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390 lines
13 KiB
390 lines
13 KiB
#pragma once
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#include <assert.h>
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#include <errno.h>
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#include <stdint.h>
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#include <stdatomic.h>
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#include "memlogging.h"
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#include "client_socket.h"
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#include "current_sandbox.h"
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#include "global_request_scheduler.h"
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#include "global_request_scheduler_deque.h"
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#include "global_request_scheduler_minheap.h"
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#include "local_runqueue.h"
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#include "local_runqueue_minheap.h"
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#include "local_runqueue_list.h"
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#include "panic.h"
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#include "sandbox_request.h"
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#include "sandbox_exit.h"
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#include "sandbox_functions.h"
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#include "sandbox_types.h"
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#include "sandbox_set_as_blocked.h"
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#include "sandbox_set_as_runnable.h"
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#include "sandbox_set_as_running.h"
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#include "worker_thread_execute_epoll_loop.h"
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enum SCHEDULER
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{
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SCHEDULER_FIFO = 0,
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SCHEDULER_EDF = 1,
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SCHEDULER_SRSF = 2
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};
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extern enum SCHEDULER scheduler;
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extern _Atomic uint32_t scheduling_counter;
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extern uint64_t system_start_timestamp;
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extern __thread uint32_t local_workload_count;
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extern __thread uint32_t local_runqueue_count;
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extern uint32_t runtime_processor_speed_MHz;
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static inline struct sandbox *
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scheduler_edf_get_next()
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{
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/* Get the deadline of the sandbox at the head of the local request queue */
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struct sandbox * local = local_runqueue_get_next();
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uint64_t local_deadline = local == NULL ? UINT64_MAX : local->absolute_deadline;
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struct sandbox_request *request = NULL;
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uint64_t global_deadline = global_request_scheduler_peek();
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/* Try to pull and allocate from the global queue if earlier
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* This will be placed at the head of the local runqueue */
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//if (global_deadline < local_deadline) {
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if (global_deadline < local_deadline && (local_workload_count <=2 || local_runqueue_count == 0)) {
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if (global_request_scheduler_remove_if_earlier(&request, local_deadline) == 0) {
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assert(request != NULL);
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assert(request->absolute_deadline < local_deadline);
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struct sandbox *global = sandbox_allocate(request);
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if (!global) goto err_allocate;
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assert(global->state == SANDBOX_INITIALIZED);
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sandbox_set_as_runnable(global, SANDBOX_INITIALIZED);
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}
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}
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/* Return what is at the head of the local runqueue or NULL if empty */
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done:
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return local_runqueue_get_next();
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err_allocate:
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client_socket_send(request->socket_descriptor, 503);
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client_socket_close(request->socket_descriptor, &request->socket_address);
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free(request);
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goto done;
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}
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static inline struct sandbox *
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scheduler_srsf_get_next()
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{
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/* Get the deadline of the sandbox at the head of the local request queue */
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struct sandbox * local = local_runqueue_get_next();
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uint64_t local_remaining_slack = local == NULL ? UINT64_MAX : local->remaining_slack;
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struct sandbox_request *request = NULL;
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uint64_t global_remaining_slack = global_request_scheduler_peek();
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/* Try to pull and allocate from the global queue if earlier
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* This will be placed at the head of the local runqueue */
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if (global_remaining_slack < local_remaining_slack && (local_workload_count <=2 || local_runqueue_count == 0)) {
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//if (global_remaining_slack < local_remaining_slack) {
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if (global_request_scheduler_remove_if_earlier(&request, local_remaining_slack) == 0) {
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//uint64_t pop_time = __getcycles() - system_start_timestamp;
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//mem_log("time %lu remove from GQ, request id:%d name %s remaining slack %lu\n", pop_time,
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// request->id, request->module->name, request->remaining_slack);
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assert(request != NULL);
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struct sandbox *global = sandbox_allocate(request);
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if (!global) goto err_allocate;
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assert(global->state == SANDBOX_INITIALIZED);
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sandbox_set_as_runnable(global, SANDBOX_INITIALIZED);
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}
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}
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/* Return what is at the head of the local runqueue or NULL if empty */
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done:
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return local_runqueue_get_next();
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err_allocate:
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client_socket_send(request->socket_descriptor, 503);
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client_socket_close(request->socket_descriptor, &request->socket_address);
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free(request);
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goto done;
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}
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static inline struct sandbox *
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scheduler_fifo_get_next()
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{
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struct sandbox *sandbox = local_runqueue_get_next();
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struct sandbox_request *sandbox_request = NULL;
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if (sandbox == NULL) {
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/* If the local runqueue is empty, pull from global request scheduler */
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if (global_request_scheduler_remove(&sandbox_request) < 0) goto err;
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sandbox = sandbox_allocate(sandbox_request);
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if (!sandbox) goto err_allocate;
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sandbox_set_as_runnable(sandbox, SANDBOX_INITIALIZED);
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} else if (sandbox == current_sandbox_get()) {
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/* Execute Round Robin Scheduling Logic if the head is the current sandbox */
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local_runqueue_list_rotate();
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sandbox = local_runqueue_get_next();
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}
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done:
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return sandbox;
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err_allocate:
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client_socket_send(sandbox_request->socket_descriptor, 503);
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client_socket_close(sandbox_request->socket_descriptor, &sandbox->client_address);
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free(sandbox_request);
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err:
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sandbox = NULL;
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goto done;
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}
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static inline struct sandbox *
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scheduler_get_next()
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{
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switch (scheduler) {
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case SCHEDULER_EDF:
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return scheduler_edf_get_next();
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case SCHEDULER_SRSF:
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return scheduler_srsf_get_next();
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case SCHEDULER_FIFO:
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return scheduler_fifo_get_next();
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default:
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panic("Unimplemented\n");
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}
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}
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static inline void
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scheduler_initialize()
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{
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switch (scheduler) {
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case SCHEDULER_EDF:
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global_request_scheduler_minheap_initialize(SCHEDULER_EDF);
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break;
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case SCHEDULER_SRSF:
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global_request_scheduler_minheap_initialize(SCHEDULER_SRSF);
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break;
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case SCHEDULER_FIFO:
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global_request_scheduler_deque_initialize();
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break;
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default:
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panic("Invalid scheduler policy: %u\n", scheduler);
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}
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}
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static inline void
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scheduler_runqueue_initialize()
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{
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switch (scheduler) {
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case SCHEDULER_EDF:
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local_runqueue_minheap_initialize(SCHEDULER_EDF);
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break;
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case SCHEDULER_SRSF:
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local_runqueue_minheap_initialize(SCHEDULER_SRSF);
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break;
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case SCHEDULER_FIFO:
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local_runqueue_list_initialize();
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break;
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default:
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panic("Invalid scheduler policy: %u\n", scheduler);
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}
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}
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static inline void
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scheduling_counter_increment()
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{
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atomic_fetch_add(&scheduling_counter, 1);
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}
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/**
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* Called by the SIGALRM handler after a quantum
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* Assumes the caller validates that there is something to preempt
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* @param user_context - The context of our user-level Worker thread
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*/
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static inline void
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scheduler_preempt(ucontext_t *user_context)
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{
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assert(user_context != NULL);
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struct sandbox *current = current_sandbox_get();
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assert(current != NULL);
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assert(current->state == SANDBOX_RUNNING);
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if (current-> remaining_slack <= 5000 * runtime_processor_speed_MHz) {
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return;
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}
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/* This is for better state-change bookkeeping */
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uint64_t now = __getcycles();
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uint64_t duration_of_last_state = now - current->last_state_change_timestamp;
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current->running_duration += duration_of_last_state;
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/* Process epoll to make sure that all runnable jobs are considered for execution */
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worker_thread_execute_epoll_loop();
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struct sandbox *next = scheduler_get_next();
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assert(next != NULL);
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/* This is for better state-change bookkeeping */
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current->last_state_change_timestamp = __getcycles();
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/* If current equals next, no switch is necessary, so resume execution */
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if (current == next) return;
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scheduling_counter_increment();
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mem_log("scheduling count is %u\n", scheduling_counter);
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#ifdef LOG_PREEMPTION
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debuglog("Preempting sandbox %lu to run sandbox %lu\n", current->id, next->id);
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#endif
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/* Save the context of the currently executing sandbox before switching from it */
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sandbox_set_as_runnable(current, SANDBOX_RUNNING);
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arch_mcontext_save(¤t->ctxt, &user_context->uc_mcontext);
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/* Update current_sandbox to the next sandbox */
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assert(next->state == SANDBOX_RUNNABLE);
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//printf("scheduler_preempt...\n");
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sandbox_set_as_running(next, SANDBOX_RUNNABLE);
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switch (next->ctxt.variant) {
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case ARCH_CONTEXT_VARIANT_FAST: {
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arch_context_restore_new(&user_context->uc_mcontext, &next->ctxt);
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break;
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}
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case ARCH_CONTEXT_VARIANT_SLOW: {
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/* Our scheduler restores a fast context when switching to a sandbox that cooperatively yielded
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* (probably by blocking) or when switching to a freshly allocated sandbox that hasn't yet run.
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* These conditions can occur in either EDF or FIFO.
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*
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* A scheduler restores a slow context when switching to a sandbox that was preempted previously.
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* Under EDF, a sandbox is only ever preempted by an earlier deadline that either had blocked and since
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* become runnable or was just freshly allocated. This means that such EDF preemption context switches
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* should always use a fast context.
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*
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* This is not true under FIFO, where there is no innate ordering between sandboxes. A runqueue is
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* normally only a single sandbox, but it may have multiple sandboxes when one blocks and the worker
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* pulls an addition request. When the blocked sandbox becomes runnable, the executing sandbox can be
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* preempted yielding a slow context. This means that FIFO preemption context switches might cause
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* either a fast or a slow context to be restored during "round robin" execution.
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*/
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assert(scheduler != SCHEDULER_EDF);
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arch_mcontext_restore(&user_context->uc_mcontext, &next->ctxt);
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break;
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}
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default: {
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panic("Unexpectedly tried to switch to a context in %s state\n",
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arch_context_variant_print(next->ctxt.variant));
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}
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}
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}
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static inline char *
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scheduler_print(enum SCHEDULER variant)
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{
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switch (variant) {
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case SCHEDULER_FIFO:
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return "FIFO";
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case SCHEDULER_EDF:
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return "EDF";
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case SCHEDULER_SRSF:
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return "SRSF";
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}
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}
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static inline void
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scheduler_log_sandbox_switch(struct sandbox *current_sandbox, struct sandbox *next_sandbox)
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{
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#ifdef LOG_CONTEXT_SWITCHES
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if (current_sandbox == NULL) {
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/* Switching from "Base Context" */
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debuglog("Base Context (@%p) (%s) > Sandbox %lu (@%p) (%s)\n", &worker_thread_base_context,
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arch_context_variant_print(worker_thread_base_context.variant), next_sandbox->id,
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&next_sandbox->ctxt, arch_context_variant_print(next_sandbox->ctxt.variant));
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} else {
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debuglog("Sandbox %lu (@%p) (%s) > Sandbox %lu (@%p) (%s)\n", current_sandbox->id,
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¤t_sandbox->ctxt, arch_context_variant_print(current_sandbox->ctxt.variant),
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next_sandbox->id, &next_sandbox->ctxt, arch_context_variant_print(next_sandbox->ctxt.variant));
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}
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#endif
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}
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/**
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* @brief Switches to the next sandbox, placing the current sandbox on the completion queue if in
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* SANDBOX_RETURNED state
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* @param next_sandbox The Sandbox Context to switch to
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*/
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static inline void
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scheduler_switch_to(struct sandbox *next_sandbox)
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{
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assert(next_sandbox != NULL);
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assert(next_sandbox->state == SANDBOX_RUNNABLE);
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struct arch_context *next_context = &next_sandbox->ctxt;
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/* Get the old sandbox we're switching from.
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* This is null if switching from base context
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*/
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struct sandbox *current_sandbox = current_sandbox_get();
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assert(next_sandbox != current_sandbox);
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struct arch_context *current_context = NULL;
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if (current_sandbox != NULL) {
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current_context = ¤t_sandbox->ctxt;
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sandbox_exit(current_sandbox);
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}
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scheduler_log_sandbox_switch(current_sandbox, next_sandbox);
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//printf("scheduler_switch_to...\n");
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sandbox_set_as_running(next_sandbox, next_sandbox->state);
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arch_context_switch(current_context, next_context);
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}
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/**
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* @brief Switches to the base context, placing the current sandbox on the completion queue if in RETURNED state
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*/
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static inline void
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scheduler_yield()
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{
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struct sandbox *current_sandbox = current_sandbox_get();
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assert(current_sandbox != NULL);
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struct arch_context *current_context = ¤t_sandbox->ctxt;
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/* Assumption: Base Context should never switch to Base Context */
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assert(current_context != &worker_thread_base_context);
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#ifdef LOG_CONTEXT_SWITCHES
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debuglog("Sandbox %lu (@%p) (%s) > Base Context (@%p) (%s)\n", current_sandbox->id, current_context,
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arch_context_variant_print(current_sandbox->ctxt.variant), &worker_thread_base_context,
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arch_context_variant_print(worker_thread_base_context.variant));
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#endif
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sandbox_exit(current_sandbox);
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current_sandbox_set(NULL);
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runtime_worker_threads_deadline[worker_thread_idx] = UINT64_MAX;
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runtime_worker_threads_remaining_slack[worker_thread_idx] = UINT64_MAX;
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/* Assumption: Base Worker context should never be preempted */
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assert(worker_thread_base_context.variant == ARCH_CONTEXT_VARIANT_FAST);
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arch_context_switch(current_context, &worker_thread_base_context);
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}
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/**
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* Mark the currently executing sandbox as blocked, remove it from the local runqueue,
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* and switch to base context
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*/
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static inline void
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scheduler_block(void)
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{
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/* Remove the sandbox we were just executing from the runqueue and mark as blocked */
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struct sandbox *current_sandbox = current_sandbox_get();
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assert(current_sandbox->state == SANDBOX_RUNNING);
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sandbox_set_as_blocked(current_sandbox, SANDBOX_RUNNING);
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generic_thread_dump_lock_overhead();
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scheduler_yield();
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}
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