQUIRRELVM vm) { const SQInteger top = sq_gettop(vm); // Contains the last received result SQRESULT res; // Attempt to forward the call to the signal instance try { // Attempt to grab the signal instance from the stack Signal * signal = Var< Signal * >(vm, 1).value; // Do we have a valid signal instance? if (!signal) { res = sq_throwerror(vm, "Invalid signal instance"); } // Forward the call to the signal instance else { res = signal->Consume(vm, top); } } catch (const Sqrat::Exception & e) { res = sq_throwerror(vm, e.what()); } // The execution was successful return res; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::SqApprove(HSQUIRRELVM vm) { const SQInteger top = sq_gettop(vm); // Contains the last received result SQRESULT res; // Attempt to forward the call to the signal instance try { // Attempt to grab the signal instance from the stack Signal * signal = Var< Signal * >(vm, 1).value; // Do we have a valid signal instance? if (!signal) { res = sq_throwerror(vm, "Invalid signal instance"); } // Forward the call to the signal instance else { res = signal->Approve(vm, top); } } catch (const Sqrat::Exception & e) { res = sq_throwerror(vm, e.what()); } // The execution was successful return res; } // ------------------------------------------------------------------------------------------------ SQInteger Signal::SqRequest(HSQUIRRELVM vm) { const SQInteger top = sq_gettop(vm); // Contains the last received result SQRESULT res; // Attempt to forward the call to the signal instance try { // Attempt to grab the signal instance from the stack Signal * signal = Var< Signal * >(vm, 1).value; // Do we have a valid signal instance? if (!signal) { res = sq_throwerror(vm, "Invalid signal instance"); } // Forward the call to the signal instance else { res = signal->Request(vm, top); } } catch (const Sqrat::Exception & e) { res = sq_throwerror(vm, e.what()); } // The execution was successful return res; } // ------------------------------------------------------------------------------------------------ void Signal::Terminate() { // Terminate named signals for (const auto & s : s_Signals) { // Clear slots s.second.first->ClearSlots(); // Release the name s.second.first->m_Name.clear(); // Release whatever is in the user data s.second.first->m_Data.Release(); } // Finally clear the container itself s_Signals.clear(); // Create a copy so we don't invalidate iterators when destructor removes the instances FreeSignals fsig(s_FreeSignals); // Terminate anonymous signals for (const auto & s : fsig) { // Clear slots s->ClearSlots(); // Release whatever is in the user data s->m_Data.Release(); } // Finally clear the container itself s_FreeSignals.clear(); } // ------------------------------------------------------------------------------------------------ LightObj Signal::CreateFree() { // Remember the current stack size const StackGuard sg; // Create the signal instance DeleteGuard< Signal > dg(new Signal()); // Attempt to create the signal instance ClassType< Signal >::PushInstance(DefaultVM::Get(), dg.Get()); // This is now managed by the script dg.Release(); // Return the created signal return Var< LightObj >(DefaultVM::Get(), -1).value; } // ------------------------------------------------------------------------------------------------ LightObj Signal::Create(StackStrF & name) { // Validate the signal name if (name.mLen <= 0) { return CreateFree(); } // Create a copy of the name String sname(name.mPtr, static_cast< size_t >(name.mLen)); // Compute the hash of the specified name const std::size_t hash = std::hash< String >{}(sname); // See if the signal already exists for (const auto & e : s_Signals) { if (e.first == hash) { return e.second.second.mObj; // Found a match so let's return it } } // Remember the current stack size const StackGuard sg; // Create the signal instance DeleteGuard< Signal > dg(new Signal(std::move(sname))); // Grab the signal instance pointer Signal * ptr = dg.Get(); // Attempt to create the signal instance ClassType< Signal >::PushInstance(DefaultVM::Get(), ptr); // This is now managed by the script dg.Release(); // Grab a reference to the instance created on the stack s_Signals.emplace_back(hash, SignalPair(ptr, Var< LightObj >(DefaultVM::Get(), -1).value)); // Return the created signal return s_Signals.back().second.second.mObj; } // ------------------------------------------------------------------------------------------------ void Signal::Remove(StackStrF & name) { // Validate the signal name if (name.mLen <= 0) { STHROWF("Signals without names cannot be removed manually"); } // Create a copy of the name const String sname(name.mPtr, static_cast< size_t >(name.mLen)); // Compute the hash of the specified name const std::size_t hash = std::hash< String >{}(sname); // Iterator to the existing signal, if any auto itr = s_Signals.cbegin(); // Search for a signal with this name for (; itr != s_Signals.cend(); ++itr) { if (itr->first == hash) { break; } } // Did we find anything? if (itr != s_Signals.cend()) { // Clear the name itr->second.first->m_Name.clear(); // Put it on the free list s_FreeSignals.push_back(itr->second.first); // Finally, remove it from the named list s_Signals.erase(itr); } } // ------------------------------------------------------------------------------------------------ const LightObj & Signal::Fetch(StackStrF & name) { // Validate the signal name if (name.mLen <= 0) { STHROWF("Signals without names cannot be retrieved manually"); } // Create a copy of the name const String sname(name.mPtr, static_cast< size_t >(name.mLen)); // Compute the hash of the specified name const std::size_t hash = std::hash< String >{}(sname); // Search for a signal with this name for (const auto & e : s_Signals) { if (e.first == hash) { return e.second.second; // Found a match so let's return it } } // No such signal exists STHROWF("Unknown signal named (%s)", sname.c_str()); // SHOULD NOT REACH THIS POINT! static LightObj slo; return slo; } /* ------------------------------------------------------------------------------------------------ * Forward the call to terminate the signals. */ void TerminateSignals() { Signal::Terminate(); } // ------------------------------------------------------------------------------------------------ void InitSignalPair(SignalPair & sp, LightObj & et, const char * name) { // Remember the current stack size const StackGuard sg; // Create the signal instance DeleteGuard< Signal > dg(new Signal()); // Attempt to create the signal instance object sp.second = LightObj(dg.Get()); // Assign the signal instance itself sp.first = dg.Get(); // This is now managed by the script dg.Release(); // Should we bind this to a certain object? if (name != nullptr) { et.Bind(name, sp.second); // Bind the signal to the specified object } } // ------------------------------------------------------------------------------------------------ void ResetSignalPair(SignalPair & sp, bool clear) { // See if the slots must be cleared as well if (clear && sp.first != nullptr) { sp.first->ClearSlots(); } // Reset the signal pair sp.first = nullptr; sp.second.Release(); } // ================================================================================================ void Register_Signal(HSQUIRRELVM vm) { RootTable(vm).Bind(Typename::Str, Class< Signal, NoConstructor< Signal > >(vm, Typename::Str) // Meta-methods .SquirrelFunc(_SC("_typename"), &Typename::Fn) .Func(_SC("_tostring"), &Signal::ToString) // Core Properties .Prop(_SC("Data"), &Signal::GetData, &Signal::SetData) .Func(_SC("Name"), &Signal::ToString) .Prop(_SC("Slots"), &Signal::GetUsed) .Prop(_SC("Empty"), &Signal::IsEmpty) // Core Methods .Func(_SC("Clear"), &Signal::ClearSlots) // Squirrel Functions .SquirrelFunc(_SC("Connect"), &Signal::SqConnect) .SquirrelFunc(_SC("ConnectOnce"), &Signal::SqConnectOnce) .SquirrelFunc(_SC("Exists"), &Signal::SqExists) .SquirrelFunc(_SC("Disconnect"), &Signal::SqDisconnect) .SquirrelFunc(_SC("ExistsThis"), &Signal::SqExistsThis) .SquirrelFunc(_SC("ExistsFunc"), &Signal::SqExistsFunc) .SquirrelFunc(_SC("Count"), &Signal::SqCount) .SquirrelFunc(_SC("CountThis"), &Signal::SqCountThis) .SquirrelFunc(_SC("CountFunc"), &Signal::SqCountFunc) .SquirrelFunc(_SC("Lead"), &Signal::SqLead) .SquirrelFunc(_SC("LeadThis"), &Signal::SqLeadThis) .SquirrelFunc(_SC("LeadFunc"), &Signal::SqLeadFunc) .SquirrelFunc(_SC("Tail"), &Signal::SqTail) .SquirrelFunc(_SC("TailThis"), &Signal::SqTailThis) .SquirrelFunc(_SC("TailFunc"), &Signal::SqTailFunc) .SquirrelFunc(_SC("Eliminate"), &Signal::SqEliminate) .SquirrelFunc(_SC("EliminateThis"), &Signal::SqEliminateThis) .SquirrelFunc(_SC("EliminateFunc"), &Signal::SqEliminateFunc) .SquirrelFunc(_SC("Emit"), &Signal::SqEmit) .SquirrelFunc(_SC("Query"), &Signal::SqQuery) .SquirrelFunc(_SC("Consume"), &Signal::SqConsume) .SquirrelFunc(_SC("Approve"), &Signal::SqApprove) .SquirrelFunc(_SC("Request"), &Signal::SqRequest) ); RootTable(vm) .FmtFunc(_SC("SqSignal"), &Signal::Fetch) .FmtFunc(_SC("SqCreateSignal"), &Signal::Create) .FmtFunc(_SC("SqRemoveSignal"), &Signal::Remove); } } // Namespace:: SqMod