c8d0edc06a
- Remove sanity checks for initialized mutexes and condition variables. This significantly boosts performance. The checks can be turned back on by compiling libmthread with MTHREAD_STRICT. According to POSIX operations on uninitialized variables are a MAY fail if, therefore allowing this optimization. - Test59 has to be accommodated to the lack of sanity checks on uninitialized variables in the library. It specifically tests for them and will run into segfaults when the checks are absent in the library. - Fix a few bugs related to the scheduler - Do some general code cleanups
203 lines
6.5 KiB
C
203 lines
6.5 KiB
C
#include <minix/mthread.h>
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#include "global.h"
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#include "proto.h"
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#define MAIN_CTX &(mainthread.m_context)
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#define MAIN_STATE mainthread.m_state
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#define OLD_CTX &(threads[old_thread]->m_context)
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#define CURRENT_CTX &(threads[current_thread]->m_context)
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#define CURRENT_STATE threads[current_thread]->m_state
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PRIVATE int yield_all;
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/*===========================================================================*
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* mthread_getcontext *
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*===========================================================================*/
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PUBLIC int mthread_getcontext(ctx)
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ucontext_t *ctx;
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{
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/* Retrieve this process' current state.*/
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/* We're not interested in FPU state nor signals, so ignore them.
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* Coincidentally, this significantly speeds up performance.
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*/
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ctx->uc_flags |= (UCF_IGNFPU | UCF_IGNSIGM);
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return getcontext(ctx);
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}
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/*===========================================================================*
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* mthread_schedule *
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*===========================================================================*/
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PUBLIC void mthread_schedule(void)
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{
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/* Pick a new thread to run and run it. In practice, this involves taking the
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* first thread off the (FIFO) run queue and resuming that thread.
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*/
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mthread_thread_t old_thread;
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mthread_tcb_t *new_tcb, *old_tcb;
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ucontext_t *new_ctx, *old_ctx;
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mthread_init(); /* Make sure libmthread is initialized */
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old_thread = current_thread;
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if (mthread_queue_isempty(&run_queue)) {
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/* No runnable threads. Let main thread run. */
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/* We keep track whether we're running the program's 'main' thread or
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* a spawned thread. In case we're already running the main thread and
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* there are no runnable threads, we can't jump back to its context.
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* Instead, we simply return.
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*/
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if (running_main_thread) return;
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/* We're running the last runnable spawned thread. Return to main
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* thread as there is no work left.
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*/
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current_thread = MAIN_THREAD;
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} else {
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current_thread = mthread_queue_remove(&run_queue);
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}
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/* Find thread entries in tcb... */
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new_tcb = mthread_find_tcb(current_thread);
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old_tcb = mthread_find_tcb(old_thread);
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/* ...and subsequently their contexts */
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new_ctx = &(new_tcb->m_context);
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old_ctx = &(old_tcb->m_context);
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/* Are we running the 'main' thread after swap? */
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running_main_thread = (current_thread == MAIN_THREAD);
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if (swapcontext(old_ctx, new_ctx) == -1)
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mthread_panic("Could not swap context");
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}
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/*===========================================================================*
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* mthread_init_scheduler *
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*===========================================================================*/
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PUBLIC void mthread_init_scheduler(void)
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{
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/* Initialize the scheduler */
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mthread_queue_init(&run_queue);
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yield_all = 0;
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}
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/*===========================================================================*
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* mthread_suspend *
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*===========================================================================*/
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PUBLIC void mthread_suspend(state)
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mthread_state_t state;
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{
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/* Stop the current thread from running. There can be multiple reasons for
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* this; the process tries to lock a locked mutex (i.e., has to wait for it to
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* become unlocked), the process has to wait for a condition, the thread
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* volunteered to let another thread to run (i.e., it called yield and remains
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* runnable itself), or the thread is dead.
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*/
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int continue_thread = 0;
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mthread_tcb_t *tcb;
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ucontext_t *ctx;
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if (state == MS_DEAD) mthread_panic("Shouldn't suspend with MS_DEAD state");
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tcb = mthread_find_tcb(current_thread);
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tcb->m_state = state;
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ctx = &(tcb->m_context);
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/* Save current thread's context */
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if (mthread_getcontext(ctx) != 0)
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mthread_panic("Couldn't save current thread's context");
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/* We return execution here with setcontext/swapcontext, but also when we
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* simply return from the getcontext call. If continue_thread is non-zero, we
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* are continuing the execution of this thread after a call from setcontext
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* or swapcontext.
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*/
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if(!continue_thread) {
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continue_thread = 1;
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mthread_schedule(); /* Let other thread run. */
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}
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}
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/*===========================================================================*
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* mthread_unsuspend *
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*===========================================================================*/
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PUBLIC void mthread_unsuspend(thread)
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mthread_thread_t thread; /* Thread to make runnable */
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{
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/* Mark the state of a thread runnable and add it to the run queue */
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mthread_tcb_t *tcb;
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if (!isokthreadid(thread)) mthread_panic("Invalid thread id");
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tcb = mthread_find_tcb(thread);
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tcb->m_state = MS_RUNNABLE;
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mthread_queue_add(&run_queue, thread);
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}
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/*===========================================================================*
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* mthread_yield *
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*===========================================================================*/
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PUBLIC int mthread_yield(void)
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{
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/* Defer further execution of the current thread and let another thread run. */
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mthread_init(); /* Make sure libmthread is initialized */
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if (mthread_queue_isempty(&run_queue)) { /* No point in yielding. */
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return(-1);
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} else if (current_thread == NO_THREAD) {
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/* Can't yield this thread */
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return(-1);
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}
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mthread_queue_add(&run_queue, current_thread);
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mthread_suspend(MS_RUNNABLE); /* We're still runnable, but we're just kind
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* enough to let someone else run.
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*/
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return(0);
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}
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/*===========================================================================*
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* mthread_yield_all *
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*===========================================================================*/
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PUBLIC void mthread_yield_all(void)
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{
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/* Yield until there are no more runnable threads left. Two threads calling
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* this function will lead to a deadlock.
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*/
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mthread_init(); /* Make sure libmthread is initialized */
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if (yield_all) mthread_panic("Deadlock: two threads trying to yield_all");
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yield_all = 1;
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/* This works as follows. Thread A is running and threads B, C, and D are
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* runnable. As A is running, it is NOT on the run_queue (see
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* mthread_schedule). It calls mthread_yield and will be added to the run
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* queue, allowing B to run. B runs and suspends eventually, possibly still
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* in a runnable state. Then C and D run. Eventually A will run again (and is
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* thus not on the list). If B, C, and D are dead, waiting for a condition,
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* or waiting for a lock, they are not on the run queue either. At that
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* point A is the only runnable thread left.
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*/
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while (!mthread_queue_isempty(&run_queue)) {
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(void) mthread_yield();
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}
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/* Done yielding all threads. */
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yield_all = 0;
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}
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