minix3/kernel/smp.c


								#include <assert.h>


								#include "smp.h"

								#include "interrupt.h"

								#include "clock.h"


								unsigned ncpus;

								unsigned ht_per_core;

								unsigned bsp_cpu_id;


								struct cpu cpus[CONFIG_MAX_CPUS];


								/* info passed to another cpu along with a sched ipi */

								struct sched_ipi_data {

									volatile u32_t	flags;

									volatile u32_t	data;

								};


								static struct sched_ipi_data  sched_ipi_data[CONFIG_MAX_CPUS];


								#define SCHED_IPI_STOP_PROC	1

								#define SCHED_IPI_VM_INHIBIT	2

								#define SCHED_IPI_SAVE_CTX	4


								static volatile unsigned ap_cpus_booted;


								SPINLOCK_DEFINE(big_kernel_lock)

								SPINLOCK_DEFINE(boot_lock)


								void wait_for_APs_to_finish_booting(void)

								{

									unsigned n = 0;

									int i;


									/* check how many cpus are actually alive */

									for (i = 0 ; i < ncpus ; i++) {

										if (cpu_test_flag(i, CPU_IS_READY))

											n++;

									}

									if (n != ncpus)

										printf("WARNING only %d out of %d cpus booted\n", n, ncpus);


									/* we must let the other CPUs to run in kernel mode first */

									BKL_UNLOCK();

									while (ap_cpus_booted != (n - 1))

										arch_pause();

									/* now we have to take the lock again as we continue execution */

									BKL_LOCK();

								}


								void ap_boot_finished(unsigned cpu)

								{

									ap_cpus_booted++;

								}


								void smp_ipi_halt_handler(void)

								{

									ipi_ack();

									stop_local_timer();

									arch_smp_halt_cpu();

								}


								void smp_schedule(unsigned cpu)

								{

									arch_send_smp_schedule_ipi(cpu);

								}


								void smp_sched_handler(void);


								/*

								 * tell another cpu about a task to do and return only after the cpu acks that

								 * the task is finished. Also wait before it finishes task sent by another cpu

								 * to the same one.

								 */

								static void smp_schedule_sync(struct proc * p, unsigned task)

								{

									unsigned cpu = p->p_cpu;

									unsigned mycpu = cpuid;


									assert(cpu != mycpu);

									/*

									 * if some other cpu made a request to the same cpu, wait until it is

									 * done before proceeding

									 */

									if (sched_ipi_data[cpu].flags != 0) {

										BKL_UNLOCK();

										while (sched_ipi_data[cpu].flags != 0) {

											if (sched_ipi_data[mycpu].flags) {

												BKL_LOCK();

												smp_sched_handler();

												BKL_UNLOCK();

											}

										}

										BKL_LOCK();

									}


									sched_ipi_data[cpu].data = (u32_t) p;

									sched_ipi_data[cpu].flags |= task;

									__insn_barrier();

									arch_send_smp_schedule_ipi(cpu);


									/* wait until the destination cpu finishes its job */

									BKL_UNLOCK();

									while (sched_ipi_data[cpu].flags != 0) {

										if (sched_ipi_data[mycpu].flags) {

											BKL_LOCK();

											smp_sched_handler();

											BKL_UNLOCK();

										}

									}

									BKL_LOCK();

								}


								void smp_schedule_stop_proc(struct proc * p)

								{

									if (proc_is_runnable(p))

										smp_schedule_sync(p, SCHED_IPI_STOP_PROC);

									else

										RTS_SET(p, RTS_PROC_STOP);

									assert(RTS_ISSET(p, RTS_PROC_STOP));

								}


								void smp_schedule_vminhibit(struct proc * p)

								{

									if (proc_is_runnable(p))

										smp_schedule_sync(p, SCHED_IPI_VM_INHIBIT);

									else

										RTS_SET(p, RTS_VMINHIBIT);

									assert(RTS_ISSET(p, RTS_VMINHIBIT));

								}


								void smp_schedule_stop_proc_save_ctx(struct proc * p)

								{

									/*

									 * stop the processes and force the complete context of the process to

									 * be saved (i.e. including FPU state and such)

									 */

									smp_schedule_sync(p, SCHED_IPI_STOP_PROC | SCHED_IPI_SAVE_CTX);

									assert(RTS_ISSET(p, RTS_PROC_STOP));

								}


								void smp_schedule_migrate_proc(struct proc * p, unsigned dest_cpu)

								{

									/*

									 * stop the processes and force the complete context of the process to

									 * be saved (i.e. including FPU state and such)

									 */

									smp_schedule_sync(p, SCHED_IPI_STOP_PROC | SCHED_IPI_SAVE_CTX);

									assert(RTS_ISSET(p, RTS_PROC_STOP));


									/* assign the new cpu and let the process run again */

									p->p_cpu = dest_cpu;

									RTS_UNSET(p, RTS_PROC_STOP);

								}


								void smp_sched_handler(void)

								{

									unsigned flgs;

									unsigned cpu = cpuid;


									flgs = sched_ipi_data[cpu].flags;


									if (flgs) {

										struct proc * p;

										p = (struct proc *)sched_ipi_data[cpu].data;


										if (flgs & SCHED_IPI_STOP_PROC) {

											RTS_SET(p, RTS_PROC_STOP);

										}

										if (flgs & SCHED_IPI_SAVE_CTX) {

											/* all context has been saved already, FPU remains */

											if (proc_used_fpu(p) &&

													get_cpulocal_var(fpu_owner) == p) {

												disable_fpu_exception();

												save_local_fpu(p, FALSE /*retain*/);

												/* we're preparing to migrate somewhere else */

												release_fpu(p);

											}

										}

										if (flgs & SCHED_IPI_VM_INHIBIT) {

											RTS_SET(p, RTS_VMINHIBIT);

										}

									}


									__insn_barrier();

									sched_ipi_data[cpu].flags = 0;

								}


								/*

								 * This function gets always called only after smp_sched_handler() has been

								 * already called. It only serves the purpose of acknowledging the IPI and

								 * preempting the current process if the CPU was not idle.

								 */

								void smp_ipi_sched_handler(void)

								{

									struct proc * curr;


									ipi_ack();


									curr = get_cpulocal_var(proc_ptr);

									if (curr->p_endpoint != IDLE) {

										RTS_SET(curr, RTS_PREEMPTED);

									}

								}