2 * AcessOS Microkernel Version
16 #define DEBUG_TRACE_SWITCH 0
17 #define DEBUG_DISABLE_DOUBLEFAULT 1
20 #define SWITCH_MAGIC 0xFF5317C8 // FF SWITCH - There is no code in this area
22 #define TIMER_BASE 1193182
23 #define TIMER_DIVISOR 11932 //~100Hz
30 Uint8 State; // 0: Unavaliable, 1: Idle, 2: Active
40 extern void APWait(void); // 16-bit AP pause code
41 extern void APStartup(void); // 16-bit AP startup code
42 extern Uint GetEIP(void); // start.asm
43 extern int GetCPUNum(void); // start.asm
44 extern Uint32 gaInitPageDir[1024]; // start.asm
45 extern char Kernel_Stack_Top[];
46 extern tShortSpinlock glThreadListLock;
49 extern tThread gThreadZero;
50 extern tThread *Threads_CloneTCB(Uint *Err, Uint Flags);
51 extern void Isr8(void); // Double Fault
52 extern void Proc_ReturnToUser(tVAddr Handler, Uint Argument, tVAddr KernelStack);
55 void ArchThreads_Init(void);
57 void MP_StartAP(int CPU);
58 void MP_SendIPI(Uint8 APICID, int Vector, int DeliveryMode);
60 void Proc_Start(void);
61 tThread *Proc_GetCurThread(void);
62 void Proc_ChangeStack(void);
63 int Proc_Clone(Uint *Err, Uint Flags);
64 void Proc_StartProcess(Uint16 SS, Uint Stack, Uint Flags, Uint16 CS, Uint IP);
65 void Proc_CallFaultHandler(tThread *Thread);
66 void Proc_Scheduler(int CPU);
69 // --- Multiprocessing ---
71 volatile int giNumInitingCPUs = 0;
72 tMPInfo *gMPFloatPtr = NULL;
73 volatile Uint32 giMP_TimerCount; // Start Count for Local APIC Timer
74 tAPIC *gpMP_LocalAPIC = NULL;
75 Uint8 gaAPIC_to_CPU[256] = {0};
76 tCPU gaCPUs[MAX_CPUS];
77 tTSS gaTSSs[MAX_CPUS]; // TSS Array
78 int giProc_BootProcessorID = 0;
80 tThread *gCurrentThread = NULL;
81 tThread *gpIdleThread = NULL;
84 Uint32 *gPML4s[4] = NULL;
86 tTSS *gTSSs = NULL; // Pointer to TSS array
88 // --- Error Recovery ---
89 char gaDoubleFaultStack[1024] __attribute__ ((section(".padata")));
90 tTSS gDoubleFault_TSS = {
91 .ESP0 = (Uint)&gaDoubleFaultStack[1024],
93 .CR3 = (Uint)gaInitPageDir - KERNEL_BASE,
95 .ESP = (Uint)&gaDoubleFaultStack[1024],
96 .CS = 0x08, .SS = 0x10,
97 .DS = 0x10, .ES = 0x10,
98 .FS = 0x10, .GS = 0x10,
103 * \fn void ArchThreads_Init(void)
104 * \brief Starts the process scheduler
106 void ArchThreads_Init(void)
113 // Mark BSP as active
116 // -- Initialise Multiprocessing
117 // Find MP Floating Table
118 // - EBDA/Last 1Kib (640KiB)
119 for(pos = KERNEL_BASE|0x9F000; pos < (KERNEL_BASE|0xA0000); pos += 16) {
120 if( *(Uint*)(pos) == MPPTR_IDENT ) {
121 Log("Possible %p", pos);
122 if( ByteSum((void*)pos, sizeof(tMPInfo)) != 0 ) continue;
123 gMPFloatPtr = (void*)pos;
127 // - Last KiB (512KiB base mem)
129 for(pos = KERNEL_BASE|0x7F000; pos < (KERNEL_BASE|0x80000); pos += 16) {
130 if( *(Uint*)(pos) == MPPTR_IDENT ) {
131 Log("Possible %p", pos);
132 if( ByteSum((void*)pos, sizeof(tMPInfo)) != 0 ) continue;
133 gMPFloatPtr = (void*)pos;
140 for(pos = KERNEL_BASE|0xE0000; pos < (KERNEL_BASE|0x100000); pos += 16) {
141 if( *(Uint*)(pos) == MPPTR_IDENT ) {
142 Log("Possible %p", pos);
143 if( ByteSum((void*)pos, sizeof(tMPInfo)) != 0 ) continue;
144 gMPFloatPtr = (void*)pos;
150 // If the MP Table Exists, parse it
155 Log("gMPFloatPtr = %p", gMPFloatPtr);
156 Log("*gMPFloatPtr = {");
157 Log("\t.Sig = 0x%08x", gMPFloatPtr->Sig);
158 Log("\t.MPConfig = 0x%08x", gMPFloatPtr->MPConfig);
159 Log("\t.Length = 0x%02x", gMPFloatPtr->Length);
160 Log("\t.Version = 0x%02x", gMPFloatPtr->Version);
161 Log("\t.Checksum = 0x%02x", gMPFloatPtr->Checksum);
162 Log("\t.Features = [0x%02x,0x%02x,0x%02x,0x%02x,0x%02x]",
163 gMPFloatPtr->Features[0], gMPFloatPtr->Features[1],
164 gMPFloatPtr->Features[2], gMPFloatPtr->Features[3],
165 gMPFloatPtr->Features[4]
169 mptable = (void*)( KERNEL_BASE|gMPFloatPtr->MPConfig );
170 Log("mptable = %p", mptable);
172 Log("\t.Sig = 0x%08x", mptable->Sig);
173 Log("\t.BaseTableLength = 0x%04x", mptable->BaseTableLength);
174 Log("\t.SpecRev = 0x%02x", mptable->SpecRev);
175 Log("\t.Checksum = 0x%02x", mptable->Checksum);
176 Log("\t.OEMID = '%8c'", mptable->OemID);
177 Log("\t.ProductID = '%8c'", mptable->ProductID);
178 Log("\t.OEMTablePtr = %p'", mptable->OEMTablePtr);
179 Log("\t.OEMTableSize = 0x%04x", mptable->OEMTableSize);
180 Log("\t.EntryCount = 0x%04x", mptable->EntryCount);
181 Log("\t.LocalAPICMemMap = 0x%08x", mptable->LocalAPICMemMap);
182 Log("\t.ExtendedTableLen = 0x%04x", mptable->ExtendedTableLen);
183 Log("\t.ExtendedTableChecksum = 0x%02x", mptable->ExtendedTableChecksum);
186 gpMP_LocalAPIC = (void*)MM_MapHWPages(mptable->LocalAPICMemMap, 1);
188 ents = mptable->Entries;
191 for( i = 0; i < mptable->EntryCount; i ++ )
198 Log("%i: Processor", i);
199 Log("\t.APICID = %i", ents->Proc.APICID);
200 Log("\t.APICVer = 0x%02x", ents->Proc.APICVer);
201 Log("\t.CPUFlags = 0x%02x", ents->Proc.CPUFlags);
202 Log("\t.CPUSignature = 0x%08x", ents->Proc.CPUSignature);
203 Log("\t.FeatureFlags = 0x%08x", ents->Proc.FeatureFlags);
206 if( !(ents->Proc.CPUFlags & 1) ) {
211 // Check if there is too many processors
212 if(giNumCPUs >= MAX_CPUS) {
213 giNumCPUs ++; // If `giNumCPUs` > MAX_CPUS later, it will be clipped
217 // Initialise CPU Info
218 gaAPIC_to_CPU[ents->Proc.APICID] = giNumCPUs;
219 gaCPUs[giNumCPUs].APICID = ents->Proc.APICID;
220 gaCPUs[giNumCPUs].State = 0;
224 if( ents->Proc.CPUFlags & 2 ) {
225 giProc_BootProcessorID = giNumCPUs-1;
234 Log("\t.ID = %i", ents->Bus.ID);
235 Log("\t.TypeString = '%6C'", ents->Bus.TypeString);
239 Log("%i: I/O APIC", i);
240 Log("\t.ID = %i", ents->IOAPIC.ID);
241 Log("\t.Version = 0x%02x", ents->IOAPIC.Version);
242 Log("\t.Flags = 0x%02x", ents->IOAPIC.Flags);
243 Log("\t.Addr = 0x%08x", ents->IOAPIC.Addr);
245 case 3: // I/O Interrupt Assignment
247 Log("%i: I/O Interrupt Assignment", i);
248 Log("\t.IntType = %i", ents->IOInt.IntType);
249 Log("\t.Flags = 0x%04x", ents->IOInt.Flags);
250 Log("\t.SourceBusID = 0x%02x", ents->IOInt.SourceBusID);
251 Log("\t.SourceBusIRQ = 0x%02x", ents->IOInt.SourceBusIRQ);
252 Log("\t.DestAPICID = 0x%02x", ents->IOInt.DestAPICID);
253 Log("\t.DestAPICIRQ = 0x%02x", ents->IOInt.DestAPICIRQ);
255 case 4: // Local Interrupt Assignment
257 Log("%i: Local Interrupt Assignment", i);
258 Log("\t.IntType = %i", ents->LocalInt.IntType);
259 Log("\t.Flags = 0x%04x", ents->LocalInt.Flags);
260 Log("\t.SourceBusID = 0x%02x", ents->LocalInt.SourceBusID);
261 Log("\t.SourceBusIRQ = 0x%02x", ents->LocalInt.SourceBusIRQ);
262 Log("\t.DestLocalAPICID = 0x%02x", ents->LocalInt.DestLocalAPICID);
263 Log("\t.DestLocalAPICIRQ = 0x%02x", ents->LocalInt.DestLocalAPICIRQ);
266 Log("%i: Unknown (%i)", i, ents->Type);
270 ents = (void*)( (Uint)ents + entSize );
273 if( giNumCPUs > MAX_CPUS ) {
274 Warning("Too many CPUs detected (%i), only using %i of them", giNumCPUs, MAX_CPUS);
275 giNumCPUs = MAX_CPUS;
280 Log("No MP Table was found, assuming uniprocessor\n");
287 MM_FinishVirtualInit();
290 #if !DEBUG_DISABLE_DOUBLEFAULT
291 // Initialise Double Fault TSS
292 gGDT[5].BaseLow = (Uint)&gDoubleFault_TSS & 0xFFFF;
293 gGDT[5].BaseMid = (Uint)&gDoubleFault_TSS >> 16;
294 gGDT[5].BaseHi = (Uint)&gDoubleFault_TSS >> 24;
296 // Set double fault IDT to use the new TSS
297 gIDT[8].OffsetLo = 0;
299 gIDT[8].Flags = 0x8500;
300 gIDT[8].OffsetHi = 0;
303 // Set timer frequency
304 outb(0x43, 0x34); // Set Channel 0, Low/High, Rate Generator
305 outb(0x40, TIMER_DIVISOR&0xFF); // Low Byte of Divisor
306 outb(0x40, (TIMER_DIVISOR>>8)&0xFF); // High Byte
308 Log("Timer Frequency %i.%03i Hz",
309 TIMER_BASE/TIMER_DIVISOR,
310 ((Uint64)TIMER_BASE*1000/TIMER_DIVISOR)%1000
314 // Get the count setting for APIC timer
315 Log("Determining APIC Count");
316 __asm__ __volatile__ ("sti");
317 while( giMP_TimerCount == 0 ) __asm__ __volatile__ ("hlt");
318 __asm__ __volatile__ ("cli");
319 Log("APIC Count %i", giMP_TimerCount);
321 Uint64 freq = giMP_TimerCount;
322 freq /= TIMER_DIVISOR;
324 if( (freq /= 1000) < 2*1000)
325 Log("Bus Frequency %i KHz", freq);
326 else if( (freq /= 1000) < 2*1000)
327 Log("Bus Frequency %i MHz", freq);
328 else if( (freq /= 1000) < 2*1000)
329 Log("Bus Frequency %i GHz", freq);
331 Log("Bus Frequency %i THz", freq);
334 // Initialise Normal TSS(s)
335 for(pos=0;pos<giNumCPUs;pos++)
340 gTSSs[pos].SS0 = 0x10;
341 gTSSs[pos].ESP0 = 0; // Set properly by scheduler
342 gGDT[6+pos].BaseLow = ((Uint)(&gTSSs[pos])) & 0xFFFF;
343 gGDT[6+pos].BaseMid = ((Uint)(&gTSSs[pos]) >> 16) & 0xFFFF;
344 gGDT[6+pos].BaseHi = ((Uint)(&gTSSs[pos])) >> 24;
349 // Load the BSP's TSS
350 __asm__ __volatile__ ("ltr %%ax"::"a"(0x30));
351 // Set Current Thread and CPU Number in DR0 and DR1
352 __asm__ __volatile__ ("mov %0, %%db0"::"r"(&gThreadZero));
353 __asm__ __volatile__ ("mov %0, %%db1"::"r"(0));
356 gaCPUs[0].Current = &gThreadZero;
358 gCurrentThread = &gThreadZero;
360 gThreadZero.CurCPU = 0;
363 gThreadZero.MemState.PDP[0] = 0;
364 gThreadZero.MemState.PDP[1] = 0;
365 gThreadZero.MemState.PDP[2] = 0;
367 gThreadZero.MemState.CR3 = (Uint)gaInitPageDir - KERNEL_BASE;
370 // Create Per-Process Data Block
371 MM_Allocate(MM_PPD_CFG);
378 void MP_StartAP(int CPU)
380 Log("Starting AP %i (APIC %i)", CPU, gaCPUs[CPU].APICID);
382 // Set location of AP startup code and mark for a warm restart
383 *(Uint16*)(KERNEL_BASE|0x467) = (Uint)&APWait - (KERNEL_BASE|0xFFFF0);
384 *(Uint16*)(KERNEL_BASE|0x469) = 0xFFFF;
385 outb(0x70, 0x0F); outb(0x71, 0x0A); // Set warm reset flag
386 MP_SendIPI(gaCPUs[CPU].APICID, 0, 5); // Init IPI
389 inb(0x80); inb(0x80); inb(0x80); inb(0x80);
391 // TODO: Use a better address, preferably registered with the MM
392 // - MM_AllocDMA mabye?
394 *(Uint8*)(KERNEL_BASE|0x11000) = 0xEA; // Far JMP
395 *(Uint16*)(KERNEL_BASE|0x11001) = (Uint)&APStartup - (KERNEL_BASE|0xFFFF0); // IP
396 *(Uint16*)(KERNEL_BASE|0x11003) = 0xFFFF; // CS
397 // Send a Startup-IPI to make the CPU execute at 0x11000 (which we
399 MP_SendIPI(gaCPUs[CPU].APICID, 0x11, 6); // StartupIPI
405 * \brief Send an Inter-Processor Interrupt
406 * \param APICID Processor's Local APIC ID
407 * \param Vector Argument of some kind
408 * \param DeliveryMode Type of signal?
410 void MP_SendIPI(Uint8 APICID, int Vector, int DeliveryMode)
415 val = (Uint)APICID << 24;
416 Log("*%p = 0x%08x", &gpMP_LocalAPIC->ICR[1], val);
417 gpMP_LocalAPIC->ICR[1].Val = val;
419 val = ((DeliveryMode & 7) << 8) | (Vector & 0xFF);
420 Log("*%p = 0x%08x", &gpMP_LocalAPIC->ICR[0], val);
421 gpMP_LocalAPIC->ICR[0].Val = val;
426 * \fn void Proc_Start(void)
427 * \brief Start process scheduler
429 void Proc_Start(void)
437 for( i = 0; i < giNumCPUs; i ++ )
440 if(i) gaCPUs[i].Current = NULL;
443 if( (tid = Proc_Clone(0, 0)) == 0)
445 for(;;) HALT(); // Just yeilds
447 gaCPUs[i].IdleThread = Threads_GetThread(tid);
448 gaCPUs[i].IdleThread->ThreadName = "Idle Thread";
449 Threads_SetPriority( gaCPUs[i].IdleThread, -1 ); // Never called randomly
450 gaCPUs[i].IdleThread->Quantum = 1; // 1 slice quantum
454 if( i != giProc_BootProcessorID ) {
459 // BSP still should run the current task
460 gaCPUs[0].Current = &gThreadZero;
462 // Start interrupts and wait for APs to come up
463 Log("Waiting for APs to come up\n");
464 __asm__ __volatile__ ("sti");
465 while( giNumInitingCPUs ) __asm__ __volatile__ ("hlt");
468 if(Proc_Clone(0, 0) == 0)
470 gpIdleThread = Proc_GetCurThread();
471 gpIdleThread->ThreadName = "Idle Thread";
472 Threads_SetPriority( gpIdleThread, -1 ); // Never called randomly
473 gpIdleThread->Quantum = 1; // 1 slice quantum
474 for(;;) HALT(); // Just yeilds
478 gCurrentThread = &gThreadZero;
480 // Start Interrupts (and hence scheduler)
481 __asm__ __volatile__("sti");
483 MM_FinishVirtualInit();
487 * \fn tThread *Proc_GetCurThread(void)
488 * \brief Gets the current thread
490 tThread *Proc_GetCurThread(void)
493 return gaCPUs[ GetCPUNum() ].Current;
495 return gCurrentThread;
500 * \fn void Proc_ChangeStack(void)
501 * \brief Swaps the current stack for a new one (in the proper stack reigon)
503 void Proc_ChangeStack(void)
507 Uint curBase, newBase;
509 __asm__ __volatile__ ("mov %%esp, %0":"=r"(esp));
510 __asm__ __volatile__ ("mov %%ebp, %0":"=r"(ebp));
515 newBase = MM_NewKStack();
518 Panic("What the?? Unable to allocate space for initial kernel stack");
522 curBase = (Uint)&Kernel_Stack_Top;
524 LOG("curBase = 0x%x, newBase = 0x%x", curBase, newBase);
526 // Get ESP as a used size
528 LOG("memcpy( %p, %p, 0x%x )", (void*)(newBase - esp), (void*)(curBase - esp), esp );
530 memcpy( (void*)(newBase - esp), (void*)(curBase - esp), esp );
531 // Get ESP as an offset in the new stack
534 ebp = newBase - (curBase - ebp);
536 // Repair EBPs & Stack Addresses
537 // Catches arguments also, but may trash stack-address-like values
538 for(tmpEbp = esp; tmpEbp < newBase; tmpEbp += 4)
540 if(oldEsp < *(Uint*)tmpEbp && *(Uint*)tmpEbp < curBase)
541 *(Uint*)tmpEbp += newBase - curBase;
544 Proc_GetCurThread()->KernelStack = newBase;
546 __asm__ __volatile__ ("mov %0, %%esp"::"r"(esp));
547 __asm__ __volatile__ ("mov %0, %%ebp"::"r"(ebp));
551 * \fn int Proc_Clone(Uint *Err, Uint Flags)
552 * \brief Clone the current process
554 int Proc_Clone(Uint *Err, Uint Flags)
557 tThread *cur = Proc_GetCurThread();
560 __asm__ __volatile__ ("mov %%esp, %0": "=r"(esp));
561 __asm__ __volatile__ ("mov %%ebp, %0": "=r"(ebp));
563 newThread = Threads_CloneTCB(Err, Flags);
564 if(!newThread) return -1;
566 // Initialise Memory Space (New Addr space or kernel stack)
567 if(Flags & CLONE_VM) {
568 newThread->MemState.CR3 = MM_Clone();
570 if(newThread->MemState.CR3 == 0) {
571 Threads_Kill(newThread, -2);
574 newThread->KernelStack = cur->KernelStack;
576 Uint tmpEbp, oldEsp = esp;
580 # warning "PAE Unimplemented"
582 newThread->MemState.CR3 = cur->MemState.CR3;
586 newThread->KernelStack = MM_NewKStack();
588 if(newThread->KernelStack == 0) {
589 Threads_Kill(newThread, -2);
593 // Get ESP as a used size
594 esp = cur->KernelStack - esp;
596 memcpy( (void*)(newThread->KernelStack - esp), (void*)(cur->KernelStack - esp), esp );
597 // Get ESP as an offset in the new stack
598 esp = newThread->KernelStack - esp;
600 ebp = newThread->KernelStack - (cur->KernelStack - ebp);
602 // Repair EBPs & Stack Addresses
603 // Catches arguments also, but may trash stack-address-like values
604 for(tmpEbp = esp; tmpEbp < newThread->KernelStack; tmpEbp += 4)
606 if(oldEsp < *(Uint*)tmpEbp && *(Uint*)tmpEbp < cur->KernelStack)
607 *(Uint*)tmpEbp += newThread->KernelStack - cur->KernelStack;
611 // Save core machine state
612 newThread->SavedState.ESP = esp;
613 newThread->SavedState.EBP = ebp;
615 if(eip == SWITCH_MAGIC) {
616 __asm__ __volatile__ ("mov %0, %%db0" : : "r" (newThread) );
620 gpMP_LocalAPIC->EOI.Val = 0;
623 outb(0x20, 0x20); // ACK Timer and return as child
624 __asm__ __volatile__ ("sti"); // Restart interrupts
629 newThread->SavedState.EIP = eip;
631 // Lock list and add to active
632 Threads_AddActive(newThread);
634 return newThread->TID;
638 * \fn int Proc_SpawnWorker(void)
639 * \brief Spawns a new worker thread
641 int Proc_SpawnWorker(void)
646 cur = Proc_GetCurThread();
649 new = malloc( sizeof(tThread) );
651 Warning("Proc_SpawnWorker - Out of heap space!\n");
654 memcpy(new, &gThreadZero, sizeof(tThread));
656 new->TID = giNextTID++;
657 // Create a new worker stack (in PID0's address space)
658 // - The stack is relocated by this function
659 new->KernelStack = MM_NewWorkerStack();
661 // Get ESP and EBP based in the new stack
662 __asm__ __volatile__ ("mov %%esp, %0": "=r"(esp));
663 __asm__ __volatile__ ("mov %%ebp, %0": "=r"(ebp));
664 esp = new->KernelStack - (cur->KernelStack - esp);
665 ebp = new->KernelStack - (cur->KernelStack - ebp);
667 // Save core machine state
668 new->SavedState.ESP = esp;
669 new->SavedState.EBP = ebp;
671 if(eip == SWITCH_MAGIC) {
672 __asm__ __volatile__ ("mov %0, %%db0" : : "r"(new));
676 gpMP_LocalAPIC->EOI.Val = 0;
679 outb(0x20, 0x20); // ACK Timer and return as child
680 __asm__ __volatile__ ("sti"); // Restart interrupts
685 new->SavedState.EIP = eip;
687 Threads_AddActive( new );
693 * \fn Uint Proc_MakeUserStack(void)
694 * \brief Creates a new user stack
696 Uint Proc_MakeUserStack(void)
699 Uint base = USER_STACK_TOP - USER_STACK_SZ;
701 // Check Prospective Space
702 for( i = USER_STACK_SZ >> 12; i--; )
703 if( MM_GetPhysAddr( base + (i<<12) ) != 0 )
706 if(i != -1) return 0;
708 // Allocate Stack - Allocate incrementally to clean up MM_Dump output
709 for( i = 0; i < USER_STACK_SZ/0x1000; i++ )
710 MM_Allocate( base + (i<<12) );
712 return base + USER_STACK_SZ;
716 * \fn void Proc_StartUser(Uint Entrypoint, Uint *Bases, int ArgC, char **ArgV, char **EnvP, int DataSize)
717 * \brief Starts a user task
719 void Proc_StartUser(Uint Entrypoint, Uint *Bases, int ArgC, char **ArgV, char **EnvP, int DataSize)
721 Uint *stack = (void*)Proc_MakeUserStack();
726 //Log("stack = %p", stack);
729 stack -= DataSize/sizeof(*stack);
730 memcpy( stack, ArgV, DataSize );
732 //Log("stack = %p", stack);
736 // Adjust Arguments and environment
737 delta = (Uint)stack - (Uint)ArgV;
738 ArgV = (char**)stack;
739 for( i = 0; ArgV[i]; i++ )
743 // Do we care about EnvP?
746 for( i = 0; EnvP[i]; i++ )
751 // User Mode Segments
752 ss = 0x23; cs = 0x1B;
755 *--stack = (Uint)EnvP;
756 *--stack = (Uint)ArgV;
757 *--stack = (Uint)ArgC;
760 *--stack = 0; // Return Address
762 Proc_StartProcess(ss, (Uint)stack, 0x202, cs, Entrypoint);
765 void Proc_StartProcess(Uint16 SS, Uint Stack, Uint Flags, Uint16 CS, Uint IP)
767 Uint *stack = (void*)Stack;
768 *--stack = SS; //Stack Segment
769 *--stack = Stack; //Stack Pointer
770 *--stack = Flags; //EFLAGS (Resvd (0x2) and IF (0x20))
771 *--stack = CS; //Code Segment
774 *--stack = 0xAAAAAAAA; // eax
775 *--stack = 0xCCCCCCCC; // ecx
776 *--stack = 0xDDDDDDDD; // edx
777 *--stack = 0xBBBBBBBB; // ebx
778 *--stack = 0xD1D1D1D1; // edi
779 *--stack = 0x54545454; // esp - NOT POPED
780 *--stack = 0x51515151; // esi
781 *--stack = 0xB4B4B4B4; // ebp
788 __asm__ __volatile__ (
789 "mov %%eax,%%esp;\n\t" // Set stack pointer
795 "iret;\n\t" : : "a" (stack));
800 * \fn int Proc_Demote(Uint *Err, int Dest, tRegs *Regs)
801 * \brief Demotes a process to a lower permission level
802 * \param Err Pointer to user's errno
803 * \param Dest New Permission Level
804 * \param Regs Pointer to user's register structure
806 int Proc_Demote(Uint *Err, int Dest, tRegs *Regs)
808 int cpl = Regs->cs & 3;
810 if(Dest > 3 || Dest < 0) {
821 // Change the Segment Registers
822 Regs->cs = (((Dest+1)<<4) | Dest) - 8;
823 Regs->ss = ((Dest+1)<<4) | Dest;
824 // Check if the GP Segs are GDT, then change them
825 if(!(Regs->ds & 4)) Regs->ds = ((Dest+1)<<4) | Dest;
826 if(!(Regs->es & 4)) Regs->es = ((Dest+1)<<4) | Dest;
827 if(!(Regs->fs & 4)) Regs->fs = ((Dest+1)<<4) | Dest;
828 if(!(Regs->gs & 4)) Regs->gs = ((Dest+1)<<4) | Dest;
834 * \brief Calls a signal handler in user mode
835 * \note Used for signals
837 void Proc_CallFaultHandler(tThread *Thread)
839 // Rewinds the stack and calls the user function
841 Proc_ReturnToUser( Thread->FaultHandler, Thread->CurFaultNum, Thread->KernelStack );
846 * \fn void Proc_Scheduler(int CPU)
847 * \brief Swap current thread and clears dead threads
849 void Proc_Scheduler(int CPU)
854 // If the spinlock is set, let it complete
855 if(IS_LOCKED(&glThreadListLock)) return;
857 // Get current thread
859 thread = gaCPUs[CPU].Current;
861 thread = gCurrentThread;
866 // Reduce remaining quantum and continue timeslice if non-zero
867 if( thread->Remaining-- )
869 // Reset quantum for next call
870 thread->Remaining = thread->Quantum;
873 __asm__ __volatile__ ( "mov %%esp, %0" : "=r" (esp) );
874 __asm__ __volatile__ ( "mov %%ebp, %0" : "=r" (ebp) );
876 if(eip == SWITCH_MAGIC) return; // Check if a switch happened
878 // Save machine state
879 thread->SavedState.ESP = esp;
880 thread->SavedState.EBP = ebp;
881 thread->SavedState.EIP = eip;
884 // Get next thread to run
885 thread = Threads_GetNextToRun(CPU, thread);
887 // No avaliable tasks, just go into low power mode (idle thread)
890 thread = gaCPUs[CPU].IdleThread;
891 Log("CPU %i Running Idle Thread", CPU);
893 thread = gpIdleThread;
897 // Set current thread
899 gaCPUs[CPU].Current = thread;
901 gCurrentThread = thread;
904 #if DEBUG_TRACE_SWITCH
905 Log("Switching to task %i, CR3 = 0x%x, EIP = %p",
907 thread->MemState.CR3,
908 thread->SavedState.EIP
912 #if USE_MP // MP Debug
913 Log("CPU = %i, Thread %p", CPU, thread);
916 // Update Kernel Stack pointer
917 gTSSs[CPU].ESP0 = thread->KernelStack-4;
921 # error "Todo: Implement PAE Address space switching"
923 __asm__ __volatile__ ("mov %0, %%cr3" : : "a" (thread->MemState.CR3));
927 if(thread->SavedState.ESP > 0xC0000000
928 && thread->SavedState.ESP < thread->KernelStack-0x2000) {
929 Log_Warning("Proc", "Possible bad ESP %p (PID %i)", thread->SavedState.ESP);
934 __asm__ __volatile__ (
935 "mov %1, %%esp\n\t" // Restore ESP
936 "mov %2, %%ebp\n\t" // and EBP
937 "jmp *%3" : : // And return to where we saved state (Proc_Clone or Proc_Scheduler)
938 "a"(SWITCH_MAGIC), "b"(thread->SavedState.ESP),
939 "d"(thread->SavedState.EBP), "c"(thread->SavedState.EIP)
941 for(;;); // Shouldn't reach here
945 EXPORT(Proc_SpawnWorker);