src/stacks.c - chromiumos/third_party/seabios - Git at Google

 // Code for manipulating stack locations.
 //
 // Copyright (C) 2009-2010  Kevin O'Connor <kevin@koconnor.net>
 //
 // This file may be distributed under the terms of the GNU LGPLv3 license.

 #include "biosvar.h" // get_ebda_seg
 #include "util.h" // dprintf
 #include "bregs.h" // CR0_PE

 // Thread info - stored at bottom of each thread stack - don't change
 // without also updating the inline assembler below.
 struct thread_info {
     struct thread_info *next;
     void *stackpos;
     struct thread_info **pprev;
 };
 struct thread_info VAR32FLATVISIBLE MainThread = {
     &MainThread, NULL, &MainThread.next
 };


 /****************************************************************
  * Low level helpers
  ****************************************************************/

 static inline u32 getcr0(void) {
     u32 cr0;
     asm("movl %%cr0, %0" : "=r"(cr0));
     return cr0;
 }
 static inline void sgdt(struct descloc_s *desc) {
     asm("sgdtl %0" : "=m"(*desc));
 }
 static inline void lgdt(struct descloc_s *desc) {
     asm("lgdtl %0" : : "m"(*desc) : "memory");
 }

 // Call a 32bit SeaBIOS function from a 16bit SeaBIOS function.
 u32
 call32(void *func, u32 eax, u32 errret)
 {
     ASSERT16();
     u32 cr0 = getcr0();
     if (cr0 & CR0_PE)
         // Called in 16bit protected mode?!
         return errret;

     // Backup cmos index register and disable nmi
     u8 cmosindex = inb(PORT_CMOS_INDEX);
     outb(cmosindex | NMI_DISABLE_BIT, PORT_CMOS_INDEX);
     inb(PORT_CMOS_DATA);

     // Backup fs/gs and gdt
     u16 fs = GET_SEG(FS), gs = GET_SEG(GS);
     struct descloc_s gdt;
     sgdt(&gdt);

     u32 bkup_ss, bkup_esp;
     asm volatile(
         // Backup ss/esp / set esp to flat stack location
         "  movl %%ss, %0\n"
         "  movl %%esp, %1\n"
         "  shll $4, %0\n"
         "  addl %0, %%esp\n"
         "  shrl $4, %0\n"

         // Transition to 32bit mode, call func, return to 16bit
         "  movl $(" __stringify(BUILD_BIOS_ADDR) " + 1f), %%edx\n"
         "  jmp transition32\n"
         "  .code32\n"
         "1:calll *%3\n"
         "  movl $2f, %%edx\n"
         "  jmp transition16big\n"

         // Restore ds/ss/esp
         "  .code16gcc\n"
         "2:movl %0, %%ds\n"
         "  movl %0, %%ss\n"
         "  movl %1, %%esp\n"
         : "=&r" (bkup_ss), "=&r" (bkup_esp), "+a" (eax)
         : "r" (func)
         : "ecx", "edx", "cc", "memory");

     // Restore gdt and fs/gs
     lgdt(&gdt);
     SET_SEG(FS, fs);
     SET_SEG(GS, gs);

     // Restore cmos index register
     outb(cmosindex, PORT_CMOS_INDEX);
     inb(PORT_CMOS_DATA);
     return eax;
 }

 // 16bit trampoline for enabling irqs from 32bit mode.
 ASM16(
     "  .global trampoline_checkirqs\n"
     "trampoline_checkirqs:\n"
     "  rep ; nop\n"
     "  lretw"
     );

 static void
 check_irqs(void)
 {
     if (MODESEGMENT) {
         asm volatile(
             "sti\n"
             "nop\n"
             "rep ; nop\n"
             "cli\n"
             "cld\n"
             : : :"memory");
         return;
     }
     extern void trampoline_checkirqs();
     struct bregs br;
     br.flags = F_IF;
     br.code.seg = SEG_BIOS;
     br.code.offset = (u32)&trampoline_checkirqs;
     call16big(&br);
 }

 // 16bit trampoline for waiting for an irq from 32bit mode.
 ASM16(
     "  .global trampoline_waitirq\n"
     "trampoline_waitirq:\n"
     "  sti\n"
     "  hlt\n"
     "  lretw"
     );

 // Wait for next irq to occur.
 void
 wait_irq(void)
 {
     if (MODESEGMENT) {
         asm volatile("sti ; hlt ; cli ; cld": : :"memory");
         return;
     }
     if (CONFIG_THREADS && MainThread.next != &MainThread) {
         // Threads still active - do a yield instead.
         yield();
         return;
     }
     extern void trampoline_waitirq();
     struct bregs br;
     br.flags = 0;
     br.code.seg = SEG_BIOS;
     br.code.offset = (u32)&trampoline_waitirq;
     call16big(&br);
 }


 /****************************************************************
  * Stack in EBDA
  ****************************************************************/

 // Switch to the extra stack in ebda and call a function.
 inline u32
 stack_hop(u32 eax, u32 edx, void *func)
 {
     ASSERT16();
     u16 ebda_seg = get_ebda_seg(), bkup_ss;
     u32 bkup_esp;
     asm volatile(
         // Backup current %ss/%esp values.
         "movw %%ss, %w3\n"
         "movl %%esp, %4\n"
         // Copy ebda seg to %ds/%ss and set %esp
         "movw %w6, %%ds\n"
         "movw %w6, %%ss\n"
         "movl %5, %%esp\n"
         // Call func
         "calll *%2\n"
         // Restore segments and stack
         "movw %w3, %%ds\n"
         "movw %w3, %%ss\n"
         "movl %4, %%esp"
         : "+a" (eax), "+d" (edx), "+c" (func), "=&r" (bkup_ss), "=&r" (bkup_esp)
         : "i" (EBDA_OFFSET_TOP_STACK), "r" (ebda_seg)
         : "cc", "memory");
     return eax;
 }


 /****************************************************************
  * Threads
  ****************************************************************/

 #define THREADSTACKSIZE 4096
 int VAR16VISIBLE CanPreempt;

 // Return the 'struct thread_info' for the currently running thread.
 struct thread_info *
 getCurThread(void)
 {
     u32 esp = getesp();
     if (esp <= BUILD_STACK_ADDR)
         return &MainThread;
     return (void*)ALIGN_DOWN(esp, THREADSTACKSIZE);
 }

 // Switch to next thread stack.
 static void
 switch_next(struct thread_info *cur)
 {
     struct thread_info *next = cur->next;
     if (cur == next)
         // Nothing to do.
         return;
     asm volatile(
         "  pushl $1f\n"                 // store return pc
         "  pushl %%ebp\n"               // backup %ebp
         "  movl %%esp, 4(%%eax)\n"      // cur->stackpos = %esp
         "  movl 4(%%ecx), %%esp\n"      // %esp = next->stackpos
         "  popl %%ebp\n"                // restore %ebp
         "  retl\n"                      // restore pc
         "1:\n"
         : "+a"(cur), "+c"(next)
         :
         : "ebx", "edx", "esi", "edi", "cc", "memory");
 }

 // Briefly permit irqs to occur.
 void
 yield(void)
 {
     if (MODESEGMENT || !CONFIG_THREADS) {
         // Just directly check irqs.
         check_irqs();
         return;
     }
     struct thread_info *cur = getCurThread();
     if (cur == &MainThread)
         // Permit irqs to fire
         check_irqs();

     // Switch to the next thread
     switch_next(cur);
 }

 // Last thing called from a thread (called on "next" stack).
 static void
 __end_thread(struct thread_info *old)
 {
     old->next->pprev = old->pprev;
     *old->pprev = old->next;
     free(old);
     dprintf(DEBUG_thread, "\\%08x/ End thread\n", (u32)old);
     if (MainThread.next == &MainThread)
         dprintf(1, "All threads complete.\n");
 }

 // Create a new thread and start executing 'func' in it.
 void
 run_thread(void (*func)(void*), void *data)
 {
     ASSERT32FLAT();
     if (! CONFIG_THREADS)
         goto fail;
     struct thread_info *thread;
     thread = memalign_tmphigh(THREADSTACKSIZE, THREADSTACKSIZE);
     if (!thread)
         goto fail;

     thread->stackpos = (void*)thread + THREADSTACKSIZE;
     struct thread_info *cur = getCurThread();
     thread->next = cur;
     thread->pprev = cur->pprev;
     cur->pprev = &thread->next;
     *thread->pprev = thread;

     dprintf(DEBUG_thread, "/%08x\\ Start thread\n", (u32)thread);
     asm volatile(
         // Start thread
         "  pushl $1f\n"                 // store return pc
         "  pushl %%ebp\n"               // backup %ebp
         "  movl %%esp, 4(%%edx)\n"      // cur->stackpos = %esp
         "  movl 4(%%ebx), %%esp\n"      // %esp = thread->stackpos
         "  calll *%%ecx\n"              // Call func

         // End thread
         "  movl (%%ebx), %%ecx\n"       // %ecx = thread->next
         "  movl 4(%%ecx), %%esp\n"      // %esp = next->stackpos
         "  movl %%ebx, %%eax\n"
         "  calll %4\n"                  // call __end_thread(thread)
         "  popl %%ebp\n"                // restore %ebp
         "  retl\n"                      // restore pc
         "1:\n"
         : "+a"(data), "+c"(func), "+b"(thread), "+d"(cur)
         : "m"(*(u8*)__end_thread)
         : "esi", "edi", "cc", "memory");
     return;

 fail:
     func(data);
 }

 // Wait for all threads (other than the main thread) to complete.
 void
 wait_threads(void)
 {
     ASSERT32FLAT();
     if (! CONFIG_THREADS)
         return;
     while (MainThread.next != &MainThread)
         yield();
 }

 void
 mutex_lock(struct mutex_s *mutex)
 {
     ASSERT32FLAT();
     if (! CONFIG_THREADS)
         return;
     while (mutex->isLocked)
         yield();
     mutex->isLocked = 1;
 }

 void
 mutex_unlock(struct mutex_s *mutex)
 {
     ASSERT32FLAT();
     if (! CONFIG_THREADS)
         return;
     mutex->isLocked = 0;
 }


 /****************************************************************
  * Thread preemption
  ****************************************************************/

 static u32 PreemptCount;

 // Turn on RTC irqs and arrange for them to check the 32bit threads.
 void
 start_preempt(void)
 {
     if (! CONFIG_THREADS || ! CONFIG_THREAD_OPTIONROMS)
         return;
     CanPreempt = 1;
     PreemptCount = 0;
     useRTC();
 }

 // Turn off RTC irqs / stop checking for thread execution.
 void
 finish_preempt(void)
 {
     if (! CONFIG_THREADS || ! CONFIG_THREAD_OPTIONROMS) {
         yield();
         return;
     }
     CanPreempt = 0;
     releaseRTC();
     dprintf(9, "Done preempt - %d checks\n", PreemptCount);
     yield();
 }

 // Check if preemption is on, and wait for it to complete if so.
 int
 wait_preempt(void)
 {
     if (MODESEGMENT || !CONFIG_THREADS || !CONFIG_THREAD_OPTIONROMS
         || !CanPreempt)
         return 0;
     while (CanPreempt)
         yield();
     return 1;
 }

 // Try to execute 32bit threads.
 void VISIBLE32INIT
 yield_preempt(void)
 {
     PreemptCount++;
     switch_next(&MainThread);
 }

 // 16bit code that checks if threads are pending and executes them if so.
 void
 check_preempt(void)
 {
     if (! CONFIG_THREADS || ! CONFIG_THREAD_OPTIONROMS
         || !GET_GLOBAL(CanPreempt)
         || GET_FLATPTR(MainThread.next) == &MainThread)
         return;

     extern void _cfunc32flat_yield_preempt(void);
     call32(_cfunc32flat_yield_preempt, 0, 0);
 }
	// Code for manipulating stack locations.
	//
	// Copyright (C) 2009-2010 Kevin O'Connor <kevin@koconnor.net>
	//
	// This file may be distributed under the terms of the GNU LGPLv3 license.

	#include "biosvar.h" // get_ebda_seg
	#include "util.h" // dprintf
	#include "bregs.h" // CR0_PE

	// Thread info - stored at bottom of each thread stack - don't change
	// without also updating the inline assembler below.
	struct thread_info {
	struct thread_info *next;
	void *stackpos;
	struct thread_info **pprev;
	};
	struct thread_info VAR32FLATVISIBLE MainThread = {
	&MainThread, NULL, &MainThread.next
	};


	/****************************************************************
	* Low level helpers
	****************************************************************/

	static inline u32 getcr0(void) {
	u32 cr0;
	asm("movl %%cr0, %0" : "=r"(cr0));
	return cr0;
	}
	static inline void sgdt(struct descloc_s *desc) {
	asm("sgdtl %0" : "=m"(*desc));
	}
	static inline void lgdt(struct descloc_s *desc) {
	asm("lgdtl %0" : : "m"(*desc) : "memory");
	}

	// Call a 32bit SeaBIOS function from a 16bit SeaBIOS function.
	u32
	call32(void *func, u32 eax, u32 errret)
	{
	ASSERT16();
	u32 cr0 = getcr0();
	if (cr0 & CR0_PE)
	// Called in 16bit protected mode?!
	return errret;

	// Backup cmos index register and disable nmi
	u8 cmosindex = inb(PORT_CMOS_INDEX);
	outb(cmosindex \| NMI_DISABLE_BIT, PORT_CMOS_INDEX);
	inb(PORT_CMOS_DATA);

	// Backup fs/gs and gdt
	u16 fs = GET_SEG(FS), gs = GET_SEG(GS);
	struct descloc_s gdt;
	sgdt(&gdt);

	u32 bkup_ss, bkup_esp;
	asm volatile(
	// Backup ss/esp / set esp to flat stack location
	" movl %%ss, %0\n"
	" movl %%esp, %1\n"
	" shll $4, %0\n"
	" addl %0, %%esp\n"
	" shrl $4, %0\n"

	// Transition to 32bit mode, call func, return to 16bit
	" movl $(" __stringify(BUILD_BIOS_ADDR) " + 1f), %%edx\n"
	" jmp transition32\n"
	" .code32\n"
	"1:calll *%3\n"
	" movl $2f, %%edx\n"
	" jmp transition16big\n"

	// Restore ds/ss/esp
	" .code16gcc\n"
	"2:movl %0, %%ds\n"
	" movl %0, %%ss\n"
	" movl %1, %%esp\n"
	: "=&r" (bkup_ss), "=&r" (bkup_esp), "+a" (eax)
	: "r" (func)
	: "ecx", "edx", "cc", "memory");

	// Restore gdt and fs/gs
	lgdt(&gdt);
	SET_SEG(FS, fs);
	SET_SEG(GS, gs);

	// Restore cmos index register
	outb(cmosindex, PORT_CMOS_INDEX);
	inb(PORT_CMOS_DATA);
	return eax;
	}

	// 16bit trampoline for enabling irqs from 32bit mode.
	ASM16(
	" .global trampoline_checkirqs\n"
	"trampoline_checkirqs:\n"
	" rep ; nop\n"
	" lretw"
	);

	static void
	check_irqs(void)
	{
	if (MODESEGMENT) {
	asm volatile(
	"sti\n"
	"nop\n"
	"rep ; nop\n"
	"cli\n"
	"cld\n"
	: : :"memory");
	return;
	}
	extern void trampoline_checkirqs();
	struct bregs br;
	br.flags = F_IF;
	br.code.seg = SEG_BIOS;
	br.code.offset = (u32)&trampoline_checkirqs;
	call16big(&br);
	}

	// 16bit trampoline for waiting for an irq from 32bit mode.
	ASM16(
	" .global trampoline_waitirq\n"
	"trampoline_waitirq:\n"
	" sti\n"
	" hlt\n"
	" lretw"
	);

	// Wait for next irq to occur.
	void
	wait_irq(void)
	{
	if (MODESEGMENT) {
	asm volatile("sti ; hlt ; cli ; cld": : :"memory");
	return;
	}
	if (CONFIG_THREADS && MainThread.next != &MainThread) {
	// Threads still active - do a yield instead.
	yield();
	return;
	}
	extern void trampoline_waitirq();
	struct bregs br;
	br.flags = 0;
	br.code.seg = SEG_BIOS;
	br.code.offset = (u32)&trampoline_waitirq;
	call16big(&br);
	}


	/****************************************************************
	* Stack in EBDA
	****************************************************************/

	// Switch to the extra stack in ebda and call a function.
	inline u32
	stack_hop(u32 eax, u32 edx, void *func)
	{
	ASSERT16();
	u16 ebda_seg = get_ebda_seg(), bkup_ss;
	u32 bkup_esp;
	asm volatile(
	// Backup current %ss/%esp values.
	"movw %%ss, %w3\n"
	"movl %%esp, %4\n"
	// Copy ebda seg to %ds/%ss and set %esp
	"movw %w6, %%ds\n"
	"movw %w6, %%ss\n"
	"movl %5, %%esp\n"
	// Call func
	"calll *%2\n"
	// Restore segments and stack
	"movw %w3, %%ds\n"
	"movw %w3, %%ss\n"
	"movl %4, %%esp"
	: "+a" (eax), "+d" (edx), "+c" (func), "=&r" (bkup_ss), "=&r" (bkup_esp)
	: "i" (EBDA_OFFSET_TOP_STACK), "r" (ebda_seg)
	: "cc", "memory");
	return eax;
	}


	/****************************************************************
	* Threads
	****************************************************************/

	#define THREADSTACKSIZE 4096
	int VAR16VISIBLE CanPreempt;

	// Return the 'struct thread_info' for the currently running thread.
	struct thread_info *
	getCurThread(void)
	{
	u32 esp = getesp();
	if (esp <= BUILD_STACK_ADDR)
	return &MainThread;
	return (void*)ALIGN_DOWN(esp, THREADSTACKSIZE);
	}

	// Switch to next thread stack.
	static void
	switch_next(struct thread_info *cur)
	{
	struct thread_info *next = cur->next;
	if (cur == next)
	// Nothing to do.
	return;
	asm volatile(
	" pushl $1f\n" // store return pc
	" pushl %%ebp\n" // backup %ebp
	" movl %%esp, 4(%%eax)\n" // cur->stackpos = %esp
	" movl 4(%%ecx), %%esp\n" // %esp = next->stackpos
	" popl %%ebp\n" // restore %ebp
	" retl\n" // restore pc
	"1:\n"
	: "+a"(cur), "+c"(next)
	:
	: "ebx", "edx", "esi", "edi", "cc", "memory");
	}

	// Briefly permit irqs to occur.
	void
	yield(void)
	{
	if (MODESEGMENT \|\| !CONFIG_THREADS) {
	// Just directly check irqs.
	check_irqs();
	return;
	}
	struct thread_info *cur = getCurThread();
	if (cur == &MainThread)
	// Permit irqs to fire
	check_irqs();

	// Switch to the next thread
	switch_next(cur);
	}

	// Last thing called from a thread (called on "next" stack).
	static void
	__end_thread(struct thread_info *old)
	{
	old->next->pprev = old->pprev;
	*old->pprev = old->next;
	free(old);
	dprintf(DEBUG_thread, "\\%08x/ End thread\n", (u32)old);
	if (MainThread.next == &MainThread)
	dprintf(1, "All threads complete.\n");
	}

	// Create a new thread and start executing 'func' in it.
	void
	run_thread(void (func)(void), void *data)
	{
	ASSERT32FLAT();
	if (! CONFIG_THREADS)
	goto fail;
	struct thread_info *thread;
	thread = memalign_tmphigh(THREADSTACKSIZE, THREADSTACKSIZE);
	if (!thread)
	goto fail;

	thread->stackpos = (void*)thread + THREADSTACKSIZE;
	struct thread_info *cur = getCurThread();
	thread->next = cur;
	thread->pprev = cur->pprev;
	cur->pprev = &thread->next;
	*thread->pprev = thread;

	dprintf(DEBUG_thread, "/%08x\\ Start thread\n", (u32)thread);
	asm volatile(
	// Start thread
	" pushl $1f\n" // store return pc
	" pushl %%ebp\n" // backup %ebp
	" movl %%esp, 4(%%edx)\n" // cur->stackpos = %esp
	" movl 4(%%ebx), %%esp\n" // %esp = thread->stackpos
	" calll *%%ecx\n" // Call func

	// End thread
	" movl (%%ebx), %%ecx\n" // %ecx = thread->next
	" movl 4(%%ecx), %%esp\n" // %esp = next->stackpos
	" movl %%ebx, %%eax\n"
	" calll %4\n" // call __end_thread(thread)
	" popl %%ebp\n" // restore %ebp
	" retl\n" // restore pc
	"1:\n"
	: "+a"(data), "+c"(func), "+b"(thread), "+d"(cur)
	: "m"((u8)__end_thread)
	: "esi", "edi", "cc", "memory");
	return;

	fail:
	func(data);
	}

	// Wait for all threads (other than the main thread) to complete.
	void
	wait_threads(void)
	{
	ASSERT32FLAT();
	if (! CONFIG_THREADS)
	return;
	while (MainThread.next != &MainThread)
	yield();
	}

	void
	mutex_lock(struct mutex_s *mutex)
	{
	ASSERT32FLAT();
	if (! CONFIG_THREADS)
	return;
	while (mutex->isLocked)
	yield();
	mutex->isLocked = 1;
	}

	void
	mutex_unlock(struct mutex_s *mutex)
	{
	ASSERT32FLAT();
	if (! CONFIG_THREADS)
	return;
	mutex->isLocked = 0;
	}


	/****************************************************************
	* Thread preemption
	****************************************************************/

	static u32 PreemptCount;

	// Turn on RTC irqs and arrange for them to check the 32bit threads.
	void
	start_preempt(void)
	{
	if (! CONFIG_THREADS \|\| ! CONFIG_THREAD_OPTIONROMS)
	return;
	CanPreempt = 1;
	PreemptCount = 0;
	useRTC();
	}

	// Turn off RTC irqs / stop checking for thread execution.
	void
	finish_preempt(void)
	{
	if (! CONFIG_THREADS \|\| ! CONFIG_THREAD_OPTIONROMS) {
	yield();
	return;
	}
	CanPreempt = 0;
	releaseRTC();
	dprintf(9, "Done preempt - %d checks\n", PreemptCount);
	yield();
	}

	// Check if preemption is on, and wait for it to complete if so.
	int
	wait_preempt(void)
	{
	if (MODESEGMENT \|\| !CONFIG_THREADS \|\| !CONFIG_THREAD_OPTIONROMS
	\|\| !CanPreempt)
	return 0;
	while (CanPreempt)
	yield();
	return 1;
	}

	// Try to execute 32bit threads.
	void VISIBLE32INIT
	yield_preempt(void)
	{
	PreemptCount++;
	switch_next(&MainThread);
	}

	// 16bit code that checks if threads are pending and executes them if so.
	void
	check_preempt(void)
	{
	if (! CONFIG_THREADS \|\| ! CONFIG_THREAD_OPTIONROMS
	\|\| !GET_GLOBAL(CanPreempt)
	\|\| GET_FLATPTR(MainThread.next) == &MainThread)
	return;

	extern void _cfunc32flat_yield_preempt(void);
	call32(_cfunc32flat_yield_preempt, 0, 0);
	}