#include "syscall.h" #include "../process/process.h" #include #include #include #include #include #include #include // 导出系统调用入口函数,定义在entry.S中 extern void system_call(void); extern void syscall_int(void); /** * @brief 导出系统调用处理函数的符号 * */ #define SYSCALL_COMMON(syscall_num, symbol) extern unsigned long symbol(struct pt_regs *regs); SYSCALL_COMMON(0, system_call_not_exists); // 导出system_call_not_exists函数 #undef SYSCALL_COMMON // 取消前述宏定义 /** * @brief 重新定义为:把系统调用函数加入系统调用表 * @param syscall_num 系统调用号 * @param symbol 系统调用处理函数 */ #define SYSCALL_COMMON(syscall_num, symbol) [syscall_num] = symbol, /** * @brief sysenter的系统调用函数,从entry.S中跳转到这里 * * @param regs 3特权级下的寄存器值,rax存储系统调用号 * @return ul 对应的系统调用函数的地址 */ ul system_call_function(struct pt_regs *regs) { return system_call_table[regs->rax](regs); } /** * @brief 初始化系统调用模块 * */ void syscall_init() { kinfo("Initializing syscall..."); set_system_trap_gate(0x80, 0, syscall_int); // 系统调用门 } /** * @brief 通过中断进入系统调用 * * @param syscall_id * @param arg0 * @param arg1 * @param arg2 * @param arg3 * @param arg4 * @param arg5 * @param arg6 * @param arg7 * @return long */ long enter_syscall_int(ul syscall_id, ul arg0, ul arg1, ul arg2, ul arg3, ul arg4, ul arg5, ul arg6, ul arg7) { long err_code; __asm__ __volatile__( "movq %2, %%r8 \n\t" "movq %3, %%r9 \n\t" "movq %4, %%r10 \n\t" "movq %5, %%r11 \n\t" "movq %6, %%r12 \n\t" "movq %7, %%r13 \n\t" "movq %8, %%r14 \n\t" "movq %9, %%r15 \n\t" "int $0x80 \n\t" : "=a"(err_code) : "a"(syscall_id), "m"(arg0), "m"(arg1), "m"(arg2), "m"(arg3), "m"(arg4), "m"(arg5), "m"(arg6), "m"(arg7) : "memory", "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15", "rcx", "rdx"); return err_code; } /** * @brief 打印字符串的系统调用 * * 当arg1和arg2均为0时,打印黑底白字,否则按照指定的前景色和背景色来打印 * * @param regs 寄存器 * @param arg0 要打印的字符串 * @param arg1 前景色 * @param arg2 背景色 * @return ul 返回值 */ ul sys_put_string(struct pt_regs *regs) { printk_color(regs->r9, regs->r10, (char *)regs->r8); // printk_color(BLACK, WHITE, (char *)regs->r8); return 0; } uint64_t sys_open(struct pt_regs *regs) { char *filename = (char *)(regs->r8); int flags = (int)(regs->r9); long path_len = strnlen_user(filename, PAGE_4K_SIZE); if (path_len <= 0) // 地址空间错误 { return -EFAULT; } else if (path_len >= PAGE_4K_SIZE) // 名称过长 { return -ENAMETOOLONG; } // 为待拷贝文件路径字符串分配内存空间 char *path = (char *)kmalloc(path_len, 0); if (path == NULL) return -ENOMEM; memset(path, 0, path_len); strncpy_from_user(path, filename, path_len); // 寻找文件 struct vfs_dir_entry_t *dentry = vfs_path_walk(path, 0); kfree(path); if (dentry != NULL) printk_color(ORANGE, BLACK, "Found %s\nDIR_FstClus:%#018lx\tDIR_FileSize:%#018lx\n", path, ((struct fat32_inode_info_t *)(dentry->dir_inode->private_inode_info))->first_clus, dentry->dir_inode->file_size); else printk_color(ORANGE, BLACK, "Can`t find file\n"); if (dentry == NULL) return -ENOENT; // 暂时认为目标是目录是一种错误 if (dentry->dir_inode->attribute == VFS_ATTR_DIR) return -EISDIR; // 创建文件描述符 struct vfs_file_t *file_ptr = (struct vfs_file_t *)kmalloc(sizeof(struct vfs_file_t), 0); memset(file_ptr, 0, sizeof(struct vfs_file_t)); int errcode = -1; file_ptr->dEntry = dentry; file_ptr->mode = flags; file_ptr->file_ops = dentry->dir_inode->file_ops; // 如果文件系统实现了打开文件的函数 if (file_ptr->file_ops && file_ptr->file_ops->open) errcode = file_ptr->file_ops->open(dentry->dir_inode, file_ptr); if (errcode != VFS_SUCCESS) { kfree(file_ptr); return -EFAULT; } if (file_ptr->mode & O_TRUNC) // 清空文件 file_ptr->dEntry->dir_inode->file_size = 0; if (file_ptr->mode & O_APPEND) file_ptr->position = file_ptr->dEntry->dir_inode->file_size; else file_ptr->position = 0; struct vfs_file_t **f = current_pcb->fds; int fd_num = -1; // 在指针数组中寻找空位 // todo: 当pcb中的指针数组改为动态指针数组之后,需要更改这里(目前还是静态指针数组) for (int i = 0; i < PROC_MAX_FD_NUM; ++i) { if (f[i] == NULL) // 找到指针数组中的空位 { fd_num = i; break; } } // 指针数组没有空位了 if (fd_num == -1) { kfree(file_ptr); return -EMFILE; } // 保存文件描述符 f[fd_num] = file_ptr; return fd_num; } /** * @brief 关闭文件系统调用 * * @param fd_num 文件描述符号 * * @param regs * @return uint64_t */ uint64_t sys_close(struct pt_regs *regs) { int fd_num = (int)regs->r8; kdebug("sys close: fd=%d", fd_num); // 校验文件描述符范围 if (fd_num < 0 || fd_num > PROC_MAX_FD_NUM) return -EBADF; // 文件描述符不存在 if (current_pcb->fds[fd_num] == NULL) return -EBADF; struct vfs_file_t *file_ptr = current_pcb->fds[fd_num]; uint64_t ret; // If there is a valid close function if (file_ptr->file_ops && file_ptr->file_ops->close) ret = file_ptr->file_ops->close(file_ptr->dEntry->dir_inode, file_ptr); kfree(file_ptr); current_pcb->fds[fd_num] = NULL; return 0; } /** * @brief 从文件中读取数据 * * @param fd_num regs->r8 文件描述符号 * @param buf regs->r9 输出缓冲区 * @param count regs->r10 要读取的字节数 * * @return uint64_t */ uint64_t sys_read(struct pt_regs *regs) { int fd_num = (int)regs->r8; void *buf = (void *)regs->r9; int64_t count = (int64_t)regs->r10; // kdebug("sys read: fd=%d", fd_num); // 校验文件描述符范围 if (fd_num < 0 || fd_num > PROC_MAX_FD_NUM) return -EBADF; // 文件描述符不存在 if (current_pcb->fds[fd_num] == NULL) return -EBADF; if (count < 0) return -EINVAL; struct vfs_file_t *file_ptr = current_pcb->fds[fd_num]; uint64_t ret; if (file_ptr->file_ops && file_ptr->file_ops->read) ret = file_ptr->file_ops->read(file_ptr, (char *)buf, count, &(file_ptr->position)); return ret; } /** * @brief 向文件写入数据 * * @param fd_num regs->r8 文件描述符号 * @param buf regs->r9 输入缓冲区 * @param count regs->r10 要写入的字节数 * * @return uint64_t */ uint64_t sys_write(struct pt_regs *regs) { int fd_num = (int)regs->r8; void *buf = (void *)regs->r9; int64_t count = (int64_t)regs->r10; kdebug("sys write: fd=%d", fd_num); // 校验文件描述符范围 if (fd_num < 0 || fd_num > PROC_MAX_FD_NUM) return -EBADF; // 文件描述符不存在 if (current_pcb->fds[fd_num] == NULL) return -EBADF; if (count < 0) return -EINVAL; struct vfs_file_t *file_ptr = current_pcb->fds[fd_num]; uint64_t ret; if (file_ptr->file_ops && file_ptr->file_ops->write) ret = file_ptr->file_ops->write(file_ptr, (char *)buf, count, &(file_ptr->position)); return ret; } /** * @brief 调整文件的访问位置 * * @param fd_num 文件描述符号 * @param offset 偏移量 * @param whence 调整模式 * @return uint64_t 调整结束后的文件访问位置 */ uint64_t sys_lseek(struct pt_regs *regs) { int fd_num = (int)regs->r8; long offset = (long)regs->r9; int whence = (int)regs->r10; kdebug("sys_lseek: fd=%d", fd_num); uint64_t retval = 0; // 校验文件描述符范围 if (fd_num < 0 || fd_num > PROC_MAX_FD_NUM) return -EBADF; // 文件描述符不存在 if (current_pcb->fds[fd_num] == NULL) return -EBADF; struct vfs_file_t *file_ptr = current_pcb->fds[fd_num]; if (file_ptr->file_ops && file_ptr->file_ops->lseek) retval = file_ptr->file_ops->lseek(file_ptr, offset, whence); return retval; } uint64_t sys_fork(struct pt_regs *regs) { kdebug("sys_fork"); return do_fork(regs, 0, regs->rsp, 0); } uint64_t sys_vfork(struct pt_regs *regs) { kdebug("sys vfork"); return do_fork(regs, CLONE_VM | CLONE_FS | CLONE_SIGNAL, regs->rsp, 0); } /** * @brief 将堆内存调整为arg0 * * @param arg0 新的堆区域的结束地址 * arg0=-1 ===> 返回堆区域的起始地址 * arg0=-2 ===> 返回堆区域的结束地址 * @return uint64_t 错误码 * */ uint64_t sys_brk(struct pt_regs *regs) { uint64_t new_brk = PAGE_2M_ALIGN(regs->r8); kdebug("sys_brk input= %#010lx , new_brk= %#010lx bytes current_pcb->mm->brk_start=%#018lx current->end_brk=%#018lx", regs->r8, new_brk, current_pcb->mm->brk_start, current_pcb->mm->brk_end); if ((int64_t)regs->r8 == -1) { kdebug("get brk_start=%#018lx", current_pcb->mm->brk_start); return 0; return current_pcb->mm->brk_start; } if ((int64_t)regs->r8 == -2) { kdebug("get brk_end=%#018lx", current_pcb->mm->brk_end); return current_pcb->mm->brk_end; } if (new_brk > current_pcb->addr_limit) // 堆地址空间超过限制 return -ENOMEM; if (new_brk < current_pcb->mm->brk_end) // todo: 释放堆内存空间 return 0; new_brk = mm_do_brk(current_pcb->mm->brk_end, new_brk - current_pcb->mm->brk_end); // 扩展堆内存空间 current_pcb->mm->brk_end = new_brk; return 0; } /** * @brief 将堆内存空间加上offset(注意,该系统调用只应在普通进程中调用,而不能是内核线程) * * @param arg0 offset偏移量 * @return uint64_t the previous program break */ uint64_t sys_sbrk(struct pt_regs *regs) { uint64_t retval = current_pcb->mm->brk_end; regs->r8 = (int64_t)current_pcb->mm->brk_end + (int64_t)regs->r8; if (sys_brk(regs) == 0) return retval; else return -ENOMEM; } ul sys_ahci_end_req(struct pt_regs *regs) { ahci_end_request(); return 0; } // 系统调用的内核入口程序 void do_syscall_int(struct pt_regs *regs, unsigned long error_code) { if(regs->rax == SYS_BRK) { kdebug("is sysbrk"); regs->rax = 0xc00000UL; return; } ul ret = system_call_table[regs->rax](regs); if(regs->rax == SYS_BRK) kdebug("brk ret=%#018lx", ret); regs->rax = ret; // 返回码 } system_call_t system_call_table[MAX_SYSTEM_CALL_NUM] = { [0] = system_call_not_exists, [1] = sys_put_string, [2] = sys_open, [3] = sys_close, [4] = sys_read, [5] = sys_write, [6] = sys_lseek, [7] = sys_fork, [8] = sys_vfork, [9] = sys_brk, [10] = sys_sbrk, [11 ... 254] = system_call_not_exists, [255] = sys_ahci_end_req};