RUNTIME: Variable forcing now uses limited list and buffer instead of systematical instance tree traversal and in-tree "fvalue" to keep track of forced value for pointed variables (external, located). Pointer swapping is performed when forcing externals and located, with backup being restored when forcing is reset. Retain still uses tree traversal.
/**
* Win32 specific code
**/
#include <stdio.h>
#include <sys/timeb.h>
#include <time.h>
#include <windows.h>
#include <locale.h>
long AtomicCompareExchange(long* atomicvar, long compared, long exchange)
{
return InterlockedCompareExchange(atomicvar, exchange, compared);
}
CRITICAL_SECTION Atomic64CS;
long long AtomicCompareExchange64(long long* atomicvar, long long compared, long long exchange)
{
long long res;
EnterCriticalSection(&Atomic64CS);
res=*atomicvar;
if(*atomicvar == compared){
*atomicvar = exchange;
}
LeaveCriticalSection(&Atomic64CS);
return res;
}
struct timeb timetmp;
void PLC_GetTime(IEC_TIME *CURRENT_TIME)
{
ftime(&timetmp);
(*CURRENT_TIME).tv_sec = timetmp.time;
(*CURRENT_TIME).tv_nsec = timetmp.millitm * 1000000;
}
void PLC_timer_notify()
{
PLC_GetTime(&__CURRENT_TIME);
__run();
}
HANDLE PLC_timer = NULL;
void PLC_SetTimer(unsigned long long next, unsigned long long period)
{
LARGE_INTEGER liDueTime;
/* arg 2 of SetWaitableTimer take 100 ns interval*/
liDueTime.QuadPart = next / (-100);
if (!SetWaitableTimer(PLC_timer, &liDueTime, period<1000000?1:period/1000000, NULL, NULL, 0))
{
printf("SetWaitableTimer failed (%d)\n", GetLastError());
}
}
int PLC_shutdown;
int ForceSaveRetainReq(void) {
return PLC_shutdown;
}
/* Variable used to stop plcloop thread */
void PlcLoop()
{
PLC_shutdown = 0;
while(!PLC_shutdown) {
if (WaitForSingleObject(PLC_timer, INFINITE) != WAIT_OBJECT_0)
PLC_shutdown = 1;
PLC_timer_notify();
}
}
HANDLE PLC_thread;
HANDLE debug_sem;
HANDLE debug_wait_sem;
HANDLE python_sem;
HANDLE python_wait_sem;
#define maxval(a,b) ((a>b)?a:b)
int startPLC(int argc,char **argv)
{
unsigned long thread_id = 0;
BOOL tmp;
setlocale(LC_NUMERIC, "C");
debug_sem = CreateSemaphore(
NULL, // default security attributes
1, // initial count
1, // maximum count
NULL); // unnamed semaphore
if (debug_sem == NULL)
{
printf("startPLC CreateSemaphore debug_sem error: %d\n", GetLastError());
return 1;
}
debug_wait_sem = CreateSemaphore(
NULL, // default security attributes
0, // initial count
1, // maximum count
NULL); // unnamed semaphore
if (debug_wait_sem == NULL)
{
printf("startPLC CreateSemaphore debug_wait_sem error: %d\n", GetLastError());
return 1;
}
python_sem = CreateSemaphore(
NULL, // default security attributes
1, // initial count
1, // maximum count
NULL); // unnamed semaphore
if (python_sem == NULL)
{
printf("startPLC CreateSemaphore python_sem error: %d\n", GetLastError());
return 1;
}
python_wait_sem = CreateSemaphore(
NULL, // default security attributes
0, // initial count
1, // maximum count
NULL); // unnamed semaphore
if (python_wait_sem == NULL)
{
printf("startPLC CreateSemaphore python_wait_sem error: %d\n", GetLastError());
return 1;
}
/* Create a waitable timer */
timeBeginPeriod(1);
PLC_timer = CreateWaitableTimer(NULL, FALSE, "WaitableTimer");
if(NULL == PLC_timer)
{
printf("CreateWaitableTimer failed (%d)\n", GetLastError());
return 1;
}
if( __init(argc,argv) == 0 )
{
PLC_SetTimer(common_ticktime__,common_ticktime__);
PLC_thread = CreateThread(NULL, 0, (LPTHREAD_START_ROUTINE)PlcLoop, NULL, 0, &thread_id);
}
else{
return 1;
}
return 0;
}
static unsigned long __debug_tick;
int TryEnterDebugSection(void)
{
//printf("TryEnterDebugSection\n");
if(WaitForSingleObject(debug_sem, 0) == WAIT_OBJECT_0){
/* Only enter if debug active */
if(__DEBUG){
return 1;
}
ReleaseSemaphore(debug_sem, 1, NULL);
}
return 0;
}
void LeaveDebugSection(void)
{
ReleaseSemaphore(debug_sem, 1, NULL);
//printf("LeaveDebugSection\n");
}
int stopPLC()
{
CloseHandle(PLC_timer);
WaitForSingleObject(PLC_thread, INFINITE);
__cleanup();
CloseHandle(debug_wait_sem);
CloseHandle(debug_sem);
CloseHandle(python_wait_sem);
CloseHandle(python_sem);
CloseHandle(PLC_thread);
}
/* from plc_debugger.c */
int WaitDebugData(unsigned long *tick)
{
DWORD res;
res = WaitForSingleObject(debug_wait_sem, INFINITE);
*tick = __debug_tick;
/* Wait signal from PLC thread */
return res != WAIT_OBJECT_0;
}
/* Called by PLC thread when debug_publish finished
* This is supposed to unlock debugger thread in WaitDebugData*/
void InitiateDebugTransfer()
{
/* remember tick */
__debug_tick = __tick;
/* signal debugger thread it can read data */
ReleaseSemaphore(debug_wait_sem, 1, NULL);
}
int suspendDebug(int disable)
{
/* Prevent PLC to enter debug code */
WaitForSingleObject(debug_sem, INFINITE);
__DEBUG = !disable;
if(disable)
ReleaseSemaphore(debug_sem, 1, NULL);
return 0;
}
void resumeDebug()
{
__DEBUG = 1;
/* Let PLC enter debug code */
ReleaseSemaphore(debug_sem, 1, NULL);
}
/* from plc_python.c */
int WaitPythonCommands(void)
{
/* Wait signal from PLC thread */
return WaitForSingleObject(python_wait_sem, INFINITE);
}
/* Called by PLC thread on each new python command*/
void UnBlockPythonCommands(void)
{
/* signal debugger thread it can read data */
ReleaseSemaphore(python_wait_sem, 1, NULL);
}
int TryLockPython(void)
{
return WaitForSingleObject(python_sem, 0) == WAIT_OBJECT_0;
}
void UnLockPython(void)
{
ReleaseSemaphore(python_sem, 1, NULL);
}
void LockPython(void)
{
WaitForSingleObject(python_sem, INFINITE);
}
static void __attribute__((constructor))
beremiz_dll_init(void)
{
InitializeCriticalSection(&Atomic64CS);
}
static void __attribute__((destructor))
beremiz_dll_destroy(void)
{
DeleteCriticalSection(&Atomic64CS);
}
struct RT_to_nRT_signal_s {
HANDLE sem;
};
typedef struct RT_to_nRT_signal_s RT_to_nRT_signal_t;
#define _LogAndReturnNull(text) \
{\
char mstr[256] = text " for ";\
strncat(mstr, name, 255);\
LogMessage(LOG_CRITICAL, mstr, strlen(mstr));\
return NULL;\
}
void *create_RT_to_nRT_signal(char* name){
RT_to_nRT_signal_t *sig = (RT_to_nRT_signal_t*)malloc(sizeof(RT_to_nRT_signal_t));
if(!sig)
_LogAndReturnNull("Failed allocating memory for RT_to_nRT signal");
sig->sem = CreateSemaphore(
NULL, // default security attributes
1, // initial count
1, // maximum count
NULL); // unnamed semaphore
if(sig->sem == NULL)
{
char mstr[256];
snprintf(mstr, 255, "startPLC CreateSemaphore %s error: %d\n", name, GetLastError());
LogMessage(LOG_CRITICAL, mstr, strlen(mstr));
return NULL;
}
return (void*)sig;
}
void delete_RT_to_nRT_signal(void* handle){
RT_to_nRT_signal_t *sig = (RT_to_nRT_signal_t*)handle;
CloseHandle(python_sem);
free(sig);
}
int wait_RT_to_nRT_signal(void* handle){
int ret;
RT_to_nRT_signal_t *sig = (RT_to_nRT_signal_t*)handle;
return WaitForSingleObject(sig->sem, INFINITE);
}
int unblock_RT_to_nRT_signal(void* handle){
RT_to_nRT_signal_t *sig = (RT_to_nRT_signal_t*)handle;
return ReleaseSemaphore(sig->sem, 1, NULL);
}
void nRT_reschedule(void){
SwitchToThread();
}