#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static void thread_fork_start(void *tf, unsigned long vmspace); /* * Implementation of fork system call * arguments: * tf: trapframe to copy * err: pointer to error return value */ pid_t sys_fork(struct trapframe *tf, int* err) { *err = 0; struct trapframe *new_tf; struct addrspace *addr_space; // Clone the current process struct proc *new_proc = proc_clone(err); if (*err) { *err = ENOMEM; return -1; } // Allocate for new trapframe new_tf = kmalloc(sizeof(struct trapframe)); if(new_tf == NULL) { *err = ENOMEM; return -1; } // Copy original tf to new tf memmove(new_tf, tf, sizeof(struct trapframe)); // Allocate for address space addr_space = kmalloc(sizeof(struct addrspace)); if (addr_space == NULL) { kfree(new_tf); *err = ENOMEM; return -1; } // Copy over address spaces struct addrspace *old_as = proc_getas(); int return_as = as_copy(old_as, &addr_space); if (return_as) { kfree(new_tf); kfree(addr_space); *err = ENOMEM; return -1; } // Fork thread into created process int return_thread = thread_fork("Child Fork", new_proc, thread_fork_start, (void *) new_tf, (unsigned long) addr_space); if (return_thread) { kfree(new_tf); as_destroy(addr_space); *err = ENOMEM; return -1; } return new_proc->pid; } /* * Initial instructions to newly forked process */ static void thread_fork_start(void *tf, unsigned long vmspace) { int spl = splhigh(); // Unused for now (void)vmspace; // Create trapframe on local stack, free the malloc'ed one struct trapframe child_frame = *(struct trapframe*) tf; kfree(tf); // change the register values child_frame.tf_v0 = 0; child_frame.tf_a3 = 0; child_frame.tf_epc += 4; mips_usermode(&child_frame); splx(spl); return; } /* * Implementation of getpid system call */ pid_t sys_getpid(void) { pid_t pid = curproc->pid; return pid; } /* * Kernel-Accessibly helper function for the sys_waitpid system call */ int wait_pid(pid_t pid, int* status, int options) { if(pid == curproc->pid) { return EINVAL; } if (options != 0 && options != WNOHANG) { return EINVAL; } if (status == NULL) { return EFAULT; } if(pid <= INVALID_PID) { return ENOSYS; } lock_acquire(pid_list_lock); pid_t parent_pid = curproc->pid; // Check that process is child before waiting if(!pid_is_child(pid, parent_pid)) { lock_release(pid_list_lock); return ECHILD; } struct pid_node * parent = pid_get_node(curproc->pid); if(parent == NULL) { lock_release(pid_list_lock); return ESRCH; } struct pid_node *child = pid_get_node(pid); if(child == NULL) { lock_release(pid_list_lock); return EINVAL; } // wait on condition variable if child is not yet finished if(child->finished == false) { cv_wait(child->pid_cv, pid_list_lock); KASSERT(child->finished); } *status = child->exit_status; pid_remove_child(pid, curproc->pid); lock_release(pid_list_lock); pid_remove(pid); return 0; } /* * Implementation of wait_pid system call * arguments: * pid: process to wait on to exit * status: process exit status * options: options to vary waitpid behaviour * err: pointer to error return value */ pid_t sys_waitpid(pid_t pid, userptr_t status, int options, int* err) { *err = 0; int return_status; if (pid > __PID_MAX || pid < 2) { *err = ESRCH; return -1; } if (options != 0) { *err = EINVAL; return -1; } // bulk of work done in kernel-accessible wait_pid function *err = wait_pid(pid, &return_status, options); if(*err) { return -1; } if(status != NULL) { *err = copyout(&return_status, status, sizeof(int)); } return pid; } /* * Implementation of exit system call * arguments: * status: exit code to report */ __DEAD void sys_exit(int status) { lock_acquire(pid_list_lock); struct proc *proc_to_exit = curproc; KASSERT(proc_to_exit != kproc); struct pid_node *cur_pid = pid_get_node(proc_to_exit->pid); KASSERT(cur_pid != NULL); cur_pid->finished = true; cur_pid->exit_status = status; // Dissociate Children while(cur_pid->child_list != NULL) { struct pid_node *child_pid = pid_get_node(cur_pid->child_list->pid); if(child_pid == NULL) { break; } if(child_pid->finished) { pid_remove_child(child_pid->pid, cur_pid->pid); pid_remove(child_pid->pid); } cur_pid->child_list = cur_pid->child_list->next; } if(cur_pid->parent_pid != INVALID_PID) // Has parent { cv_broadcast(cur_pid->pid_cv, pid_list_lock); } else // Has no parent { lock_release(pid_list_lock); pid_remove(proc_to_exit->pid); } lock_release(pid_list_lock); // remove thread from exiting proc KASSERT(curthread->t_proc == proc_to_exit); proc_remthread(curthread); proc_addthread(kproc, curthread); KASSERT(threadarray_num(&proc_to_exit->p_threads) == 0); proc_destroy(proc_to_exit); // exit process thread thread_exit(); // exit kernel thread thread_exit(); } /* * Implementation of execv system call * arguments: * program: program to replace currently executing program * args: arguments to pass to program * err: pointer to error return value */ int sys_execv(userptr_t program, userptr_t args, int* err) { *err = 0; if (program == NULL || args == NULL) { *err = EFAULT; return -1; } char *filename = kmalloc(PATH_MAX); struct vnode* v; int instr_return = copyinstr(program, filename, PATH_MAX, NULL); if (instr_return) { *err = EFAULT; kfree(filename); return -1; } instr_return = vfs_open(filename, O_RDONLY, 0, &v); if (instr_return) { *err = instr_return; kfree(filename); return -1; } // Start with 4K size int arg_size = PAGE_SIZE; size_t data_length = 0; size_t arg_len = 0; int argCount = 0; userptr_t cur_arg; userptr_t shifted_args = args; char *argv; ALLOC_ARGS: data_length = 0; arg_len = 0; argCount = 0; shifted_args = args; argv = kmalloc(arg_size); if(argv==NULL) { *err = ENOMEM; kfree(filename); return 1; } while(true) { // Get address of an argument instr_return = copyin(shifted_args, &cur_arg, sizeof(userptr_t)); if (instr_return) { *err = EFAULT; vfs_close(v); kfree(argv); kfree(filename); return -1; } // if argument null, reached end of arguments if (cur_arg == NULL) { break; } // Copy argument contents into argument list argv instr_return = copyinstr(cur_arg, argv + data_length, arg_size - data_length, &arg_len); if(instr_return == ENAMETOOLONG) { // If 4K was not enough, try again with 64K kfree(argv); arg_size = ARG_MAX; goto ALLOC_ARGS; } else if (instr_return) { *err = EFAULT; vfs_close(v); kfree(argv); kfree(filename); return - 1; } // Update argument count and apply necessary shifts for next read argCount++; data_length += arg_len; shifted_args += sizeof(userptr_t); } vaddr_t entryAddr,stackAddr; struct addrspace *vm_backup; struct addrspace *vm_new; // Create a new address space for program vm_new = as_create(); if (vm_new == NULL) { vfs_close(v); *err = ENOMEM; kfree(argv); kfree(filename); return -1; } /* * Create a backup of original address space to restore if needed * and set current proc's address space to newly created one */ spinlock_acquire(&curproc->p_lock); vm_backup = curproc->p_addrspace; curproc->p_addrspace = vm_new; spinlock_release(&curproc->p_lock); as_activate(); // Load elf pointed to by program pointer instr_return = load_elf(v, &entryAddr); if (instr_return) { // Restore original address space and cleanup before exiting spinlock_acquire(&curproc->p_lock); curproc->p_addrspace = vm_backup; spinlock_release(&curproc->p_lock); vfs_close(v); as_destroy(vm_new); *err = instr_return; kfree(filename); return -1; } vfs_close(v); instr_return = as_define_stack(vm_new, &stackAddr); if (instr_return) { // Restore original address space and cleanup before exiting spinlock_acquire(&curproc->p_lock); curproc->p_addrspace = vm_backup; spinlock_release(&curproc->p_lock); as_destroy(vm_new); *err = instr_return; kfree(filename); return -1; } /* * stackAddr initialized by DUMBVM to 0x80000000, marking the top of the kuseg user segment * Above the user stack, there will be a data segment and an argument segment containing arg data and pointers * Want to shift stackAddr down below these segments and populate these areas of the stack before passing to usermode * 0x80000000 * 0x7fffffff┌────────────┐ * │ │ kuseg * │ │ * │Data Segment│ * │ │ * │ │ * │ │ * │ │ * ├────────────┤ * │Arg Segment │ * │ │ * │ │ * │ │ * │ │ * │ │ * stackAddr├────────────┤ * │ │ * │ │ * │ │ * │ │ * └────────────┘ */ // Use stack pointer as starting address to determine address locations of data and args // Adjust stack pointer depending on data size and mark bottom of data segment, data segment stored above args stackAddr -= data_length; // Ensure that stack address is aligned stackAddr -= (stackAddr & (sizeof(void *) - 1)); userptr_t user_stack_data_vaddr = (userptr_t)stackAddr; // Move stack down to make space for args and mark bottom of arg segment stackAddr -=(argCount + 1) * sizeof(userptr_t); userptr_t user_stack_args_vaddr = (userptr_t)stackAddr; for(size_t offset = 0; offset < data_length; offset += arg_len) { cur_arg = user_stack_data_vaddr + offset; // copy out adress to argument to userspace instr_return = copyout(&cur_arg, user_stack_args_vaddr, sizeof(cur_arg)); if (instr_return) { spinlock_acquire(&curproc->p_lock); curproc->p_addrspace = vm_backup; spinlock_release(&curproc->p_lock); as_destroy(vm_new); *err = instr_return; kfree(filename); return -1; } // copy out argument to userspace instr_return = copyoutstr(argv + offset, cur_arg, data_length - offset , &arg_len); if (instr_return) { spinlock_acquire(&curproc->p_lock); curproc->p_addrspace = vm_backup; spinlock_release(&curproc->p_lock); as_destroy(vm_new); *err = instr_return; kfree(filename); return -1; } // Advance args vaddr pointer by size of written argument user_stack_args_vaddr += sizeof(cur_arg); } // Add null entry to end of arg list cur_arg = NULL; instr_return = copyout(&cur_arg, user_stack_args_vaddr, sizeof(cur_arg)); if (instr_return) { spinlock_acquire(&curproc->p_lock); curproc->p_addrspace = vm_backup; spinlock_release(&curproc->p_lock); as_destroy(vm_new); *err = instr_return; kfree(filename); return -1; } // Backup no longer needed, cannot allow execv to fail after this if(vm_backup) { as_destroy(vm_backup); } // Update current thread's name based on input kfree(curthread->t_name); curthread->t_name = kstrdup(filename); kfree(filename); enter_new_process(argCount, (userptr_t)stackAddr, NULL, stackAddr, entryAddr); panic("returned from new process"); *err = EINVAL; return -1; }