/* $NetBSD: netbsd32_netbsd.c,v 1.206.2.3 2023/06/21 20:38:35 martin Exp $ */ /* * Copyright (c) 1998, 2001, 2008 Matthew R. Green * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include __KERNEL_RCSID(0, "$NetBSD: netbsd32_netbsd.c,v 1.206.2.3 2023/06/21 20:38:35 martin Exp $"); #if defined(_KERNEL_OPT) #include "opt_ddb.h" #include "opt_ntp.h" #include "opt_ktrace.h" #include "opt_compat_netbsd.h" #include "opt_compat_43.h" #include "opt_sysv.h" #include "opt_syscall_debug.h" #endif /* * Though COMPAT_OLDSOCK is needed only for COMPAT_43, SunOS, Linux, * HP-UX, FreeBSD, Ultrix, OSF1, we define it unconditionally so that * this would be module-safe. */ #define COMPAT_OLDSOCK /* used by */ #include #include #include //#define msg __msg /* Don't ask me! */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if defined(DDB) #include #endif extern struct sysent netbsd32_sysent[]; #ifdef SYSCALL_DEBUG extern const char * const netbsd32_syscallnames[]; #endif #ifdef __HAVE_SYSCALL_INTERN void netbsd32_syscall_intern(struct proc *); #else void syscall(void); #endif #define LIMITCHECK(a, b) ((a) != RLIM_INFINITY && (a) > (b)) #ifdef COMPAT_16 extern char netbsd32_sigcode[], netbsd32_esigcode[]; struct uvm_object *emul_netbsd32_object; #endif extern struct sysctlnode netbsd32_sysctl_root; #ifdef MODULAR #include #endif struct emul emul_netbsd32 = { .e_name = "netbsd32", .e_path = "/emul/netbsd32", #ifndef __HAVE_MINIMAL_EMUL .e_flags = 0, .e_errno = NULL, .e_nosys = NETBSD32_SYS_netbsd32_syscall, .e_nsysent = NETBSD32_SYS_NSYSENT, #endif .e_sysent = netbsd32_sysent, #ifdef SYSCALL_DEBUG .e_syscallnames = netbsd32_syscallnames, #else .e_syscallnames = NULL, #endif #ifdef MODULAR .e_sc_autoload = netbsd32_syscalls_autoload, #endif .e_sendsig = netbsd32_sendsig, .e_trapsignal = trapsignal, .e_tracesig = NULL, #ifdef COMPAT_16 .e_sigcode = netbsd32_sigcode, .e_esigcode = netbsd32_esigcode, .e_sigobject = &emul_netbsd32_object, #else .e_sigcode = NULL, .e_esigcode = NULL, .e_sigobject = NULL, #endif .e_setregs = netbsd32_setregs, .e_proc_exec = NULL, .e_proc_fork = NULL, .e_proc_exit = NULL, .e_lwp_fork = NULL, .e_lwp_exit = NULL, #ifdef __HAVE_SYSCALL_INTERN .e_syscall_intern = netbsd32_syscall_intern, #else .e_syscall = syscall, #endif .e_sysctlovly = &netbsd32_sysctl_root, .e_fault = NULL, .e_vm_default_addr = netbsd32_vm_default_addr, .e_usertrap = NULL, .e_ucsize = sizeof(ucontext32_t), .e_startlwp = startlwp32, .e_ktrpsig = netbsd32_ktrpsig }; /* * below are all the standard NetBSD system calls, in the 32bit * environment, with the necessary conversions to 64bit before * calling the real syscall. anything that needs special * attention is handled elsewhere. */ int netbsd32_exit(struct lwp *l, const struct netbsd32_exit_args *uap, register_t *retval) { /* { syscallarg(int) rval; } */ struct sys_exit_args ua; NETBSD32TO64_UAP(rval); return sys_exit(l, &ua, retval); } int netbsd32_read(struct lwp *l, const struct netbsd32_read_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(netbsd32_voidp) buf; syscallarg(netbsd32_size_t) nbyte; } */ struct sys_read_args ua; if (SCARG(uap, nbyte) > NETBSD32_SSIZE_MAX) return EINVAL; NETBSD32TO64_UAP(fd); NETBSD32TOP_UAP(buf, void *); NETBSD32TOX_UAP(nbyte, size_t); return sys_read(l, &ua, retval); } int netbsd32_write(struct lwp *l, const struct netbsd32_write_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(const netbsd32_voidp) buf; syscallarg(netbsd32_size_t) nbyte; } */ struct sys_write_args ua; if (SCARG(uap, nbyte) > NETBSD32_SSIZE_MAX) return EINVAL; NETBSD32TO64_UAP(fd); NETBSD32TOP_UAP(buf, void *); NETBSD32TOX_UAP(nbyte, size_t); return sys_write(l, &ua, retval); } int netbsd32_close(struct lwp *l, const struct netbsd32_close_args *uap, register_t *retval) { /* { syscallarg(int) fd; } */ struct sys_close_args ua; NETBSD32TO64_UAP(fd); return sys_close(l, &ua, retval); } int netbsd32_open(struct lwp *l, const struct netbsd32_open_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) flags; syscallarg(mode_t) mode; } */ struct sys_open_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(flags); NETBSD32TO64_UAP(mode); return sys_open(l, &ua, retval); } int netbsd32_link(struct lwp *l, const struct netbsd32_link_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(const netbsd32_charp) link; } */ struct sys_link_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(link, const char); return (sys_link(l, &ua, retval)); } int netbsd32_unlink(struct lwp *l, const struct netbsd32_unlink_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; } */ struct sys_unlink_args ua; NETBSD32TOP_UAP(path, const char); return (sys_unlink(l, &ua, retval)); } int netbsd32_chdir(struct lwp *l, const struct netbsd32_chdir_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; } */ struct sys_chdir_args ua; NETBSD32TOP_UAP(path, const char); return (sys_chdir(l, &ua, retval)); } int netbsd32_fchdir(struct lwp *l, const struct netbsd32_fchdir_args *uap, register_t *retval) { /* { syscallarg(int) fd; } */ struct sys_fchdir_args ua; NETBSD32TO64_UAP(fd); return (sys_fchdir(l, &ua, retval)); } int netbsd32___mknod50(struct lwp *l, const struct netbsd32___mknod50_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(mode_t) mode; syscallarg(netbsd32_dev_t) dev; } */ return do_sys_mknod(l, SCARG_P32(uap, path), SCARG(uap, mode), SCARG(uap, dev), retval, UIO_USERSPACE); } int netbsd32_chmod(struct lwp *l, const struct netbsd32_chmod_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(mode_t) mode; } */ struct sys_chmod_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(mode); return (sys_chmod(l, &ua, retval)); } int netbsd32_chown(struct lwp *l, const struct netbsd32_chown_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(uid_t) uid; syscallarg(gid_t) gid; } */ struct sys_chown_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(uid); NETBSD32TO64_UAP(gid); return (sys_chown(l, &ua, retval)); } int netbsd32_break(struct lwp *l, const struct netbsd32_break_args *uap, register_t *retval) { /* { syscallarg(netbsd32_charp) nsize; } */ struct sys_obreak_args ua; NETBSD32TOP_UAP(nsize, char); return (sys_obreak(l, &ua, retval)); } int netbsd32_mount(struct lwp *l, const struct netbsd32_mount_args *uap, register_t *retval) { #ifdef COMPAT_40 /* { syscallarg(const netbsd32_charp) type; syscallarg(const netbsd32_charp) path; syscallarg(int) flags; syscallarg(netbsd32_voidp) data; } */ struct compat_40_sys_mount_args ua; NETBSD32TOP_UAP(type, const char); NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(flags); NETBSD32TOP_UAP(data, void); return (compat_40_sys_mount(l, &ua, retval)); #else return ENOSYS; #endif } int netbsd32_unmount(struct lwp *l, const struct netbsd32_unmount_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) flags; } */ struct sys_unmount_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(flags); return (sys_unmount(l, &ua, retval)); } int netbsd32_setuid(struct lwp *l, const struct netbsd32_setuid_args *uap, register_t *retval) { /* { syscallarg(uid_t) uid; } */ struct sys_setuid_args ua; NETBSD32TO64_UAP(uid); return (sys_setuid(l, &ua, retval)); } int netbsd32_accept(struct lwp *l, const struct netbsd32_accept_args *uap, register_t *retval) { /* { syscallarg(int) s; syscallarg(netbsd32_sockaddrp_t) name; syscallarg(netbsd32_intp) anamelen; } */ struct sys_accept_args ua; NETBSD32TO64_UAP(s); NETBSD32TOP_UAP(name, struct sockaddr); NETBSD32TOP_UAP(anamelen, socklen_t); return (sys_accept(l, &ua, retval)); } int netbsd32_getpeername(struct lwp *l, const struct netbsd32_getpeername_args *uap, register_t *retval) { /* { syscallarg(int) fdes; syscallarg(netbsd32_sockaddrp_t) asa; syscallarg(netbsd32_intp) alen; } */ struct sys_getpeername_args ua; NETBSD32TO64_UAP(fdes); NETBSD32TOP_UAP(asa, struct sockaddr); NETBSD32TOP_UAP(alen, socklen_t); /* NB: do the protocol specific sockaddrs need to be converted? */ return (sys_getpeername(l, &ua, retval)); } int netbsd32_getsockname(struct lwp *l, const struct netbsd32_getsockname_args *uap, register_t *retval) { /* { syscallarg(int) fdes; syscallarg(netbsd32_sockaddrp_t) asa; syscallarg(netbsd32_intp) alen; } */ struct sys_getsockname_args ua; NETBSD32TO64_UAP(fdes); NETBSD32TOP_UAP(asa, struct sockaddr); NETBSD32TOP_UAP(alen, socklen_t); return (sys_getsockname(l, &ua, retval)); } int netbsd32_access(struct lwp *l, const struct netbsd32_access_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) flags; } */ struct sys_access_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(flags); return sys_access(l, &ua, retval); } int netbsd32_chflags(struct lwp *l, const struct netbsd32_chflags_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(netbsd32_u_long) flags; } */ struct sys_chflags_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(flags); return (sys_chflags(l, &ua, retval)); } int netbsd32_fchflags(struct lwp *l, const struct netbsd32_fchflags_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(netbsd32_u_long) flags; } */ struct sys_fchflags_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(flags); return (sys_fchflags(l, &ua, retval)); } int netbsd32_lchflags(struct lwp *l, const struct netbsd32_lchflags_args *uap, register_t *retval) { /* { syscallarg(const char *) path; syscallarg(netbsd32_u_long) flags; } */ struct sys_lchflags_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(flags); return (sys_lchflags(l, &ua, retval)); } int netbsd32_kill(struct lwp *l, const struct netbsd32_kill_args *uap, register_t *retval) { /* { syscallarg(int) pid; syscallarg(int) signum; } */ struct sys_kill_args ua; NETBSD32TO64_UAP(pid); NETBSD32TO64_UAP(signum); return (sys_kill(l, &ua, retval)); } int netbsd32_dup(struct lwp *l, const struct netbsd32_dup_args *uap, register_t *retval) { /* { syscallarg(int) fd; } */ struct sys_dup_args ua; NETBSD32TO64_UAP(fd); return (sys_dup(l, &ua, retval)); } int netbsd32_profil(struct lwp *l, const struct netbsd32_profil_args *uap, register_t *retval) { /* { syscallarg(netbsd32_voidp) samples; syscallarg(netbsd32_size_t) size; syscallarg(netbsd32_u_long) offset; syscallarg(u_int) scale; } */ struct sys_profil_args ua; NETBSD32TOP_UAP(samples, void *); NETBSD32TOX_UAP(size, size_t); NETBSD32TOX_UAP(offset, u_long); NETBSD32TO64_UAP(scale); return (sys_profil(l, &ua, retval)); } int netbsd32_ktrace(struct lwp *l, const struct netbsd32_ktrace_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) fname; syscallarg(int) ops; syscallarg(int) facs; syscallarg(int) pid; } */ struct sys_ktrace_args ua; NETBSD32TOP_UAP(fname, const char); NETBSD32TO64_UAP(ops); NETBSD32TO64_UAP(facs); NETBSD32TO64_UAP(pid); return (sys_ktrace(l, &ua, retval)); } int netbsd32_utrace(struct lwp *l, const struct netbsd32_utrace_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) label; syscallarg(netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; } */ struct sys_utrace_args ua; NETBSD32TOP_UAP(label, const char); NETBSD32TOP_UAP(addr, void); NETBSD32TO64_UAP(len); return (sys_utrace(l, &ua, retval)); } int netbsd32___getlogin(struct lwp *l, const struct netbsd32___getlogin_args *uap, register_t *retval) { /* { syscallarg(netbsd32_charp) namebuf; syscallarg(u_int) namelen; } */ struct sys___getlogin_args ua; NETBSD32TOP_UAP(namebuf, char); NETBSD32TO64_UAP(namelen); return (sys___getlogin(l, &ua, retval)); } int netbsd32_setlogin(struct lwp *l, const struct netbsd32_setlogin_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) namebuf; } */ struct sys___setlogin_args ua; NETBSD32TOP_UAP(namebuf, char); return (sys___setlogin(l, &ua, retval)); } int netbsd32_acct(struct lwp *l, const struct netbsd32_acct_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; } */ struct sys_acct_args ua; NETBSD32TOP_UAP(path, const char); return (sys_acct(l, &ua, retval)); } int netbsd32_revoke(struct lwp *l, const struct netbsd32_revoke_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; } */ struct sys_revoke_args ua; NETBSD32TOP_UAP(path, const char); return (sys_revoke(l, &ua, retval)); } int netbsd32_symlink(struct lwp *l, const struct netbsd32_symlink_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(const netbsd32_charp) link; } */ struct sys_symlink_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(link, const char); return (sys_symlink(l, &ua, retval)); } int netbsd32_readlink(struct lwp *l, const struct netbsd32_readlink_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(netbsd32_charp) buf; syscallarg(netbsd32_size_t) count; } */ struct sys_readlink_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(buf, char); NETBSD32TOX_UAP(count, size_t); return (sys_readlink(l, &ua, retval)); } int netbsd32_umask(struct lwp *l, const struct netbsd32_umask_args *uap, register_t *retval) { /* { syscallarg(mode_t) newmask; } */ struct sys_umask_args ua; NETBSD32TO64_UAP(newmask); return (sys_umask(l, &ua, retval)); } int netbsd32_chroot(struct lwp *l, const struct netbsd32_chroot_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; } */ struct sys_chroot_args ua; NETBSD32TOP_UAP(path, const char); return (sys_chroot(l, &ua, retval)); } int netbsd32_sbrk(struct lwp *l, const struct netbsd32_sbrk_args *uap, register_t *retval) { /* { syscallarg(int) incr; } */ struct sys_sbrk_args ua; NETBSD32TO64_UAP(incr); return (sys_sbrk(l, &ua, retval)); } int netbsd32_sstk(struct lwp *l, const struct netbsd32_sstk_args *uap, register_t *retval) { /* { syscallarg(int) incr; } */ struct sys_sstk_args ua; NETBSD32TO64_UAP(incr); return (sys_sstk(l, &ua, retval)); } int netbsd32_munmap(struct lwp *l, const struct netbsd32_munmap_args *uap, register_t *retval) { /* { syscallarg(netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; } */ struct sys_munmap_args ua; NETBSD32TOP_UAP(addr, void); NETBSD32TOX_UAP(len, size_t); return (sys_munmap(l, &ua, retval)); } int netbsd32_mprotect(struct lwp *l, const struct netbsd32_mprotect_args *uap, register_t *retval) { /* { syscallarg(netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; syscallarg(int) prot; } */ struct sys_mprotect_args ua; NETBSD32TOP_UAP(addr, void); NETBSD32TOX_UAP(len, size_t); NETBSD32TO64_UAP(prot); return (sys_mprotect(l, &ua, retval)); } int netbsd32_madvise(struct lwp *l, const struct netbsd32_madvise_args *uap, register_t *retval) { /* { syscallarg(netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; syscallarg(int) behav; } */ struct sys_madvise_args ua; NETBSD32TOP_UAP(addr, void); NETBSD32TOX_UAP(len, size_t); NETBSD32TO64_UAP(behav); return (sys_madvise(l, &ua, retval)); } int netbsd32_mincore(struct lwp *l, const struct netbsd32_mincore_args *uap, register_t *retval) { /* { syscallarg(netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; syscallarg(netbsd32_charp) vec; } */ struct sys_mincore_args ua; NETBSD32TOP_UAP(addr, void *); NETBSD32TOX_UAP(len, size_t); NETBSD32TOP_UAP(vec, char); return (sys_mincore(l, &ua, retval)); } /* XXX MOVE ME XXX ? */ int netbsd32_getgroups(struct lwp *l, const struct netbsd32_getgroups_args *uap, register_t *retval) { /* { syscallarg(int) gidsetsize; syscallarg(netbsd32_gid_tp) gidset; } */ struct sys_getgroups_args ua; /* Since sizeof (gid_t) == sizeof (netbsd32_gid_t) ... */ NETBSD32TO64_UAP(gidsetsize); NETBSD32TOP_UAP(gidset, gid_t); return (sys_getgroups(l, &ua, retval)); } int netbsd32_setgroups(struct lwp *l, const struct netbsd32_setgroups_args *uap, register_t *retval) { /* { syscallarg(int) gidsetsize; syscallarg(const netbsd32_gid_tp) gidset; } */ struct sys_setgroups_args ua; NETBSD32TO64_UAP(gidsetsize); NETBSD32TOP_UAP(gidset, gid_t); return (sys_setgroups(l, &ua, retval)); } int netbsd32_setpgid(struct lwp *l, const struct netbsd32_setpgid_args *uap, register_t *retval) { /* { syscallarg(int) pid; syscallarg(int) pgid; } */ struct sys_setpgid_args ua; NETBSD32TO64_UAP(pid); NETBSD32TO64_UAP(pgid); return (sys_setpgid(l, &ua, retval)); } int netbsd32_fcntl(struct lwp *l, const struct netbsd32_fcntl_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) cmd; syscallarg(netbsd32_voidp) arg; } */ struct sys_fcntl_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(cmd); NETBSD32TOP_UAP(arg, void); /* we can do this because `struct flock' doesn't change */ return (sys_fcntl(l, &ua, retval)); } int netbsd32_dup2(struct lwp *l, const struct netbsd32_dup2_args *uap, register_t *retval) { /* { syscallarg(int) from; syscallarg(int) to; } */ struct sys_dup2_args ua; NETBSD32TO64_UAP(from); NETBSD32TO64_UAP(to); return (sys_dup2(l, &ua, retval)); } int netbsd32_fsync(struct lwp *l, const struct netbsd32_fsync_args *uap, register_t *retval) { /* { syscallarg(int) fd; } */ struct sys_fsync_args ua; NETBSD32TO64_UAP(fd); return (sys_fsync(l, &ua, retval)); } int netbsd32_setpriority(struct lwp *l, const struct netbsd32_setpriority_args *uap, register_t *retval) { /* { syscallarg(int) which; syscallarg(int) who; syscallarg(int) prio; } */ struct sys_setpriority_args ua; NETBSD32TO64_UAP(which); NETBSD32TO64_UAP(who); NETBSD32TO64_UAP(prio); return (sys_setpriority(l, &ua, retval)); } int netbsd32___socket30(struct lwp *l, const struct netbsd32___socket30_args *uap, register_t *retval) { /* { syscallarg(int) domain; syscallarg(int) type; syscallarg(int) protocol; } */ struct sys___socket30_args ua; NETBSD32TO64_UAP(domain); NETBSD32TO64_UAP(type); NETBSD32TO64_UAP(protocol); return (sys___socket30(l, &ua, retval)); } int netbsd32_connect(struct lwp *l, const struct netbsd32_connect_args *uap, register_t *retval) { /* { syscallarg(int) s; syscallarg(const netbsd32_sockaddrp_t) name; syscallarg(int) namelen; } */ struct sys_connect_args ua; NETBSD32TO64_UAP(s); NETBSD32TOP_UAP(name, struct sockaddr); NETBSD32TO64_UAP(namelen); return (sys_connect(l, &ua, retval)); } int netbsd32_getpriority(struct lwp *l, const struct netbsd32_getpriority_args *uap, register_t *retval) { /* { syscallarg(int) which; syscallarg(int) who; } */ struct sys_getpriority_args ua; NETBSD32TO64_UAP(which); NETBSD32TO64_UAP(who); return (sys_getpriority(l, &ua, retval)); } int netbsd32_bind(struct lwp *l, const struct netbsd32_bind_args *uap, register_t *retval) { /* { syscallarg(int) s; syscallarg(const netbsd32_sockaddrp_t) name; syscallarg(int) namelen; } */ struct sys_bind_args ua; NETBSD32TO64_UAP(s); NETBSD32TOP_UAP(name, struct sockaddr); NETBSD32TO64_UAP(namelen); return (sys_bind(l, &ua, retval)); } int netbsd32_setsockopt(struct lwp *l, const struct netbsd32_setsockopt_args *uap, register_t *retval) { /* { syscallarg(int) s; syscallarg(int) level; syscallarg(int) name; syscallarg(const netbsd32_voidp) val; syscallarg(int) valsize; } */ struct sys_setsockopt_args ua; NETBSD32TO64_UAP(s); NETBSD32TO64_UAP(level); NETBSD32TO64_UAP(name); NETBSD32TOP_UAP(val, void); NETBSD32TO64_UAP(valsize); /* may be more efficient to do this inline. */ return (sys_setsockopt(l, &ua, retval)); } int netbsd32_listen(struct lwp *l, const struct netbsd32_listen_args *uap, register_t *retval) { /* { syscallarg(int) s; syscallarg(int) backlog; } */ struct sys_listen_args ua; NETBSD32TO64_UAP(s); NETBSD32TO64_UAP(backlog); return (sys_listen(l, &ua, retval)); } int netbsd32_fchown(struct lwp *l, const struct netbsd32_fchown_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(uid_t) uid; syscallarg(gid_t) gid; } */ struct sys_fchown_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(uid); NETBSD32TO64_UAP(gid); return (sys_fchown(l, &ua, retval)); } int netbsd32_fchmod(struct lwp *l, const struct netbsd32_fchmod_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(mode_t) mode; } */ struct sys_fchmod_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(mode); return (sys_fchmod(l, &ua, retval)); } int netbsd32_setreuid(struct lwp *l, const struct netbsd32_setreuid_args *uap, register_t *retval) { /* { syscallarg(uid_t) ruid; syscallarg(uid_t) euid; } */ struct sys_setreuid_args ua; NETBSD32TO64_UAP(ruid); NETBSD32TO64_UAP(euid); return (sys_setreuid(l, &ua, retval)); } int netbsd32_setregid(struct lwp *l, const struct netbsd32_setregid_args *uap, register_t *retval) { /* { syscallarg(gid_t) rgid; syscallarg(gid_t) egid; } */ struct sys_setregid_args ua; NETBSD32TO64_UAP(rgid); NETBSD32TO64_UAP(egid); return (sys_setregid(l, &ua, retval)); } int netbsd32_getsockopt(struct lwp *l, const struct netbsd32_getsockopt_args *uap, register_t *retval) { /* { syscallarg(int) s; syscallarg(int) level; syscallarg(int) name; syscallarg(netbsd32_voidp) val; syscallarg(netbsd32_intp) avalsize; } */ struct sys_getsockopt_args ua; NETBSD32TO64_UAP(s); NETBSD32TO64_UAP(level); NETBSD32TO64_UAP(name); NETBSD32TOP_UAP(val, void); NETBSD32TOP_UAP(avalsize, socklen_t); return (sys_getsockopt(l, &ua, retval)); } int netbsd32_rename(struct lwp *l, const struct netbsd32_rename_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) from; syscallarg(const netbsd32_charp) to; } */ struct sys_rename_args ua; NETBSD32TOP_UAP(from, const char); NETBSD32TOP_UAP(to, const char); return (sys_rename(l, &ua, retval)); } int netbsd32_flock(struct lwp *l, const struct netbsd32_flock_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) how; } */ struct sys_flock_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(how); return (sys_flock(l, &ua, retval)); } int netbsd32_mkfifo(struct lwp *l, const struct netbsd32_mkfifo_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(mode_t) mode; } */ struct sys_mkfifo_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(mode); return (sys_mkfifo(l, &ua, retval)); } int netbsd32_shutdown(struct lwp *l, const struct netbsd32_shutdown_args *uap, register_t *retval) { /* { syscallarg(int) s; syscallarg(int) how; } */ struct sys_shutdown_args ua; NETBSD32TO64_UAP(s); NETBSD32TO64_UAP(how); return (sys_shutdown(l, &ua, retval)); } int netbsd32_socketpair(struct lwp *l, const struct netbsd32_socketpair_args *uap, register_t *retval) { /* { syscallarg(int) domain; syscallarg(int) type; syscallarg(int) protocol; syscallarg(netbsd32_intp) rsv; } */ struct sys_socketpair_args ua; NETBSD32TO64_UAP(domain); NETBSD32TO64_UAP(type); NETBSD32TO64_UAP(protocol); NETBSD32TOP_UAP(rsv, int); /* Since we're just copying out two `int's we can do this */ return (sys_socketpair(l, &ua, retval)); } int netbsd32_mkdir(struct lwp *l, const struct netbsd32_mkdir_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(mode_t) mode; } */ struct sys_mkdir_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(mode); return (sys_mkdir(l, &ua, retval)); } int netbsd32_rmdir(struct lwp *l, const struct netbsd32_rmdir_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; } */ struct sys_rmdir_args ua; NETBSD32TOP_UAP(path, const char); return (sys_rmdir(l, &ua, retval)); } int netbsd32___quotactl(struct lwp *l, const struct netbsd32___quotactl_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(netbsd32_voidp) args; } */ struct netbsd32_quotactlargs args32; struct quotactl_args args; int error; error = copyin(SCARG_P32(uap, args), &args32, sizeof(args32)); if (error) { return error; } args.qc_op = args32.qc_op; switch (args.qc_op) { case QUOTACTL_STAT: args.u.stat.qc_info = NETBSD32PTR64(args32.u.stat.qc_info); break; case QUOTACTL_IDTYPESTAT: args.u.idtypestat.qc_idtype = args32.u.idtypestat.qc_idtype; args.u.idtypestat.qc_info = NETBSD32PTR64(args32.u.idtypestat.qc_info); break; case QUOTACTL_OBJTYPESTAT: args.u.objtypestat.qc_objtype = args32.u.objtypestat.qc_objtype; args.u.objtypestat.qc_info = NETBSD32PTR64(args32.u.objtypestat.qc_info); break; case QUOTACTL_GET: args.u.get.qc_key = NETBSD32PTR64(args32.u.get.qc_key); args.u.get.qc_val = NETBSD32PTR64(args32.u.get.qc_val); break; case QUOTACTL_PUT: args.u.put.qc_key = NETBSD32PTR64(args32.u.put.qc_key); args.u.put.qc_val = NETBSD32PTR64(args32.u.put.qc_val); break; case QUOTACTL_DEL: args.u.del.qc_key = NETBSD32PTR64(args32.u.del.qc_key); break; case QUOTACTL_CURSOROPEN: args.u.cursoropen.qc_cursor = NETBSD32PTR64(args32.u.cursoropen.qc_cursor); break; case QUOTACTL_CURSORCLOSE: args.u.cursorclose.qc_cursor = NETBSD32PTR64(args32.u.cursorclose.qc_cursor); break; case QUOTACTL_CURSORSKIPIDTYPE: args.u.cursorskipidtype.qc_cursor = NETBSD32PTR64(args32.u.cursorskipidtype.qc_cursor); args.u.cursorskipidtype.qc_idtype = args32.u.cursorskipidtype.qc_idtype; break; case QUOTACTL_CURSORGET: args.u.cursorget.qc_cursor = NETBSD32PTR64(args32.u.cursorget.qc_cursor); args.u.cursorget.qc_keys = NETBSD32PTR64(args32.u.cursorget.qc_keys); args.u.cursorget.qc_vals = NETBSD32PTR64(args32.u.cursorget.qc_vals); args.u.cursorget.qc_maxnum = args32.u.cursorget.qc_maxnum; args.u.cursorget.qc_ret = NETBSD32PTR64(args32.u.cursorget.qc_ret); break; case QUOTACTL_CURSORATEND: args.u.cursoratend.qc_cursor = NETBSD32PTR64(args32.u.cursoratend.qc_cursor); args.u.cursoratend.qc_ret = NETBSD32PTR64(args32.u.cursoratend.qc_ret); break; case QUOTACTL_CURSORREWIND: args.u.cursorrewind.qc_cursor = NETBSD32PTR64(args32.u.cursorrewind.qc_cursor); break; case QUOTACTL_QUOTAON: args.u.quotaon.qc_idtype = args32.u.quotaon.qc_idtype; args.u.quotaon.qc_quotafile = NETBSD32PTR64(args32.u.quotaon.qc_quotafile); break; case QUOTACTL_QUOTAOFF: args.u.quotaoff.qc_idtype = args32.u.quotaoff.qc_idtype; break; default: return EINVAL; } return do_sys_quotactl(SCARG_P32(uap, path), &args); } int netbsd32___getfh30(struct lwp *l, const struct netbsd32___getfh30_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) fname; syscallarg(netbsd32_fhandlep_t) fhp; syscallarg(netbsd32_size_tp) fh_size; } */ struct vnode *vp; fhandle_t *fh; int error; struct pathbuf *pb; struct nameidata nd; netbsd32_size_t usz32, sz32; size_t sz; /* * Must be super user */ error = kauth_authorize_system(l->l_cred, KAUTH_SYSTEM_FILEHANDLE, 0, NULL, NULL, NULL); if (error) return (error); error = pathbuf_copyin(SCARG_P32(uap, fname), &pb); if (error) { return error; } NDINIT(&nd, LOOKUP, FOLLOW | LOCKLEAF | TRYEMULROOT, pb); error = namei(&nd); if (error) { pathbuf_destroy(pb); return error; } vp = nd.ni_vp; pathbuf_destroy(pb); error = vfs_composefh_alloc(vp, &fh); vput(vp); if (error != 0) { return error; } error = copyin(SCARG_P32(uap, fh_size), &usz32, sizeof(usz32)); if (error != 0) { goto out; } sz = FHANDLE_SIZE(fh); sz32 = sz; error = copyout(&sz32, SCARG_P32(uap, fh_size), sizeof(sz32)); if (error != 0) { goto out; } if (usz32 >= sz32) { error = copyout(fh, SCARG_P32(uap, fhp), sz); } else { error = E2BIG; } out: vfs_composefh_free(fh); return (error); } int netbsd32_pread(struct lwp *l, const struct netbsd32_pread_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(netbsd32_voidp) buf; syscallarg(netbsd32_size_t) nbyte; syscallarg(int) PAD; syscallarg(netbsd32_off_t) offset; } */ struct sys_pread_args ua; if (SCARG(uap, nbyte) > NETBSD32_SSIZE_MAX) return EINVAL; NETBSD32TO64_UAP(fd); NETBSD32TOP_UAP(buf, void); NETBSD32TOX_UAP(nbyte, size_t); NETBSD32TO64_UAP(PAD); NETBSD32TO64_UAP(offset); return sys_pread(l, &ua, retval); } int netbsd32_pwrite(struct lwp *l, const struct netbsd32_pwrite_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(const netbsd32_voidp) buf; syscallarg(netbsd32_size_t) nbyte; syscallarg(int) PAD; syscallarg(netbsd32_off_t) offset; } */ struct sys_pwrite_args ua; if (SCARG(uap, nbyte) > NETBSD32_SSIZE_MAX) return EINVAL; NETBSD32TO64_UAP(fd); NETBSD32TOP_UAP(buf, void); NETBSD32TOX_UAP(nbyte, size_t); NETBSD32TO64_UAP(PAD); NETBSD32TO64_UAP(offset); return sys_pwrite(l, &ua, retval); } int netbsd32_setgid(struct lwp *l, const struct netbsd32_setgid_args *uap, register_t *retval) { /* { syscallarg(gid_t) gid; } */ struct sys_setgid_args ua; NETBSD32TO64_UAP(gid); return (sys_setgid(l, &ua, retval)); } int netbsd32_setegid(struct lwp *l, const struct netbsd32_setegid_args *uap, register_t *retval) { /* { syscallarg(gid_t) egid; } */ struct sys_setegid_args ua; NETBSD32TO64_UAP(egid); return (sys_setegid(l, &ua, retval)); } int netbsd32_seteuid(struct lwp *l, const struct netbsd32_seteuid_args *uap, register_t *retval) { /* { syscallarg(gid_t) euid; } */ struct sys_seteuid_args ua; NETBSD32TO64_UAP(euid); return (sys_seteuid(l, &ua, retval)); } int netbsd32_pathconf(struct lwp *l, const struct netbsd32_pathconf_args *uap, register_t *retval) { /* { syscallarg(netbsd32_charp) path; syscallarg(int) name; } */ struct sys_pathconf_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(name); return sys_pathconf(l, &ua, retval); } int netbsd32_fpathconf(struct lwp *l, const struct netbsd32_fpathconf_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) name; } */ struct sys_fpathconf_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(name); return sys_fpathconf(l, &ua, retval); } static void fixlimit(int which, struct rlimit *alim) { switch (which) { case RLIMIT_DATA: if (LIMITCHECK(alim->rlim_cur, MAXDSIZ32)) alim->rlim_cur = MAXDSIZ32; if (LIMITCHECK(alim->rlim_max, MAXDSIZ32)) alim->rlim_max = MAXDSIZ32; return; case RLIMIT_STACK: if (LIMITCHECK(alim->rlim_cur, MAXSSIZ32)) alim->rlim_cur = MAXSSIZ32; if (LIMITCHECK(alim->rlim_max, MAXSSIZ32)) alim->rlim_max = MAXSSIZ32; return; default: return; } } int netbsd32_getrlimit(struct lwp *l, const struct netbsd32_getrlimit_args *uap, register_t *retval) { /* { syscallarg(int) which; syscallarg(netbsd32_rlimitp_t) rlp; } */ int which = SCARG(uap, which); struct rlimit alim; if ((u_int)which >= RLIM_NLIMITS) return EINVAL; alim = l->l_proc->p_rlimit[which]; fixlimit(which, &alim); return copyout(&alim, SCARG_P32(uap, rlp), sizeof(alim)); } int netbsd32_setrlimit(struct lwp *l, const struct netbsd32_setrlimit_args *uap, register_t *retval) { /* { syscallarg(int) which; syscallarg(const netbsd32_rlimitp_t) rlp; } */ int which = SCARG(uap, which); struct rlimit alim; int error; if ((u_int)which >= RLIM_NLIMITS) return EINVAL; error = copyin(SCARG_P32(uap, rlp), &alim, sizeof(struct rlimit)); if (error) return (error); fixlimit(which, &alim); return dosetrlimit(l, l->l_proc, which, &alim); } int netbsd32_mmap(struct lwp *l, const struct netbsd32_mmap_args *uap, register_t *retval) { /* { syscallarg(netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; syscallarg(int) prot; syscallarg(int) flags; syscallarg(int) fd; syscallarg(netbsd32_long) PAD; syscallarg(netbsd32_off_t) pos; } */ struct sys_mmap_args ua; int error; NETBSD32TOP_UAP(addr, void); NETBSD32TOX_UAP(len, size_t); NETBSD32TO64_UAP(prot); NETBSD32TO64_UAP(flags); #ifdef __x86_64__ /* * Ancient kernel on x86 did not obey PROT_EXEC on i386 at least * and ld.so did not turn it on! */ if (SCARG(&ua, flags) & COMPAT_MAP_COPY) { SCARG(&ua, flags) = MAP_PRIVATE | (SCARG(&ua, flags) & ~COMPAT_MAP_COPY); SCARG(&ua, prot) |= PROT_EXEC; } #endif NETBSD32TO64_UAP(fd); NETBSD32TOX_UAP(PAD, long); NETBSD32TOX_UAP(pos, off_t); #ifdef DEBUG_MMAP printf("mmap(addr=0x%lx, len=0x%lx, prot=0x%lx, flags=0x%lx, " "fd=%ld, pos=0x%lx);\n", (long)SCARG(&ua, addr), (long)SCARG(&ua, len), (long)SCARG(&ua, prot), (long)SCARG(&ua, flags), (long)SCARG(&ua, fd), (long)SCARG(&ua, pos)); #endif error = sys_mmap(l, &ua, retval); if ((u_long)*retval > (u_long)UINT_MAX) { printf("netbsd32_mmap: retval out of range: 0x%lx\n", (u_long)*retval); /* Should try to recover and return an error here. */ } return (error); } int netbsd32_mremap(struct lwp *l, const struct netbsd32_mremap_args *uap, register_t *retval) { /* { syscallarg(void *) old_address; syscallarg(size_t) old_size; syscallarg(void *) new_address; syscallarg(size_t) new_size; syscallarg(int) flags; } */ struct sys_mremap_args ua; NETBSD32TOP_UAP(old_address, void); NETBSD32TOX_UAP(old_size, size_t); NETBSD32TOP_UAP(new_address, void); NETBSD32TOX_UAP(new_size, size_t); NETBSD32TO64_UAP(flags); return sys_mremap(l, &ua, retval); } int netbsd32_lseek(struct lwp *l, const struct netbsd32_lseek_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) PAD; syscallarg(netbsd32_off_t) offset; syscallarg(int) whence; } */ struct sys_lseek_args ua; union { register_t retval64[2]; register32_t retval32[4]; } newpos; int rv; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(PAD); NETBSD32TO64_UAP(offset); NETBSD32TO64_UAP(whence); rv = sys_lseek(l, &ua, newpos.retval64); /* * We have to split the 64 bit value into 2 halves which will * end up in separate 32 bit registers. * This should DTRT on big and little-endian systems provided that * gcc's 'strict aliasing' tests don't decide that the retval32[] * entries can't have been assigned to, so need not be read! */ retval[0] = newpos.retval32[0]; retval[1] = newpos.retval32[1]; return rv; } int netbsd32_truncate(struct lwp *l, const struct netbsd32_truncate_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) PAD; syscallarg(netbsd32_off_t) length; } */ struct sys_truncate_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(PAD); NETBSD32TO64_UAP(length); return (sys_truncate(l, &ua, retval)); } int netbsd32_ftruncate(struct lwp *l, const struct netbsd32_ftruncate_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) PAD; syscallarg(netbsd32_off_t) length; } */ struct sys_ftruncate_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(PAD); NETBSD32TO64_UAP(length); return (sys_ftruncate(l, &ua, retval)); } int netbsd32_mlock(struct lwp *l, const struct netbsd32_mlock_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; } */ struct sys_mlock_args ua; NETBSD32TOP_UAP(addr, const void); NETBSD32TO64_UAP(len); return (sys_mlock(l, &ua, retval)); } int netbsd32_munlock(struct lwp *l, const struct netbsd32_munlock_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; } */ struct sys_munlock_args ua; NETBSD32TOP_UAP(addr, const void); NETBSD32TO64_UAP(len); return (sys_munlock(l, &ua, retval)); } int netbsd32_undelete(struct lwp *l, const struct netbsd32_undelete_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; } */ struct sys_undelete_args ua; NETBSD32TOP_UAP(path, const char); return (sys_undelete(l, &ua, retval)); } int netbsd32_getpgid(struct lwp *l, const struct netbsd32_getpgid_args *uap, register_t *retval) { /* { syscallarg(pid_t) pid; } */ struct sys_getpgid_args ua; NETBSD32TO64_UAP(pid); return (sys_getpgid(l, &ua, retval)); } int netbsd32_reboot(struct lwp *l, const struct netbsd32_reboot_args *uap, register_t *retval) { /* { syscallarg(int) opt; syscallarg(netbsd32_charp) bootstr; } */ struct sys_reboot_args ua; NETBSD32TO64_UAP(opt); NETBSD32TOP_UAP(bootstr, char); return (sys_reboot(l, &ua, retval)); } #include int netbsd32_poll(struct lwp *l, const struct netbsd32_poll_args *uap, register_t *retval) { /* { syscallarg(netbsd32_pollfdp_t) fds; syscallarg(u_int) nfds; syscallarg(int) timeout; } */ struct sys_poll_args ua; NETBSD32TOP_UAP(fds, struct pollfd); NETBSD32TO64_UAP(nfds); NETBSD32TO64_UAP(timeout); return (sys_poll(l, &ua, retval)); } int netbsd32_fdatasync(struct lwp *l, const struct netbsd32_fdatasync_args *uap, register_t *retval) { /* { syscallarg(int) fd; } */ struct sys_fdatasync_args ua; NETBSD32TO64_UAP(fd); return (sys_fdatasync(l, &ua, retval)); } int netbsd32___posix_rename(struct lwp *l, const struct netbsd32___posix_rename_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) from; syscallarg(const netbsd32_charp) to; } */ struct sys___posix_rename_args ua; NETBSD32TOP_UAP(from, const char); NETBSD32TOP_UAP(to, const char); return (sys___posix_rename(l, &ua, retval)); } static int netbsd32_swapctl_stats(struct lwp *l, struct sys_swapctl_args *uap, register_t *retval) { struct swapent *ksep; struct netbsd32_swapent *usep32; struct netbsd32_swapent se32; int count = SCARG(uap, misc); int i, error = 0; size_t ksep_len; if (count < 0) return EINVAL; swapsys_lock(RW_WRITER); if ((size_t)count > (size_t)uvmexp.nswapdev) count = uvmexp.nswapdev; if (count == 0) { /* No swap device */ swapsys_unlock(); return 0; } ksep_len = sizeof(*ksep) * count; ksep = kmem_zalloc(ksep_len, KM_SLEEP); usep32 = (struct netbsd32_swapent *)SCARG(uap, arg); uvm_swap_stats(SWAP_STATS, ksep, count, retval); count = *retval; swapsys_unlock(); for (i = 0; i < count; i++) { se32.se_dev = ksep[i].se_dev; se32.se_flags = ksep[i].se_flags; se32.se_nblks = ksep[i].se_nblks; se32.se_inuse = ksep[i].se_inuse; se32.se_priority = ksep[i].se_priority; memcpy(se32.se_path, ksep[i].se_path, sizeof(se32.se_path)); error = copyout(&se32, usep32 + i, sizeof(se32)); if (error) break; } kmem_free(ksep, ksep_len); return error; } int netbsd32_swapctl(struct lwp *l, const struct netbsd32_swapctl_args *uap, register_t *retval) { /* { syscallarg(int) cmd; syscallarg(const netbsd32_voidp) arg; syscallarg(int) misc; } */ struct sys_swapctl_args ua; NETBSD32TO64_UAP(cmd); NETBSD32TOP_UAP(arg, void); NETBSD32TO64_UAP(misc); /* SWAP_STATS50 and SWAP_STATS13 structures need no translation */ if (SCARG(&ua, cmd) == SWAP_STATS) return netbsd32_swapctl_stats(l, &ua, retval); return (sys_swapctl(l, &ua, retval)); } int netbsd32_minherit(struct lwp *l, const struct netbsd32_minherit_args *uap, register_t *retval) { /* { syscallarg(netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; syscallarg(int) inherit; } */ struct sys_minherit_args ua; NETBSD32TOP_UAP(addr, void); NETBSD32TOX_UAP(len, size_t); NETBSD32TO64_UAP(inherit); return (sys_minherit(l, &ua, retval)); } int netbsd32_lchmod(struct lwp *l, const struct netbsd32_lchmod_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(mode_t) mode; } */ struct sys_lchmod_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(mode); return (sys_lchmod(l, &ua, retval)); } int netbsd32_lchown(struct lwp *l, const struct netbsd32_lchown_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(uid_t) uid; syscallarg(gid_t) gid; } */ struct sys_lchown_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(uid); NETBSD32TO64_UAP(gid); return (sys_lchown(l, &ua, retval)); } int netbsd32___msync13(struct lwp *l, const struct netbsd32___msync13_args *uap, register_t *retval) { /* { syscallarg(netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; syscallarg(int) flags; } */ struct sys___msync13_args ua; NETBSD32TOP_UAP(addr, void); NETBSD32TOX_UAP(len, size_t); NETBSD32TO64_UAP(flags); return (sys___msync13(l, &ua, retval)); } int netbsd32___posix_chown(struct lwp *l, const struct netbsd32___posix_chown_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(uid_t) uid; syscallarg(gid_t) gid; } */ struct sys___posix_chown_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(uid); NETBSD32TO64_UAP(gid); return (sys___posix_chown(l, &ua, retval)); } int netbsd32___posix_fchown(struct lwp *l, const struct netbsd32___posix_fchown_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(uid_t) uid; syscallarg(gid_t) gid; } */ struct sys___posix_fchown_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(uid); NETBSD32TO64_UAP(gid); return (sys___posix_fchown(l, &ua, retval)); } int netbsd32___posix_lchown(struct lwp *l, const struct netbsd32___posix_lchown_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(uid_t) uid; syscallarg(gid_t) gid; } */ struct sys___posix_lchown_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(uid); NETBSD32TO64_UAP(gid); return (sys___posix_lchown(l, &ua, retval)); } int netbsd32_getsid(struct lwp *l, const struct netbsd32_getsid_args *uap, register_t *retval) { /* { syscallarg(pid_t) pid; } */ struct sys_getsid_args ua; NETBSD32TO64_UAP(pid); return (sys_getsid(l, &ua, retval)); } int netbsd32_fktrace(struct lwp *l, const struct netbsd32_fktrace_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) ops; syscallarg(int) facs; syscallarg(int) pid; } */ struct sys_fktrace_args ua; NETBSD32TOX_UAP(fd, int); NETBSD32TO64_UAP(ops); NETBSD32TO64_UAP(facs); NETBSD32TO64_UAP(pid); return (sys_fktrace(l, &ua, retval)); } int netbsd32___sigpending14(struct lwp *l, const struct netbsd32___sigpending14_args *uap, register_t *retval) { /* { syscallarg(sigset_t *) set; } */ struct sys___sigpending14_args ua; NETBSD32TOP_UAP(set, sigset_t); return (sys___sigpending14(l, &ua, retval)); } int netbsd32___sigprocmask14(struct lwp *l, const struct netbsd32___sigprocmask14_args *uap, register_t *retval) { /* { syscallarg(int) how; syscallarg(const sigset_t *) set; syscallarg(sigset_t *) oset; } */ struct sys___sigprocmask14_args ua; NETBSD32TO64_UAP(how); NETBSD32TOP_UAP(set, sigset_t); NETBSD32TOP_UAP(oset, sigset_t); return (sys___sigprocmask14(l, &ua, retval)); } int netbsd32___sigsuspend14(struct lwp *l, const struct netbsd32___sigsuspend14_args *uap, register_t *retval) { /* { syscallarg(const sigset_t *) set; } */ struct sys___sigsuspend14_args ua; NETBSD32TOP_UAP(set, sigset_t); return (sys___sigsuspend14(l, &ua, retval)); } int netbsd32_fchroot(struct lwp *l, const struct netbsd32_fchroot_args *uap, register_t *retval) { /* { syscallarg(int) fd; } */ struct sys_fchroot_args ua; NETBSD32TO64_UAP(fd); return (sys_fchroot(l, &ua, retval)); } /* * Open a file given a file handle. * * Check permissions, allocate an open file structure, * and call the device open routine if any. */ int netbsd32___fhopen40(struct lwp *l, const struct netbsd32___fhopen40_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_pointer_t *) fhp; syscallarg(netbsd32_size_t) fh_size; syscallarg(int) flags; } */ struct sys___fhopen40_args ua; NETBSD32TOP_UAP(fhp, fhandle_t); NETBSD32TO64_UAP(fh_size); NETBSD32TO64_UAP(flags); return (sys___fhopen40(l, &ua, retval)); } /* virtual memory syscalls */ int netbsd32_ovadvise(struct lwp *l, const struct netbsd32_ovadvise_args *uap, register_t *retval) { /* { syscallarg(int) anom; } */ struct sys_ovadvise_args ua; NETBSD32TO64_UAP(anom); return (sys_ovadvise(l, &ua, retval)); } void netbsd32_adjust_limits(struct proc *p) { static const struct { int id; rlim_t lim; } lm[] = { { RLIMIT_DATA, MAXDSIZ32 }, { RLIMIT_STACK, MAXSSIZ32 }, }; size_t i; struct plimit *lim; struct rlimit *rlim; /* * We can only reduce the current limits, we cannot stop external * processes from changing them (eg via sysctl) later on. * So there is no point trying to lock out such changes here. * * If we assume that rlim_cur/max are accessed using atomic * operations, we don't need to lock against any other updates * that might happen if the plimit structure is shared writable * between multiple processes. */ /* Scan to determine is any limits are out of range */ lim = p->p_limit; for (i = 0; ; i++) { if (i >= __arraycount(lm)) /* All in range */ return; rlim = lim->pl_rlimit + lm[i].id; if (LIMITCHECK(rlim->rlim_cur, lm[i].lim)) break; if (LIMITCHECK(rlim->rlim_max, lm[i].lim)) break; } lim_privatise(p); lim = p->p_limit; for (i = 0; i < __arraycount(lm); i++) { rlim = lim->pl_rlimit + lm[i].id; if (LIMITCHECK(rlim->rlim_cur, lm[i].lim)) rlim->rlim_cur = lm[i].lim; if (LIMITCHECK(rlim->rlim_max, lm[i].lim)) rlim->rlim_max = lm[i].lim; } } int netbsd32_uuidgen(struct lwp *l, const struct netbsd32_uuidgen_args *uap, register_t *retval) { /* { syscallarg(netbsd32_uuidp_t) store; syscallarg(int) count; } */ struct sys_uuidgen_args ua; NETBSD32TOP_UAP(store, struct uuid); NETBSD32TO64_UAP(count); return (sys_uuidgen(l, &ua, retval)); } int netbsd32_extattrctl(struct lwp *l, const struct netbsd32_extattrctl_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) cmd; syscallarg(const netbsd32_charp) filename; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; } */ struct sys_extattrctl_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(cmd); NETBSD32TOP_UAP(filename, const char); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); return sys_extattrctl(l, &ua, retval); } int netbsd32_extattr_set_fd(struct lwp *l, const struct netbsd32_extattr_set_fd_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; syscallarg(const netbsd32_voidp) data; syscallarg(netbsd32_size_t) nbytes; } */ struct sys_extattr_set_fd_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); NETBSD32TOP_UAP(data, const void); NETBSD32TOX_UAP(nbytes, size_t); return sys_extattr_set_fd(l, &ua, retval); } int netbsd32_extattr_set_file(struct lwp *l, const struct netbsd32_extattr_set_file_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; syscallarg(const netbsd32_voidp) data; syscallarg(netbsd32_size_t) nbytes; } */ struct sys_extattr_set_file_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); NETBSD32TOP_UAP(data, const void); NETBSD32TOX_UAP(nbytes, size_t); return sys_extattr_set_file(l, &ua, retval); } int netbsd32_extattr_set_link(struct lwp *l, const struct netbsd32_extattr_set_link_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; syscallarg(const netbsd32_voidp) data; syscallarg(netbsd32_size_t) nbytes; } */ struct sys_extattr_set_link_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); NETBSD32TOP_UAP(data, const void); NETBSD32TOX_UAP(nbytes, size_t); return sys_extattr_set_link(l, &ua, retval); } int netbsd32_extattr_get_fd(struct lwp *l, const struct netbsd32_extattr_get_fd_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; syscallarg(netbsd32_voidp) data; syscallarg(netbsd32_size_t) nbytes; } */ struct sys_extattr_get_fd_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); NETBSD32TOP_UAP(data, void); NETBSD32TOX_UAP(nbytes, size_t); return sys_extattr_get_fd(l, &ua, retval); } int netbsd32_extattr_get_file(struct lwp *l, const struct netbsd32_extattr_get_file_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; syscallarg(netbsd32_voidp) data; syscallarg(netbsd32_size_t) nbytes; } */ struct sys_extattr_get_file_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); NETBSD32TOP_UAP(data, void); NETBSD32TOX_UAP(nbytes, size_t); return sys_extattr_get_file(l, &ua, retval); } int netbsd32_extattr_get_link(struct lwp *l, const struct netbsd32_extattr_get_link_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; syscallarg(netbsd32_voidp) data; syscallarg(netbsd32_size_t) nbytes; } */ struct sys_extattr_get_link_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); NETBSD32TOP_UAP(data, void); NETBSD32TOX_UAP(nbytes, size_t); return sys_extattr_get_link(l, &ua, retval); } int netbsd32_extattr_delete_fd(struct lwp *l, const struct netbsd32_extattr_delete_fd_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; } */ struct sys_extattr_delete_fd_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); return sys_extattr_delete_fd(l, &ua, retval); } int netbsd32_extattr_delete_file(struct lwp *l, const struct netbsd32_extattr_delete_file_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; } */ struct sys_extattr_delete_file_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); return sys_extattr_delete_file(l, &ua, retval); } int netbsd32_extattr_delete_link(struct lwp *l, const struct netbsd32_extattr_delete_link_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) attrnamespace; syscallarg(const netbsd32_charp) attrname; } */ struct sys_extattr_delete_link_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(attrname, const char); return sys_extattr_delete_link(l, &ua, retval); } int netbsd32_extattr_list_fd(struct lwp *l, const struct netbsd32_extattr_list_fd_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) attrnamespace; syscallarg(netbsd32_voidp) data; syscallarg(netbsd32_size_t) nbytes; } */ struct sys_extattr_list_fd_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(data, void); NETBSD32TOX_UAP(nbytes, size_t); return sys_extattr_list_fd(l, &ua, retval); } int netbsd32_extattr_list_file(struct lwp *l, const struct netbsd32_extattr_list_file_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) attrnamespace; syscallarg(netbsd32_voidp) data; syscallarg(netbsd32_size_t) nbytes; } */ struct sys_extattr_list_file_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(data, void); NETBSD32TOX_UAP(nbytes, size_t); return sys_extattr_list_file(l, &ua, retval); } int netbsd32_extattr_list_link(struct lwp *l, const struct netbsd32_extattr_list_link_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(int) attrnamespace; syscallarg(netbsd32_voidp) data; syscallarg(netbsd32_size_t) nbytes; } */ struct sys_extattr_list_link_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TO64_UAP(attrnamespace); NETBSD32TOP_UAP(data, void); NETBSD32TOX_UAP(nbytes, size_t); return sys_extattr_list_link(l, &ua, retval); } int netbsd32_mlockall(struct lwp *l, const struct netbsd32_mlockall_args *uap, register_t *retval) { /* { syscallarg(int) flags; } */ struct sys_mlockall_args ua; NETBSD32TO64_UAP(flags); return (sys_mlockall(l, &ua, retval)); } int netbsd32___clone(struct lwp *l, const struct netbsd32___clone_args *uap, register_t *retval) { /* { syscallarg(int) flags; syscallarg(netbsd32_voidp) stack; } */ struct sys___clone_args ua; NETBSD32TO64_UAP(flags); NETBSD32TOP_UAP(stack, void); return sys___clone(l, &ua, retval); } int netbsd32_fsync_range(struct lwp *l, const struct netbsd32_fsync_range_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) flags; syscallarg(off_t) start; syscallarg(off_t) length; } */ struct sys_fsync_range_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(flags); NETBSD32TO64_UAP(start); NETBSD32TO64_UAP(length); return (sys_fsync_range(l, &ua, retval)); } int netbsd32_rasctl(struct lwp *l, const struct netbsd32_rasctl_args *uap, register_t *retval) { /* { syscallarg(netbsd32_voidp) addr; syscallarg(netbsd32_size_t) len; syscallarg(int) op; } */ struct sys_rasctl_args ua; NETBSD32TOP_UAP(addr, void *); NETBSD32TOX_UAP(len, size_t); NETBSD32TO64_UAP(op); return sys_rasctl(l, &ua, retval); } int netbsd32_setxattr(struct lwp *l, const struct netbsd32_setxattr_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(const netbsd32_charp) name; syscallarg(netbsd32_voidp) value; syscallarg(netbsd32_size_t) size; syscallarg(int) flags; } */ struct sys_setxattr_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(name, const char); NETBSD32TOP_UAP(value, void); NETBSD32TOX_UAP(size, size_t); NETBSD32TO64_UAP(flags); return sys_setxattr(l, &ua, retval); } int netbsd32_lsetxattr(struct lwp *l, const struct netbsd32_lsetxattr_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(const netbsd32_charp) name; syscallarg(netbsd32_voidp) value; syscallarg(netbsd32_size_t) size; syscallarg(int) flags; } */ struct sys_lsetxattr_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(name, const char); NETBSD32TOP_UAP(value, void); NETBSD32TOX_UAP(size, size_t); NETBSD32TO64_UAP(flags); return sys_lsetxattr(l, &ua, retval); } int netbsd32_fsetxattr(struct lwp *l, const struct netbsd32_fsetxattr_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(const netbsd32_charp) name; syscallarg(netbsd32_voidp) value; syscallarg(netbsd32_size_t) size; syscallarg(int) flags; } */ struct sys_fsetxattr_args ua; NETBSD32TO64_UAP(fd); NETBSD32TOP_UAP(name, const char); NETBSD32TOP_UAP(value, void); NETBSD32TOX_UAP(size, size_t); NETBSD32TO64_UAP(flags); return sys_fsetxattr(l, &ua, retval); } int netbsd32_getxattr(struct lwp *l, const struct netbsd32_getxattr_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(const netbsd32_charp) name; syscallarg(netbsd32_voidp) value; syscallarg(netbsd32_size_t) size; } */ struct sys_getxattr_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(name, const char); NETBSD32TOP_UAP(value, void); NETBSD32TOX_UAP(size, size_t); return sys_getxattr(l, &ua, retval); } int netbsd32_lgetxattr(struct lwp *l, const struct netbsd32_lgetxattr_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(const netbsd32_charp) name; syscallarg(netbsd32_voidp) value; syscallarg(netbsd32_size_t) size; } */ struct sys_lgetxattr_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(name, const char); NETBSD32TOP_UAP(value, void); NETBSD32TOX_UAP(size, size_t); return sys_lgetxattr(l, &ua, retval); } int netbsd32_fgetxattr(struct lwp *l, const struct netbsd32_fgetxattr_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(const netbsd32_charp) name; syscallarg(netbsd32_voidp) value; syscallarg(netbsd32_size_t) size; } */ struct sys_fgetxattr_args ua; NETBSD32TO64_UAP(fd); NETBSD32TOP_UAP(name, const char); NETBSD32TOP_UAP(value, void); NETBSD32TOX_UAP(size, size_t); return sys_fgetxattr(l, &ua, retval); } int netbsd32_listxattr(struct lwp *l, const struct netbsd32_listxattr_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(netbsd32_charp) list; syscallarg(netbsd32_size_t) size; } */ struct sys_listxattr_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(list, char); NETBSD32TOX_UAP(size, size_t); return sys_listxattr(l, &ua, retval); } int netbsd32_llistxattr(struct lwp *l, const struct netbsd32_llistxattr_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(netbsd32_charp) list; syscallarg(netbsd32_size_t) size; } */ struct sys_llistxattr_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(list, char); NETBSD32TOX_UAP(size, size_t); return sys_llistxattr(l, &ua, retval); } int netbsd32_flistxattr(struct lwp *l, const struct netbsd32_flistxattr_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(netbsd32_charp) list; syscallarg(netbsd32_size_t) size; } */ struct sys_flistxattr_args ua; NETBSD32TO64_UAP(fd); NETBSD32TOP_UAP(list, char); NETBSD32TOX_UAP(size, size_t); return sys_flistxattr(l, &ua, retval); } int netbsd32_removexattr(struct lwp *l, const struct netbsd32_removexattr_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(const netbsd32_charp) name; } */ struct sys_removexattr_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(name, const char); return sys_removexattr(l, &ua, retval); } int netbsd32_lremovexattr(struct lwp *l, const struct netbsd32_lremovexattr_args *uap, register_t *retval) { /* { syscallarg(const netbsd32_charp) path; syscallarg(const netbsd32_charp) name; } */ struct sys_lremovexattr_args ua; NETBSD32TOP_UAP(path, const char); NETBSD32TOP_UAP(name, const char); return sys_lremovexattr(l, &ua, retval); } int netbsd32_fremovexattr(struct lwp *l, const struct netbsd32_fremovexattr_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(const netbsd32_charp) name; } */ struct sys_fremovexattr_args ua; NETBSD32TO64_UAP(fd); NETBSD32TOP_UAP(name, const char); return sys_fremovexattr(l, &ua, retval); } int netbsd32___posix_fadvise50(struct lwp *l, const struct netbsd32___posix_fadvise50_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(int) PAD; syscallarg(netbsd32_off_t) offset; syscallarg(netbsd32_off_t) len; syscallarg(int) advice; } */ *retval = do_posix_fadvise(SCARG(uap, fd), SCARG(uap, offset), SCARG(uap, len), SCARG(uap, advice)); return 0; } int netbsd32__sched_setparam(struct lwp *l, const struct netbsd32__sched_setparam_args *uap, register_t *retval) { /* { syscallarg(pid_t) pid; syscallarg(lwpid_t) lid; syscallarg(int) policy; syscallarg(const netbsd32_sched_paramp_t) params; } */ struct sys__sched_setparam_args ua; NETBSD32TO64_UAP(pid); NETBSD32TO64_UAP(lid); NETBSD32TO64_UAP(policy); NETBSD32TOP_UAP(params, const struct sched_param *); return sys__sched_setparam(l, &ua, retval); } int netbsd32__sched_getparam(struct lwp *l, const struct netbsd32__sched_getparam_args *uap, register_t *retval) { /* { syscallarg(pid_t) pid; syscallarg(lwpid_t) lid; syscallarg(netbsd32_intp) policy; syscallarg(netbsd32_sched_paramp_t) params; } */ struct sys__sched_getparam_args ua; NETBSD32TO64_UAP(pid); NETBSD32TO64_UAP(lid); NETBSD32TOP_UAP(policy, int *); NETBSD32TOP_UAP(params, struct sched_param *); return sys__sched_getparam(l, &ua, retval); } int netbsd32__sched_setaffinity(struct lwp *l, const struct netbsd32__sched_setaffinity_args *uap, register_t *retval) { /* { syscallarg(pid_t) pid; syscallarg(lwpid_t) lid; syscallarg(netbsd_size_t) size; syscallarg(const netbsd32_cpusetp_t) cpuset; } */ struct sys__sched_setaffinity_args ua; NETBSD32TO64_UAP(pid); NETBSD32TO64_UAP(lid); NETBSD32TOX_UAP(size, size_t); NETBSD32TOP_UAP(cpuset, const cpuset_t *); return sys__sched_setaffinity(l, &ua, retval); } int netbsd32__sched_getaffinity(struct lwp *l, const struct netbsd32__sched_getaffinity_args *uap, register_t *retval) { /* { syscallarg(pid_t) pid; syscallarg(lwpid_t) lid; syscallarg(netbsd_size_t) size; syscallarg(netbsd32_cpusetp_t) cpuset; } */ struct sys__sched_getaffinity_args ua; NETBSD32TO64_UAP(pid); NETBSD32TO64_UAP(lid); NETBSD32TOX_UAP(size, size_t); NETBSD32TOP_UAP(cpuset, cpuset_t *); return sys__sched_getaffinity(l, &ua, retval); } int netbsd32__sched_protect(struct lwp *l, const struct netbsd32__sched_protect_args *uap, register_t *retval) { /* { syscallarg(int) priority; } */ struct sys__sched_protect_args ua; NETBSD32TO64_UAP(priority); return sys__sched_protect(l, &ua, retval); } int netbsd32_pipe2(struct lwp *l, const struct netbsd32_pipe2_args *uap, register_t *retval) { /* { syscallarg(netbsd32_intp) fildes; syscallarg(int) flags; } */ int fd[2], error; error = pipe1(l, retval, SCARG(uap, flags)); if (error != 0) return error; fd[0] = retval[0]; fd[1] = retval[1]; error = copyout(fd, SCARG_P32(uap, fildes), sizeof(fd)); if (error != 0) return error; retval[0] = 0; return 0; } int netbsd32_dup3(struct lwp *l, const struct netbsd32_dup3_args *uap, register_t *retval) { /* { syscallarg(int) from; syscallarg(int) to; syscallarg(int) flags; } */ struct sys_dup3_args ua; NETBSD32TO64_UAP(from); NETBSD32TO64_UAP(to); NETBSD32TO64_UAP(flags); return sys_dup3(l, &ua, retval); } int netbsd32_kqueue1(struct lwp *l, const struct netbsd32_kqueue1_args *uap, register_t *retval) { /* { syscallarg(int) flags; } */ struct sys_kqueue1_args ua; NETBSD32TO64_UAP(flags); return sys_kqueue1(l, &ua, retval); } int netbsd32_paccept(struct lwp *l, const struct netbsd32_paccept_args *uap, register_t *retval) { /* { syscallarg(int) s; syscallarg(netbsd32_sockaddrp_t) name; syscallarg(netbsd32_socklenp_t) anamelen; syscallarg(const netbsd32_sigsetp_t) mask; syscallarg(int) flags; } */ struct sys_paccept_args ua; NETBSD32TO64_UAP(s); NETBSD32TOP_UAP(name, struct sockaddr *); NETBSD32TOP_UAP(anamelen, socklen_t *); NETBSD32TOP_UAP(mask, const sigset_t *); NETBSD32TO64_UAP(flags); return sys_paccept(l, &ua, retval); } int netbsd32_fdiscard(struct lwp *l, const struct netbsd32_fdiscard_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(netbsd32_off_t) pos; syscallarg(netbsd32_off_t) len; } */ struct sys_fdiscard_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(pos); NETBSD32TO64_UAP(len); return sys_fdiscard(l, &ua, retval); } int netbsd32_posix_fallocate(struct lwp *l, const struct netbsd32_posix_fallocate_args *uap, register_t *retval) { /* { syscallarg(int) fd; syscallarg(netbsd32_off_t) pos; syscallarg(netbsd32_off_t) len; } */ struct sys_posix_fallocate_args ua; NETBSD32TO64_UAP(fd); NETBSD32TO64_UAP(pos); NETBSD32TO64_UAP(len); return sys_posix_fallocate(l, &ua, retval); } int netbsd32_pset_create(struct lwp *l, const struct netbsd32_pset_create_args *uap, register_t *retval) { /* { syscallarg(netbsd32_psetidp_t) psid; }; */ struct sys_pset_create_args ua; NETBSD32TOP_UAP(psid, psetid_t); return sys_pset_create(l, &ua, retval); } int netbsd32_pset_destroy(struct lwp *l, const struct netbsd32_pset_destroy_args *uap, register_t *retval) { /* { syscallarg(psetid_t) psid; }; */ return sys_pset_destroy(l, (const void *)uap, retval); } int netbsd32_pset_assign(struct lwp *l, const struct netbsd32_pset_assign_args *uap, register_t *retval) { /* { syscallarg(psetid_t) psid; syscallarg(cpuid_t) cpuid; syscallarg(netbsd32_psetidp_t) opsid; }; */ struct sys_pset_assign_args ua; SCARG(&ua, psid) = SCARG(uap, psid); NETBSD32TO64_UAP(cpuid); NETBSD32TOP_UAP(opsid, psetid_t); return sys_pset_assign(l, &ua, retval); } int netbsd32__pset_bind(struct lwp *l, const struct netbsd32__pset_bind_args *uap, register_t *retval) { /* { syscallarg(idtype_t) idtype; syscallarg(id_t) first_id; syscallarg(id_t) second_id; syscallarg(psetid_t) psid; syscallarg(netbsd32_psetidp_t) opsid; }; */ struct sys__pset_bind_args ua; SCARG(&ua, idtype) = SCARG(uap, idtype); SCARG(&ua, first_id) = SCARG(uap, first_id); SCARG(&ua, second_id) = SCARG(uap, second_id); SCARG(&ua, psid) = SCARG(uap, psid); NETBSD32TOP_UAP(opsid, psetid_t); return sys__pset_bind(l, &ua, retval); } /* * MI indirect system call support. * Only used if the MD netbsd32_syscall.c doesn't intercept the calls. */ #define NETBSD32_SYSCALL #undef SYS_NSYSENT #define SYS_NSYSENT NETBSD32_SYS_NSYSENT #define SYS_SYSCALL netbsd32_syscall #include "../../kern/sys_syscall.c" #undef SYS_SYSCALL #define SYS_SYSCALL netbsd32____syscall #include "../../kern/sys_syscall.c" #undef SYS_SYSCALL