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/*--------------------------------------------------------------------

 * TITLE: Plasma Real Time Operating System

 * AUTHOR: Steve Rhoads (rhoadss@yahoo.com)

 * DATE CREATED: 12/17/05

 * FILENAME: rtos.c

 * PROJECT: Plasma CPU core

 * COPYRIGHT: Software placed into the public domain by the author.

 *    Software 'as is' without warranty.  Author liable for nothing.

 * DESCRIPTION:

 *    Plasma Real Time Operating System

 *    Fully pre-emptive RTOS with support for:

 *       Heaps, Threads, Semaphores, Mutexes, Message Queues, and Timers.

 *    This file tries to be hardware independent except for calls to:

 *       MemoryRead() and MemoryWrite() for interrupts.

 *    Support for multiple CPUs using symmetric multiprocessing.

 *--------------------------------------------------------------------*/

#include "plasma.h"

#include "rtos.h"

#define HEAP_MAGIC 0x1234abcd

#define THREAD_MAGIC 0x4321abcd

#define SEM_RESERVED_COUNT 2

#define INFO_COUNT 4

#define HEAP_COUNT 8

#define PRINTF_DEBUG(STRING, A, B)

//#define PRINTF_DEBUG(STRING, A, B) UartPrintfCritical(STRING, A, B)

/*************** Structures ***************/

#ifdef WIN32

   #define setjmp _setjmp

   //x86 registers

   typedef struct jmp_buf2 {

      uint32 Ebp, Ebx, Edi, Esi, sp, pc, extra[10];

   } jmp_buf2;

#elif defined(ARM_CPU)

   //ARM registers

   typedef struct jmp_buf2 {

      uint32 r[13], sp, lr, pc, cpsr, extra[5];

   } jmp_buf2;

#else  

   //Plasma registers

   typedef struct jmp_buf2 {

      uint32 s[9], gp, sp, pc;

   } jmp_buf2;

#endif

typedef struct HeapNode_s {

   struct HeapNode_s *next;

   int size;

} HeapNode_t;

struct OS_Heap_s {

   uint32 magic;

   const char *name;

   OS_Semaphore_t *semaphore;

   HeapNode_t *available;

   HeapNode_t base;

   int count;

   struct OS_Heap_s *alternate;

};

//typedef struct OS_Heap_s OS_Heap_t;

typedef enum {

   THREAD_PEND    = 0,       //Thread in semaphore's linked list

   THREAD_READY   = 1,       //Thread in ThreadHead linked list

   THREAD_RUNNING = 2        //Thread == ThreadCurrent[cpu]

} OS_ThreadState_e;

struct OS_Thread_s {

   const char *name;         //Name of thread

   OS_ThreadState_e state;   //Pending, ready, or running

   int cpuIndex;             //Which CPU is running the thread

   int cpuLock;              //Lock the thread to a specific CPU

   jmp_buf env;              //Registers saved during context swap

   OS_FuncPtr_t funcPtr;     //First function called

   void *arg;                //Argument to first function called

   uint32 priority;          //Priority of thread (0=low, 255=high)

   uint32 ticksTimeout;      //Tick value when semaphore pend times out

   void *info[INFO_COUNT];   //User storage

   OS_Semaphore_t *semaphorePending;  //Semaphore thread is blocked on

   int returnCode;           //Return value from semaphore pend

   uint32 processId;         //Process ID if using MMU

   OS_Heap_t *heap;          //Heap used if no heap specified

   struct OS_Thread_s *next; //Linked list of threads by priority

   struct OS_Thread_s *prev;

   struct OS_Thread_s *nextTimeout; //Linked list of threads by timeout

   struct OS_Thread_s *prevTimeout;

   uint32 magic[1];          //Bottom of stack to detect stack overflow

};

//typedef struct OS_Thread_s OS_Thread_t;

struct OS_Semaphore_s {

   const char *name;

   struct OS_Thread_s *threadHead; //threads pending on semaphore

   int count;

};

//typedef struct OS_Semaphore_s OS_Semaphore_t;

struct OS_Mutex_s {

   OS_Semaphore_t *semaphore;

   OS_Thread_t *thread;

   uint32 priorityRestore;

   int count;

};

//typedef struct OS_Mutex_s OS_Mutex_t;

struct OS_MQueue_s {

   const char *name;

   OS_Semaphore_t *semaphore;

   int count, size, used, read, write;

};

//typedef struct OS_MQueue_s OS_MQueue_t;

struct OS_Timer_s {

   const char *name;

   struct OS_Timer_s *next, *prev;

   uint32 ticksTimeout;

   uint32 ticksRestart;

   int active;

   OS_TimerFuncPtr_t callback;

   OS_MQueue_t *mqueue;

   uint32 info;

};

//typedef struct OS_Timer_s OS_Timer_t;

/*************** Globals ******************/

static OS_Heap_t *HeapArray[HEAP_COUNT];

static int InterruptInside[OS_CPU_COUNT];

static int ThreadNeedReschedule[OS_CPU_COUNT];

static OS_Thread_t *ThreadCurrent[OS_CPU_COUNT];  //Currently running thread(s)

static OS_Thread_t *ThreadHead;   //Linked list of threads sorted by priority

static OS_Thread_t *TimeoutHead;  //Linked list of threads sorted by timeout

static int ThreadSwapEnabled;

static uint32 ThreadTime;         //Number of ~10ms ticks since reboot

static void *NeedToFree;          //Closed but not yet freed thread

static OS_Semaphore_t SemaphoreReserved[SEM_RESERVED_COUNT];

static OS_Semaphore_t *SemaphoreSleep;

static OS_Semaphore_t *SemaphoreRelease; //Protects NeedToFree

static OS_Semaphore_t *SemaphoreLock;

static OS_Semaphore_t *SemaphoreTimer;

static OS_Timer_t *TimerHead;     //Linked list of timers sorted by timeout

static OS_FuncPtr_t Isr[32];      //Interrupt service routines

#if defined(WIN32) && OS_CPU_COUNT > 1

static unsigned int Registration[OS_CPU_COUNT];

#endif

/***************** Heap *******************/

/******************************************/

OS_Heap_t *OS_HeapCreate(const char *name, void *memory, uint32 size)

{

   OS_Heap_t *heap;

   assert(((uint32)memory & 3) == 0);

   heap = (OS_Heap_t*)memory;

   heap->magic = HEAP_MAGIC;

   heap->name = name;

   heap->semaphore = OS_SemaphoreCreate(name, 1);

   heap->available = (HeapNode_t*)(heap + 1);

   heap->available->next = &heap->base;

   heap->available->size = (size - sizeof(OS_Heap_t)) / sizeof(HeapNode_t);

   heap->base.next = heap->available;

   heap->base.size = 0;

   heap->count = 0;

   heap->alternate = NULL;

   return heap;

}

/******************************************/

void OS_HeapDestroy(OS_Heap_t *heap)

{

   OS_SemaphoreDelete(heap->semaphore);

}

/******************************************/

//Modified from Kernighan & Ritchie "The C Programming Language"

void *OS_HeapMalloc(OS_Heap_t *heap, int bytes)

{

   HeapNode_t *node, *prevp;

   int nunits;

   if(heap == NULL && OS_ThreadSelf())

      heap = OS_ThreadSelf()->heap;

   if((uint32)heap < HEAP_COUNT)

      heap = HeapArray[(int)heap];

   nunits = (bytes + sizeof(HeapNode_t) - 1) / sizeof(HeapNode_t) + 1;

   OS_SemaphorePend(heap->semaphore, OS_WAIT_FOREVER);

   prevp = heap->available;

   for(node = prevp->next; ; prevp = node, node = node->next)

   {

      if(node->size >= nunits)       //Big enough?

      {

         if(node->size == nunits)    //Exactly

            prevp->next = node->next;

         else

         {                           //Allocate tail end

            node->size -= nunits;

            node += node->size;

            node->size = nunits;

         }

         heap->available = prevp;

         node->next = (HeapNode_t*)heap;

         PRINTF_DEBUG("malloc(%d, %d)\n", node->size * sizeof(HeapNode_t), heap->count);

         ++heap->count;

         OS_SemaphorePost(heap->semaphore);

         //UartPrintfCritical("OS_HeapMalloc(%d)=0x%x\n", bytes, (int)(node+1));

         return (void*)(node + 1);

      }

      if(node == heap->available)   //Wrapped around free list

      {

         OS_SemaphorePost(heap->semaphore);

         if(heap->alternate)

            return OS_HeapMalloc(heap->alternate, bytes);

         printf("M%d ", heap->count);

         return NULL;

      }

   }

}

/******************************************/

//Modified from K&R

void OS_HeapFree(void *block)

{

   OS_Heap_t *heap;

   HeapNode_t *bp, *node;

   //UartPrintfCritical("OS_HeapFree(0x%x)\n", block);

   assert(block);

   bp = (HeapNode_t*)block - 1;   //point to block header

   heap = (OS_Heap_t*)bp->next;

   assert(heap->magic == HEAP_MAGIC);

   if(heap->magic != HEAP_MAGIC)

      return;

   OS_SemaphorePend(heap->semaphore, OS_WAIT_FOREVER);

   --heap->count;

   PRINTF_DEBUG("free(%d, %d)\n", bp->size * sizeof(HeapNode_t), heap->count);

   for(node = heap->available; !(node < bp && bp < node->next); node = node->next)

   {

      if(node >= node->next && (bp > node || bp < node->next))

         break;               //freed block at start or end of area

   }

   if(bp + bp->size == node->next)   //join to upper

   {

      bp->size += node->next->size;

      bp->next = node->next->next;

   }

   else

   {

      bp->next = node->next;

   }

   if(node + node->size == bp)       //join to lower

   {

      node->size += bp->size;

      node->next = bp->next;

   }

   else

      node->next = bp;

   heap->available = node;

   OS_SemaphorePost(heap->semaphore);

}

/******************************************/

void OS_HeapAlternate(OS_Heap_t *heap, OS_Heap_t *alternate)

{

   heap->alternate = alternate;

}

/******************************************/

void OS_HeapRegister(void *index, OS_Heap_t *heap)

{

   if((uint32)index < HEAP_COUNT)

      HeapArray[(int)index] = heap;

}

/***************** Thread *****************/

/******************************************/

//Linked list of threads sorted by priority

//The listed list is either ThreadHead (ready to run threads not including

//the currently running thread) or a list of threads waiting on a semaphore.

//Must be called with interrupts disabled

static void OS_ThreadPriorityInsert(OS_Thread_t **head, OS_Thread_t *thread)

{

   OS_Thread_t *node, *prev;

   prev = NULL;

   for(node = *head; node; node = node->next)

   {

      if(node->priority < thread->priority)

         break;

      prev = node;

   }

   if(prev == NULL)

   {

      thread->next = *head;

      thread->prev = NULL;

      if(*head)

         (*head)->prev = thread;

      *head = thread;

   }

   else

   {

      if(prev->next)

         prev->next->prev = thread;

      thread->next = prev->next;

      thread->prev = prev;

      prev->next = thread;

   }

   assert(ThreadHead);

   thread->state = THREAD_READY;

}

/******************************************/

//Must be called with interrupts disabled

static void OS_ThreadPriorityRemove(OS_Thread_t **head, OS_Thread_t *thread)

{

   assert(thread->magic[0] == THREAD_MAGIC);  //check stack overflow

   if(thread->prev == NULL)

      *head = thread->next;

   else

      thread->prev->next = thread->next;

   if(thread->next)

      thread->next->prev = thread->prev;

   thread->next = NULL;

   thread->prev = NULL;

}

/******************************************/

//Linked list of threads sorted by timeout value

//Must be called with interrupts disabled

static void OS_ThreadTimeoutInsert(OS_Thread_t *thread)

{

   OS_Thread_t *node, *prev;

   int diff;

   prev = NULL;

   for(node = TimeoutHead; node; node = node->nextTimeout)

   {

      diff = thread->ticksTimeout - node->ticksTimeout;

      if(diff <= 0)

         break;

      prev = node;

   }

   if(prev == NULL)

   {

      thread->nextTimeout = TimeoutHead;

      thread->prevTimeout = NULL;

      if(TimeoutHead)

         TimeoutHead->prevTimeout = thread;

      TimeoutHead = thread;

   }

   else

   {

      if(prev->nextTimeout)

         prev->nextTimeout->prevTimeout = thread;

      thread->nextTimeout = prev->nextTimeout;

      thread->prevTimeout = prev;

      prev->nextTimeout = thread;

   }

}

/******************************************/

//Must be called with interrupts disabled

static void OS_ThreadTimeoutRemove(OS_Thread_t *thread)

{

   if(thread->prevTimeout == NULL && TimeoutHead != thread)

      return;         //not in list

   if(thread->prevTimeout == NULL)

      TimeoutHead = thread->nextTimeout;

   else

      thread->prevTimeout->nextTimeout = thread->nextTimeout;

   if(thread->nextTimeout)

      thread->nextTimeout->prevTimeout = thread->prevTimeout;

   thread->nextTimeout = NULL;

   thread->prevTimeout = NULL;

}

/******************************************/

//Loads highest priority thread from the ThreadHead linked list

//The currently running thread isn't in the ThreadHead list

//Must be called with interrupts disabled

static void OS_ThreadReschedule(int roundRobin)

{

   OS_Thread_t *threadNext, *threadCurrent;

   int rc, cpuIndex = OS_CpuIndex();

   if(ThreadSwapEnabled == 0 || InterruptInside[cpuIndex])

   {

      ThreadNeedReschedule[cpuIndex] |= 2 + roundRobin;  //Reschedule later

      return;

   }

   ThreadNeedReschedule[cpuIndex] = 0;

   //Determine which thread should run

   threadNext = ThreadHead;

   while(threadNext && threadNext->cpuLock != -1 &&

         threadNext->cpuLock != cpuIndex)

      threadNext = threadNext->next;         //Skip CPU locked threads

   if(threadNext == NULL)

      return;

   threadCurrent = ThreadCurrent[cpuIndex];

   if(threadCurrent == NULL ||

      threadCurrent->state == THREAD_PEND ||

      threadCurrent->priority < threadNext->priority ||

      (roundRobin && threadCurrent->priority == threadNext->priority))

   {

      //Swap threads

      ThreadCurrent[cpuIndex] = threadNext;

      if(threadCurrent)

      {

         assert(threadCurrent->magic[0] == THREAD_MAGIC); //check stack overflow

         if(threadCurrent->state == THREAD_RUNNING)

            OS_ThreadPriorityInsert(&ThreadHead, threadCurrent);

         //PRINTF_DEBUG("Pause(%d,%s) ", OS_CpuIndex(), threadCurrent->name);

         rc = setjmp(threadCurrent->env);  //ANSI C call to save registers

         if(rc)

         {

            //PRINTF_DEBUG("Resume(%d,%s) ", OS_CpuIndex(), 

            //   ThreadCurrent[OS_CpuIndex()]->name);

            return;  //Returned from longjmp()

         }

      }

      //Remove the new running thread from the ThreadHead linked list

      threadNext = ThreadCurrent[OS_CpuIndex()]; //removed warning

      assert(threadNext->state == THREAD_READY);

      OS_ThreadPriorityRemove(&ThreadHead, threadNext);

      threadNext->state = THREAD_RUNNING;

      threadNext->cpuIndex = OS_CpuIndex();

#if defined(WIN32) && OS_CPU_COUNT > 1

      //Set the Windows thread that the Plasma thread is running on

      ((jmp_buf2*)threadNext->env)->extra[0] = Registration[threadNext->cpuIndex];

#endif

      longjmp(threadNext->env, 1);         //ANSI C call to restore registers

   }

}

/******************************************/

void OS_ThreadCpuLock(OS_Thread_t *thread, int cpuIndex)

{

   thread->cpuLock = cpuIndex;

   if(thread == OS_ThreadSelf() && cpuIndex != (int)OS_CpuIndex())

      OS_ThreadSleep(1);

}

/******************************************/

static void OS_ThreadInit(void *arg)

{

   uint32 cpuIndex = OS_CpuIndex();

   (void)arg;

   PRINTF_DEBUG("Starting(%d,%s) ", cpuIndex, OS_ThreadSelf()->name);

   OS_CriticalEnd(1);

   ThreadCurrent[cpuIndex]->funcPtr(ThreadCurrent[cpuIndex]->arg);

   OS_ThreadExit();

}

/******************************************/

//Stops warning "argument X might be clobbered by `longjmp'"

static void OS_ThreadRegsInit(jmp_buf env)

{

   setjmp(env); //ANSI C call to save registers

}

/******************************************/

OS_Thread_t *OS_ThreadCreate(const char *name,

                             OS_FuncPtr_t funcPtr,

                             void *arg,

                             uint32 priority,

                             uint32 stackSize)

{

   OS_Thread_t *thread;

   uint8 *stack;

   jmp_buf2 *env;

   uint32 state;

#ifdef WIN32

   int stackFrameSize;

#endif

   OS_SemaphorePend(SemaphoreRelease, OS_WAIT_FOREVER);

   if(NeedToFree)

      OS_HeapFree(NeedToFree);

   NeedToFree = NULL;

   OS_SemaphorePost(SemaphoreRelease);

   if(stackSize == 0)

      stackSize = STACK_SIZE_DEFAULT;

   if(stackSize < STACK_SIZE_MINIMUM)

      stackSize = STACK_SIZE_MINIMUM;

   thread = (OS_Thread_t*)OS_HeapMalloc(NULL, sizeof(OS_Thread_t) + stackSize);

   assert(thread);

   if(thread == NULL)

      return NULL;

   memset(thread, 0, sizeof(OS_Thread_t));

   stack = (uint8*)(thread + 1);

   memset(stack, 0xcd, stackSize);

   thread->name = name;

   thread->state = THREAD_READY;

   thread->cpuLock = -1;

   thread->funcPtr = funcPtr;

   thread->arg = arg;

   thread->priority = priority;

   thread->semaphorePending = NULL;

   thread->returnCode = 0;

   if(OS_ThreadSelf())

   {

      thread->processId = OS_ThreadSelf()->processId;

      thread->heap = OS_ThreadSelf()->heap;

   }

   else

   {

      thread->processId = 0;

      thread->heap = NULL;

   }

   thread->next = NULL;

   thread->prev = NULL;

   thread->nextTimeout = NULL;

   thread->prevTimeout = NULL;

   thread->magic[0] = THREAD_MAGIC;

   OS_ThreadRegsInit(thread->env);

   env = (jmp_buf2*)thread->env;

   env->pc = (uint32)OS_ThreadInit;

#ifndef WIN32

   env->sp = (uint32)stack + stackSize - 24; //minimum stack frame size

#else

   stackFrameSize = env->Ebp - env->sp;

   env->Ebp = (uint32)stack + stackSize - 24;//stack frame base pointer

   env->sp =  env->Ebp - stackFrameSize;

#endif

   //Add thread to linked list of ready to run threads

   state = OS_CriticalBegin();

   OS_ThreadPriorityInsert(&ThreadHead, thread);

   OS_ThreadReschedule(0);                   //run highest priority thread

   OS_CriticalEnd(state);

   return thread;

}

/******************************************/

void OS_ThreadExit(void)

{

   uint32 state, cpuIndex = OS_CpuIndex();

   for(;;)

   {

      //Free the memory for closed but not yet freed threads

      OS_SemaphorePend(SemaphoreRelease, OS_WAIT_FOREVER);

      if(NeedToFree)

         OS_HeapFree(NeedToFree);

      NeedToFree = NULL;

      OS_SemaphorePost(SemaphoreRelease);

      state = OS_CriticalBegin();

      if(NeedToFree)

      {

         OS_CriticalEnd(state);

         continue;

      }

      ThreadCurrent[cpuIndex]->state = THREAD_PEND;

      NeedToFree = ThreadCurrent[cpuIndex];

      OS_ThreadReschedule(0);

      OS_CriticalEnd(state);

   }

}

/******************************************/

//Return currently running thread

OS_Thread_t *OS_ThreadSelf(void)

{

   return ThreadCurrent[OS_CpuIndex()];

}

/******************************************/

//Sleep for ~10 msecs ticks

void OS_ThreadSleep(int ticks)

{

   OS_SemaphorePend(SemaphoreSleep, ticks);

}

/******************************************/

//Return the number of ~10 msecs ticks since reboot

uint32 OS_ThreadTime(void)

{

   return ThreadTime;

}

/******************************************/

//Save thread unique values

void OS_ThreadInfoSet(OS_Thread_t *thread, uint32 index, void *Info)

{

   if(index < INFO_COUNT)

      thread->info[index] = Info;

}

/******************************************/

void *OS_ThreadInfoGet(OS_Thread_t *thread, uint32 index)

{

   if(index < INFO_COUNT)

      return thread->info[index];

   return NULL;

}

/******************************************/

uint32 OS_ThreadPriorityGet(OS_Thread_t *thread)

{

   return thread->priority;

}

/******************************************/

void OS_ThreadPrioritySet(OS_Thread_t *thread, uint32 priority)

{

   uint32 state;

   state = OS_CriticalBegin();

   thread->priority = priority;

   if(thread->state == THREAD_READY)

   {

      OS_ThreadPriorityRemove(&ThreadHead, thread);

      OS_ThreadPriorityInsert(&ThreadHead, thread);

      OS_ThreadReschedule(0);

   }

   OS_CriticalEnd(state);

}

/******************************************/

void OS_ThreadProcessId(OS_Thread_t *thread, uint32 processId, OS_Heap_t *heap)

{

   thread->processId = processId;

   thread->heap = heap;

}

/******************************************/

//Must be called with interrupts disabled every ~10 msecs

//Will wake up threads that have timed out waiting on a semaphore

static void OS_ThreadTick(void *Arg)

{

   OS_Thread_t *thread;

   OS_Semaphore_t *semaphore;

   int diff;

   (void)Arg;