qemu/linux-user/syscall_defs.h

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/* common syscall defines for all architectures */
/* Note: although the syscall numbers change between architectures,
most of them stay the same, so we handle it by putting ifdefs if
necessary */
#ifndef SYSCALL_DEFS_H
#define SYSCALL_DEFS_H
#include "syscall_nr.h"
/* socket operations for socketcall() */
#define TARGET_SYS_SOCKET 1 /* socket() */
#define TARGET_SYS_BIND 2 /* bind() */
#define TARGET_SYS_CONNECT 3 /* connect() */
#define TARGET_SYS_LISTEN 4 /* listen() */
#define TARGET_SYS_ACCEPT 5 /* accept() */
#define TARGET_SYS_GETSOCKNAME 6 /* getsockname() */
#define TARGET_SYS_GETPEERNAME 7 /* getpeername() */
#define TARGET_SYS_SOCKETPAIR 8 /* socketpair() */
#define TARGET_SYS_SEND 9 /* send() */
#define TARGET_SYS_RECV 10 /* recv() */
#define TARGET_SYS_SENDTO 11 /* sendto() */
#define TARGET_SYS_RECVFROM 12 /* recvfrom() */
#define TARGET_SYS_SHUTDOWN 13 /* shutdown() */
#define TARGET_SYS_SETSOCKOPT 14 /* setsockopt() */
#define TARGET_SYS_GETSOCKOPT 15 /* getsockopt() */
#define TARGET_SYS_SENDMSG 16 /* sendmsg() */
#define TARGET_SYS_RECVMSG 17 /* recvmsg() */
#define TARGET_SYS_ACCEPT4 18 /* accept4() */
#define TARGET_SYS_RECVMMSG 19 /* recvmmsg() */
#define TARGET_SYS_SENDMMSG 20 /* sendmmsg() */
#define IPCOP_CALL(VERSION, OP) ((VERSION) << 16 | (OP))
#define IPCOP_semop 1
#define IPCOP_semget 2
#define IPCOP_semctl 3
#define IPCOP_semtimedop 4
#define IPCOP_msgsnd 11
#define IPCOP_msgrcv 12
#define IPCOP_msgget 13
#define IPCOP_msgctl 14
#define IPCOP_shmat 21
#define IPCOP_shmdt 22
#define IPCOP_shmget 23
#define IPCOP_shmctl 24
linux-user: Fix 'semop()' and 'semtimedop()' implementation The implementations of syscalls 'semop()' and 'semtimedop()' in file 'syscall.c' use function 'target_to_host_sembuf()' to convert values of 'struct sembuf' from host to target. However, before this conversion it should be check whether the number of semaphore operations 'nsops' is not bigger than maximum allowed semaphor operations per syscall: 'SEMOPM'. In these cases, errno 'E2BIG' ("Arg list too long") should be set. But the implementation will set errno 'EFAULT' ("Bad address") in this case since the conversion from target to host in this case fails. This was confirmed with the LTP test for 'semop()' ('ipc/semop/semop02') in test case where 'nsops' is greater than SEMOPM with unaproppriate errno EFAULT: semop02.c:130: FAIL: semop failed unexpectedly; expected: E2BIG: EFAULT (14) This patch changes this by adding a check whether 'nsops' is bigger than 'SEMOPM' before the conversion function 'target_to_host_sembuf()' is called. After the changes from this patch, the test works fine along with the other LTP testcases for 'semop()'): semop02.c:126: PASS: semop failed as expected: E2BIG (7) Implementation notes: A target value ('TARGET_SEMOPM') was added for 'SEMOPM' as to be sure in case the value is not available for some targets. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Reviewed-by: Laurent Vivier <laurent@vivier.eu> Message-Id: <20200818180722.45089-1-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-18 21:07:22 +03:00
#define TARGET_SEMOPM 500
/*
* The following is for compatibility across the various Linux
* platforms. The i386 ioctl numbering scheme doesn't really enforce
* a type field. De facto, however, the top 8 bits of the lower 16
* bits are indeed used as a type field, so we might just as well make
* this explicit here. Please be sure to use the decoding macros
* below from now on.
*/
#define TARGET_IOC_NRBITS 8
#define TARGET_IOC_TYPEBITS 8
#if (defined(TARGET_I386) && defined(TARGET_ABI32)) \
|| (defined(TARGET_ARM) && defined(TARGET_ABI32)) \
|| defined(TARGET_SPARC) \
|| defined(TARGET_M68K) || defined(TARGET_SH4) || defined(TARGET_CRIS)
/* 16 bit uid wrappers emulation */
#define USE_UID16
#define target_id uint16_t
#else
#define target_id uint32_t
#endif
#if defined(TARGET_I386) || defined(TARGET_ARM) || defined(TARGET_SH4) \
|| defined(TARGET_M68K) || defined(TARGET_CRIS) \
|| defined(TARGET_S390X) || defined(TARGET_OPENRISC) \
|| defined(TARGET_NIOS2) || defined(TARGET_RISCV) \
|| defined(TARGET_XTENSA)
#define TARGET_IOC_SIZEBITS 14
#define TARGET_IOC_DIRBITS 2
#define TARGET_IOC_NONE 0U
#define TARGET_IOC_WRITE 1U
#define TARGET_IOC_READ 2U
#elif defined(TARGET_PPC) || defined(TARGET_ALPHA) || \
defined(TARGET_SPARC) || defined(TARGET_MICROBLAZE) || \
defined(TARGET_MIPS)
#define TARGET_IOC_SIZEBITS 13
#define TARGET_IOC_DIRBITS 3
#define TARGET_IOC_NONE 1U
#define TARGET_IOC_READ 2U
#define TARGET_IOC_WRITE 4U
#elif defined(TARGET_HPPA)
#define TARGET_IOC_SIZEBITS 14
#define TARGET_IOC_DIRBITS 2
#define TARGET_IOC_NONE 0U
#define TARGET_IOC_WRITE 2U
#define TARGET_IOC_READ 1U
#elif defined(TARGET_HEXAGON)
#define TARGET_IOC_SIZEBITS 14
#define TARGET_IOC_NONE 0U
#define TARGET_IOC_WRITE 1U
#define TARGET_IOC_READ 2U
#else
#error unsupported CPU
#endif
#define TARGET_IOC_NRMASK ((1 << TARGET_IOC_NRBITS)-1)
#define TARGET_IOC_TYPEMASK ((1 << TARGET_IOC_TYPEBITS)-1)
#define TARGET_IOC_SIZEMASK ((1 << TARGET_IOC_SIZEBITS)-1)
#define TARGET_IOC_DIRMASK ((1 << TARGET_IOC_DIRBITS)-1)
#define TARGET_IOC_NRSHIFT 0
#define TARGET_IOC_TYPESHIFT (TARGET_IOC_NRSHIFT+TARGET_IOC_NRBITS)
#define TARGET_IOC_SIZESHIFT (TARGET_IOC_TYPESHIFT+TARGET_IOC_TYPEBITS)
#define TARGET_IOC_DIRSHIFT (TARGET_IOC_SIZESHIFT+TARGET_IOC_SIZEBITS)
#define TARGET_IOC(dir,type,nr,size) \
(((dir) << TARGET_IOC_DIRSHIFT) | \
((type) << TARGET_IOC_TYPESHIFT) | \
((nr) << TARGET_IOC_NRSHIFT) | \
((size) << TARGET_IOC_SIZESHIFT))
/* used to create numbers */
#define TARGET_IO(type,nr) TARGET_IOC(TARGET_IOC_NONE,(type),(nr),0)
#define TARGET_IOR(type,nr,size) TARGET_IOC(TARGET_IOC_READ,(type),(nr),sizeof(size))
#define TARGET_IOW(type,nr,size) TARGET_IOC(TARGET_IOC_WRITE,(type),(nr),sizeof(size))
#define TARGET_IOWR(type,nr,size) TARGET_IOC(TARGET_IOC_READ|TARGET_IOC_WRITE,(type),(nr),sizeof(size))
/* the size is automatically computed for these defines */
#define TARGET_IORU(type,nr) TARGET_IOC(TARGET_IOC_READ,(type),(nr),TARGET_IOC_SIZEMASK)
#define TARGET_IOWU(type,nr) TARGET_IOC(TARGET_IOC_WRITE,(type),(nr),TARGET_IOC_SIZEMASK)
#define TARGET_IOWRU(type,nr) TARGET_IOC(TARGET_IOC_READ|TARGET_IOC_WRITE,(type),(nr),TARGET_IOC_SIZEMASK)
struct target_sockaddr {
abi_ushort sa_family;
uint8_t sa_data[14];
};
struct target_sockaddr_ll {
abi_ushort sll_family; /* Always AF_PACKET */
abi_ushort sll_protocol; /* Physical layer protocol */
abi_int sll_ifindex; /* Interface number */
abi_ushort sll_hatype; /* ARP hardware type */
uint8_t sll_pkttype; /* Packet type */
uint8_t sll_halen; /* Length of address */
uint8_t sll_addr[8]; /* Physical layer address */
};
struct target_sockaddr_un {
abi_ushort su_family;
uint8_t sun_path[108];
};
struct target_sockaddr_nl {
abi_ushort nl_family; /* AF_NETLINK */
abi_ushort __pad;
abi_uint nl_pid;
abi_uint nl_groups;
};
struct target_in_addr {
abi_uint s_addr; /* big endian */
};
struct target_sockaddr_in {
abi_ushort sin_family;
abi_short sin_port; /* big endian */
struct target_in_addr sin_addr;
uint8_t __pad[sizeof(struct target_sockaddr) -
sizeof(abi_ushort) - sizeof(abi_short) -
sizeof(struct target_in_addr)];
};
struct target_sockaddr_in6 {
abi_ushort sin6_family;
abi_ushort sin6_port; /* big endian */
abi_uint sin6_flowinfo; /* big endian */
struct in6_addr sin6_addr; /* IPv6 address, big endian */
abi_uint sin6_scope_id;
};
struct target_sock_filter {
abi_ushort code;
uint8_t jt;
uint8_t jf;
abi_uint k;
};
struct target_sock_fprog {
abi_ushort len;
abi_ulong filter;
};
struct target_ip_mreq {
struct target_in_addr imr_multiaddr;
struct target_in_addr imr_address;
};
struct target_ip_mreqn {
struct target_in_addr imr_multiaddr;
struct target_in_addr imr_address;
abi_long imr_ifindex;
};
struct target_ip_mreq_source {
/* big endian */
uint32_t imr_multiaddr;
uint32_t imr_interface;
uint32_t imr_sourceaddr;
};
struct target_linger {
abi_int l_onoff; /* Linger active */
abi_int l_linger; /* How long to linger for */
};
#if defined(TARGET_SPARC64) && !defined(TARGET_ABI32)
struct target_timeval {
abi_long tv_sec;
abi_int tv_usec;
};
#define target__kernel_sock_timeval target_timeval
#else
struct target_timeval {
abi_long tv_sec;
abi_long tv_usec;
};
struct target__kernel_sock_timeval {
abi_llong tv_sec;
abi_llong tv_usec;
};
#endif
struct target_timespec {
abi_long tv_sec;
abi_long tv_nsec;
};
struct target__kernel_timespec {
abi_llong tv_sec;
abi_llong tv_nsec;
};
struct target_timezone {
abi_int tz_minuteswest;
abi_int tz_dsttime;
};
struct target_itimerval {
struct target_timeval it_interval;
struct target_timeval it_value;
};
struct target_itimerspec {
struct target_timespec it_interval;
struct target_timespec it_value;
};
linux-user: Add support for a group of 2038 safe syscalls This patch implements functionality for following time64 syscalls: *clock_getres_time64 This a year 2038 safe variant of syscall: int clock_getres(clockid_t clockid, struct timespec *res) --finding the resoultion of a specified clock-- man page: https://man7.org/linux/man-pages/man2/clock_getres.2.html *timer_gettime64 *timer_settime64 These are year 2038 safe variants of syscalls: int timer_settime(timer_t timerid, int flags, const struct itimerspec *new_value, struct itimerspec *old_value) int timer_gettime(timer_t timerid, struct itimerspec *curr_value) --arming/dissarming and fetching state of POSIX per-process timer-- man page: https://man7.org/linux/man-pages/man2/timer_settime.2.html *timerfd_gettime64 *timerfd_settime64 These are year 2038 safe variants of syscalls: int timerfd_settime(int fd, int flags, const struct itimerspec *new_value, struct itimerspec *old_value) int timerfd_gettime(int fd, struct itimerspec *curr_value) --timers that notify via file descriptor-- man page: https://man7.org/linux/man-pages/man2/timerfd_settime.2.html Implementation notes: Syscall 'clock_getres_time64' was implemented similarly to 'clock_getres()'. The only difference was that for the conversion of 'struct timespec' from host to target, function 'host_to_target_timespec64()' was used instead of 'host_to_target_timespec()'. For other syscalls, new functions 'host_to_target_itimerspec64()' and 'target_to_host_itimerspec64()' were added to convert the value of the 'struct itimerspec' from host to target and vice versa. A new type 'struct target__kernel_itimerspec' was added in 'syscall_defs.h'. This type was defined with fields which are of the already defined type 'struct target_timespec'. This new 'struct target__kernel_itimerspec' type is used in these new converting functions. These new functions were defined similarly to 'host_to_target_itimerspec()' and 'target_to_host_itimerspec()' the only difference being that 'target_to_host_timespec64()' and 'host_to_target_timespec64()' were used. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Reviewed-by: Laurent Vivier <laurent@vivier.eu> Message-Id: <20200722153421.295411-3-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-07-22 18:34:21 +03:00
struct target__kernel_itimerspec {
struct target__kernel_timespec it_interval;
struct target__kernel_timespec it_value;
};
struct target_timex {
abi_uint modes; /* Mode selector */
abi_long offset; /* Time offset */
abi_long freq; /* Frequency offset */
abi_long maxerror; /* Maximum error (microseconds) */
abi_long esterror; /* Estimated error (microseconds) */
abi_int status; /* Clock command/status */
abi_long constant; /* PLL (phase-locked loop) time constant */
abi_long precision; /* Clock precision (microseconds, ro) */
abi_long tolerance; /* Clock freq. tolerance (ppm, ro) */
struct target_timeval time; /* Current time */
abi_long tick; /* Microseconds between clock ticks */
abi_long ppsfreq; /* PPS (pulse per second) frequency */
abi_long jitter; /* PPS jitter (ro); nanoseconds */
abi_int shift; /* PPS interval duration (seconds) */
abi_long stabil; /* PPS stability */
abi_long jitcnt; /* PPS jitter limit exceeded (ro) */
abi_long calcnt; /* PPS calibration intervals */
abi_long errcnt; /* PPS calibration errors */
abi_long stbcnt; /* PPS stability limit exceeded */
abi_int tai; /* TAI offset */
/* Further padding bytes to allow for future expansion */
abi_int:32; abi_int:32; abi_int:32; abi_int:32;
abi_int:32; abi_int:32; abi_int:32; abi_int:32;
abi_int:32; abi_int:32; abi_int:32;
};
linux-user: Add support for 'clock_nanosleep_time64()' and 'clock_adjtime64()' This patch implements functionality for following time64 syscall: *clock_nanosleep_time64() This is a year 2038 safe vairant of syscall: int clock_nanosleep(clockid_t clockid, int flags, const struct timespec *request, struct timespec *remain) --high-resolution sleep with specifiable clock-- man page: https://man7.org/linux/man-pages/man2/clock_nanosleep.2.html *clock_adjtime64() This is a year 2038 safe variant of syscall: int clock_adjtime(clockid_t clk_id, struct timex *buf) --tune kernel clock-- man page: https://man7.org/linux/man-pages/man2/clock_adjtime.2.html Implementation notes: Syscall 'clock_nanosleep_time64()' was implemented similarly to syscall 'clock_nanosleep()' except that 'host_to_target_timespec64()' and 'target_to_host_timespec64()' were used instead of the regular 'host_to_target_timespec()' and 'target_to_host_timespec()'. For 'clock_adjtime64()' a 64-bit target kernel version of 'struct timex' was defined in 'syscall_defs.h': 'struct target__kernel_timex'. This type was used to convert the values of 64-bit timex type between host and target. For this purpose a 64-bit timex converting functions 'target_to_host_timex64()' and 'host_to_target_timex64()'. An existing function 'copy_to_user_timeval64()' was used to convert the field 'time' which if of type 'struct timeval' from host to target. Function 'copy_from_user_timveal64()' was added in this patch and used to convert the 'time' field from target to host. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Reviewed-by: Laurent Vivier <laurent@vivier.eu> Message-Id: <20200824192116.65562-2-Filip.Bozuta@syrmia.com> [lv: add missing ifdef's] Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-24 22:21:15 +03:00
struct target__kernel_timex {
abi_uint modes; /* Mode selector */
abi_int: 32; /* pad */
abi_llong offset; /* Time offset */
abi_llong freq; /* Frequency offset */
abi_llong maxerror; /* Maximum error (microseconds) */
abi_llong esterror; /* Estimated error (microseconds) */
abi_int status; /* Clock command/status */
abi_int: 32; /* pad */
abi_llong constant; /* PLL (phase-locked loop) time constant */
abi_llong precision; /* Clock precision (microseconds, ro) */
abi_llong tolerance; /* Clock freq. tolerance (ppm, ro) */
struct target__kernel_sock_timeval time; /* Current time */
abi_llong tick; /* Microseconds between clock ticks */
abi_llong ppsfreq; /* PPS (pulse per second) frequency */
abi_llong jitter; /* PPS jitter (ro); nanoseconds */
abi_int shift; /* PPS interval duration (seconds) */
abi_int: 32; /* pad */
abi_llong stabil; /* PPS stability */
abi_llong jitcnt; /* PPS jitter limit exceeded (ro) */
abi_llong calcnt; /* PPS calibration intervals */
abi_llong errcnt; /* PPS calibration errors */
abi_llong stbcnt; /* PPS stability limit exceeded */
abi_int tai; /* TAI offset */
/* Further padding bytes to allow for future expansion */
abi_int:32; abi_int:32; abi_int:32; abi_int:32;
abi_int:32; abi_int:32; abi_int:32; abi_int:32;
abi_int:32; abi_int:32; abi_int:32;
};
typedef abi_long target_clock_t;
#define TARGET_HZ 100
struct target_tms {
target_clock_t tms_utime;
target_clock_t tms_stime;
target_clock_t tms_cutime;
target_clock_t tms_cstime;
};
struct target_utimbuf {
abi_long actime;
abi_long modtime;
};
struct target_sel_arg_struct {
abi_long n;
abi_long inp, outp, exp;
abi_long tvp;
};
struct target_iovec {
abi_long iov_base; /* Starting address */
abi_long iov_len; /* Number of bytes */
};
struct target_msghdr {
abi_long msg_name; /* Socket name */
int msg_namelen; /* Length of name */
abi_long msg_iov; /* Data blocks */
abi_long msg_iovlen; /* Number of blocks */
abi_long msg_control; /* Per protocol magic (eg BSD file descriptor passing) */
abi_long msg_controllen; /* Length of cmsg list */
unsigned int msg_flags;
};
struct target_cmsghdr {
abi_long cmsg_len;
int cmsg_level;
int cmsg_type;
};
#define TARGET_CMSG_DATA(cmsg) ((unsigned char *) ((struct target_cmsghdr *) (cmsg) + 1))
#define TARGET_CMSG_NXTHDR(mhdr, cmsg, cmsg_start) \
__target_cmsg_nxthdr(mhdr, cmsg, cmsg_start)
#define TARGET_CMSG_ALIGN(len) (((len) + sizeof (abi_long) - 1) \
& (size_t) ~(sizeof (abi_long) - 1))
#define TARGET_CMSG_SPACE(len) (sizeof(struct target_cmsghdr) + \
TARGET_CMSG_ALIGN(len))
#define TARGET_CMSG_LEN(len) (sizeof(struct target_cmsghdr) + (len))
static __inline__ struct target_cmsghdr *
__target_cmsg_nxthdr(struct target_msghdr *__mhdr,
struct target_cmsghdr *__cmsg,
struct target_cmsghdr *__cmsg_start)
{
struct target_cmsghdr *__ptr;
__ptr = (struct target_cmsghdr *)((unsigned char *) __cmsg
+ TARGET_CMSG_ALIGN (tswapal(__cmsg->cmsg_len)));
if ((unsigned long)((char *)(__ptr+1) - (char *)__cmsg_start)
> tswapal(__mhdr->msg_controllen)) {
/* No more entries. */
return (struct target_cmsghdr *)0;
}
return __ptr;
}
struct target_mmsghdr {
struct target_msghdr msg_hdr; /* Message header */
unsigned int msg_len; /* Number of bytes transmitted */
};
struct target_rusage {
struct target_timeval ru_utime; /* user time used */
struct target_timeval ru_stime; /* system time used */
abi_long ru_maxrss; /* maximum resident set size */
abi_long ru_ixrss; /* integral shared memory size */
abi_long ru_idrss; /* integral unshared data size */
abi_long ru_isrss; /* integral unshared stack size */
abi_long ru_minflt; /* page reclaims */
abi_long ru_majflt; /* page faults */
abi_long ru_nswap; /* swaps */
abi_long ru_inblock; /* block input operations */
abi_long ru_oublock; /* block output operations */
abi_long ru_msgsnd; /* messages sent */
abi_long ru_msgrcv; /* messages received */
abi_long ru_nsignals; /* signals received */
abi_long ru_nvcsw; /* voluntary context switches */
abi_long ru_nivcsw; /* involuntary " */
};
typedef struct {
int val[2];
} kernel_fsid_t;
struct target_dirent {
abi_long d_ino;
abi_long d_off;
unsigned short d_reclen;
char d_name[];
};
struct target_dirent64 {
abi_ullong d_ino;
abi_llong d_off;
abi_ushort d_reclen;
unsigned char d_type;
char d_name[];
};
/* mostly generic signal stuff */
#define TARGET_SIG_DFL ((abi_long)0) /* default signal handling */
#define TARGET_SIG_IGN ((abi_long)1) /* ignore signal */
#define TARGET_SIG_ERR ((abi_long)-1) /* error return from signal */
#ifdef TARGET_MIPS
#define TARGET_NSIG 128
#else
#define TARGET_NSIG 64
#endif
#define TARGET_NSIG_BPW TARGET_ABI_BITS
#define TARGET_NSIG_WORDS (TARGET_NSIG / TARGET_NSIG_BPW)
typedef struct {
abi_ulong sig[TARGET_NSIG_WORDS];
} target_sigset_t;
#ifdef BSWAP_NEEDED
static inline void tswap_sigset(target_sigset_t *d, const target_sigset_t *s)
{
int i;
for(i = 0;i < TARGET_NSIG_WORDS; i++)
d->sig[i] = tswapal(s->sig[i]);
}
#else
static inline void tswap_sigset(target_sigset_t *d, const target_sigset_t *s)
{
*d = *s;
}
#endif
static inline void target_siginitset(target_sigset_t *d, abi_ulong set)
{
int i;
d->sig[0] = set;
for(i = 1;i < TARGET_NSIG_WORDS; i++)
d->sig[i] = 0;
}
void host_to_target_sigset(target_sigset_t *d, const sigset_t *s);
void target_to_host_sigset(sigset_t *d, const target_sigset_t *s);
void host_to_target_old_sigset(abi_ulong *old_sigset,
const sigset_t *sigset);
void target_to_host_old_sigset(sigset_t *sigset,
const abi_ulong *old_sigset);
struct target_sigaction;
int do_sigaction(int sig, const struct target_sigaction *act,
struct target_sigaction *oact, abi_ulong ka_restorer);
#include "target_signal.h"
#ifdef TARGET_SA_RESTORER
#define TARGET_ARCH_HAS_SA_RESTORER 1
#endif
#if defined(TARGET_ALPHA)
typedef int32_t target_old_sa_flags;
#else
typedef abi_ulong target_old_sa_flags;
#endif
#if defined(TARGET_MIPS)
struct target_sigaction {
uint32_t sa_flags;
#if defined(TARGET_ABI_MIPSN32)
uint32_t _sa_handler;
#else
abi_ulong _sa_handler;
#endif
target_sigset_t sa_mask;
#ifdef TARGET_ARCH_HAS_SA_RESTORER
/* ??? This is always present, but ignored unless O32. */
abi_ulong sa_restorer;
#endif
};
#else
struct target_old_sigaction {
abi_ulong _sa_handler;
abi_ulong sa_mask;
target_old_sa_flags sa_flags;
#ifdef TARGET_ARCH_HAS_SA_RESTORER
abi_ulong sa_restorer;
#endif
};
struct target_sigaction {
abi_ulong _sa_handler;
abi_ulong sa_flags;
#ifdef TARGET_ARCH_HAS_SA_RESTORER
abi_ulong sa_restorer;
#endif
target_sigset_t sa_mask;
#ifdef TARGET_ARCH_HAS_KA_RESTORER
abi_ulong ka_restorer;
#endif
};
#endif
typedef union target_sigval {
int sival_int;
abi_ulong sival_ptr;
} target_sigval_t;
#if 0
#if defined (TARGET_SPARC)
typedef struct {
struct {
abi_ulong psr;
abi_ulong pc;
abi_ulong npc;
abi_ulong y;
abi_ulong u_regs[16]; /* globals and ins */
} si_regs;
int si_mask;
} __siginfo_t;
typedef struct {
unsigned long si_float_regs [32];
unsigned long si_fsr;
unsigned long si_fpqdepth;
struct {
unsigned long *insn_addr;
unsigned long insn;
} si_fpqueue [16];
} __siginfo_fpu_t;
#endif
#endif
#define TARGET_SI_MAX_SIZE 128
#if TARGET_ABI_BITS == 32
#define TARGET_SI_PREAMBLE_SIZE (3 * sizeof(int))
#else
#define TARGET_SI_PREAMBLE_SIZE (4 * sizeof(int))
#endif
#define TARGET_SI_PAD_SIZE ((TARGET_SI_MAX_SIZE - TARGET_SI_PREAMBLE_SIZE) / sizeof(int))
/* Within QEMU the top 16 bits of si_code indicate which of the parts of
* the union in target_siginfo is valid. This only applies between
* host_to_target_siginfo_noswap() and tswap_siginfo(); it does not
* appear either within host siginfo_t or in target_siginfo structures
* which we get from the guest userspace program. (The Linux kernel
* does a similar thing with using the top bits for its own internal
* purposes but not letting them be visible to userspace.)
*/
#define QEMU_SI_KILL 0
#define QEMU_SI_TIMER 1
#define QEMU_SI_POLL 2
#define QEMU_SI_FAULT 3
#define QEMU_SI_CHLD 4
#define QEMU_SI_RT 5
typedef struct target_siginfo {
#ifdef TARGET_MIPS
int si_signo;
int si_code;
int si_errno;
#else
int si_signo;
int si_errno;
int si_code;
#endif
union {
int _pad[TARGET_SI_PAD_SIZE];
/* kill() */
struct {
pid_t _pid; /* sender's pid */
uid_t _uid; /* sender's uid */
} _kill;
/* POSIX.1b timers */
struct {
unsigned int _timer1;
unsigned int _timer2;
} _timer;
/* POSIX.1b signals */
struct {
pid_t _pid; /* sender's pid */
uid_t _uid; /* sender's uid */
target_sigval_t _sigval;
} _rt;
/* SIGCHLD */
struct {
pid_t _pid; /* which child */
uid_t _uid; /* sender's uid */
int _status; /* exit code */
target_clock_t _utime;
target_clock_t _stime;
} _sigchld;
/* SIGILL, SIGFPE, SIGSEGV, SIGBUS */
struct {
abi_ulong _addr; /* faulting insn/memory ref. */
} _sigfault;
/* SIGPOLL */
struct {
int _band; /* POLL_IN, POLL_OUT, POLL_MSG */
int _fd;
} _sigpoll;
} _sifields;
} target_siginfo_t;
/*
* si_code values
* Digital reserves positive values for kernel-generated signals.
*/
#define TARGET_SI_USER 0 /* sent by kill, sigsend, raise */
#define TARGET_SI_KERNEL 0x80 /* sent by the kernel from somewhere */
#define TARGET_SI_QUEUE -1 /* sent by sigqueue */
#define TARGET_SI_TIMER -2 /* sent by timer expiration */
#define TARGET_SI_MESGQ -3 /* sent by real time mesq state change */
#define TARGET_SI_ASYNCIO -4 /* sent by AIO completion */
#define TARGET_SI_SIGIO -5 /* sent by queued SIGIO */
/*
* SIGILL si_codes
*/
#define TARGET_ILL_ILLOPC (1) /* illegal opcode */
#define TARGET_ILL_ILLOPN (2) /* illegal operand */
#define TARGET_ILL_ILLADR (3) /* illegal addressing mode */
#define TARGET_ILL_ILLTRP (4) /* illegal trap */
#define TARGET_ILL_PRVOPC (5) /* privileged opcode */
#define TARGET_ILL_PRVREG (6) /* privileged register */
#define TARGET_ILL_COPROC (7) /* coprocessor error */
#define TARGET_ILL_BADSTK (8) /* internal stack error */
/*
* SIGFPE si_codes
*/
#define TARGET_FPE_INTDIV (1) /* integer divide by zero */
#define TARGET_FPE_INTOVF (2) /* integer overflow */
#define TARGET_FPE_FLTDIV (3) /* floating point divide by zero */
#define TARGET_FPE_FLTOVF (4) /* floating point overflow */
#define TARGET_FPE_FLTUND (5) /* floating point underflow */
#define TARGET_FPE_FLTRES (6) /* floating point inexact result */
#define TARGET_FPE_FLTINV (7) /* floating point invalid operation */
#define TARGET_FPE_FLTSUB (8) /* subscript out of range */
#define TARGET_FPE_FLTUNK (14) /* undiagnosed fp exception */
#define TARGET_FPE_CONDTRAP (15) /* trap on condition */
/*
* SIGSEGV si_codes
*/
#define TARGET_SEGV_MAPERR (1) /* address not mapped to object */
#define TARGET_SEGV_ACCERR (2) /* invalid permissions for mapped object */
#define TARGET_SEGV_BNDERR (3) /* failed address bound checks */
/*
* SIGBUS si_codes
*/
#define TARGET_BUS_ADRALN (1) /* invalid address alignment */
#define TARGET_BUS_ADRERR (2) /* non-existent physical address */
#define TARGET_BUS_OBJERR (3) /* object specific hardware error */
/* hardware memory error consumed on a machine check: action required */
#define TARGET_BUS_MCEERR_AR (4)
/* hardware memory error detected in process but not consumed: action optional*/
#define TARGET_BUS_MCEERR_AO (5)
/*
* SIGTRAP si_codes
*/
#define TARGET_TRAP_BRKPT (1) /* process breakpoint */
#define TARGET_TRAP_TRACE (2) /* process trace trap */
#define TARGET_TRAP_BRANCH (3) /* process taken branch trap */
#define TARGET_TRAP_HWBKPT (4) /* hardware breakpoint/watchpoint */
#define TARGET_TRAP_UNK (5) /* undiagnosed trap */
#include "target_resource.h"
struct target_pollfd {
int fd; /* file descriptor */
short events; /* requested events */
short revents; /* returned events */
};
/* virtual terminal ioctls */
#define TARGET_KIOCSOUND 0x4B2F /* start sound generation (0 for off) */
#define TARGET_KDMKTONE 0x4B30 /* generate tone */
#define TARGET_KDGKBTYPE 0x4b33
#define TARGET_KDSETMODE 0x4b3a
#define TARGET_KDGKBMODE 0x4b44
#define TARGET_KDSKBMODE 0x4b45
#define TARGET_KDGKBENT 0x4B46 /* gets one entry in translation table */
#define TARGET_KDGKBSENT 0x4B48 /* gets one function key string entry */
#define TARGET_KDGKBLED 0x4B64 /* get led flags (not lights) */
#define TARGET_KDSKBLED 0x4B65 /* set led flags (not lights) */
#define TARGET_KDGETLED 0x4B31 /* return current led state */
#define TARGET_KDSETLED 0x4B32 /* set led state [lights, not flags] */
#define TARGET_KDSIGACCEPT 0x4B4E
linux-user: Add support for getting/setting RTC PLL correction using ioctls This patch implements functionalities of following ioctls: RTC_PLL_GET - Getting PLL correction Read the PLL correction for RTCs that support PLL. The PLL correction is returned in the following structure: struct rtc_pll_info { int pll_ctrl; /* placeholder for fancier control */ int pll_value; /* get/set correction value */ int pll_max; /* max +ve (faster) adjustment value */ int pll_min; /* max -ve (slower) adjustment value */ int pll_posmult; /* factor for +ve correction */ int pll_negmult; /* factor for -ve correction */ long pll_clock; /* base PLL frequency */ }; A pointer to this structure should be passed as the third ioctl's argument. RTC_PLL_SET - Setting PLL correction Sets the PLL correction for RTCs that support PLL. The PLL correction that is set is specified by the rtc_pll_info structure pointed to by the third ioctl's' argument. Implementation notes: All ioctls in this patch have a pointer to a structure rtc_pll_info as their third argument. All elements of this structure are of type 'int', except the last one that is of type 'long'. That is the reason why a separate target structure (target_rtc_pll_info) is defined in linux-user/syscall_defs. The rest of the implementation is straightforward. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-6-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:39 +03:00
struct target_rtc_pll_info {
int pll_ctrl;
int pll_value;
int pll_max;
int pll_min;
int pll_posmult;
int pll_negmult;
abi_long pll_clock;
};
linux-user: Add support for enabling/disabling RTC features using ioctls This patch implements functionalities of following ioctls: RTC_AIE_ON, RTC_AIE_OFF - Alarm interrupt enabling on/off Enable or disable the alarm interrupt, for RTCs that support alarms. The third ioctl's argument is ignored. RTC_UIE_ON, RTC_UIE_OFF - Update interrupt enabling on/off Enable or disable the interrupt on every clock update, for RTCs that support this once-per-second interrupt. The third ioctl's argument is ignored. RTC_PIE_ON, RTC_PIE_OFF - Periodic interrupt enabling on/off Enable or disable the periodic interrupt, for RTCs that sup‐ port these periodic interrupts. The third ioctl's argument is ignored. Only a privileged process (i.e., one having the CAP_SYS_RESOURCE capability) can enable the periodic interrupt if the frequency is currently set above the value specified in /proc/sys/dev/rtc/max-user-freq. RTC_WIE_ON, RTC_WIE_OFF - Watchdog interrupt enabling on/off Enable or disable the Watchdog interrupt, for RTCs that sup- port this Watchdog interrupt. The third ioctl's argument is ignored. Implementation notes: Since all of involved ioctls have NULL as their third argument, their implementation was straightforward. The line '#include <linux/rtc.h>' was added to recognize preprocessor definitions for these ioctls. This needs to be done only once in this series of commits. Also, the content of this file (with respect to ioctl definitions) remained unchanged for a long time, therefore there is no need to worry about supporting older Linux kernel version. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-2-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:35 +03:00
/* real time clock ioctls */
#define TARGET_RTC_AIE_ON TARGET_IO('p', 0x01)
#define TARGET_RTC_AIE_OFF TARGET_IO('p', 0x02)
#define TARGET_RTC_UIE_ON TARGET_IO('p', 0x03)
#define TARGET_RTC_UIE_OFF TARGET_IO('p', 0x04)
#define TARGET_RTC_PIE_ON TARGET_IO('p', 0x05)
#define TARGET_RTC_PIE_OFF TARGET_IO('p', 0x06)
#define TARGET_RTC_WIE_ON TARGET_IO('p', 0x0f)
#define TARGET_RTC_WIE_OFF TARGET_IO('p', 0x10)
linux-user: Add support for getting/setting RTC time and alarm using ioctls This patch implements functionalities of following ioctls: RTC_RD_TIME - Getting RTC time Returns this RTC's time in the following structure: struct rtc_time { int tm_sec; int tm_min; int tm_hour; int tm_mday; int tm_mon; int tm_year; int tm_wday; /* unused */ int tm_yday; /* unused */ int tm_isdst; /* unused */ }; The fields in this structure have the same meaning and ranges as the tm structure described in gmtime man page. A pointer to this structure should be passed as the third ioctl's argument. RTC_SET_TIME - Setting RTC time Sets this RTC's time to the time specified by the rtc_time structure pointed to by the third ioctl's argument. To set the RTC's time the process must be privileged (i.e., have the CAP_SYS_TIME capability). RTC_ALM_READ, RTC_ALM_SET - Getting/Setting alarm time Read and set the alarm time, for RTCs that support alarms. The alarm interrupt must be separately enabled or disabled using the RTC_AIE_ON, RTC_AIE_OFF requests. The third ioctl's argument is a pointer to a rtc_time structure. Only the tm_sec, tm_min, and tm_hour fields of this structure are used. Implementation notes: All ioctls in this patch have pointer to a structure rtc_time as their third argument. That is the reason why corresponding definition is added in linux-user/syscall_types.h. Since all elements of this structure are of type 'int', the rest of the implementation is straightforward. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-3-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:36 +03:00
#define TARGET_RTC_ALM_READ TARGET_IOR('p', 0x08, struct rtc_time)
#define TARGET_RTC_ALM_SET TARGET_IOW('p', 0x07, struct rtc_time)
#define TARGET_RTC_RD_TIME TARGET_IOR('p', 0x09, struct rtc_time)
#define TARGET_RTC_SET_TIME TARGET_IOW('p', 0x0a, struct rtc_time)
linux-user: Add support for getting/setting RTC periodic interrupt and epoch using ioctls This patch implements functionalities of following ioctls: RTC_IRQP_READ, RTC_IRQP_SET - Getting/Setting IRQ rate Read and set the frequency for periodic interrupts, for RTCs that support periodic interrupts. The periodic interrupt must be separately enabled or disabled using the RTC_PIE_ON, RTC_PIE_OFF requests. The third ioctl's argument is an unsigned long * or an unsigned long, respectively. The value is the frequency in interrupts per second. The set of allow‐ able frequencies is the multiples of two in the range 2 to 8192. Only a privileged process (i.e., one having the CAP_SYS_RESOURCE capability) can set frequencies above the value specified in /proc/sys/dev/rtc/max-user-freq. (This file contains the value 64 by default.) RTC_EPOCH_READ, RTC_EPOCH_SET - Getting/Setting epoch Many RTCs encode the year in an 8-bit register which is either interpreted as an 8-bit binary number or as a BCD number. In both cases, the number is interpreted relative to this RTC's Epoch. The RTC's Epoch is initialized to 1900 on most systems but on Alpha and MIPS it might also be initialized to 1952, 1980, or 2000, depending on the value of an RTC register for the year. With some RTCs, these operations can be used to read or to set the RTC's Epoch, respectively. The third ioctl's argument is an unsigned long * or an unsigned long, respectively, and the value returned (or assigned) is the Epoch. To set the RTC's Epoch the process must be privileged (i.e., have the CAP_SYS_TIME capability). Implementation notes: All ioctls in this patch have a pointer to 'ulong' as their third argument. That is the reason why corresponding parts of added code in linux-user/syscall_defs.h contain special handling related to 'ulong' type: they use 'abi_ulong' type to make sure that ioctl's code is calculated correctly for both 32-bit and 64-bit targets. Also, 'MK_PTR(TYPE_ULONG)' is used for the similar reason in linux-user/ioctls.h. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-4-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:37 +03:00
#define TARGET_RTC_IRQP_READ TARGET_IOR('p', 0x0b, abi_ulong)
#define TARGET_RTC_IRQP_SET TARGET_IOW('p', 0x0c, abi_ulong)
#define TARGET_RTC_EPOCH_READ TARGET_IOR('p', 0x0d, abi_ulong)
#define TARGET_RTC_EPOCH_SET TARGET_IOW('p', 0x0e, abi_ulong)
linux-user: Add support for getting/setting RTC wakeup alarm using ioctls This patch implements functionalities of following ioctls: RTC_WKALM_SET, RTC_WKALM_GET - Getting/Setting wakeup alarm Some RTCs support a more powerful alarm interface, using these ioctls to read or write the RTC's alarm time (respectively) with this structure: struct rtc_wkalrm { unsigned char enabled; unsigned char pending; struct rtc_time time; }; The enabled flag is used to enable or disable the alarm interrupt, or to read its current status; when using these calls, RTC_AIE_ON and RTC_AIE_OFF are not used. The pending flag is used by RTC_WKALM_RD to report a pending interrupt (so it's mostly useless on Linux, except when talking to the RTC managed by EFI firmware). The time field is as used with RTC_ALM_READ and RTC_ALM_SET except that the tm_mday, tm_mon, and tm_year fields are also valid. A pointer to this structure should be passed as the third ioctl's argument. Implementation notes: All ioctls in this patch have a pointer to a structure rtc_wkalrm as their third argument. That is the reason why corresponding definition is added in linux-user/syscall_types.h. Since all elements of this structure are either of type 'unsigned char' or 'struct rtc_time' (that was covered in one of previous patches), the rest of the implementation is straightforward. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-5-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:38 +03:00
#define TARGET_RTC_WKALM_RD TARGET_IOR('p', 0x10, struct rtc_wkalrm)
#define TARGET_RTC_WKALM_SET TARGET_IOW('p', 0x0f, struct rtc_wkalrm)
linux-user: Add support for getting/setting RTC PLL correction using ioctls This patch implements functionalities of following ioctls: RTC_PLL_GET - Getting PLL correction Read the PLL correction for RTCs that support PLL. The PLL correction is returned in the following structure: struct rtc_pll_info { int pll_ctrl; /* placeholder for fancier control */ int pll_value; /* get/set correction value */ int pll_max; /* max +ve (faster) adjustment value */ int pll_min; /* max -ve (slower) adjustment value */ int pll_posmult; /* factor for +ve correction */ int pll_negmult; /* factor for -ve correction */ long pll_clock; /* base PLL frequency */ }; A pointer to this structure should be passed as the third ioctl's argument. RTC_PLL_SET - Setting PLL correction Sets the PLL correction for RTCs that support PLL. The PLL correction that is set is specified by the rtc_pll_info structure pointed to by the third ioctl's' argument. Implementation notes: All ioctls in this patch have a pointer to a structure rtc_pll_info as their third argument. All elements of this structure are of type 'int', except the last one that is of type 'long'. That is the reason why a separate target structure (target_rtc_pll_info) is defined in linux-user/syscall_defs. The rest of the implementation is straightforward. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-6-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:39 +03:00
#define TARGET_RTC_PLL_GET TARGET_IOR('p', 0x11, \
struct target_rtc_pll_info)
#define TARGET_RTC_PLL_SET TARGET_IOW('p', 0x12, \
struct target_rtc_pll_info)
#define TARGET_RTC_VL_READ TARGET_IOR('p', 0x13, int)
#define TARGET_RTC_VL_CLR TARGET_IO('p', 0x14)
linux-user: Add support for enabling/disabling RTC features using ioctls This patch implements functionalities of following ioctls: RTC_AIE_ON, RTC_AIE_OFF - Alarm interrupt enabling on/off Enable or disable the alarm interrupt, for RTCs that support alarms. The third ioctl's argument is ignored. RTC_UIE_ON, RTC_UIE_OFF - Update interrupt enabling on/off Enable or disable the interrupt on every clock update, for RTCs that support this once-per-second interrupt. The third ioctl's argument is ignored. RTC_PIE_ON, RTC_PIE_OFF - Periodic interrupt enabling on/off Enable or disable the periodic interrupt, for RTCs that sup‐ port these periodic interrupts. The third ioctl's argument is ignored. Only a privileged process (i.e., one having the CAP_SYS_RESOURCE capability) can enable the periodic interrupt if the frequency is currently set above the value specified in /proc/sys/dev/rtc/max-user-freq. RTC_WIE_ON, RTC_WIE_OFF - Watchdog interrupt enabling on/off Enable or disable the Watchdog interrupt, for RTCs that sup- port this Watchdog interrupt. The third ioctl's argument is ignored. Implementation notes: Since all of involved ioctls have NULL as their third argument, their implementation was straightforward. The line '#include <linux/rtc.h>' was added to recognize preprocessor definitions for these ioctls. This needs to be done only once in this series of commits. Also, the content of this file (with respect to ioctl definitions) remained unchanged for a long time, therefore there is no need to worry about supporting older Linux kernel version. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-2-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:35 +03:00
linux-user: Fix support for SIOCATMARK and SIOCGPGRP ioctls for xtensa Fix support for the SIOCATMARK and SIOCGPGRP ioctls for xtensa by correcting corresponding macro definition. Values for TARGET_SIOCATMARK and TARGET_SIOCGPGRP are determined by Linux kernel. Following relevant lines (obtained by grep) are from the kernel source tree: arch/ia64/include/uapi/asm/sockios.h:#define SIOCATMARK 0x8905 arch/mips/include/uapi/asm/sockios.h:#define SIOCATMARK _IOR('s', 7, int) arch/parisc/include/uapi/asm/sockios.h:#define SIOCATMARK 0x8905 arch/sh/include/uapi/asm/sockios.h:#define SIOCATMARK _IOR('s', 7, int) arch/xtensa/include/uapi/asm/sockios.h:#define SIOCATMARK _IOR('s', 7, int) arch/alpha/include/uapi/asm/sockios.h:#define SIOCATMARK _IOR('s', 7, int) arch/sparc/include/uapi/asm/sockios.h:#define SIOCATMARK 0x8905 include/uapi/asm-generic/sockios.h:#define SIOCATMARK 0x8905 arch/ia64/include/uapi/asm/sockios.h:#define SIOCGPGRP 0x8904 arch/mips/include/uapi/asm/sockios.h:#define SIOCGPGRP _IOR('s', 9, pid_t) arch/parisc/include/uapi/asm/sockios.h:#define SIOCGPGRP 0x8904 arch/sh/include/uapi/asm/sockios.h:#define SIOCGPGRP _IOR('s', 9, pid_t) arch/xtensa/include/uapi/asm/sockios.h:#define SIOCGPGRP _IOR('s', 9, pid_t) arch/alpha/include/uapi/asm/sockios.h:#define SIOCGPGRP _IOR('s', 9, pid_t) arch/sparc/include/uapi/asm/sockios.h:#define SIOCGPGRP 0x8904 include/uapi/asm-generic/sockios.h:#define SIOCGPGRP 0x8904 It is visible from above that xtensa should have the same definitions as alpha, mips and sh4 already do. This patch brings QEMU to the accurate state wrt these two ioctls. Acked-by: Max Filippov <jcmvbkbc@gmail.com> Signed-off-by: Aleksandar Markovic <amarkovic@wavecomp.com> Reviewed-by: Laurent Vivier <laurent@vivier.eu> Message-Id: <1558282527-22183-2-git-send-email-aleksandar.markovic@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-19 19:15:22 +03:00
#if defined(TARGET_ALPHA) || defined(TARGET_MIPS) || defined(TARGET_SH4) || \
defined(TARGET_XTENSA)
#define TARGET_FIOGETOWN TARGET_IOR('f', 123, int)
#define TARGET_FIOSETOWN TARGET_IOW('f', 124, int)
#define TARGET_SIOCATMARK TARGET_IOR('s', 7, int)
#define TARGET_SIOCSPGRP TARGET_IOW('s', 8, pid_t)
#define TARGET_SIOCGPGRP TARGET_IOR('s', 9, pid_t)
#else
#define TARGET_FIOGETOWN 0x8903
#define TARGET_FIOSETOWN 0x8901
#define TARGET_SIOCATMARK 0x8905
#define TARGET_SIOCSPGRP 0x8902
#define TARGET_SIOCGPGRP 0x8904
#endif
#if defined(TARGET_SH4)
#define TARGET_SIOCGSTAMP_OLD TARGET_IOR('s', 100, struct target_timeval)
#define TARGET_SIOCGSTAMPNS_OLD TARGET_IOR('s', 101, struct target_timespec)
#else
#define TARGET_SIOCGSTAMP_OLD 0x8906
#define TARGET_SIOCGSTAMPNS_OLD 0x8907
#endif
#define TARGET_SIOCGSTAMP_NEW TARGET_IOR(0x89, 0x06, abi_llong[2])
#define TARGET_SIOCGSTAMPNS_NEW TARGET_IOR(0x89, 0x07, abi_llong[2])
/* Networking ioctls */
#define TARGET_SIOCADDRT 0x890B /* add routing table entry */
#define TARGET_SIOCDELRT 0x890C /* delete routing table entry */
#define TARGET_SIOCGIFNAME 0x8910 /* get iface name */
#define TARGET_SIOCSIFLINK 0x8911 /* set iface channel */
#define TARGET_SIOCGIFCONF 0x8912 /* get iface list */
#define TARGET_SIOCGIFFLAGS 0x8913 /* get flags */
#define TARGET_SIOCSIFFLAGS 0x8914 /* set flags */
#define TARGET_SIOCGIFADDR 0x8915 /* get PA address */
#define TARGET_SIOCSIFADDR 0x8916 /* set PA address */
#define TARGET_SIOCGIFDSTADDR 0x8917 /* get remote PA address */
#define TARGET_SIOCSIFDSTADDR 0x8918 /* set remote PA address */
#define TARGET_SIOCGIFBRDADDR 0x8919 /* get broadcast PA address */
#define TARGET_SIOCSIFBRDADDR 0x891a /* set broadcast PA address */
#define TARGET_SIOCGIFNETMASK 0x891b /* get network PA mask */
#define TARGET_SIOCSIFNETMASK 0x891c /* set network PA mask */
#define TARGET_SIOCGIFMETRIC 0x891d /* get metric */
#define TARGET_SIOCSIFMETRIC 0x891e /* set metric */
#define TARGET_SIOCGIFMEM 0x891f /* get memory address (BSD) */
#define TARGET_SIOCSIFMEM 0x8920 /* set memory address (BSD) */
#define TARGET_SIOCGIFMTU 0x8921 /* get MTU size */
#define TARGET_SIOCSIFMTU 0x8922 /* set MTU size */
#define TARGET_SIOCSIFHWADDR 0x8924 /* set hardware address (NI) */
#define TARGET_SIOCGIFENCAP 0x8925 /* get/set slip encapsulation */
#define TARGET_SIOCSIFENCAP 0x8926
#define TARGET_SIOCGIFHWADDR 0x8927 /* Get hardware address */
#define TARGET_SIOCGIFSLAVE 0x8929 /* Driver slaving support */
#define TARGET_SIOCSIFSLAVE 0x8930
#define TARGET_SIOCADDMULTI 0x8931 /* Multicast address lists */
#define TARGET_SIOCDELMULTI 0x8932
#define TARGET_SIOCGIFINDEX 0x8933
#define TARGET_SIOCSIFPFLAGS 0x8934 /* set extended flags */
#define TARGET_SIOCGIFPFLAGS 0x8935 /* get extended flags */
/* Bridging control calls */
#define TARGET_SIOCGIFBR 0x8940 /* Bridging support */
#define TARGET_SIOCSIFBR 0x8941 /* Set bridging options */
#define TARGET_SIOCGIFTXQLEN 0x8942 /* Get the tx queue length */
#define TARGET_SIOCSIFTXQLEN 0x8943 /* Set the tx queue length */
/* ARP cache control calls. */
#define TARGET_OLD_SIOCDARP 0x8950 /* old delete ARP table entry */
#define TARGET_OLD_SIOCGARP 0x8951 /* old get ARP table entry */
#define TARGET_OLD_SIOCSARP 0x8952 /* old set ARP table entry */
#define TARGET_SIOCDARP 0x8953 /* delete ARP table entry */
#define TARGET_SIOCGARP 0x8954 /* get ARP table entry */
#define TARGET_SIOCSARP 0x8955 /* set ARP table entry */
/* RARP cache control calls. */
#define TARGET_SIOCDRARP 0x8960 /* delete RARP table entry */
#define TARGET_SIOCGRARP 0x8961 /* get RARP table entry */
#define TARGET_SIOCSRARP 0x8962 /* set RARP table entry */
/* Driver configuration calls */
#define TARGET_SIOCGIFMAP 0x8970 /* Get device parameters */
#define TARGET_SIOCSIFMAP 0x8971 /* Set device parameters */
/* DLCI configuration calls */
#define TARGET_SIOCADDDLCI 0x8980 /* Create new DLCI device */
#define TARGET_SIOCDELDLCI 0x8981 /* Delete DLCI device */
/* From <linux/wireless.h> */
#define TARGET_SIOCGIWNAME 0x8B01 /* get name == wireless protocol */
/* From <linux/if_tun.h> */
#define TARGET_TUNSETDEBUG TARGET_IOW('T', 201, int)
#define TARGET_TUNSETIFF TARGET_IOW('T', 202, int)
#define TARGET_TUNSETPERSIST TARGET_IOW('T', 203, int)
#define TARGET_TUNSETOWNER TARGET_IOW('T', 204, int)
#define TARGET_TUNSETLINK TARGET_IOW('T', 205, int)
#define TARGET_TUNSETGROUP TARGET_IOW('T', 206, int)
#define TARGET_TUNGETFEATURES TARGET_IOR('T', 207, unsigned int)
#define TARGET_TUNSETOFFLOAD TARGET_IOW('T', 208, unsigned int)
#define TARGET_TUNSETTXFILTER TARGET_IOW('T', 209, unsigned int)
#define TARGET_TUNGETIFF TARGET_IOR('T', 210, unsigned int)
#define TARGET_TUNGETSNDBUF TARGET_IOR('T', 211, int)
#define TARGET_TUNSETSNDBUF TARGET_IOW('T', 212, int)
/*
* TUNATTACHFILTER and TUNDETACHFILTER are not supported. Linux kernel keeps a
* user pointer in TUNATTACHFILTER, which we are not able to correctly handle.
*/
#define TARGET_TUNGETVNETHDRSZ TARGET_IOR('T', 215, int)
#define TARGET_TUNSETVNETHDRSZ TARGET_IOW('T', 216, int)
#define TARGET_TUNSETQUEUE TARGET_IOW('T', 217, int)
#define TARGET_TUNSETIFINDEX TARGET_IOW('T', 218, unsigned int)
/* TUNGETFILTER is not supported: see TUNATTACHFILTER. */
#define TARGET_TUNSETVNETLE TARGET_IOW('T', 220, int)
#define TARGET_TUNGETVNETLE TARGET_IOR('T', 221, int)
#define TARGET_TUNSETVNETBE TARGET_IOW('T', 222, int)
#define TARGET_TUNGETVNETBE TARGET_IOR('T', 223, int)
#define TARGET_TUNSETSTEERINGEBPF TARGET_IOR('T', 224, int)
#define TARGET_TUNSETFILTEREBPF TARGET_IOR('T', 225, int)
#define TARGET_TUNSETCARRIER TARGET_IOW('T', 226, int)
#define TARGET_TUNGETDEVNETNS TARGET_IO('T', 227)
/* From <linux/random.h> */
#define TARGET_RNDGETENTCNT TARGET_IOR('R', 0x00, int)
#define TARGET_RNDADDTOENTCNT TARGET_IOW('R', 0x01, int)
#define TARGET_RNDZAPENTCNT TARGET_IO('R', 0x04)
#define TARGET_RNDCLEARPOOL TARGET_IO('R', 0x06)
#define TARGET_RNDRESEEDCRNG TARGET_IO('R', 0x07)
/* From <linux/fs.h> */
#define TARGET_BLKROSET TARGET_IO(0x12,93) /* set device read-only (0 = read-write) */
#define TARGET_BLKROGET TARGET_IO(0x12,94) /* get read-only status (0 = read_write) */
#define TARGET_BLKRRPART TARGET_IO(0x12,95) /* re-read partition table */
#define TARGET_BLKGETSIZE TARGET_IO(0x12,96) /* return device size /512 (long *arg) */
#define TARGET_BLKFLSBUF TARGET_IO(0x12,97) /* flush buffer cache */
#define TARGET_BLKRASET TARGET_IO(0x12,98) /* Set read ahead for block device */
#define TARGET_BLKRAGET TARGET_IO(0x12,99) /* get current read ahead setting */
#define TARGET_BLKFRASET TARGET_IO(0x12,100)/* set filesystem (mm/filemap.c) read-ahead */
#define TARGET_BLKFRAGET TARGET_IO(0x12,101)/* get filesystem (mm/filemap.c) read-ahead */
#define TARGET_BLKSECTSET TARGET_IO(0x12,102)/* set max sectors per request (ll_rw_blk.c) */
#define TARGET_BLKSECTGET TARGET_IO(0x12,103)/* get max sectors per request (ll_rw_blk.c) */
#define TARGET_BLKSSZGET TARGET_IO(0x12,104)/* get block device sector size */
#define TARGET_BLKPG TARGET_IO(0x12,105)/* Partition table and disk geometry handling */
/* A jump here: 108-111 have been used for various private purposes. */
#define TARGET_BLKBSZGET TARGET_IOR(0x12, 112, abi_ulong)
#define TARGET_BLKBSZSET TARGET_IOW(0x12, 113, abi_ulong)
#define TARGET_BLKGETSIZE64 TARGET_IOR(0x12,114,abi_ulong)
/* return device size in bytes
(u64 *arg) */
#define TARGET_BLKDISCARD TARGET_IO(0x12, 119)
#define TARGET_BLKIOMIN TARGET_IO(0x12, 120)
#define TARGET_BLKIOOPT TARGET_IO(0x12, 121)
#define TARGET_BLKALIGNOFF TARGET_IO(0x12, 122)
#define TARGET_BLKPBSZGET TARGET_IO(0x12, 123)
#define TARGET_BLKDISCARDZEROES TARGET_IO(0x12, 124)
#define TARGET_BLKSECDISCARD TARGET_IO(0x12, 125)
#define TARGET_BLKROTATIONAL TARGET_IO(0x12, 126)
#define TARGET_BLKZEROOUT TARGET_IO(0x12, 127)
/* From <linux/fd.h> */
#define TARGET_FDMSGON TARGET_IO(2, 0x45)
#define TARGET_FDMSGOFF TARGET_IO(2, 0x46)
#define TARGET_FDFMTBEG TARGET_IO(2, 0x47)
#define TARGET_FDFMTTRK TARGET_IOW(2, 0x48, struct format_descr)
#define TARGET_FDFMTEND TARGET_IO(2, 0x49)
#define TARGET_FDSETEMSGTRESH TARGET_IO(2, 0x4a)
#define TARGET_FDFLUSH TARGET_IO(2, 0x4b)
#define TARGET_FDSETMAXERRS TARGET_IOW(2, 0x4c, struct floppy_max_errors)
#define TARGET_FDGETMAXERRS TARGET_IOR(2, 0x0e, struct floppy_max_errors)
#define TARGET_FDRESET TARGET_IO(2, 0x54)
#define TARGET_FDRAWCMD TARGET_IO(2, 0x58)
#define TARGET_FDTWADDLE TARGET_IO(2, 0x59)
#define TARGET_FDEJECT TARGET_IO(2, 0x5a)
#define TARGET_FIBMAP TARGET_IO(0x00,1) /* bmap access */
#define TARGET_FIGETBSZ TARGET_IO(0x00,2) /* get the block size used for bmap */
#define TARGET_FICLONE TARGET_IOW(0x94, 9, int)
#define TARGET_FICLONERANGE TARGET_IOW(0x94, 13, struct file_clone_range)
/*
* Note that the ioctl numbers for FS_IOC_<GET|SET><FLAGS|VERSION>
* claim type "long" but the actual type used by the kernel is "int".
*/
#define TARGET_FS_IOC_GETFLAGS TARGET_IOR('f', 1, abi_long)
#define TARGET_FS_IOC_SETFLAGS TARGET_IOW('f', 2, abi_long)
#define TARGET_FS_IOC_GETVERSION TARGET_IOR('v', 1, abi_long)
#define TARGET_FS_IOC_SETVERSION TARGET_IOW('v', 2, abi_long)
#define TARGET_FS_IOC_FIEMAP TARGET_IOWR('f',11,struct fiemap)
#define TARGET_FS_IOC32_GETFLAGS TARGET_IOR('f', 1, int)
#define TARGET_FS_IOC32_SETFLAGS TARGET_IOW('f', 2, int)
#define TARGET_FS_IOC32_GETVERSION TARGET_IOR('v', 1, int)
#define TARGET_FS_IOC32_SETVERSION TARGET_IOW('v', 2, int)
linux-user: Add support for a group of btrfs ioctls used for subvolumes This patch implements functionality of following ioctls: BTRFS_IOC_SUBVOL_CREATE - Creating a btrfs subvolume Create a btrfs subvolume. The subvolume is created using the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_vol_args { __s64 fd; char name[BTRFS_PATH_NAME_MAX + 1]; }; Before calling this ioctl, the fields of this structure should be filled with aproppriate values. The fd field represents the file descriptor value of the subvolume and the name field represents the subvolume path. BTRFS_IOC_SUBVOL_GETFLAGS - Getting subvolume flags Read the flags of the btrfs subvolume. The flags are read using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of following values: BTRFS_SUBVOL_RDONLY (1ULL << 1) BTRFS_SUBVOL_QGROUP_INHERIT (1ULL << 2) BTRFS_DEVICE_SPEC_BY_ID (1ULL << 3) BTRFS_SUBVOL_SPEC_BY_ID (1ULL << 4) BTRFS_IOC_SUBVOL_SETFLAGS - Setting subvolume flags Set the flags of the btrfs subvolume. The flags are set using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of same values as in the case of previous ioctl (BTRFS_IOC_SUBVOL_GETFLAGS). BTRFS_IOC_SUBVOL_GETINFO - Getting subvolume information Read information about the subvolume. The subvolume information is returned in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_get_subvol_info_args { /* Id of this subvolume */ __u64 treeid; /* Name of this subvolume, used to get the real name at mount point */ char name[BTRFS_VOL_NAME_MAX + 1]; /* * Id of the subvolume which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume. */ __u64 parent_id; /* * Inode number of the directory which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume */ __u64 dirid; /* Latest transaction id of this subvolume */ __u64 generation; /* Flags of this subvolume */ __u64 flags; /* UUID of this subvolume */ __u8 uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume of which this subvolume is a snapshot. * All zero for a non-snapshot subvolume. */ __u8 parent_uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume from which this subvolume was received. * All zero for non-received subvolume. */ __u8 received_uuid[BTRFS_UUID_SIZE]; /* Transaction id indicating when change/create/send/receive happened */ __u64 ctransid; __u64 otransid; __u64 stransid; __u64 rtransid; /* Time corresponding to c/o/s/rtransid */ struct btrfs_ioctl_timespec ctime; struct btrfs_ioctl_timespec otime; struct btrfs_ioctl_timespec stime; struct btrfs_ioctl_timespec rtime; /* Must be zero */ __u64 reserved[8]; }; All of the fields of this structure are filled after the ioctl call. Implementation notes: Ioctls BTRFS_IOC_SUBVOL_CREATE and BTRFS_IOC_SUBVOL_GETINFO have structure types as third arguments. That is the reason why a corresponding definition are added in file 'linux-user/syscall_types.h'. The line '#include <linux/btrfs.h>' is added in file 'linux-user/syscall.c' to recognise preprocessor definitions for these ioctls. Since the file "linux/btrfs.h" was added in the kernel version 3.9, it is enwrapped in an #ifdef statement with parameter CONFIG_BTRFS which is defined in 'configure' if the header file is present. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-2-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:07 +03:00
/* btrfs ioctls */
#ifdef HAVE_BTRFS_H
#define TARGET_BTRFS_IOC_SNAP_CREATE TARGET_IOWU(BTRFS_IOCTL_MAGIC, 1)
linux-user: Add support for btrfs ioctls used to manipulate with devices This patch implements functionality for following ioctls: BTRFS_IOC_SCAN_DEV - Scanning device for a btrfs filesystem Scan a device for a btrfs filesystem. The device that is to be scanned is passed in the ioctl's third argument which represents a pointer to a 'struct ioc_vol_args' (which was mentioned in a previous patch). Before calling this ioctl, the name field of this structure should be filled with the aproppriate name value which represents a path for the device. If the device contains a btrfs filesystem, the ioctl returns 0, otherwise a negative value is returned. BTRFS_IOC_ADD_DEV - Adding a device to a btrfs filesystem Add a device to a btrfs filesystem. The device that is to be added is passed in the ioctl's third argument which represents a pointer to a 'struct ioc_vol_args' (which was mentioned in a previous patch). Before calling this ioctl, the name field of this structure should be filled with the aproppriate name value which represents a path for the device. BTRFS_IOC_RM_DEV - Removing a device from a btrfs filesystem Remove a device from a btrfs filesystem. The device that is to be removed is passed in the ioctl's third argument which represents a pointer to a 'struct ioc_vol_args' (which was mentioned in a previous patch). Before calling this ioctl, the name field of this structure should be filled with the aproppriate name value which represents a path for the device. BTRFS_IOC_DEV_INFO - Getting information about a device Obtain information for device in a btrfs filesystem. The information is gathered in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_dev_info_args { __u64 devid; /* in/out */ __u8 uuid[BTRFS_UUID_SIZE]; /* in/out */ __u64 bytes_used; /* out */ __u64 total_bytes; /* out */ __u64 unused[379]; /* pad to 4k */ __u8 path[BTRFS_DEVICE_PATH_NAME_MAX]; /* out */ }; Before calling this ioctl, field "devid" should be set with the id value for the device for which the information is to be obtained. If this field is not aproppriately set, the errno ENODEV ("No such device") is returned. BTRFS_IOC_GET_DEV_STATS - Getting device statistics Obtain stats informatin for device in a btrfs filesystem. The information is gathered in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_get_dev_stats { __u64 devid; /* in */ __u64 nr_items; /* in/out */ __u64 flags; /* in/out */ /* out values: */ __u64 values[BTRFS_DEV_STAT_VALUES_MAX]; /* * This pads the struct to 1032 bytes. It was originally meant to pad to * 1024 bytes, but when adding the flags field, the padding calculation * was not adjusted. */ __u64 unused[128 - 2 - BTRFS_DEV_STAT_VALUES_MAX]; }; Before calling this ioctl, field "devid" should be set with the id value for the device for which the information is to be obtained. If this field is not aproppriately set, the errno ENODEV ("No such device") is returned. BTRFS_IOC_FORGET_DEV - Remove unmounted devices Search and remove all stale devices (devices which are not mounted). The third ioctl argument is a pointer to a 'struct btrfs_ioctl_vol_args'. The ioctl call will release all unmounted devices which match the path which is specified in the "name" field of the structure. If an empty path ("") is specified, all unmounted devices will be released. Implementation notes: Ioctls BTRFS_IOC_DEV_INFO and BTRFS_IOC_GET_DEV_STATS use types 'struct btrfs_ioctl_dev_info_args' and ' struct btrfs_ioctl_get_dev_stats' as third argument types. That is the reason why corresponding structure definitions were added in file 'linux-user/syscall_types.h'. Since the thunk type for 'struct ioc_vol_args' was already added in a previous patch, the rest of the implementation was straightforward. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-4-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:09 +03:00
#define TARGET_BTRFS_IOC_SCAN_DEV TARGET_IOWU(BTRFS_IOCTL_MAGIC, 4)
#define TARGET_BTRFS_IOC_FORGET_DEV TARGET_IOWU(BTRFS_IOCTL_MAGIC, 5)
#define TARGET_BTRFS_IOC_ADD_DEV TARGET_IOWU(BTRFS_IOCTL_MAGIC, 10)
#define TARGET_BTRFS_IOC_RM_DEV TARGET_IOWU(BTRFS_IOCTL_MAGIC, 11)
linux-user: Add support for a group of btrfs ioctls used for subvolumes This patch implements functionality of following ioctls: BTRFS_IOC_SUBVOL_CREATE - Creating a btrfs subvolume Create a btrfs subvolume. The subvolume is created using the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_vol_args { __s64 fd; char name[BTRFS_PATH_NAME_MAX + 1]; }; Before calling this ioctl, the fields of this structure should be filled with aproppriate values. The fd field represents the file descriptor value of the subvolume and the name field represents the subvolume path. BTRFS_IOC_SUBVOL_GETFLAGS - Getting subvolume flags Read the flags of the btrfs subvolume. The flags are read using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of following values: BTRFS_SUBVOL_RDONLY (1ULL << 1) BTRFS_SUBVOL_QGROUP_INHERIT (1ULL << 2) BTRFS_DEVICE_SPEC_BY_ID (1ULL << 3) BTRFS_SUBVOL_SPEC_BY_ID (1ULL << 4) BTRFS_IOC_SUBVOL_SETFLAGS - Setting subvolume flags Set the flags of the btrfs subvolume. The flags are set using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of same values as in the case of previous ioctl (BTRFS_IOC_SUBVOL_GETFLAGS). BTRFS_IOC_SUBVOL_GETINFO - Getting subvolume information Read information about the subvolume. The subvolume information is returned in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_get_subvol_info_args { /* Id of this subvolume */ __u64 treeid; /* Name of this subvolume, used to get the real name at mount point */ char name[BTRFS_VOL_NAME_MAX + 1]; /* * Id of the subvolume which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume. */ __u64 parent_id; /* * Inode number of the directory which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume */ __u64 dirid; /* Latest transaction id of this subvolume */ __u64 generation; /* Flags of this subvolume */ __u64 flags; /* UUID of this subvolume */ __u8 uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume of which this subvolume is a snapshot. * All zero for a non-snapshot subvolume. */ __u8 parent_uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume from which this subvolume was received. * All zero for non-received subvolume. */ __u8 received_uuid[BTRFS_UUID_SIZE]; /* Transaction id indicating when change/create/send/receive happened */ __u64 ctransid; __u64 otransid; __u64 stransid; __u64 rtransid; /* Time corresponding to c/o/s/rtransid */ struct btrfs_ioctl_timespec ctime; struct btrfs_ioctl_timespec otime; struct btrfs_ioctl_timespec stime; struct btrfs_ioctl_timespec rtime; /* Must be zero */ __u64 reserved[8]; }; All of the fields of this structure are filled after the ioctl call. Implementation notes: Ioctls BTRFS_IOC_SUBVOL_CREATE and BTRFS_IOC_SUBVOL_GETINFO have structure types as third arguments. That is the reason why a corresponding definition are added in file 'linux-user/syscall_types.h'. The line '#include <linux/btrfs.h>' is added in file 'linux-user/syscall.c' to recognise preprocessor definitions for these ioctls. Since the file "linux/btrfs.h" was added in the kernel version 3.9, it is enwrapped in an #ifdef statement with parameter CONFIG_BTRFS which is defined in 'configure' if the header file is present. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-2-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:07 +03:00
#define TARGET_BTRFS_IOC_SUBVOL_CREATE TARGET_IOWU(BTRFS_IOCTL_MAGIC, 14)
#define TARGET_BTRFS_IOC_SNAP_DESTROY TARGET_IOWU(BTRFS_IOCTL_MAGIC, 15)
linux-user: Add support for a group of btrfs inode ioctls This patch implements functionality of following ioctls: BTRFS_IOC_INO_LOOKUP - Reading tree root id and path Read tree root id and path for a given file or directory. The name and tree root id are returned in an ioctl's third argument that represents a pointer to a following type: struct btrfs_ioctl_ino_lookup_args { __u64 treeid; __u64 objectid; char name[BTRFS_INO_LOOKUP_PATH_MAX]; }; Before calling this ioctl, field 'objectid' should be filled with the object id value for which the tree id and path are to be read. Value 'BTRFS_FIRST_FREE_OBJECTID' represents the object id for the first available btrfs object (directory or file). BTRFS_IOC_INO_PATHS - Reading paths to all files Read path to all files with a certain inode number. The paths are returned in the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_ino_path_args { __u64 inum; /* in */ __u64 size; /* in */ __u64 reserved[4]; /* struct btrfs_data_container *fspath; out */ __u64 fspath; /* out */ }; Before calling this ioctl, the 'inum' and 'size' field should be filled with the aproppriate inode number and size of the directory where file paths should be looked for. For now, the paths are returned in an '__u64' (unsigned long long) value 'fspath'. BTRFS_IOC_LOGICAL_INO - Reading inode numbers Read inode numbers for files on a certain logical adress. The inode numbers are returned in the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_logical_ino_args { __u64 logical; /* in */ __u64 size; /* in */ __u64 reserved[3]; /* must be 0 for now */ __u64 flags; /* in, v2 only */ /* struct btrfs_data_container *inodes; out */ __u64 inodes; }; Before calling this ioctl, the 'logical' and 'size' field should be filled with the aproppriate logical adress and size of where the inode numbers of files should be looked for. For now, the inode numbers are returned in an '__u64' (unsigned long long) value 'inodes'. BTRFS_IOC_LOGICAL_INO_V2 - Reading inode numbers Same as the above mentioned ioctl except that it allows passing a flags 'BTRFS_LOGICAL_INO_ARGS_IGNORE_OFFSET'. BTRFS_IOC_INO_LOOKUP_USER - Reading subvolume name and path Read name and path of a subvolume. The tree root id and path are read in an ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_ino_lookup_user_args { /* in, inode number containing the subvolume of 'subvolid' */ __u64 dirid; /* in */ __u64 treeid; /* out, name of the subvolume of 'treeid' */ char name[BTRFS_VOL_NAME_MAX + 1]; /* * out, constructed path from the directory with which the ioctl is * called to dirid */ char path[BTRFS_INO_LOOKUP_USER_PATH_MAX]; }; Before calling this ioctl, the 'dirid' and 'treeid' field should be filled with aproppriate values which represent the inode number of the directory that contains the subvolume and treeid of the subvolume. Implementation notes: All of the ioctls in this patch use structure types as third arguments. That is the reason why aproppriate thunk definitions were added in file 'syscall_types.h'. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-6-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:11 +03:00
#define TARGET_BTRFS_IOC_INO_LOOKUP TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 18)
#define TARGET_BTRFS_IOC_DEFAULT_SUBVOL TARGET_IOW(BTRFS_IOCTL_MAGIC, 19,\
abi_ullong)
linux-user: Add support for a group of btrfs ioctls used for subvolumes This patch implements functionality of following ioctls: BTRFS_IOC_SUBVOL_CREATE - Creating a btrfs subvolume Create a btrfs subvolume. The subvolume is created using the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_vol_args { __s64 fd; char name[BTRFS_PATH_NAME_MAX + 1]; }; Before calling this ioctl, the fields of this structure should be filled with aproppriate values. The fd field represents the file descriptor value of the subvolume and the name field represents the subvolume path. BTRFS_IOC_SUBVOL_GETFLAGS - Getting subvolume flags Read the flags of the btrfs subvolume. The flags are read using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of following values: BTRFS_SUBVOL_RDONLY (1ULL << 1) BTRFS_SUBVOL_QGROUP_INHERIT (1ULL << 2) BTRFS_DEVICE_SPEC_BY_ID (1ULL << 3) BTRFS_SUBVOL_SPEC_BY_ID (1ULL << 4) BTRFS_IOC_SUBVOL_SETFLAGS - Setting subvolume flags Set the flags of the btrfs subvolume. The flags are set using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of same values as in the case of previous ioctl (BTRFS_IOC_SUBVOL_GETFLAGS). BTRFS_IOC_SUBVOL_GETINFO - Getting subvolume information Read information about the subvolume. The subvolume information is returned in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_get_subvol_info_args { /* Id of this subvolume */ __u64 treeid; /* Name of this subvolume, used to get the real name at mount point */ char name[BTRFS_VOL_NAME_MAX + 1]; /* * Id of the subvolume which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume. */ __u64 parent_id; /* * Inode number of the directory which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume */ __u64 dirid; /* Latest transaction id of this subvolume */ __u64 generation; /* Flags of this subvolume */ __u64 flags; /* UUID of this subvolume */ __u8 uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume of which this subvolume is a snapshot. * All zero for a non-snapshot subvolume. */ __u8 parent_uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume from which this subvolume was received. * All zero for non-received subvolume. */ __u8 received_uuid[BTRFS_UUID_SIZE]; /* Transaction id indicating when change/create/send/receive happened */ __u64 ctransid; __u64 otransid; __u64 stransid; __u64 rtransid; /* Time corresponding to c/o/s/rtransid */ struct btrfs_ioctl_timespec ctime; struct btrfs_ioctl_timespec otime; struct btrfs_ioctl_timespec stime; struct btrfs_ioctl_timespec rtime; /* Must be zero */ __u64 reserved[8]; }; All of the fields of this structure are filled after the ioctl call. Implementation notes: Ioctls BTRFS_IOC_SUBVOL_CREATE and BTRFS_IOC_SUBVOL_GETINFO have structure types as third arguments. That is the reason why a corresponding definition are added in file 'linux-user/syscall_types.h'. The line '#include <linux/btrfs.h>' is added in file 'linux-user/syscall.c' to recognise preprocessor definitions for these ioctls. Since the file "linux/btrfs.h" was added in the kernel version 3.9, it is enwrapped in an #ifdef statement with parameter CONFIG_BTRFS which is defined in 'configure' if the header file is present. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-2-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:07 +03:00
#define TARGET_BTRFS_IOC_SUBVOL_GETFLAGS TARGET_IOR(BTRFS_IOCTL_MAGIC, 25,\
abi_ullong)
#define TARGET_BTRFS_IOC_SUBVOL_SETFLAGS TARGET_IOW(BTRFS_IOCTL_MAGIC, 26,\
abi_ullong)
linux-user: Add support for btrfs ioctls used to scrub a filesystem This patch implements functionality for following ioctls: BTRFS_IOC_SCRUB - Starting a btrfs filesystem scrub Start a btrfs filesystem scrub. The third ioctls argument is a pointer to a following type: struct btrfs_ioctl_scrub_args { __u64 devid; /* in */ __u64 start; /* in */ __u64 end; /* in */ __u64 flags; /* in */ struct btrfs_scrub_progress progress; /* out */ /* pad to 1k */ __u64 unused[(1024-32-sizeof(struct btrfs_scrub_progress))/8]; }; Before calling this ioctl, field 'devid' should be filled with value that represents the device id of the btrfs filesystem for which the scrub is to be started. BTRFS_IOC_SCRUB_CANCEL - Canceling scrub of a btrfs filesystem Cancel a btrfs filesystem scrub if it is running. The third ioctls argument is ignored. BTRFS_IOC_SCRUB_PROGRESS - Getting status of a running scrub Read the status of a running btrfs filesystem scrub. The third ioctls argument is a pointer to the above mentioned 'struct btrfs_ioctl_scrub_args'. Similarly as with 'BTRFS_IOC_SCRUB', the 'devid' field should be filled with value that represents the id of the btrfs device for which the scrub has started. The status of a running scrub is returned in the field 'progress' which is of type 'struct btrfs_scrub_progress' and its definition can be found at: https://elixir.bootlin.com/linux/latest/source/include/uapi/linux/btrfs.h#L150 Implementation nots: Ioctls in this patch use type 'struct btrfs_ioctl_scrub_args' as their third argument. That is the reason why an aproppriate thunk type definition is added in file 'syscall_types.h'. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-9-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:14 +03:00
#define TARGET_BTRFS_IOC_SCRUB TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 27)
#define TARGET_BTRFS_IOC_SCRUB_CANCEL TARGET_IO(BTRFS_IOCTL_MAGIC, 28)
#define TARGET_BTRFS_IOC_SCRUB_PROGRESS TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 29)
linux-user: Add support for btrfs ioctls used to manipulate with devices This patch implements functionality for following ioctls: BTRFS_IOC_SCAN_DEV - Scanning device for a btrfs filesystem Scan a device for a btrfs filesystem. The device that is to be scanned is passed in the ioctl's third argument which represents a pointer to a 'struct ioc_vol_args' (which was mentioned in a previous patch). Before calling this ioctl, the name field of this structure should be filled with the aproppriate name value which represents a path for the device. If the device contains a btrfs filesystem, the ioctl returns 0, otherwise a negative value is returned. BTRFS_IOC_ADD_DEV - Adding a device to a btrfs filesystem Add a device to a btrfs filesystem. The device that is to be added is passed in the ioctl's third argument which represents a pointer to a 'struct ioc_vol_args' (which was mentioned in a previous patch). Before calling this ioctl, the name field of this structure should be filled with the aproppriate name value which represents a path for the device. BTRFS_IOC_RM_DEV - Removing a device from a btrfs filesystem Remove a device from a btrfs filesystem. The device that is to be removed is passed in the ioctl's third argument which represents a pointer to a 'struct ioc_vol_args' (which was mentioned in a previous patch). Before calling this ioctl, the name field of this structure should be filled with the aproppriate name value which represents a path for the device. BTRFS_IOC_DEV_INFO - Getting information about a device Obtain information for device in a btrfs filesystem. The information is gathered in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_dev_info_args { __u64 devid; /* in/out */ __u8 uuid[BTRFS_UUID_SIZE]; /* in/out */ __u64 bytes_used; /* out */ __u64 total_bytes; /* out */ __u64 unused[379]; /* pad to 4k */ __u8 path[BTRFS_DEVICE_PATH_NAME_MAX]; /* out */ }; Before calling this ioctl, field "devid" should be set with the id value for the device for which the information is to be obtained. If this field is not aproppriately set, the errno ENODEV ("No such device") is returned. BTRFS_IOC_GET_DEV_STATS - Getting device statistics Obtain stats informatin for device in a btrfs filesystem. The information is gathered in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_get_dev_stats { __u64 devid; /* in */ __u64 nr_items; /* in/out */ __u64 flags; /* in/out */ /* out values: */ __u64 values[BTRFS_DEV_STAT_VALUES_MAX]; /* * This pads the struct to 1032 bytes. It was originally meant to pad to * 1024 bytes, but when adding the flags field, the padding calculation * was not adjusted. */ __u64 unused[128 - 2 - BTRFS_DEV_STAT_VALUES_MAX]; }; Before calling this ioctl, field "devid" should be set with the id value for the device for which the information is to be obtained. If this field is not aproppriately set, the errno ENODEV ("No such device") is returned. BTRFS_IOC_FORGET_DEV - Remove unmounted devices Search and remove all stale devices (devices which are not mounted). The third ioctl argument is a pointer to a 'struct btrfs_ioctl_vol_args'. The ioctl call will release all unmounted devices which match the path which is specified in the "name" field of the structure. If an empty path ("") is specified, all unmounted devices will be released. Implementation notes: Ioctls BTRFS_IOC_DEV_INFO and BTRFS_IOC_GET_DEV_STATS use types 'struct btrfs_ioctl_dev_info_args' and ' struct btrfs_ioctl_get_dev_stats' as third argument types. That is the reason why corresponding structure definitions were added in file 'linux-user/syscall_types.h'. Since the thunk type for 'struct ioc_vol_args' was already added in a previous patch, the rest of the implementation was straightforward. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-4-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:09 +03:00
#define TARGET_BTRFS_IOC_DEV_INFO TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 30)
linux-user: Add support for a group of btrfs inode ioctls This patch implements functionality of following ioctls: BTRFS_IOC_INO_LOOKUP - Reading tree root id and path Read tree root id and path for a given file or directory. The name and tree root id are returned in an ioctl's third argument that represents a pointer to a following type: struct btrfs_ioctl_ino_lookup_args { __u64 treeid; __u64 objectid; char name[BTRFS_INO_LOOKUP_PATH_MAX]; }; Before calling this ioctl, field 'objectid' should be filled with the object id value for which the tree id and path are to be read. Value 'BTRFS_FIRST_FREE_OBJECTID' represents the object id for the first available btrfs object (directory or file). BTRFS_IOC_INO_PATHS - Reading paths to all files Read path to all files with a certain inode number. The paths are returned in the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_ino_path_args { __u64 inum; /* in */ __u64 size; /* in */ __u64 reserved[4]; /* struct btrfs_data_container *fspath; out */ __u64 fspath; /* out */ }; Before calling this ioctl, the 'inum' and 'size' field should be filled with the aproppriate inode number and size of the directory where file paths should be looked for. For now, the paths are returned in an '__u64' (unsigned long long) value 'fspath'. BTRFS_IOC_LOGICAL_INO - Reading inode numbers Read inode numbers for files on a certain logical adress. The inode numbers are returned in the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_logical_ino_args { __u64 logical; /* in */ __u64 size; /* in */ __u64 reserved[3]; /* must be 0 for now */ __u64 flags; /* in, v2 only */ /* struct btrfs_data_container *inodes; out */ __u64 inodes; }; Before calling this ioctl, the 'logical' and 'size' field should be filled with the aproppriate logical adress and size of where the inode numbers of files should be looked for. For now, the inode numbers are returned in an '__u64' (unsigned long long) value 'inodes'. BTRFS_IOC_LOGICAL_INO_V2 - Reading inode numbers Same as the above mentioned ioctl except that it allows passing a flags 'BTRFS_LOGICAL_INO_ARGS_IGNORE_OFFSET'. BTRFS_IOC_INO_LOOKUP_USER - Reading subvolume name and path Read name and path of a subvolume. The tree root id and path are read in an ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_ino_lookup_user_args { /* in, inode number containing the subvolume of 'subvolid' */ __u64 dirid; /* in */ __u64 treeid; /* out, name of the subvolume of 'treeid' */ char name[BTRFS_VOL_NAME_MAX + 1]; /* * out, constructed path from the directory with which the ioctl is * called to dirid */ char path[BTRFS_INO_LOOKUP_USER_PATH_MAX]; }; Before calling this ioctl, the 'dirid' and 'treeid' field should be filled with aproppriate values which represent the inode number of the directory that contains the subvolume and treeid of the subvolume. Implementation notes: All of the ioctls in this patch use structure types as third arguments. That is the reason why aproppriate thunk definitions were added in file 'syscall_types.h'. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-6-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:11 +03:00
#define TARGET_BTRFS_IOC_INO_PATHS TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 35)
#define TARGET_BTRFS_IOC_LOGICAL_INO TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 36)
linux-user: Add support for btrfs ioctls used to manage quota This patch implements functionality for following ioctls: BTRFS_IOC_QUOTA_CTL - Enabling/Disabling quota support Enable or disable quota support for a btrfs filesystem. Quota support is enabled or disabled using the ioctls third argument which represents a pointer to a following type: struct btrfs_ioctl_quota_ctl_args { __u64 cmd; __u64 status; }; Before calling this ioctl, the 'cmd' field should be filled with one of the values 'BTRFS_QUOTA_CTL_ENABLE' (enabling quota) 'BTRFS_QUOTA_CTL_DISABLE' (disabling quota). BTRFS_IOC_QGROUP_CREATE - Creating/Removing a subvolume quota group Create or remove a subvolume quota group. The subvolume quota group is created or removed using the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_qgroup_create_args { __u64 create; __u64 qgroupid; }; Before calling this ioctl, the 'create' field should be filled with the aproppriate value depending on if the user wants to create or remove a quota group (0 for removing, everything else for creating). Also, the 'qgroupid' field should be filled with the value for the quota group id that is to be created. BTRFS_IOC_QGROUP_ASSIGN - Asigning or removing a quota group as child group Asign or remove a quota group as child quota group of another group in the btrfs filesystem. The asignment is done using the ioctl's third argument which represents a pointert to a following type: struct btrfs_ioctl_qgroup_assign_args { __u64 assign; __u64 src; __u64 dst; }; Before calling this ioctl, the 'assign' field should be filled with the aproppriate value depending on if the user wants to asign or remove a quota group as a child quota group of another group (0 for removing, everythin else for asigning). Also, the 'src' and 'dst' fields should be filled with the aproppriate quota group id values depending on which quota group needs to asigned or removed as child quota group of another group ('src' gets asigned or removed as child group of 'dst'). BTRFS_IOC_QGROUP_LIMIT - Limiting the size of a quota group Limit the size of a quota group. The size of the quota group is limited with the ioctls third argument which represents a pointer to a following type: struct btrfs_ioctl_qgroup_limit_args { __u64 qgroupid; struct btrfs_qgroup_limit lim; }; Before calling this ioctl, the 'qgroup' id field should be filled with aproppriate value of the quota group id for which the size is to be limited. The second field is of following type: struct btrfs_qgroup_limit { __u64 flags; __u64 max_rfer; __u64 max_excl; __u64 rsv_rfer; __u64 rsv_excl; }; The 'max_rfer' field should be filled with the size to which the quota group should be limited. The 'flags' field can be used for passing additional options and can have values which can be found on: https://elixir.bootlin.com/linux/latest/source/include/uapi/linux/btrfs.h#L67 BTRFS_IOC_QUOTA_RESCAN_STATUS - Checking status of running rescan operation Check status of a running rescan operation. The status is checked using the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_quota_rescan_args { __u64 flags; __u64 progress; __u64 reserved[6]; }; If there is a rescan operation running, 'flags' field is set to 1, and 'progress' field is set to aproppriate value which represents the progress of the operation. BTRFS_IOC_QUOTA_RESCAN - Starting a rescan operation Start ar rescan operation to Trash all quota groups and scan the metadata again with the current config. Before calling this ioctl, BTRFS_IOC_QUOTA_RESCAN_STATUS sould be run to check if there is already a rescan operation runing. After that ioctl call, the received 'struct btrfs_ioctl_quota_rescan_args' should be than passed as this ioctls third argument. BTRFS_IOC_QUOTA_RESCAN_WAIT - Waiting for a rescan operation to finish Wait until a rescan operation is finished (if there is a rescan operation running). The third ioctls argument is ignored. Implementation notes: Almost all of the ioctls in this patch use structure types as third arguments. That is the reason why aproppriate thunk definitions were added in file 'syscall_types.h'. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-8-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:13 +03:00
#define TARGET_BTRFS_IOC_QUOTA_CTL TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 40)
#define TARGET_BTRFS_IOC_QGROUP_ASSIGN TARGET_IOWU(BTRFS_IOCTL_MAGIC, 41)
#define TARGET_BTRFS_IOC_QGROUP_CREATE TARGET_IOWU(BTRFS_IOCTL_MAGIC, 42)
#define TARGET_BTRFS_IOC_QGROUP_LIMIT TARGET_IORU(BTRFS_IOCTL_MAGIC, 43)
#define TARGET_BTRFS_IOC_QUOTA_RESCAN TARGET_IOWU(BTRFS_IOCTL_MAGIC, 44)
#define TARGET_BTRFS_IOC_QUOTA_RESCAN_STATUS TARGET_IORU(BTRFS_IOCTL_MAGIC, 45)
#define TARGET_BTRFS_IOC_QUOTA_RESCAN_WAIT TARGET_IO(BTRFS_IOCTL_MAGIC, 46)
linux-user: Add support for btrfs ioctls used to manipulate with devices This patch implements functionality for following ioctls: BTRFS_IOC_SCAN_DEV - Scanning device for a btrfs filesystem Scan a device for a btrfs filesystem. The device that is to be scanned is passed in the ioctl's third argument which represents a pointer to a 'struct ioc_vol_args' (which was mentioned in a previous patch). Before calling this ioctl, the name field of this structure should be filled with the aproppriate name value which represents a path for the device. If the device contains a btrfs filesystem, the ioctl returns 0, otherwise a negative value is returned. BTRFS_IOC_ADD_DEV - Adding a device to a btrfs filesystem Add a device to a btrfs filesystem. The device that is to be added is passed in the ioctl's third argument which represents a pointer to a 'struct ioc_vol_args' (which was mentioned in a previous patch). Before calling this ioctl, the name field of this structure should be filled with the aproppriate name value which represents a path for the device. BTRFS_IOC_RM_DEV - Removing a device from a btrfs filesystem Remove a device from a btrfs filesystem. The device that is to be removed is passed in the ioctl's third argument which represents a pointer to a 'struct ioc_vol_args' (which was mentioned in a previous patch). Before calling this ioctl, the name field of this structure should be filled with the aproppriate name value which represents a path for the device. BTRFS_IOC_DEV_INFO - Getting information about a device Obtain information for device in a btrfs filesystem. The information is gathered in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_dev_info_args { __u64 devid; /* in/out */ __u8 uuid[BTRFS_UUID_SIZE]; /* in/out */ __u64 bytes_used; /* out */ __u64 total_bytes; /* out */ __u64 unused[379]; /* pad to 4k */ __u8 path[BTRFS_DEVICE_PATH_NAME_MAX]; /* out */ }; Before calling this ioctl, field "devid" should be set with the id value for the device for which the information is to be obtained. If this field is not aproppriately set, the errno ENODEV ("No such device") is returned. BTRFS_IOC_GET_DEV_STATS - Getting device statistics Obtain stats informatin for device in a btrfs filesystem. The information is gathered in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_get_dev_stats { __u64 devid; /* in */ __u64 nr_items; /* in/out */ __u64 flags; /* in/out */ /* out values: */ __u64 values[BTRFS_DEV_STAT_VALUES_MAX]; /* * This pads the struct to 1032 bytes. It was originally meant to pad to * 1024 bytes, but when adding the flags field, the padding calculation * was not adjusted. */ __u64 unused[128 - 2 - BTRFS_DEV_STAT_VALUES_MAX]; }; Before calling this ioctl, field "devid" should be set with the id value for the device for which the information is to be obtained. If this field is not aproppriately set, the errno ENODEV ("No such device") is returned. BTRFS_IOC_FORGET_DEV - Remove unmounted devices Search and remove all stale devices (devices which are not mounted). The third ioctl argument is a pointer to a 'struct btrfs_ioctl_vol_args'. The ioctl call will release all unmounted devices which match the path which is specified in the "name" field of the structure. If an empty path ("") is specified, all unmounted devices will be released. Implementation notes: Ioctls BTRFS_IOC_DEV_INFO and BTRFS_IOC_GET_DEV_STATS use types 'struct btrfs_ioctl_dev_info_args' and ' struct btrfs_ioctl_get_dev_stats' as third argument types. That is the reason why corresponding structure definitions were added in file 'linux-user/syscall_types.h'. Since the thunk type for 'struct ioc_vol_args' was already added in a previous patch, the rest of the implementation was straightforward. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-4-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:09 +03:00
#define TARGET_BTRFS_IOC_GET_DEV_STATS TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 52)
linux-user: Add support for btrfs ioctls used to get/set features This patch implements functionality for following ioctls: BTRFS_IOC_GET_FEATURES - Getting feature flags Read feature flags for a btrfs filesystem. The feature flags are returned inside the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_feature_flags { __u64 compat_flags; __u64 compat_ro_flags; __u64 incompat_flags; }; All of the structure field represent bit masks that can be composed of values which can be found on: https://elixir.bootlin.com/linux/latest/source/fs/btrfs/ctree.h#L282 BTRFS_IOC_SET_FEATURES - Setting feature flags Set and clear feature flags for a btrfs filesystem. The feature flags are set using the ioctl's third argument which represents a 'struct btrfs_ioctl_feature_flags[2]' array. The first element of the array represent flags which are to be cleared and the second element of the array represent flags which are to be set. The second element has the priority over the first, which means that if there are matching flags in the elements, they will be set in the filesystem. If the flag values in the third argument aren't correctly set to be composed of the available predefined flag values, errno ENOPERM ("Operation not permitted") is returned. BTRFS_IOC_GET_SUPPORTED_FEATURES - Getting supported feature flags Read supported feature flags for a btrfs filesystem. The supported feature flags are read using the ioctl's third argument which represents a 'struct btrfs_ioctl_feature_flags[3]' array. The first element of this array represents all of the supported flags in the btrfs filesystem. The second element represents flags that can be safely set and third element represent flags that can be safely clearead. Implementation notes: All of the implemented ioctls use 'struct btrfs_ioctl_feature_flags' as third argument. That is the reason why a corresponding defintion was added in file 'linux-user/syscall_types.h'. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-5-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:10 +03:00
#define TARGET_BTRFS_IOC_GET_FEATURES TARGET_IORU(BTRFS_IOCTL_MAGIC, 57)
#define TARGET_BTRFS_IOC_SET_FEATURES TARGET_IOWU(BTRFS_IOCTL_MAGIC, 57)
#define TARGET_BTRFS_IOC_GET_SUPPORTED_FEATURES TARGET_IORU(BTRFS_IOCTL_MAGIC, 57)
linux-user: Add support for a group of btrfs inode ioctls This patch implements functionality of following ioctls: BTRFS_IOC_INO_LOOKUP - Reading tree root id and path Read tree root id and path for a given file or directory. The name and tree root id are returned in an ioctl's third argument that represents a pointer to a following type: struct btrfs_ioctl_ino_lookup_args { __u64 treeid; __u64 objectid; char name[BTRFS_INO_LOOKUP_PATH_MAX]; }; Before calling this ioctl, field 'objectid' should be filled with the object id value for which the tree id and path are to be read. Value 'BTRFS_FIRST_FREE_OBJECTID' represents the object id for the first available btrfs object (directory or file). BTRFS_IOC_INO_PATHS - Reading paths to all files Read path to all files with a certain inode number. The paths are returned in the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_ino_path_args { __u64 inum; /* in */ __u64 size; /* in */ __u64 reserved[4]; /* struct btrfs_data_container *fspath; out */ __u64 fspath; /* out */ }; Before calling this ioctl, the 'inum' and 'size' field should be filled with the aproppriate inode number and size of the directory where file paths should be looked for. For now, the paths are returned in an '__u64' (unsigned long long) value 'fspath'. BTRFS_IOC_LOGICAL_INO - Reading inode numbers Read inode numbers for files on a certain logical adress. The inode numbers are returned in the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_logical_ino_args { __u64 logical; /* in */ __u64 size; /* in */ __u64 reserved[3]; /* must be 0 for now */ __u64 flags; /* in, v2 only */ /* struct btrfs_data_container *inodes; out */ __u64 inodes; }; Before calling this ioctl, the 'logical' and 'size' field should be filled with the aproppriate logical adress and size of where the inode numbers of files should be looked for. For now, the inode numbers are returned in an '__u64' (unsigned long long) value 'inodes'. BTRFS_IOC_LOGICAL_INO_V2 - Reading inode numbers Same as the above mentioned ioctl except that it allows passing a flags 'BTRFS_LOGICAL_INO_ARGS_IGNORE_OFFSET'. BTRFS_IOC_INO_LOOKUP_USER - Reading subvolume name and path Read name and path of a subvolume. The tree root id and path are read in an ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_ino_lookup_user_args { /* in, inode number containing the subvolume of 'subvolid' */ __u64 dirid; /* in */ __u64 treeid; /* out, name of the subvolume of 'treeid' */ char name[BTRFS_VOL_NAME_MAX + 1]; /* * out, constructed path from the directory with which the ioctl is * called to dirid */ char path[BTRFS_INO_LOOKUP_USER_PATH_MAX]; }; Before calling this ioctl, the 'dirid' and 'treeid' field should be filled with aproppriate values which represent the inode number of the directory that contains the subvolume and treeid of the subvolume. Implementation notes: All of the ioctls in this patch use structure types as third arguments. That is the reason why aproppriate thunk definitions were added in file 'syscall_types.h'. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-6-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:11 +03:00
#define TARGET_BTRFS_IOC_LOGICAL_INO_V2 TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 59)
linux-user: Add support for a group of btrfs ioctls used for subvolumes This patch implements functionality of following ioctls: BTRFS_IOC_SUBVOL_CREATE - Creating a btrfs subvolume Create a btrfs subvolume. The subvolume is created using the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_vol_args { __s64 fd; char name[BTRFS_PATH_NAME_MAX + 1]; }; Before calling this ioctl, the fields of this structure should be filled with aproppriate values. The fd field represents the file descriptor value of the subvolume and the name field represents the subvolume path. BTRFS_IOC_SUBVOL_GETFLAGS - Getting subvolume flags Read the flags of the btrfs subvolume. The flags are read using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of following values: BTRFS_SUBVOL_RDONLY (1ULL << 1) BTRFS_SUBVOL_QGROUP_INHERIT (1ULL << 2) BTRFS_DEVICE_SPEC_BY_ID (1ULL << 3) BTRFS_SUBVOL_SPEC_BY_ID (1ULL << 4) BTRFS_IOC_SUBVOL_SETFLAGS - Setting subvolume flags Set the flags of the btrfs subvolume. The flags are set using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of same values as in the case of previous ioctl (BTRFS_IOC_SUBVOL_GETFLAGS). BTRFS_IOC_SUBVOL_GETINFO - Getting subvolume information Read information about the subvolume. The subvolume information is returned in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_get_subvol_info_args { /* Id of this subvolume */ __u64 treeid; /* Name of this subvolume, used to get the real name at mount point */ char name[BTRFS_VOL_NAME_MAX + 1]; /* * Id of the subvolume which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume. */ __u64 parent_id; /* * Inode number of the directory which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume */ __u64 dirid; /* Latest transaction id of this subvolume */ __u64 generation; /* Flags of this subvolume */ __u64 flags; /* UUID of this subvolume */ __u8 uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume of which this subvolume is a snapshot. * All zero for a non-snapshot subvolume. */ __u8 parent_uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume from which this subvolume was received. * All zero for non-received subvolume. */ __u8 received_uuid[BTRFS_UUID_SIZE]; /* Transaction id indicating when change/create/send/receive happened */ __u64 ctransid; __u64 otransid; __u64 stransid; __u64 rtransid; /* Time corresponding to c/o/s/rtransid */ struct btrfs_ioctl_timespec ctime; struct btrfs_ioctl_timespec otime; struct btrfs_ioctl_timespec stime; struct btrfs_ioctl_timespec rtime; /* Must be zero */ __u64 reserved[8]; }; All of the fields of this structure are filled after the ioctl call. Implementation notes: Ioctls BTRFS_IOC_SUBVOL_CREATE and BTRFS_IOC_SUBVOL_GETINFO have structure types as third arguments. That is the reason why a corresponding definition are added in file 'linux-user/syscall_types.h'. The line '#include <linux/btrfs.h>' is added in file 'linux-user/syscall.c' to recognise preprocessor definitions for these ioctls. Since the file "linux/btrfs.h" was added in the kernel version 3.9, it is enwrapped in an #ifdef statement with parameter CONFIG_BTRFS which is defined in 'configure' if the header file is present. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-2-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:07 +03:00
#define TARGET_BTRFS_IOC_GET_SUBVOL_INFO TARGET_IORU(BTRFS_IOCTL_MAGIC, 60)
#define TARGET_BTRFS_IOC_GET_SUBVOL_ROOTREF TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 61)
linux-user: Add support for a group of btrfs inode ioctls This patch implements functionality of following ioctls: BTRFS_IOC_INO_LOOKUP - Reading tree root id and path Read tree root id and path for a given file or directory. The name and tree root id are returned in an ioctl's third argument that represents a pointer to a following type: struct btrfs_ioctl_ino_lookup_args { __u64 treeid; __u64 objectid; char name[BTRFS_INO_LOOKUP_PATH_MAX]; }; Before calling this ioctl, field 'objectid' should be filled with the object id value for which the tree id and path are to be read. Value 'BTRFS_FIRST_FREE_OBJECTID' represents the object id for the first available btrfs object (directory or file). BTRFS_IOC_INO_PATHS - Reading paths to all files Read path to all files with a certain inode number. The paths are returned in the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_ino_path_args { __u64 inum; /* in */ __u64 size; /* in */ __u64 reserved[4]; /* struct btrfs_data_container *fspath; out */ __u64 fspath; /* out */ }; Before calling this ioctl, the 'inum' and 'size' field should be filled with the aproppriate inode number and size of the directory where file paths should be looked for. For now, the paths are returned in an '__u64' (unsigned long long) value 'fspath'. BTRFS_IOC_LOGICAL_INO - Reading inode numbers Read inode numbers for files on a certain logical adress. The inode numbers are returned in the ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_logical_ino_args { __u64 logical; /* in */ __u64 size; /* in */ __u64 reserved[3]; /* must be 0 for now */ __u64 flags; /* in, v2 only */ /* struct btrfs_data_container *inodes; out */ __u64 inodes; }; Before calling this ioctl, the 'logical' and 'size' field should be filled with the aproppriate logical adress and size of where the inode numbers of files should be looked for. For now, the inode numbers are returned in an '__u64' (unsigned long long) value 'inodes'. BTRFS_IOC_LOGICAL_INO_V2 - Reading inode numbers Same as the above mentioned ioctl except that it allows passing a flags 'BTRFS_LOGICAL_INO_ARGS_IGNORE_OFFSET'. BTRFS_IOC_INO_LOOKUP_USER - Reading subvolume name and path Read name and path of a subvolume. The tree root id and path are read in an ioctl's third argument which represents a pointer to a following type: struct btrfs_ioctl_ino_lookup_user_args { /* in, inode number containing the subvolume of 'subvolid' */ __u64 dirid; /* in */ __u64 treeid; /* out, name of the subvolume of 'treeid' */ char name[BTRFS_VOL_NAME_MAX + 1]; /* * out, constructed path from the directory with which the ioctl is * called to dirid */ char path[BTRFS_INO_LOOKUP_USER_PATH_MAX]; }; Before calling this ioctl, the 'dirid' and 'treeid' field should be filled with aproppriate values which represent the inode number of the directory that contains the subvolume and treeid of the subvolume. Implementation notes: All of the ioctls in this patch use structure types as third arguments. That is the reason why aproppriate thunk definitions were added in file 'syscall_types.h'. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-6-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:11 +03:00
#define TARGET_BTRFS_IOC_INO_LOOKUP_USER TARGET_IOWRU(BTRFS_IOCTL_MAGIC, 62)
#endif
linux-user: Add support for a group of btrfs ioctls used for subvolumes This patch implements functionality of following ioctls: BTRFS_IOC_SUBVOL_CREATE - Creating a btrfs subvolume Create a btrfs subvolume. The subvolume is created using the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_vol_args { __s64 fd; char name[BTRFS_PATH_NAME_MAX + 1]; }; Before calling this ioctl, the fields of this structure should be filled with aproppriate values. The fd field represents the file descriptor value of the subvolume and the name field represents the subvolume path. BTRFS_IOC_SUBVOL_GETFLAGS - Getting subvolume flags Read the flags of the btrfs subvolume. The flags are read using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of following values: BTRFS_SUBVOL_RDONLY (1ULL << 1) BTRFS_SUBVOL_QGROUP_INHERIT (1ULL << 2) BTRFS_DEVICE_SPEC_BY_ID (1ULL << 3) BTRFS_SUBVOL_SPEC_BY_ID (1ULL << 4) BTRFS_IOC_SUBVOL_SETFLAGS - Setting subvolume flags Set the flags of the btrfs subvolume. The flags are set using the ioctl's third argument that is a pointer of __u64 (unsigned long). The third argument represents a bit mask that can be composed of same values as in the case of previous ioctl (BTRFS_IOC_SUBVOL_GETFLAGS). BTRFS_IOC_SUBVOL_GETINFO - Getting subvolume information Read information about the subvolume. The subvolume information is returned in the ioctl's third argument which represents a pointer to a following structure type: struct btrfs_ioctl_get_subvol_info_args { /* Id of this subvolume */ __u64 treeid; /* Name of this subvolume, used to get the real name at mount point */ char name[BTRFS_VOL_NAME_MAX + 1]; /* * Id of the subvolume which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume. */ __u64 parent_id; /* * Inode number of the directory which contains this subvolume. * Zero for top-level subvolume or a deleted subvolume */ __u64 dirid; /* Latest transaction id of this subvolume */ __u64 generation; /* Flags of this subvolume */ __u64 flags; /* UUID of this subvolume */ __u8 uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume of which this subvolume is a snapshot. * All zero for a non-snapshot subvolume. */ __u8 parent_uuid[BTRFS_UUID_SIZE]; /* * UUID of the subvolume from which this subvolume was received. * All zero for non-received subvolume. */ __u8 received_uuid[BTRFS_UUID_SIZE]; /* Transaction id indicating when change/create/send/receive happened */ __u64 ctransid; __u64 otransid; __u64 stransid; __u64 rtransid; /* Time corresponding to c/o/s/rtransid */ struct btrfs_ioctl_timespec ctime; struct btrfs_ioctl_timespec otime; struct btrfs_ioctl_timespec stime; struct btrfs_ioctl_timespec rtime; /* Must be zero */ __u64 reserved[8]; }; All of the fields of this structure are filled after the ioctl call. Implementation notes: Ioctls BTRFS_IOC_SUBVOL_CREATE and BTRFS_IOC_SUBVOL_GETINFO have structure types as third arguments. That is the reason why a corresponding definition are added in file 'linux-user/syscall_types.h'. The line '#include <linux/btrfs.h>' is added in file 'linux-user/syscall.c' to recognise preprocessor definitions for these ioctls. Since the file "linux/btrfs.h" was added in the kernel version 3.9, it is enwrapped in an #ifdef statement with parameter CONFIG_BTRFS which is defined in 'configure' if the header file is present. Signed-off-by: Filip Bozuta <Filip.Bozuta@syrmia.com> Tested-by: Daniel P. Berrangé <berrange@redhat.com> Message-Id: <20200823195014.116226-2-Filip.Bozuta@syrmia.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-08-23 22:50:07 +03:00
/* usb ioctls */
#define TARGET_USBDEVFS_CONTROL TARGET_IOWRU('U', 0)
#define TARGET_USBDEVFS_BULK TARGET_IOWRU('U', 2)
#define TARGET_USBDEVFS_RESETEP TARGET_IORU('U', 3)
#define TARGET_USBDEVFS_SETINTERFACE TARGET_IORU('U', 4)
#define TARGET_USBDEVFS_SETCONFIGURATION TARGET_IORU('U', 5)
#define TARGET_USBDEVFS_GETDRIVER TARGET_IOWU('U', 8)
#define TARGET_USBDEVFS_SUBMITURB TARGET_IORU('U', 10)
#define TARGET_USBDEVFS_DISCARDURB TARGET_IO('U', 11)
#define TARGET_USBDEVFS_REAPURB TARGET_IOWU('U', 12)
#define TARGET_USBDEVFS_REAPURBNDELAY TARGET_IOWU('U', 13)
#define TARGET_USBDEVFS_DISCSIGNAL TARGET_IORU('U', 14)
#define TARGET_USBDEVFS_CLAIMINTERFACE TARGET_IORU('U', 15)
#define TARGET_USBDEVFS_RELEASEINTERFACE TARGET_IORU('U', 16)
#define TARGET_USBDEVFS_CONNECTINFO TARGET_IOWU('U', 17)
#define TARGET_USBDEVFS_IOCTL TARGET_IOWRU('U', 18)
#define TARGET_USBDEVFS_HUB_PORTINFO TARGET_IORU('U', 19)
#define TARGET_USBDEVFS_RESET TARGET_IO('U', 20)
#define TARGET_USBDEVFS_CLEAR_HALT TARGET_IORU('U', 21)
#define TARGET_USBDEVFS_DISCONNECT TARGET_IO('U', 22)
#define TARGET_USBDEVFS_CONNECT TARGET_IO('U', 23)
#define TARGET_USBDEVFS_CLAIM_PORT TARGET_IORU('U', 24)
#define TARGET_USBDEVFS_RELEASE_PORT TARGET_IORU('U', 25)
#define TARGET_USBDEVFS_GET_CAPABILITIES TARGET_IORU('U', 26)
#define TARGET_USBDEVFS_DISCONNECT_CLAIM TARGET_IORU('U', 27)
#define TARGET_USBDEVFS_DROP_PRIVILEGES TARGET_IOWU('U', 30)
#define TARGET_USBDEVFS_GET_SPEED TARGET_IO('U', 31)
/* cdrom commands */
#define TARGET_CDROMPAUSE 0x5301 /* Pause Audio Operation */
#define TARGET_CDROMRESUME 0x5302 /* Resume paused Audio Operation */
#define TARGET_CDROMPLAYMSF 0x5303 /* Play Audio MSF (struct cdrom_msf) */
#define TARGET_CDROMPLAYTRKIND 0x5304 /* Play Audio Track/index
(struct cdrom_ti) */
#define TARGET_CDROMREADTOCHDR 0x5305 /* Read TOC header
(struct cdrom_tochdr) */
#define TARGET_CDROMREADTOCENTRY 0x5306 /* Read TOC entry
(struct cdrom_tocentry) */
#define TARGET_CDROMSTOP 0x5307 /* Stop the cdrom drive */
#define TARGET_CDROMSTART 0x5308 /* Start the cdrom drive */
#define TARGET_CDROMEJECT 0x5309 /* Ejects the cdrom media */
#define TARGET_CDROMVOLCTRL 0x530a /* Control output volume
(struct cdrom_volctrl) */
#define TARGET_CDROMSUBCHNL 0x530b /* Read subchannel data
(struct cdrom_subchnl) */
#define TARGET_CDROMREADMODE2 0x530c /* Read TARGET_CDROM mode 2 data (2336 Bytes)
(struct cdrom_read) */
#define TARGET_CDROMREADMODE1 0x530d /* Read TARGET_CDROM mode 1 data (2048 Bytes)
(struct cdrom_read) */
#define TARGET_CDROMREADAUDIO 0x530e /* (struct cdrom_read_audio) */
#define TARGET_CDROMEJECT_SW 0x530f /* enable(1)/disable(0) auto-ejecting */
#define TARGET_CDROMMULTISESSION 0x5310 /* Obtain the start-of-last-session
address of multi session disks
(struct cdrom_multisession) */
#define TARGET_CDROM_GET_MCN 0x5311 /* Obtain the "Universal Product Code"
if available (struct cdrom_mcn) */
#define TARGET_CDROM_GET_UPC TARGET_CDROM_GET_MCN /* This one is deprecated,
but here anyway for compatibility */
#define TARGET_CDROMRESET 0x5312 /* hard-reset the drive */
#define TARGET_CDROMVOLREAD 0x5313 /* Get the drive's volume setting
(struct cdrom_volctrl) */
#define TARGET_CDROMREADRAW 0x5314 /* read data in raw mode (2352 Bytes)
(struct cdrom_read) */
/*
* These ioctls are used only used in aztcd.c and optcd.c
*/
#define TARGET_CDROMREADCOOKED 0x5315 /* read data in cooked mode */
#define TARGET_CDROMSEEK 0x5316 /* seek msf address */
/*
* This ioctl is only used by the scsi-cd driver.
It is for playing audio in logical block addressing mode.
*/
#define TARGET_CDROMPLAYBLK 0x5317 /* (struct cdrom_blk) */
/*
* These ioctls are only used in optcd.c
*/
#define TARGET_CDROMREADALL 0x5318 /* read all 2646 bytes */
/*
* These ioctls are (now) only in ide-cd.c for controlling
* drive spindown time. They should be implemented in the
* Uniform driver, via generic packet commands, GPCMD_MODE_SELECT_10,
* GPCMD_MODE_SENSE_10 and the GPMODE_POWER_PAGE...
* -Erik
*/
#define TARGET_CDROMGETSPINDOWN 0x531d
#define TARGET_CDROMSETSPINDOWN 0x531e
/*
* These ioctls are implemented through the uniform CD-ROM driver
* They _will_ be adopted by all CD-ROM drivers, when all the CD-ROM
* drivers are eventually ported to the uniform CD-ROM driver interface.
*/
#define TARGET_CDROMCLOSETRAY 0x5319 /* pendant of CDROMEJECT */
#define TARGET_CDROM_SET_OPTIONS 0x5320 /* Set behavior options */
#define TARGET_CDROM_CLEAR_OPTIONS 0x5321 /* Clear behavior options */
#define TARGET_CDROM_SELECT_SPEED 0x5322 /* Set the CD-ROM speed */
#define TARGET_CDROM_SELECT_DISC 0x5323 /* Select disc (for juke-boxes) */
#define TARGET_CDROM_MEDIA_CHANGED 0x5325 /* Check is media changed */
#define TARGET_CDROM_DRIVE_STATUS 0x5326 /* Get tray position, etc. */
#define TARGET_CDROM_DISC_STATUS 0x5327 /* Get disc type, etc. */
#define TARGET_CDROM_CHANGER_NSLOTS 0x5328 /* Get number of slots */
#define TARGET_CDROM_LOCKDOOR 0x5329 /* lock or unlock door */
#define TARGET_CDROM_DEBUG 0x5330 /* Turn debug messages on/off */
#define TARGET_CDROM_GET_CAPABILITY 0x5331 /* get capabilities */
/* Note that scsi/scsi_ioctl.h also uses 0x5382 - 0x5386.
* Future CDROM ioctls should be kept below 0x537F
*/
/* This ioctl is only used by sbpcd at the moment */
#define TARGET_CDROMAUDIOBUFSIZ 0x5382 /* set the audio buffer size */
/* conflict with SCSI_IOCTL_GET_IDLUN */
/* DVD-ROM Specific ioctls */
#define TARGET_DVD_READ_STRUCT 0x5390 /* Read structure */
#define TARGET_DVD_WRITE_STRUCT 0x5391 /* Write structure */
#define TARGET_DVD_AUTH 0x5392 /* Authentication */
#define TARGET_CDROM_SEND_PACKET 0x5393 /* send a packet to the drive */
#define TARGET_CDROM_NEXT_WRITABLE 0x5394 /* get next writable block */
#define TARGET_CDROM_LAST_WRITTEN 0x5395 /* get last block written on disc */
/* HD commands */
/* hd/ide ctl's that pass (arg) ptrs to user space are numbered 0x030n/0x031n */
#define TARGET_HDIO_GETGEO 0x0301 /* get device geometry */
#define TARGET_HDIO_GET_UNMASKINTR 0x0302 /* get current unmask setting */
#define TARGET_HDIO_GET_MULTCOUNT 0x0304 /* get current IDE blockmode setting */
#define TARGET_HDIO_GET_KEEPSETTINGS 0x0308 /* get keep-settings-on-reset flag */
#define TARGET_HDIO_GET_32BIT 0x0309 /* get current io_32bit setting */
#define TARGET_HDIO_GET_NOWERR 0x030a /* get ignore-write-error flag */
#define TARGET_HDIO_GET_DMA 0x030b /* get use-dma flag */
#define TARGET_HDIO_GET_IDENTITY 0x030d /* get IDE identification info */
#define TARGET_HDIO_DRIVE_CMD 0x031f /* execute a special drive command */
/* hd/ide ctl's that pass (arg) non-ptr values are numbered 0x032n/0x033n */
#define TARGET_HDIO_SET_MULTCOUNT 0x0321 /* change IDE blockmode */
#define TARGET_HDIO_SET_UNMASKINTR 0x0322 /* permit other irqs during I/O */
#define TARGET_HDIO_SET_KEEPSETTINGS 0x0323 /* keep ioctl settings on reset */
#define TARGET_HDIO_SET_32BIT 0x0324 /* change io_32bit flags */
#define TARGET_HDIO_SET_NOWERR 0x0325 /* change ignore-write-error flag */
#define TARGET_HDIO_SET_DMA 0x0326 /* change use-dma flag */
#define TARGET_HDIO_SET_PIO_MODE 0x0327 /* reconfig interface to new speed */
/* loop ioctls */
#define TARGET_LOOP_SET_FD 0x4C00
#define TARGET_LOOP_CLR_FD 0x4C01
#define TARGET_LOOP_SET_STATUS 0x4C02
#define TARGET_LOOP_GET_STATUS 0x4C03
#define TARGET_LOOP_SET_STATUS64 0x4C04
#define TARGET_LOOP_GET_STATUS64 0x4C05
#define TARGET_LOOP_CHANGE_FD 0x4C06
#define TARGET_LOOP_SET_CAPACITY 0x4C07
#define TARGET_LOOP_SET_DIRECT_IO 0x4C08
#define TARGET_LOOP_SET_BLOCK_SIZE 0x4C09
#define TARGET_LOOP_CONFIGURE 0x4C0A
#define TARGET_LOOP_CTL_ADD 0x4C80
#define TARGET_LOOP_CTL_REMOVE 0x4C81
#define TARGET_LOOP_CTL_GET_FREE 0x4C82
/* fb ioctls */
#define TARGET_FBIOGET_VSCREENINFO 0x4600
#define TARGET_FBIOPUT_VSCREENINFO 0x4601
#define TARGET_FBIOGET_FSCREENINFO 0x4602
#define TARGET_FBIOGETCMAP 0x4604
#define TARGET_FBIOPUTCMAP 0x4605
#define TARGET_FBIOPAN_DISPLAY 0x4606
#define TARGET_FBIOGET_CON2FBMAP 0x460F
#define TARGET_FBIOPUT_CON2FBMAP 0x4610
/* vt ioctls */
#define TARGET_VT_OPENQRY 0x5600
#define TARGET_VT_GETSTATE 0x5603
#define TARGET_VT_ACTIVATE 0x5606
#define TARGET_VT_WAITACTIVE 0x5607
#define TARGET_VT_LOCKSWITCH 0x560b
#define TARGET_VT_UNLOCKSWITCH 0x560c
#define TARGET_VT_GETMODE 0x5601
#define TARGET_VT_SETMODE 0x5602
#define TARGET_VT_RELDISP 0x5605
#define TARGET_VT_DISALLOCATE 0x5608
/* device mapper */
#define TARGET_DM_VERSION TARGET_IOWRU(0xfd, 0x00)
#define TARGET_DM_REMOVE_ALL TARGET_IOWRU(0xfd, 0x01)
#define TARGET_DM_LIST_DEVICES TARGET_IOWRU(0xfd, 0x02)
#define TARGET_DM_DEV_CREATE TARGET_IOWRU(0xfd, 0x03)
#define TARGET_DM_DEV_REMOVE TARGET_IOWRU(0xfd, 0x04)
#define TARGET_DM_DEV_RENAME TARGET_IOWRU(0xfd, 0x05)
#define TARGET_DM_DEV_SUSPEND TARGET_IOWRU(0xfd, 0x06)
#define TARGET_DM_DEV_STATUS TARGET_IOWRU(0xfd, 0x07)
#define TARGET_DM_DEV_WAIT TARGET_IOWRU(0xfd, 0x08)
#define TARGET_DM_TABLE_LOAD TARGET_IOWRU(0xfd, 0x09)
#define TARGET_DM_TABLE_CLEAR TARGET_IOWRU(0xfd, 0x0a)
#define TARGET_DM_TABLE_DEPS TARGET_IOWRU(0xfd, 0x0b)
#define TARGET_DM_TABLE_STATUS TARGET_IOWRU(0xfd, 0x0c)
#define TARGET_DM_LIST_VERSIONS TARGET_IOWRU(0xfd, 0x0d)
#define TARGET_DM_TARGET_MSG TARGET_IOWRU(0xfd, 0x0e)
#define TARGET_DM_DEV_SET_GEOMETRY TARGET_IOWRU(0xfd, 0x0f)
/* drm ioctls */
#define TARGET_DRM_IOCTL_VERSION TARGET_IOWRU('d', 0x00)
/* drm i915 ioctls */
#define TARGET_DRM_IOCTL_I915_GETPARAM TARGET_IOWRU('d', 0x46)
/* from asm/termbits.h */
#define TARGET_NCC 8
struct target_termio {
unsigned short c_iflag; /* input mode flags */
unsigned short c_oflag; /* output mode flags */
unsigned short c_cflag; /* control mode flags */
unsigned short c_lflag; /* local mode flags */
unsigned char c_line; /* line discipline */
unsigned char c_cc[TARGET_NCC]; /* control characters */
};
struct target_winsize {
unsigned short ws_row;
unsigned short ws_col;
unsigned short ws_xpixel;
unsigned short ws_ypixel;
};
#include "termbits.h"
#if defined(TARGET_MIPS)
#define TARGET_PROT_SEM 0x10
#else
#define TARGET_PROT_SEM 0x08
#endif
#ifdef TARGET_AARCH64
#define TARGET_PROT_BTI 0x10
#define TARGET_PROT_MTE 0x20
#endif
/* Common */
#define TARGET_MAP_SHARED 0x01 /* Share changes */
#define TARGET_MAP_PRIVATE 0x02 /* Changes are private */
#if defined(TARGET_HPPA)
#define TARGET_MAP_TYPE 0x03 /* Mask for type of mapping */
#else
#define TARGET_MAP_TYPE 0x0f /* Mask for type of mapping */
#endif
/* Target specific */
#if defined(TARGET_MIPS)
#define TARGET_MAP_FIXED 0x10 /* Interpret addr exactly */
#define TARGET_MAP_ANONYMOUS 0x0800 /* don't use a file */
#define TARGET_MAP_GROWSDOWN 0x1000 /* stack-like segment */
#define TARGET_MAP_DENYWRITE 0x2000 /* ETXTBSY */
#define TARGET_MAP_EXECUTABLE 0x4000 /* mark it as an executable */
#define TARGET_MAP_LOCKED 0x8000 /* pages are locked */
#define TARGET_MAP_NORESERVE 0x0400 /* don't check for reservations */
#define TARGET_MAP_POPULATE 0x10000 /* populate (prefault) pagetables */
#define TARGET_MAP_NONBLOCK 0x20000 /* do not block on IO */
#define TARGET_MAP_STACK 0x40000 /* ignored */
#define TARGET_MAP_HUGETLB 0x80000 /* create a huge page mapping */
#elif defined(TARGET_PPC)
#define TARGET_MAP_FIXED 0x10 /* Interpret addr exactly */
#define TARGET_MAP_ANONYMOUS 0x20 /* don't use a file */
#define TARGET_MAP_GROWSDOWN 0x0100 /* stack-like segment */
#define TARGET_MAP_DENYWRITE 0x0800 /* ETXTBSY */
#define TARGET_MAP_EXECUTABLE 0x1000 /* mark it as an executable */
#define TARGET_MAP_LOCKED 0x0080 /* pages are locked */
#define TARGET_MAP_NORESERVE 0x0040 /* don't check for reservations */
#define TARGET_MAP_POPULATE 0x8000 /* populate (prefault) pagetables */
#define TARGET_MAP_NONBLOCK 0x10000 /* do not block on IO */
#define TARGET_MAP_STACK 0x20000 /* ignored */
#define TARGET_MAP_HUGETLB 0x40000 /* create a huge page mapping */
#elif defined(TARGET_ALPHA)
#define TARGET_MAP_ANONYMOUS 0x10 /* don't use a file */
#define TARGET_MAP_FIXED 0x100 /* Interpret addr exactly */
#define TARGET_MAP_GROWSDOWN 0x01000 /* stack-like segment */
#define TARGET_MAP_DENYWRITE 0x02000 /* ETXTBSY */
#define TARGET_MAP_EXECUTABLE 0x04000 /* mark it as an executable */
#define TARGET_MAP_LOCKED 0x08000 /* lock the mapping */
#define TARGET_MAP_NORESERVE 0x10000 /* no check for reservations */
#define TARGET_MAP_POPULATE 0x20000 /* pop (prefault) pagetables */
#define TARGET_MAP_NONBLOCK 0x40000 /* do not block on IO */
#define TARGET_MAP_STACK 0x80000 /* ignored */
#define TARGET_MAP_HUGETLB 0x100000 /* create a huge page mapping */
#elif defined(TARGET_HPPA)
#define TARGET_MAP_ANONYMOUS 0x10 /* don't use a file */
#define TARGET_MAP_FIXED 0x04 /* Interpret addr exactly */
#define TARGET_MAP_GROWSDOWN 0x08000 /* stack-like segment */
#define TARGET_MAP_DENYWRITE 0x00800 /* ETXTBSY */
#define TARGET_MAP_EXECUTABLE 0x01000 /* mark it as an executable */
#define TARGET_MAP_LOCKED 0x02000 /* lock the mapping */
#define TARGET_MAP_NORESERVE 0x04000 /* no check for reservations */
#define TARGET_MAP_POPULATE 0x10000 /* pop (prefault) pagetables */
#define TARGET_MAP_NONBLOCK 0x20000 /* do not block on IO */
#define TARGET_MAP_STACK 0x40000 /* ignored */
#define TARGET_MAP_HUGETLB 0x80000 /* create a huge page mapping */
#elif defined(TARGET_XTENSA)
#define TARGET_MAP_FIXED 0x10 /* Interpret addr exactly */
#define TARGET_MAP_ANONYMOUS 0x0800 /* don't use a file */
#define TARGET_MAP_GROWSDOWN 0x1000 /* stack-like segment */
#define TARGET_MAP_DENYWRITE 0x2000 /* ETXTBSY */
#define TARGET_MAP_EXECUTABLE 0x4000 /* mark it as an executable */
#define TARGET_MAP_LOCKED 0x8000 /* pages are locked */
#define TARGET_MAP_NORESERVE 0x0400 /* don't check for reservations */
#define TARGET_MAP_POPULATE 0x10000 /* populate (prefault) pagetables */
#define TARGET_MAP_NONBLOCK 0x20000 /* do not block on IO */
#define TARGET_MAP_STACK 0x40000
#define TARGET_MAP_HUGETLB 0x80000 /* create a huge page mapping */
#else
#define TARGET_MAP_FIXED 0x10 /* Interpret addr exactly */
#define TARGET_MAP_ANONYMOUS 0x20 /* don't use a file */
#define TARGET_MAP_GROWSDOWN 0x0100 /* stack-like segment */
#define TARGET_MAP_DENYWRITE 0x0800 /* ETXTBSY */
#define TARGET_MAP_EXECUTABLE 0x1000 /* mark it as an executable */
#define TARGET_MAP_LOCKED 0x2000 /* pages are locked */
#define TARGET_MAP_NORESERVE 0x4000 /* don't check for reservations */
#define TARGET_MAP_POPULATE 0x8000 /* populate (prefault) pagetables */
#define TARGET_MAP_NONBLOCK 0x10000 /* do not block on IO */
#define TARGET_MAP_STACK 0x20000 /* ignored */
#define TARGET_MAP_HUGETLB 0x40000 /* create a huge page mapping */
#define TARGET_MAP_UNINITIALIZED 0x4000000 /* for anonymous mmap, memory could be uninitialized */
#endif
#if (defined(TARGET_I386) && defined(TARGET_ABI32)) \
|| (defined(TARGET_ARM) && defined(TARGET_ABI32)) \
|| defined(TARGET_CRIS)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
unsigned short st_dev;
unsigned short __pad1;
abi_ulong st_ino;
unsigned short st_mode;
unsigned short st_nlink;
unsigned short st_uid;
unsigned short st_gid;
unsigned short st_rdev;
unsigned short __pad2;
abi_ulong st_size;
abi_ulong st_blksize;
abi_ulong st_blocks;
abi_ulong target_st_atime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_ctime_nsec;
abi_ulong __unused4;
abi_ulong __unused5;
};
/* This matches struct stat64 in glibc2.1, hence the absolutely
* insane amounts of padding around dev_t's.
*/
#define TARGET_HAS_STRUCT_STAT64
struct target_stat64 {
unsigned short st_dev;
unsigned char __pad0[10];
#define TARGET_STAT64_HAS_BROKEN_ST_INO 1
abi_ulong __st_ino;
unsigned int st_mode;
unsigned int st_nlink;
abi_ulong st_uid;
abi_ulong st_gid;
unsigned short st_rdev;
unsigned char __pad3[10];
long long st_size;
abi_ulong st_blksize;
abi_ulong st_blocks; /* Number 512-byte blocks allocated. */
abi_ulong __pad4; /* future possible st_blocks high bits */
abi_ulong target_st_atime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_ctime_nsec;
unsigned long long st_ino;
} QEMU_PACKED;
#ifdef TARGET_ARM
#define TARGET_HAS_STRUCT_STAT64
struct target_eabi_stat64 {
unsigned long long st_dev;
unsigned int __pad1;
abi_ulong __st_ino;
unsigned int st_mode;
unsigned int st_nlink;
abi_ulong st_uid;
abi_ulong st_gid;
unsigned long long st_rdev;
unsigned int __pad2[2];
long long st_size;
abi_ulong st_blksize;
unsigned int __pad3;
unsigned long long st_blocks;
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
unsigned long long st_ino;
} QEMU_PACKED;
#endif
#elif defined(TARGET_SPARC64) && !defined(TARGET_ABI32)
struct target_stat {
unsigned int st_dev;
abi_ulong st_ino;
unsigned int st_mode;
unsigned int st_nlink;
unsigned int st_uid;
unsigned int st_gid;
unsigned int st_rdev;
abi_long st_size;
abi_long target_st_atime;
abi_long target_st_mtime;
abi_long target_st_ctime;
abi_long st_blksize;
abi_long st_blocks;
abi_ulong __unused4[2];
};
#define TARGET_HAS_STRUCT_STAT64
struct target_stat64 {
unsigned char __pad0[6];
unsigned short st_dev;
uint64_t st_ino;
uint64_t st_nlink;
unsigned int st_mode;
unsigned int st_uid;
unsigned int st_gid;
unsigned char __pad2[6];
unsigned short st_rdev;
int64_t st_size;
int64_t st_blksize;
unsigned char __pad4[4];
unsigned int st_blocks;
abi_ulong target_st_atime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_ctime_nsec;
abi_ulong __unused4[3];
};
#elif defined(TARGET_SPARC)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
unsigned short st_dev;
abi_ulong st_ino;
unsigned short st_mode;
short st_nlink;
unsigned short st_uid;
unsigned short st_gid;
unsigned short st_rdev;
abi_long st_size;
abi_long target_st_atime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_atime_nsec;
abi_long target_st_mtime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_mtime_nsec;
abi_long target_st_ctime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong target_st_ctime_nsec;
abi_long st_blksize;
abi_long st_blocks;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
abi_ulong __unused1[2];
};
#define TARGET_HAS_STRUCT_STAT64
struct target_stat64 {
unsigned char __pad0[6];
unsigned short st_dev;
uint64_t st_ino;
unsigned int st_mode;
unsigned int st_nlink;
unsigned int st_uid;
unsigned int st_gid;
unsigned char __pad2[6];
unsigned short st_rdev;
unsigned char __pad3[8];
int64_t st_size;
unsigned int st_blksize;
unsigned char __pad4[8];
unsigned int st_blocks;
unsigned int target_st_atime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
unsigned int target_st_atime_nsec;
unsigned int target_st_mtime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
unsigned int target_st_mtime_nsec;
unsigned int target_st_ctime;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
unsigned int target_st_ctime_nsec;
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
unsigned int __unused1;
unsigned int __unused2;
};
#elif defined(TARGET_PPC)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
abi_ulong st_dev;
abi_ulong st_ino;
#if defined(TARGET_PPC64)
abi_ulong st_nlink;
unsigned int st_mode;
#else
unsigned int st_mode;
unsigned short st_nlink;
#endif
unsigned int st_uid;
unsigned int st_gid;
abi_ulong st_rdev;
abi_ulong st_size;
abi_ulong st_blksize;
abi_ulong st_blocks;
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
abi_ulong __unused4;
abi_ulong __unused5;
#if defined(TARGET_PPC64)
abi_ulong __unused6;
#endif
};
#if !defined(TARGET_PPC64)
#define TARGET_HAS_STRUCT_STAT64
struct QEMU_PACKED target_stat64 {
unsigned long long st_dev;
unsigned long long st_ino;
unsigned int st_mode;
unsigned int st_nlink;
unsigned int st_uid;
unsigned int st_gid;
unsigned long long st_rdev;
unsigned long long __pad0;
long long st_size;
int st_blksize;
unsigned int __pad1;
long long st_blocks; /* Number 512-byte blocks allocated. */
int target_st_atime;
unsigned int target_st_atime_nsec;
int target_st_mtime;
unsigned int target_st_mtime_nsec;
int target_st_ctime;
unsigned int target_st_ctime_nsec;
unsigned int __unused4;
unsigned int __unused5;
};
#endif
#elif defined(TARGET_MICROBLAZE)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
abi_ulong st_dev;
abi_ulong st_ino;
unsigned int st_mode;
unsigned short st_nlink;
unsigned int st_uid;
unsigned int st_gid;
abi_ulong st_rdev;
abi_ulong st_size;
abi_ulong st_blksize;
abi_ulong st_blocks;
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
abi_ulong __unused4;
abi_ulong __unused5;
};
/* FIXME: Microblaze no-mmu user-space has a difference stat64 layout... */
#define TARGET_HAS_STRUCT_STAT64
struct QEMU_PACKED target_stat64 {
uint64_t st_dev;
#define TARGET_STAT64_HAS_BROKEN_ST_INO 1
uint32_t pad0;
uint32_t __st_ino;
uint32_t st_mode;
uint32_t st_nlink;
uint32_t st_uid;
uint32_t st_gid;
uint64_t st_rdev;
uint64_t __pad1;
int64_t st_size;
int32_t st_blksize;
uint32_t __pad2;
int64_t st_blocks; /* Number 512-byte blocks allocated. */
int target_st_atime;
unsigned int target_st_atime_nsec;
int target_st_mtime;
unsigned int target_st_mtime_nsec;
int target_st_ctime;
unsigned int target_st_ctime_nsec;
uint64_t st_ino;
};
#elif defined(TARGET_M68K)
struct target_stat {
unsigned short st_dev;
unsigned short __pad1;
abi_ulong st_ino;
unsigned short st_mode;
unsigned short st_nlink;
unsigned short st_uid;
unsigned short st_gid;
unsigned short st_rdev;
unsigned short __pad2;
abi_ulong st_size;
abi_ulong st_blksize;
abi_ulong st_blocks;
abi_ulong target_st_atime;
abi_ulong __unused1;
abi_ulong target_st_mtime;
abi_ulong __unused2;
abi_ulong target_st_ctime;
abi_ulong __unused3;
abi_ulong __unused4;
abi_ulong __unused5;
};
/* This matches struct stat64 in glibc2.1, hence the absolutely
* insane amounts of padding around dev_t's.
*/
#define TARGET_HAS_STRUCT_STAT64
struct target_stat64 {
unsigned long long st_dev;
unsigned char __pad1[2];
#define TARGET_STAT64_HAS_BROKEN_ST_INO 1
abi_ulong __st_ino;
unsigned int st_mode;
unsigned int st_nlink;
abi_ulong st_uid;
abi_ulong st_gid;
unsigned long long st_rdev;
unsigned char __pad3[2];
long long st_size;
abi_ulong st_blksize;
abi_ulong __pad4; /* future possible st_blocks high bits */
abi_ulong st_blocks; /* Number 512-byte blocks allocated. */
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
unsigned long long st_ino;
} QEMU_PACKED;
#elif defined(TARGET_ABI_MIPSN64)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
/* The memory layout is the same as of struct stat64 of the 32-bit kernel. */
struct target_stat {
unsigned int st_dev;
unsigned int st_pad0[3]; /* Reserved for st_dev expansion */
abi_ulong st_ino;
unsigned int st_mode;
unsigned int st_nlink;
int st_uid;
int st_gid;
unsigned int st_rdev;
unsigned int st_pad1[3]; /* Reserved for st_rdev expansion */
abi_ulong st_size;
/*
* Actually this should be timestruc_t st_atime, st_mtime and st_ctime
* but we don't have it under Linux.
*/
unsigned int target_st_atime;
unsigned int target_st_atime_nsec;
unsigned int target_st_mtime;
unsigned int target_st_mtime_nsec;
unsigned int target_st_ctime;
unsigned int target_st_ctime_nsec;
unsigned int st_blksize;
unsigned int st_pad2;
abi_ulong st_blocks;
};
#elif defined(TARGET_ABI_MIPSN32)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
abi_ulong st_dev;
abi_ulong st_pad0[3]; /* Reserved for st_dev expansion */
uint64_t st_ino;
unsigned int st_mode;
unsigned int st_nlink;
int st_uid;
int st_gid;
abi_ulong st_rdev;
abi_ulong st_pad1[3]; /* Reserved for st_rdev expansion */
int64_t st_size;
abi_long target_st_atime;
abi_ulong target_st_atime_nsec; /* Reserved for st_atime expansion */
abi_long target_st_mtime;
abi_ulong target_st_mtime_nsec; /* Reserved for st_mtime expansion */
abi_long target_st_ctime;
abi_ulong target_st_ctime_nsec; /* Reserved for st_ctime expansion */
abi_ulong st_blksize;
abi_ulong st_pad2;
int64_t st_blocks;
};
#elif defined(TARGET_ABI_MIPSO32)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
unsigned st_dev;
abi_long st_pad1[3]; /* Reserved for network id */
abi_ulong st_ino;
unsigned int st_mode;
unsigned int st_nlink;
int st_uid;
int st_gid;
unsigned st_rdev;
abi_long st_pad2[2];
abi_long st_size;
abi_long st_pad3;
/*
* Actually this should be timestruc_t st_atime, st_mtime and st_ctime
* but we don't have it under Linux.
*/
abi_long target_st_atime;
abi_long target_st_atime_nsec;
abi_long target_st_mtime;
abi_long target_st_mtime_nsec;
abi_long target_st_ctime;
abi_long target_st_ctime_nsec;
abi_long st_blksize;
abi_long st_blocks;
abi_long st_pad4[14];
};
/*
* This matches struct stat64 in glibc2.1, hence the absolutely insane
* amounts of padding around dev_t's. The memory layout is the same as of
* struct stat of the 64-bit kernel.
*/
#define TARGET_HAS_STRUCT_STAT64
struct target_stat64 {
abi_ulong st_dev;
abi_ulong st_pad0[3]; /* Reserved for st_dev expansion */
uint64_t st_ino;
unsigned int st_mode;
unsigned int st_nlink;
int st_uid;
int st_gid;
abi_ulong st_rdev;
abi_ulong st_pad1[3]; /* Reserved for st_rdev expansion */
int64_t st_size;
/*
* Actually this should be timestruc_t st_atime, st_mtime and st_ctime
* but we don't have it under Linux.
*/
abi_long target_st_atime;
abi_ulong target_st_atime_nsec; /* Reserved for st_atime expansion */
abi_long target_st_mtime;
abi_ulong target_st_mtime_nsec; /* Reserved for st_mtime expansion */
abi_long target_st_ctime;
abi_ulong target_st_ctime_nsec; /* Reserved for st_ctime expansion */
abi_ulong st_blksize;
abi_ulong st_pad2;
int64_t st_blocks;
};
#elif defined(TARGET_ALPHA)
struct target_stat {
unsigned int st_dev;
unsigned int st_ino;
unsigned int st_mode;
unsigned int st_nlink;
unsigned int st_uid;
unsigned int st_gid;
unsigned int st_rdev;
abi_long st_size;
abi_ulong target_st_atime;
abi_ulong target_st_mtime;
abi_ulong target_st_ctime;
unsigned int st_blksize;
unsigned int st_blocks;
unsigned int st_flags;
unsigned int st_gen;
};
#define TARGET_HAS_STRUCT_STAT64
struct target_stat64 {
abi_ulong st_dev;
abi_ulong st_ino;
abi_ulong st_rdev;
abi_long st_size;
abi_ulong st_blocks;
unsigned int st_mode;
unsigned int st_uid;
unsigned int st_gid;
unsigned int st_blksize;
unsigned int st_nlink;
unsigned int __pad0;
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
abi_long __unused[3];
};
#elif defined(TARGET_SH4)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
abi_ulong st_dev;
abi_ulong st_ino;
unsigned short st_mode;
unsigned short st_nlink;
unsigned short st_uid;
unsigned short st_gid;
abi_ulong st_rdev;
abi_ulong st_size;
abi_ulong st_blksize;
abi_ulong st_blocks;
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
abi_ulong __unused4;
abi_ulong __unused5;
};
/* This matches struct stat64 in glibc2.1, hence the absolutely
* insane amounts of padding around dev_t's.
*/
#define TARGET_HAS_STRUCT_STAT64
struct QEMU_PACKED target_stat64 {
unsigned long long st_dev;
unsigned char __pad0[4];
#define TARGET_STAT64_HAS_BROKEN_ST_INO 1
abi_ulong __st_ino;
unsigned int st_mode;
unsigned int st_nlink;
abi_ulong st_uid;
abi_ulong st_gid;
unsigned long long st_rdev;
unsigned char __pad3[4];
long long st_size;
abi_ulong st_blksize;
unsigned long long st_blocks; /* Number 512-byte blocks allocated. */
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
unsigned long long st_ino;
};
#elif defined(TARGET_I386) && !defined(TARGET_ABI32)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
abi_ulong st_dev;
abi_ulong st_ino;
abi_ulong st_nlink;
unsigned int st_mode;
unsigned int st_uid;
unsigned int st_gid;
unsigned int __pad0;
abi_ulong st_rdev;
abi_long st_size;
abi_long st_blksize;
abi_long st_blocks; /* Number 512-byte blocks allocated. */
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
abi_long __unused[3];
};
#elif defined(TARGET_S390X)
struct target_stat {
abi_ulong st_dev;
abi_ulong st_ino;
abi_ulong st_nlink;
unsigned int st_mode;
unsigned int st_uid;
unsigned int st_gid;
unsigned int __pad1;
abi_ulong st_rdev;
abi_ulong st_size;
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
abi_ulong st_blksize;
abi_long st_blocks;
abi_ulong __unused[3];
};
#elif defined(TARGET_AARCH64)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
abi_ulong st_dev;
abi_ulong st_ino;
unsigned int st_mode;
unsigned int st_nlink;
unsigned int st_uid;
unsigned int st_gid;
abi_ulong st_rdev;
abi_ulong _pad1;
abi_long st_size;
int st_blksize;
int __pad2;
abi_long st_blocks;
abi_long target_st_atime;
abi_ulong target_st_atime_nsec;
abi_long target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_long target_st_ctime;
abi_ulong target_st_ctime_nsec;
unsigned int __unused[2];
};
#elif defined(TARGET_XTENSA)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
abi_ulong st_dev;
abi_ulong st_ino;
unsigned int st_mode;
unsigned int st_nlink;
unsigned int st_uid;
unsigned int st_gid;
abi_ulong st_rdev;
abi_long st_size;
abi_ulong st_blksize;
abi_ulong st_blocks;
abi_ulong target_st_atime;
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime;
abi_ulong target_st_ctime_nsec;
abi_ulong __unused4;
abi_ulong __unused5;
};
#define TARGET_HAS_STRUCT_STAT64
struct target_stat64 {
uint64_t st_dev; /* Device */
uint64_t st_ino; /* File serial number */
unsigned int st_mode; /* File mode. */
unsigned int st_nlink; /* Link count. */
unsigned int st_uid; /* User ID of the file's owner. */
unsigned int st_gid; /* Group ID of the file's group. */
uint64_t st_rdev; /* Device number, if device. */
int64_t st_size; /* Size of file, in bytes. */
abi_ulong st_blksize; /* Optimal block size for I/O. */
abi_ulong __unused2;
uint64_t st_blocks; /* Number 512-byte blocks allocated. */
abi_ulong target_st_atime; /* Time of last access. */
abi_ulong target_st_atime_nsec;
abi_ulong target_st_mtime; /* Time of last modification. */
abi_ulong target_st_mtime_nsec;
abi_ulong target_st_ctime; /* Time of last status change. */
abi_ulong target_st_ctime_nsec;
abi_ulong __unused4;
abi_ulong __unused5;
};
#elif defined(TARGET_OPENRISC) || defined(TARGET_NIOS2) \
|| defined(TARGET_RISCV) || defined(TARGET_HEXAGON)
/* These are the asm-generic versions of the stat and stat64 structures */
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
abi_ulong st_dev;
abi_ulong st_ino;
unsigned int st_mode;
unsigned int st_nlink;
unsigned int st_uid;
unsigned int st_gid;
abi_ulong st_rdev;
abi_ulong __pad1;
abi_long st_size;
int st_blksize;
int __pad2;
abi_long st_blocks;
abi_long target_st_atime;
abi_ulong target_st_atime_nsec;
abi_long target_st_mtime;
abi_ulong target_st_mtime_nsec;
abi_long target_st_ctime;
abi_ulong target_st_ctime_nsec;
unsigned int __unused4;
unsigned int __unused5;
};
#if !defined(TARGET_RISCV64)
#define TARGET_HAS_STRUCT_STAT64
struct target_stat64 {
uint64_t st_dev;
uint64_t st_ino;
unsigned int st_mode;
unsigned int st_nlink;
unsigned int st_uid;
unsigned int st_gid;
uint64_t st_rdev;
uint64_t __pad1;
int64_t st_size;
int st_blksize;
int __pad2;
int64_t st_blocks;
int target_st_atime;
unsigned int target_st_atime_nsec;
int target_st_mtime;
unsigned int target_st_mtime_nsec;
int target_st_ctime;
unsigned int target_st_ctime_nsec;
unsigned int __unused4;
unsigned int __unused5;
};
#endif
#elif defined(TARGET_HPPA)
linux-user: Pass through nanosecond timestamp components for stat syscalls Since Linux 2.6 the stat syscalls have mostly supported nanosecond components for each of the file-related timestamps. QEMU user mode emulation currently does not pass through the nanosecond portion of the timestamp, even when the host system fills in the value. This results in a mismatch when run on subsecond resolution filesystems such as ext4 or XFS. An example of this leading to inconsistency is cross-debootstraping a full desktop root filesystem of Debian Buster. Recent versions of fontconfig store the full timestamp (instead of just the second portion) of the directory in its per-directory cache file, and checks this against the directory to see if the cache is up-to-date. With QEMU user mode emulation, the timestamp stored is incorrect, and upon booting the rootfs natively, fontconfig discovers the mismatch, and proceeds to rebuild the cache on the comparatively slow machine (low-power ARM vs x86). This stalls the first attempt to open whatever application that incorporates fontconfig. This patch renames the "unused" padding trailing each timestamp element to its nanosecond counterpart name if such an element exists in the kernel sources for the given platform. Not all do. Then have the syscall wrapper fill in the nanosecond portion if the host supports it, as specified by the _POSIX_C_SOURCE and _XOPEN_SOURCE feature macros. Recent versions of glibc only use stat64 and newfstatat syscalls on 32-bit and 64-bit platforms respectively. The changes in this patch were tested by directly calling the stat, stat64 and newfstatat syscalls directly, in addition to the glibc wrapper, on arm and aarch64 little endian targets. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Chen-Yu Tsai <wens@csie.org> Message-Id: <20190522162147.26303-1-wens@kernel.org> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-05-22 19:21:47 +03:00
#define TARGET_STAT_HAVE_NSEC
struct target_stat {
abi_uint st_dev;
abi_uint st_ino;
abi_ushort st_mode;
abi_ushort st_nlink;
abi_ushort _res1;
abi_ushort _res2;
abi_uint st_rdev;
abi_int st_size;
abi_int target_st_atime;
abi_uint target_st_atime_nsec;
abi_int target_st_mtime;
abi_uint target_st_mtime_nsec;
abi_int target_st_ctime;
abi_uint target_st_ctime_nsec;
abi_int st_blksize;
abi_int st_blocks;
abi_uint _unused1;
abi_uint _unused2;
abi_uint _unused3;
abi_uint _unused4;
abi_ushort _unused5;
abi_short st_fstype;
abi_uint st_realdev;
abi_ushort st_basemode;
abi_ushort _unused6;
abi_uint st_uid;
abi_uint st_gid;
abi_uint _unused7[3];
};
#define TARGET_HAS_STRUCT_STAT64
struct target_stat64 {
uint64_t st_dev;
abi_uint _pad1;
abi_uint _res1;
abi_uint st_mode;
abi_uint st_nlink;
abi_uint st_uid;
abi_uint st_gid;
uint64_t st_rdev;
abi_uint _pad2;
int64_t st_size;
abi_int st_blksize;
int64_t st_blocks;
abi_int target_st_atime;
abi_uint target_st_atime_nsec;
abi_int target_st_mtime;
abi_uint target_st_mtime_nsec;
abi_int target_st_ctime;
abi_uint target_st_ctime_nsec;
uint64_t st_ino;
};
#else
#error unsupported CPU
#endif
typedef struct {
int val[2];
} target_fsid_t;
#ifdef TARGET_MIPS
#ifdef TARGET_ABI_MIPSN32
struct target_statfs {
int32_t f_type;
int32_t f_bsize;
int32_t f_frsize; /* Fragment size - unsupported */
int32_t f_blocks;
int32_t f_bfree;
int32_t f_files;
int32_t f_ffree;
int32_t f_bavail;
/* Linux specials */
target_fsid_t f_fsid;
int32_t f_namelen;
int32_t f_flags;
int32_t f_spare[5];
};
#else
struct target_statfs {
abi_long f_type;
abi_long f_bsize;
abi_long f_frsize; /* Fragment size - unsupported */
abi_long f_blocks;
abi_long f_bfree;
abi_long f_files;
abi_long f_ffree;
abi_long f_bavail;
/* Linux specials */
target_fsid_t f_fsid;
abi_long f_namelen;
abi_long f_flags;
abi_long f_spare[5];
};
#endif
struct target_statfs64 {
uint32_t f_type;
uint32_t f_bsize;
uint32_t f_frsize; /* Fragment size - unsupported */
uint32_t __pad;
uint64_t f_blocks;
uint64_t f_bfree;
uint64_t f_files;
uint64_t f_ffree;
uint64_t f_bavail;
target_fsid_t f_fsid;
uint32_t f_namelen;
uint32_t f_flags;
uint32_t f_spare[5];
};
#elif (defined(TARGET_PPC64) || defined(TARGET_X86_64) || \
defined(TARGET_SPARC64) || defined(TARGET_AARCH64) || \
defined(TARGET_RISCV)) && !defined(TARGET_ABI32)
struct target_statfs {
abi_long f_type;
abi_long f_bsize;
abi_long f_blocks;
abi_long f_bfree;
abi_long f_bavail;
abi_long f_files;
abi_long f_ffree;
target_fsid_t f_fsid;
abi_long f_namelen;
abi_long f_frsize;
abi_long f_flags;
abi_long f_spare[4];
};
struct target_statfs64 {
abi_long f_type;
abi_long f_bsize;
abi_long f_blocks;
abi_long f_bfree;
abi_long f_bavail;
abi_long f_files;
abi_long f_ffree;
target_fsid_t f_fsid;
abi_long f_namelen;
abi_long f_frsize;
abi_long f_flags;
abi_long f_spare[4];
};
#elif defined(TARGET_S390X)
struct target_statfs {
int32_t f_type;
int32_t f_bsize;
abi_long f_blocks;
abi_long f_bfree;
abi_long f_bavail;
abi_long f_files;
abi_long f_ffree;
kernel_fsid_t f_fsid;
int32_t f_namelen;
int32_t f_frsize;
int32_t f_flags;
int32_t f_spare[4];
};
struct target_statfs64 {
int32_t f_type;
int32_t f_bsize;
abi_long f_blocks;
abi_long f_bfree;
abi_long f_bavail;
abi_long f_files;
abi_long f_ffree;
kernel_fsid_t f_fsid;
int32_t f_namelen;
int32_t f_frsize;
int32_t f_flags;
int32_t f_spare[4];
};
#else
struct target_statfs {
uint32_t f_type;
uint32_t f_bsize;
uint32_t f_blocks;
uint32_t f_bfree;
uint32_t f_bavail;
uint32_t f_files;
uint32_t f_ffree;
target_fsid_t f_fsid;
uint32_t f_namelen;
uint32_t f_frsize;
uint32_t f_flags;
uint32_t f_spare[4];
};
struct target_statfs64 {
uint32_t f_type;
uint32_t f_bsize;
uint64_t f_blocks;
uint64_t f_bfree;
uint64_t f_bavail;
uint64_t f_files;
uint64_t f_ffree;
target_fsid_t f_fsid;
uint32_t f_namelen;
uint32_t f_frsize;
uint32_t f_flags;
uint32_t f_spare[4];
};
#endif
#define TARGET_F_LINUX_SPECIFIC_BASE 1024
#define TARGET_F_SETLEASE (TARGET_F_LINUX_SPECIFIC_BASE + 0)
#define TARGET_F_GETLEASE (TARGET_F_LINUX_SPECIFIC_BASE + 1)
#define TARGET_F_DUPFD_CLOEXEC (TARGET_F_LINUX_SPECIFIC_BASE + 6)
#define TARGET_F_NOTIFY (TARGET_F_LINUX_SPECIFIC_BASE + 2)
#define TARGET_F_SETPIPE_SZ (TARGET_F_LINUX_SPECIFIC_BASE + 7)
#define TARGET_F_GETPIPE_SZ (TARGET_F_LINUX_SPECIFIC_BASE + 8)
#define TARGET_F_ADD_SEALS (TARGET_F_LINUX_SPECIFIC_BASE + 9)
#define TARGET_F_GET_SEALS (TARGET_F_LINUX_SPECIFIC_BASE + 10)
#include "target_fcntl.h"
/* soundcard defines */
/* XXX: convert them all to arch independent entries */
#define TARGET_SNDCTL_COPR_HALT TARGET_IOWR('C', 7, int);
#define TARGET_SNDCTL_COPR_LOAD 0xcfb04301
#define TARGET_SNDCTL_COPR_RCODE 0xc0144303
#define TARGET_SNDCTL_COPR_RCVMSG 0x8fa44309
#define TARGET_SNDCTL_COPR_RDATA 0xc0144302
#define TARGET_SNDCTL_COPR_RESET 0x00004300
#define TARGET_SNDCTL_COPR_RUN 0xc0144306
#define TARGET_SNDCTL_COPR_SENDMSG 0xcfa44308
#define TARGET_SNDCTL_COPR_WCODE 0x40144305
#define TARGET_SNDCTL_COPR_WDATA 0x40144304
#define TARGET_SNDCTL_DSP_RESET TARGET_IO('P', 0)
#define TARGET_SNDCTL_DSP_SYNC TARGET_IO('P', 1)
#define TARGET_SNDCTL_DSP_SPEED TARGET_IOWR('P', 2, int)
#define TARGET_SNDCTL_DSP_STEREO TARGET_IOWR('P', 3, int)
#define TARGET_SNDCTL_DSP_GETBLKSIZE TARGET_IOWR('P', 4, int)
#define TARGET_SNDCTL_DSP_SETFMT TARGET_IOWR('P', 5, int)
#define TARGET_SNDCTL_DSP_CHANNELS TARGET_IOWR('P', 6, int)
#define TARGET_SOUND_PCM_WRITE_FILTER TARGET_IOWR('P', 7, int)
#define TARGET_SNDCTL_DSP_POST TARGET_IO('P', 8)
#define TARGET_SNDCTL_DSP_SUBDIVIDE TARGET_IOWR('P', 9, int)
#define TARGET_SNDCTL_DSP_SETFRAGMENT TARGET_IOWR('P',10, int)
#define TARGET_SNDCTL_DSP_GETFMTS TARGET_IOR('P', 11, int)
#define TARGET_SNDCTL_DSP_GETOSPACE TARGET_IORU('P',12)
#define TARGET_SNDCTL_DSP_GETISPACE TARGET_IORU('P',13)
#define TARGET_SNDCTL_DSP_GETCAPS TARGET_IOR('P', 15, int)
#define TARGET_SNDCTL_DSP_GETTRIGGER TARGET_IOR('P',16, int)
#define TARGET_SNDCTL_DSP_GETIPTR TARGET_IORU('P',17)
#define TARGET_SNDCTL_DSP_GETOPTR TARGET_IORU('P',18)
#define TARGET_SNDCTL_DSP_MAPINBUF TARGET_IORU('P', 19)
#define TARGET_SNDCTL_DSP_MAPOUTBUF TARGET_IORU('P', 20)
#define TARGET_SNDCTL_DSP_NONBLOCK 0x0000500e
#define TARGET_SNDCTL_DSP_SAMPLESIZE 0xc0045005
#define TARGET_SNDCTL_DSP_SETDUPLEX 0x00005016
#define TARGET_SNDCTL_DSP_SETSYNCRO 0x00005015
#define TARGET_SNDCTL_DSP_SETTRIGGER 0x40045010
#define TARGET_SNDCTL_FM_4OP_ENABLE 0x4004510f
#define TARGET_SNDCTL_FM_LOAD_INSTR 0x40285107
#define TARGET_SNDCTL_MIDI_INFO 0xc074510c
#define TARGET_SNDCTL_MIDI_MPUCMD 0xc0216d02
#define TARGET_SNDCTL_MIDI_MPUMODE 0xc0046d01
#define TARGET_SNDCTL_MIDI_PRETIME 0xc0046d00
#define TARGET_SNDCTL_PMGR_ACCESS 0xcfb85110
#define TARGET_SNDCTL_PMGR_IFACE 0xcfb85001
#define TARGET_SNDCTL_SEQ_CTRLRATE 0xc0045103
#define TARGET_SNDCTL_SEQ_GETINCOUNT 0x80045105
#define TARGET_SNDCTL_SEQ_GETOUTCOUNT 0x80045104
#define TARGET_SNDCTL_SEQ_NRMIDIS 0x8004510b
#define TARGET_SNDCTL_SEQ_NRSYNTHS 0x8004510a
#define TARGET_SNDCTL_SEQ_OUTOFBAND 0x40085112
#define TARGET_SNDCTL_SEQ_PANIC 0x00005111
#define TARGET_SNDCTL_SEQ_PERCMODE 0x40045106
#define TARGET_SNDCTL_SEQ_RESET 0x00005100
#define TARGET_SNDCTL_SEQ_RESETSAMPLES 0x40045109
#define TARGET_SNDCTL_SEQ_SYNC 0x00005101
#define TARGET_SNDCTL_SEQ_TESTMIDI 0x40045108
#define TARGET_SNDCTL_SEQ_THRESHOLD 0x4004510d
#define TARGET_SNDCTL_SEQ_TRESHOLD 0x4004510d
#define TARGET_SNDCTL_SYNTH_INFO 0xc08c5102
#define TARGET_SNDCTL_SYNTH_MEMAVL 0xc004510e
#define TARGET_SNDCTL_TMR_CONTINUE 0x00005404
#define TARGET_SNDCTL_TMR_METRONOME 0x40045407
#define TARGET_SNDCTL_TMR_SELECT 0x40045408
#define TARGET_SNDCTL_TMR_SOURCE 0xc0045406
#define TARGET_SNDCTL_TMR_START 0x00005402
#define TARGET_SNDCTL_TMR_STOP 0x00005403
#define TARGET_SNDCTL_TMR_TEMPO 0xc0045405
#define TARGET_SNDCTL_TMR_TIMEBASE 0xc0045401
#define TARGET_SOUND_PCM_READ_RATE 0x80045002
#define TARGET_SOUND_PCM_READ_CHANNELS 0x80045006
#define TARGET_SOUND_PCM_READ_BITS 0x80045005
#define TARGET_SOUND_PCM_READ_FILTER 0x80045007
#define TARGET_SOUND_MIXER_INFO TARGET_IOR ('M', 101, mixer_info)
#define TARGET_SOUND_MIXER_ACCESS 0xc0804d66
#define TARGET_SOUND_MIXER_PRIVATE1 TARGET_IOWR('M', 111, int)
#define TARGET_SOUND_MIXER_PRIVATE2 TARGET_IOWR('M', 112, int)
#define TARGET_SOUND_MIXER_PRIVATE3 TARGET_IOWR('M', 113, int)
#define TARGET_SOUND_MIXER_PRIVATE4 TARGET_IOWR('M', 114, int)
#define TARGET_SOUND_MIXER_PRIVATE5 TARGET_IOWR('M', 115, int)
#define TARGET_MIXER_READ(dev) TARGET_IOR('M', dev, int)
#define TARGET_SOUND_MIXER_READ_VOLUME TARGET_MIXER_READ(SOUND_MIXER_VOLUME)
#define TARGET_SOUND_MIXER_READ_BASS TARGET_MIXER_READ(SOUND_MIXER_BASS)
#define TARGET_SOUND_MIXER_READ_TREBLE TARGET_MIXER_READ(SOUND_MIXER_TREBLE)
#define TARGET_SOUND_MIXER_READ_SYNTH TARGET_MIXER_READ(SOUND_MIXER_SYNTH)
#define TARGET_SOUND_MIXER_READ_PCM TARGET_MIXER_READ(SOUND_MIXER_PCM)
#define TARGET_SOUND_MIXER_READ_SPEAKER TARGET_MIXER_READ(SOUND_MIXER_SPEAKER)
#define TARGET_SOUND_MIXER_READ_LINE TARGET_MIXER_READ(SOUND_MIXER_LINE)
#define TARGET_SOUND_MIXER_READ_MIC TARGET_MIXER_READ(SOUND_MIXER_MIC)
#define TARGET_SOUND_MIXER_READ_CD TARGET_MIXER_READ(SOUND_MIXER_CD)
#define TARGET_SOUND_MIXER_READ_IMIX TARGET_MIXER_READ(SOUND_MIXER_IMIX)
#define TARGET_SOUND_MIXER_READ_ALTPCM TARGET_MIXER_READ(SOUND_MIXER_ALTPCM)
#define TARGET_SOUND_MIXER_READ_RECLEV TARGET_MIXER_READ(SOUND_MIXER_RECLEV)
#define TARGET_SOUND_MIXER_READ_IGAIN TARGET_MIXER_READ(SOUND_MIXER_IGAIN)
#define TARGET_SOUND_MIXER_READ_OGAIN TARGET_MIXER_READ(SOUND_MIXER_OGAIN)
#define TARGET_SOUND_MIXER_READ_LINE1 TARGET_MIXER_READ(SOUND_MIXER_LINE1)
#define TARGET_SOUND_MIXER_READ_LINE2 TARGET_MIXER_READ(SOUND_MIXER_LINE2)
#define TARGET_SOUND_MIXER_READ_LINE3 TARGET_MIXER_READ(SOUND_MIXER_LINE3)
/* Obsolete macros */
#define TARGET_SOUND_MIXER_READ_MUTE TARGET_MIXER_READ(SOUND_MIXER_MUTE)
#define TARGET_SOUND_MIXER_READ_ENHANCE TARGET_MIXER_READ(SOUND_MIXER_ENHANCE)
#define TARGET_SOUND_MIXER_READ_LOUD TARGET_MIXER_READ(SOUND_MIXER_LOUD)
#define TARGET_SOUND_MIXER_READ_RECSRC TARGET_MIXER_READ(SOUND_MIXER_RECSRC)
#define TARGET_SOUND_MIXER_READ_DEVMASK TARGET_MIXER_READ(SOUND_MIXER_DEVMASK)
#define TARGET_SOUND_MIXER_READ_RECMASK TARGET_MIXER_READ(SOUND_MIXER_RECMASK)
#define TARGET_SOUND_MIXER_READ_STEREODEVS TARGET_MIXER_READ(SOUND_MIXER_STEREODEVS)
#define TARGET_SOUND_MIXER_READ_CAPS TARGET_MIXER_READ(SOUND_MIXER_CAPS)
#define TARGET_MIXER_WRITE(dev) TARGET_IOWR('M', dev, int)
#define TARGET_SOUND_MIXER_WRITE_VOLUME TARGET_MIXER_WRITE(SOUND_MIXER_VOLUME)
#define TARGET_SOUND_MIXER_WRITE_BASS TARGET_MIXER_WRITE(SOUND_MIXER_BASS)
#define TARGET_SOUND_MIXER_WRITE_TREBLE TARGET_MIXER_WRITE(SOUND_MIXER_TREBLE)
#define TARGET_SOUND_MIXER_WRITE_SYNTH TARGET_MIXER_WRITE(SOUND_MIXER_SYNTH)
#define TARGET_SOUND_MIXER_WRITE_PCM TARGET_MIXER_WRITE(SOUND_MIXER_PCM)
#define TARGET_SOUND_MIXER_WRITE_SPEAKER TARGET_MIXER_WRITE(SOUND_MIXER_SPEAKER)
#define TARGET_SOUND_MIXER_WRITE_LINE TARGET_MIXER_WRITE(SOUND_MIXER_LINE)
#define TARGET_SOUND_MIXER_WRITE_MIC TARGET_MIXER_WRITE(SOUND_MIXER_MIC)
#define TARGET_SOUND_MIXER_WRITE_CD TARGET_MIXER_WRITE(SOUND_MIXER_CD)
#define TARGET_SOUND_MIXER_WRITE_IMIX TARGET_MIXER_WRITE(SOUND_MIXER_IMIX)
#define TARGET_SOUND_MIXER_WRITE_ALTPCM TARGET_MIXER_WRITE(SOUND_MIXER_ALTPCM)
#define TARGET_SOUND_MIXER_WRITE_RECLEV TARGET_MIXER_WRITE(SOUND_MIXER_RECLEV)
#define TARGET_SOUND_MIXER_WRITE_IGAIN TARGET_MIXER_WRITE(SOUND_MIXER_IGAIN)
#define TARGET_SOUND_MIXER_WRITE_OGAIN TARGET_MIXER_WRITE(SOUND_MIXER_OGAIN)
#define TARGET_SOUND_MIXER_WRITE_LINE1 TARGET_MIXER_WRITE(SOUND_MIXER_LINE1)
#define TARGET_SOUND_MIXER_WRITE_LINE2 TARGET_MIXER_WRITE(SOUND_MIXER_LINE2)
#define TARGET_SOUND_MIXER_WRITE_LINE3 TARGET_MIXER_WRITE(SOUND_MIXER_LINE3)
/* Obsolete macros */
#define TARGET_SOUND_MIXER_WRITE_MUTE TARGET_MIXER_WRITE(SOUND_MIXER_MUTE)
#define TARGET_SOUND_MIXER_WRITE_ENHANCE TARGET_MIXER_WRITE(SOUND_MIXER_ENHANCE)
#define TARGET_SOUND_MIXER_WRITE_LOUD TARGET_MIXER_WRITE(SOUND_MIXER_LOUD)
#define TARGET_SOUND_MIXER_WRITE_RECSRC TARGET_MIXER_WRITE(SOUND_MIXER_RECSRC)
linux-user: Add support for getting/setting specified alsa timer parameters using ioctls This patch implements functionalities of following ioctls: SNDRV_TIMER_IOCTL_GINFO - Getting information about specified timer Read information about the specified timer. The information about the timer is returned in the following structure: struct snd_timer_ginfo { struct snd_timer_id tid; /* requested timer ID */ unsigned int flags; /* timer flags - SNDRV_TIMER_FLG_* */ int card; /* card number */ unsigned char id[64]; /* timer identification */ unsigned char name[80]; /* timer name */ unsigned long reserved0; /* reserved for future use */ unsigned long resolution; /* average period resolution in ns */ unsigned long resolution_min; /* minimal period resolution in ns */ unsigned long resolution_max; /* maximal period resolution in ns */ unsigned int clients; /* active timer clients */ unsigned char reserved[32]; /* reserved */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling the ioctl, the field "tid" should be initialized with the id information for the timer which information is to be obtained. After the ioctl call, the rest of the structure fields are filled with values from the timer device with the specified id. If there is no device with the specified id, the error ENODEV ("No such device") is returned. SNDRV_TIMER_IOCTL_GPARAMS - Setting precise period duration Sets timer precise period duration numerator and denominator in seconds. The period duration is set in the following structure: struct snd_timer_gparams { struct snd_timer_id tid; /* requested timer ID */ unsigned long period_num; /* period duration - numerator */ unsigned long period_den; /* period duration - denominator */ unsigned char reserved[32]; /* reserved */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling the ioctl, the field "tid" should be initialized with the id information for the timer which period duration is to be set. Also, the fileds "period_num" and "period_den" should be filled with the period duration numerator and denominator values that are to be set respectively. If there is no device with the specified id, the error ENODEV ("No such device") is returned. SNDRV_TIMER_IOCTL_GSTATUS - Getting current period resolution Read timer current period resolution in nanoseconds and period resolution numerator and denominator in seconds. The period resolution information is returned in the following structure: struct snd_timer_gstatus { struct snd_timer_id tid; /* requested timer ID */ unsigned long resolution; /* current period resolution in ns */ unsigned long resolution_num; /* period resolution - numerator */ unsigned long resolution_den; /* period resolution - denominator */ unsigned char reserved[32]; /* reserved for future use */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling the ioctl, the field "tid" should be initialized with the id information for the timer which period resolution is to be obtained. After the ioctl call, the rest of the structure fields are filled with values from the timer device with the specified id. If there is no device with the specified id, the error ENODEV ("No such device") is returned. Implementation notes: All ioctls in this patch have pointer to some kind of a structure as their third argument. That is the reason why corresponding definitions were added in 'linux-user/syscall_types.h'. All of these strcutures have some fields that are of type 'unsigned long'. That is the reason why separate target structures were defined in 'linux-user/syscall_defs.h'. Also, all of the structures have a field with type 'struct snd_timer_id' which is the reason why a separate target structure 'struct target_snd_timer_id' was also defined. The rest of the implementation was straightforward. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-10-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:43 +03:00
struct target_snd_timer_id {
int dev_class;
int dev_sclass;
int card;
int device;
int subdevice;
};
struct target_snd_timer_ginfo {
struct target_snd_timer_id tid;
unsigned int flags;
int card;
unsigned char id[64];
unsigned char name[80];
abi_ulong reserved0;
abi_ulong resolution;
abi_ulong resolution_min;
abi_ulong resolution_max;
unsigned int clients;
unsigned char reserved[32];
};
struct target_snd_timer_gparams {
struct target_snd_timer_id tid;
abi_ulong period_num;
abi_ulong period_den;
unsigned char reserved[32];
};
struct target_snd_timer_gstatus {
struct target_snd_timer_id tid;
abi_ulong resolution;
abi_ulong resolution_num;
abi_ulong resolution_den;
unsigned char reserved[32];
};
struct target_snd_timer_select {
struct target_snd_timer_id id;
unsigned char reserved[32];
};
linux-user: Add support for getting/setting selected alsa timer parameters using ioctls This patch implements functionalities of following ioctls: SNDRV_TIMER_IOCTL_INFO - Getting information about selected timer Read information about the selected timer. The information is returned in the following structure: struct snd_timer_info { unsigned int flags; /* timer flags - SNDRV_TIMER_FLG_* */ int card; /* card number */ unsigned char id[64]; /* timer identificator */ unsigned char name[80]; /* timer name */ unsigned long reserved0; /* reserved for future use */ unsigned long resolution; /* average period resolution in ns */ unsigned char reserved[64]; /* reserved for future use */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer which information is to be obtained. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. SNDRV_TIMER_IOCTL_PARAMS - Setting parameters for selected timer Sets parameters for the selected timer. The paramaters are set in the following structure: struct snd_timer_params { unsigned int flags; /* flags - SNDRV_TIMER_PSFLG_* */ unsigned int ticks; /* requested resolution in ticks */ unsigned int queue_size; /* total size of queue (32-1024) */ unsigned int reserved0; /* reserved, was: failure locations */ unsigned int filter; /* event filter */ unsigned char reserved[60]; /* reserved */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer which parameters are to be set. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. SNDRV_TIMER_IOCTL_STATUS - Getting status of selected timer Read status of the selected timer. The status of the timer is returned in the following structure: struct snd_timer_status { struct timespec tstamp; /* Timestamp - last update */ unsigned int resolution; /* current period resolution in ns */ unsigned int lost; /* counter of master tick lost */ unsigned int overrun; /* count of read queue overruns */ unsigned int queue; /* used queue size */ unsigned char reserved[64]; /* reserved */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer which status is to be obtained. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. Implementation notes: All ioctls in this patch have pointer to some kind of a structure as their third argument. That is the reason why corresponding definitions were added in 'linux-user/syscall_types.h'. Structure 'snd_timer_status' has field of type 'struct timespec' which is why a corresponding definition of that structure was also added in 'linux-user/syscall_types.h'. All of these strucutures have some fields that are of type 'unsigned long'. That is the reason why separate target structures were defined in 'linux-user/syscall_defs.h'. Structure 'struct timespec' already had a separate target definition so that definition was used to define a target structure for 'snd_timer_status'. The rest of the implementation was straightforward. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-12-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:45 +03:00
struct target_snd_timer_info {
unsigned int flags;
int card;
unsigned char id[64];
unsigned char name[80];
abi_ulong reserved0;
abi_ulong resolution;
unsigned char reserved[64];
};
struct target_snd_timer_status {
struct target_timespec tstamp;
unsigned int resolution;
unsigned int lost;
unsigned int overrun;
unsigned int queue;
unsigned char reserved[64];
};
linux-user: Add support for getting alsa timer version and id This patch implements functionalities of following ioctls: SNDRV_TIMER_IOCTL_PVERSION - Getting the sound timer version Read the sound timer version. The third ioctl's argument is a pointer to an int in which the specified timers version is returned. SNDRV_TIMER_IOCTL_NEXT_DEVICE - Getting id information about next timer Read id information about the next timer device from the sound timer device list. The id infomration is returned in the following structure: struct snd_timer_id { int dev_class; /* timer device class number */ int dev_sclass; /* slave device class number (unused) */ int card; /* card number */ int device; /* device number */ int subdevice; /* sub-device number */ }; The devices in the sound timer device list are arranged by the fields of this structure respectively (first by dev_class number, then by card number, ...). A pointer to this structure should be passed as the third ioctl's argument. Before calling the ioctl, the parameters of this structure should be initialized in relation to the next timer device which information is to be obtained. For example, if a wanted timer device has the device class number equal to or bigger then 2, the field dev_class should be initialized to 2. After the ioctl call, the structure fields are filled with values from the next device in the sound timer device list. If there is no next device in the list, the structure is filled with "zero" id values (in that case all fields are filled with value -1). Implementation notes: The ioctl 'SNDRV_TIMER_IOCTL_NEXT_DEVICE' has a pointer to a 'struct snd_timer_id' as its third argument. That is the reason why corresponding definition is added in 'linux-user/syscall_types.h'. Since all elements of this structure are of type 'int', the rest of the implementation was straightforward. The line '#include <linux/rtc.h>' was added to recognize preprocessor definitions for these ioctls. This needs to be done only once in this series of commits. Also, the content of this file (with respect to ioctl definitions) remained unchanged for a long time, therefore there is no need to worry about supporting older Linux kernel version. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-8-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:41 +03:00
/* alsa timer ioctls */
#define TARGET_SNDRV_TIMER_IOCTL_PVERSION TARGET_IOR('T', 0x00, int)
#define TARGET_SNDRV_TIMER_IOCTL_NEXT_DEVICE TARGET_IOWR('T', 0x01, \
struct snd_timer_id)
linux-user: Add support for getting/setting specified alsa timer parameters using ioctls This patch implements functionalities of following ioctls: SNDRV_TIMER_IOCTL_GINFO - Getting information about specified timer Read information about the specified timer. The information about the timer is returned in the following structure: struct snd_timer_ginfo { struct snd_timer_id tid; /* requested timer ID */ unsigned int flags; /* timer flags - SNDRV_TIMER_FLG_* */ int card; /* card number */ unsigned char id[64]; /* timer identification */ unsigned char name[80]; /* timer name */ unsigned long reserved0; /* reserved for future use */ unsigned long resolution; /* average period resolution in ns */ unsigned long resolution_min; /* minimal period resolution in ns */ unsigned long resolution_max; /* maximal period resolution in ns */ unsigned int clients; /* active timer clients */ unsigned char reserved[32]; /* reserved */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling the ioctl, the field "tid" should be initialized with the id information for the timer which information is to be obtained. After the ioctl call, the rest of the structure fields are filled with values from the timer device with the specified id. If there is no device with the specified id, the error ENODEV ("No such device") is returned. SNDRV_TIMER_IOCTL_GPARAMS - Setting precise period duration Sets timer precise period duration numerator and denominator in seconds. The period duration is set in the following structure: struct snd_timer_gparams { struct snd_timer_id tid; /* requested timer ID */ unsigned long period_num; /* period duration - numerator */ unsigned long period_den; /* period duration - denominator */ unsigned char reserved[32]; /* reserved */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling the ioctl, the field "tid" should be initialized with the id information for the timer which period duration is to be set. Also, the fileds "period_num" and "period_den" should be filled with the period duration numerator and denominator values that are to be set respectively. If there is no device with the specified id, the error ENODEV ("No such device") is returned. SNDRV_TIMER_IOCTL_GSTATUS - Getting current period resolution Read timer current period resolution in nanoseconds and period resolution numerator and denominator in seconds. The period resolution information is returned in the following structure: struct snd_timer_gstatus { struct snd_timer_id tid; /* requested timer ID */ unsigned long resolution; /* current period resolution in ns */ unsigned long resolution_num; /* period resolution - numerator */ unsigned long resolution_den; /* period resolution - denominator */ unsigned char reserved[32]; /* reserved for future use */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling the ioctl, the field "tid" should be initialized with the id information for the timer which period resolution is to be obtained. After the ioctl call, the rest of the structure fields are filled with values from the timer device with the specified id. If there is no device with the specified id, the error ENODEV ("No such device") is returned. Implementation notes: All ioctls in this patch have pointer to some kind of a structure as their third argument. That is the reason why corresponding definitions were added in 'linux-user/syscall_types.h'. All of these strcutures have some fields that are of type 'unsigned long'. That is the reason why separate target structures were defined in 'linux-user/syscall_defs.h'. Also, all of the structures have a field with type 'struct snd_timer_id' which is the reason why a separate target structure 'struct target_snd_timer_id' was also defined. The rest of the implementation was straightforward. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-10-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:43 +03:00
#define TARGET_SNDRV_TIMER_IOCTL_GINFO TARGET_IOWR('T', 0x03, \
struct target_snd_timer_ginfo)
#define TARGET_SNDRV_TIMER_IOCTL_GPARAMS TARGET_IOW('T', 0x04, \
struct target_snd_timer_gparams)
#define TARGET_SNDRV_TIMER_IOCTL_GSTATUS TARGET_IOWR('T', 0x05, \
struct target_snd_timer_gstatus)
#define TARGET_SNDRV_TIMER_IOCTL_SELECT TARGET_IOW('T', 0x10, \
struct target_snd_timer_select)
linux-user: Add support for getting/setting selected alsa timer parameters using ioctls This patch implements functionalities of following ioctls: SNDRV_TIMER_IOCTL_INFO - Getting information about selected timer Read information about the selected timer. The information is returned in the following structure: struct snd_timer_info { unsigned int flags; /* timer flags - SNDRV_TIMER_FLG_* */ int card; /* card number */ unsigned char id[64]; /* timer identificator */ unsigned char name[80]; /* timer name */ unsigned long reserved0; /* reserved for future use */ unsigned long resolution; /* average period resolution in ns */ unsigned char reserved[64]; /* reserved for future use */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer which information is to be obtained. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. SNDRV_TIMER_IOCTL_PARAMS - Setting parameters for selected timer Sets parameters for the selected timer. The paramaters are set in the following structure: struct snd_timer_params { unsigned int flags; /* flags - SNDRV_TIMER_PSFLG_* */ unsigned int ticks; /* requested resolution in ticks */ unsigned int queue_size; /* total size of queue (32-1024) */ unsigned int reserved0; /* reserved, was: failure locations */ unsigned int filter; /* event filter */ unsigned char reserved[60]; /* reserved */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer which parameters are to be set. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. SNDRV_TIMER_IOCTL_STATUS - Getting status of selected timer Read status of the selected timer. The status of the timer is returned in the following structure: struct snd_timer_status { struct timespec tstamp; /* Timestamp - last update */ unsigned int resolution; /* current period resolution in ns */ unsigned int lost; /* counter of master tick lost */ unsigned int overrun; /* count of read queue overruns */ unsigned int queue; /* used queue size */ unsigned char reserved[64]; /* reserved */ }; A pointer to this structure should be passed as the third ioctl's argument. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer which status is to be obtained. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. Implementation notes: All ioctls in this patch have pointer to some kind of a structure as their third argument. That is the reason why corresponding definitions were added in 'linux-user/syscall_types.h'. Structure 'snd_timer_status' has field of type 'struct timespec' which is why a corresponding definition of that structure was also added in 'linux-user/syscall_types.h'. All of these strucutures have some fields that are of type 'unsigned long'. That is the reason why separate target structures were defined in 'linux-user/syscall_defs.h'. Structure 'struct timespec' already had a separate target definition so that definition was used to define a target structure for 'snd_timer_status'. The rest of the implementation was straightforward. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-12-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:45 +03:00
#define TARGET_SNDRV_TIMER_IOCTL_INFO TARGET_IOR('T', 0x11, \
struct target_snd_timer_info)
#define TARGET_SNDRV_TIMER_IOCTL_PARAMS TARGET_IOW('T', 0x12, \
struct snd_timer_params)
#define TARGET_SNDRV_TIMER_IOCTL_STATUS TARGET_IOR('T', 0x14, \
struct target_snd_timer_status)
linux-user: Add support for selected alsa timer instructions using ioctls This patch implements functionalities of following ioctls: SNDRV_TIMER_IOCTL_START - Start selected alsa timer Starts the timer device that is selected. The third ioctl's argument is ignored. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer that is to be started. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. SNDRV_TIMER_IOCTL_STOP - Stop selected alsa timer Stops the timer device that is selected. The third ioctl's argument is ignored. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer that is to be stopped. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. SNDRV_TIMER_IOCTL_CONTINUE - Continue selected alsa timer Continues the timer device that is selected. The third ioctl's argument is ignored. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer that is to be continued. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. SNDRV_TIMER_IOCTL_PAUSE - Pause selected alsa timer Pauses the timer device that is selected. The third ioctl's argument is ignored. Before calling this ioctl, the ioctl "SNDRV_TIMER_IOCTL_SELECT" should be called first to select the timer that is to be paused. If no timer is selected, the error EBADFD ("File descriptor in bad shape") is returned. Implementation notes: Since all of the implemented ioctls have NULL as their third argument, their implementation was straightforward. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-13-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:46 +03:00
#define TARGET_SNDRV_TIMER_IOCTL_START TARGET_IO('T', 0xa0)
#define TARGET_SNDRV_TIMER_IOCTL_STOP TARGET_IO('T', 0xa1)
#define TARGET_SNDRV_TIMER_IOCTL_CONTINUE TARGET_IO('T', 0xa2)
#define TARGET_SNDRV_TIMER_IOCTL_PAUSE TARGET_IO('T', 0xa3)
linux-user: Add support for getting alsa timer version and id This patch implements functionalities of following ioctls: SNDRV_TIMER_IOCTL_PVERSION - Getting the sound timer version Read the sound timer version. The third ioctl's argument is a pointer to an int in which the specified timers version is returned. SNDRV_TIMER_IOCTL_NEXT_DEVICE - Getting id information about next timer Read id information about the next timer device from the sound timer device list. The id infomration is returned in the following structure: struct snd_timer_id { int dev_class; /* timer device class number */ int dev_sclass; /* slave device class number (unused) */ int card; /* card number */ int device; /* device number */ int subdevice; /* sub-device number */ }; The devices in the sound timer device list are arranged by the fields of this structure respectively (first by dev_class number, then by card number, ...). A pointer to this structure should be passed as the third ioctl's argument. Before calling the ioctl, the parameters of this structure should be initialized in relation to the next timer device which information is to be obtained. For example, if a wanted timer device has the device class number equal to or bigger then 2, the field dev_class should be initialized to 2. After the ioctl call, the structure fields are filled with values from the next device in the sound timer device list. If there is no next device in the list, the structure is filled with "zero" id values (in that case all fields are filled with value -1). Implementation notes: The ioctl 'SNDRV_TIMER_IOCTL_NEXT_DEVICE' has a pointer to a 'struct snd_timer_id' as its third argument. That is the reason why corresponding definition is added in 'linux-user/syscall_types.h'. Since all elements of this structure are of type 'int', the rest of the implementation was straightforward. The line '#include <linux/rtc.h>' was added to recognize preprocessor definitions for these ioctls. This needs to be done only once in this series of commits. Also, the content of this file (with respect to ioctl definitions) remained unchanged for a long time, therefore there is no need to worry about supporting older Linux kernel version. Reviewed-by: Laurent Vivier <laurent@vivier.eu> Signed-off-by: Filip Bozuta <Filip.Bozuta@rt-rk.com> Message-Id: <1579117007-7565-8-git-send-email-Filip.Bozuta@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2020-01-15 22:36:41 +03:00
/* vfat ioctls */
#define TARGET_VFAT_IOCTL_READDIR_BOTH TARGET_IORU('r', 1)
#define TARGET_VFAT_IOCTL_READDIR_SHORT TARGET_IORU('r', 2)
struct target_mtop {
abi_short mt_op;
abi_int mt_count;
};
#if defined(TARGET_SPARC) || defined(TARGET_MIPS)
typedef abi_long target_kernel_daddr_t;
#else
typedef abi_int target_kernel_daddr_t;
#endif
struct target_mtget {
abi_long mt_type;
abi_long mt_resid;
abi_long mt_dsreg;
abi_long mt_gstat;
abi_long mt_erreg;
target_kernel_daddr_t mt_fileno;
target_kernel_daddr_t mt_blkno;
};
struct target_mtpos {
abi_long mt_blkno;
};
#define TARGET_MTIOCTOP TARGET_IOW('m', 1, struct target_mtop)
#define TARGET_MTIOCGET TARGET_IOR('m', 2, struct target_mtget)
#define TARGET_MTIOCPOS TARGET_IOR('m', 3, struct target_mtpos)
/* kcov ioctls */
#define TARGET_KCOV_ENABLE TARGET_IO('c', 100)
#define TARGET_KCOV_DISABLE TARGET_IO('c', 101)
#define TARGET_KCOV_INIT_TRACE TARGET_IOR('c', 1, abi_ulong)
struct target_sysinfo {
abi_long uptime; /* Seconds since boot */
abi_ulong loads[3]; /* 1, 5, and 15 minute load averages */
abi_ulong totalram; /* Total usable main memory size */
abi_ulong freeram; /* Available memory size */
abi_ulong sharedram; /* Amount of shared memory */
abi_ulong bufferram; /* Memory used by buffers */
abi_ulong totalswap; /* Total swap space size */
abi_ulong freeswap; /* swap space still available */
unsigned short procs; /* Number of current processes */
unsigned short pad; /* explicit padding for m68k */
abi_ulong totalhigh; /* Total high memory size */
abi_ulong freehigh; /* Available high memory size */
unsigned int mem_unit; /* Memory unit size in bytes */
char _f[20-2*sizeof(abi_long)-sizeof(int)]; /* Padding: libc5 uses this.. */
};
struct linux_dirent {
long d_ino;
unsigned long d_off;
unsigned short d_reclen;
char d_name[];
};
struct linux_dirent64 {
uint64_t d_ino;
int64_t d_off;
unsigned short d_reclen;
unsigned char d_type;
char d_name[];
};
struct target_mq_attr {
abi_long mq_flags;
abi_long mq_maxmsg;
abi_long mq_msgsize;
abi_long mq_curmsgs;
};
struct target_drm_version {
int version_major;
int version_minor;
int version_patchlevel;
abi_ulong name_len;
abi_ulong name;
abi_ulong date_len;
abi_ulong date;
abi_ulong desc_len;
abi_ulong desc;
};
struct target_drm_i915_getparam {
int param;
abi_ulong value;
};
#include "socket.h"
#include "target_errno_defs.h"
#define FUTEX_WAIT 0
#define FUTEX_WAKE 1
#define FUTEX_FD 2
#define FUTEX_REQUEUE 3
#define FUTEX_CMP_REQUEUE 4
#define FUTEX_WAKE_OP 5
#define FUTEX_LOCK_PI 6
#define FUTEX_UNLOCK_PI 7
#define FUTEX_TRYLOCK_PI 8
#define FUTEX_WAIT_BITSET 9
#define FUTEX_WAKE_BITSET 10
#define FUTEX_PRIVATE_FLAG 128
#define FUTEX_CLOCK_REALTIME 256
#define FUTEX_CMD_MASK ~(FUTEX_PRIVATE_FLAG | FUTEX_CLOCK_REALTIME)
#ifdef CONFIG_EPOLL
#if defined(TARGET_X86_64)
#define TARGET_EPOLL_PACKED QEMU_PACKED
#else
#define TARGET_EPOLL_PACKED
#endif
typedef union target_epoll_data {
abi_ulong ptr;
abi_int fd;
abi_uint u32;
abi_ullong u64;
} target_epoll_data_t;
struct target_epoll_event {
abi_uint events;
target_epoll_data_t data;
} TARGET_EPOLL_PACKED;
#define TARGET_EP_MAX_EVENTS (INT_MAX / sizeof(struct target_epoll_event))
#endif
struct target_ucred {
uint32_t pid;
uint32_t uid;
uint32_t gid;
};
typedef int32_t target_timer_t;
#define TARGET_SIGEV_MAX_SIZE 64
/* This is architecture-specific but most architectures use the default */
#ifdef TARGET_MIPS
#define TARGET_SIGEV_PREAMBLE_SIZE (sizeof(int32_t) * 2 + sizeof(abi_long))
#else
#define TARGET_SIGEV_PREAMBLE_SIZE (sizeof(int32_t) * 2 \
+ sizeof(target_sigval_t))
#endif
#define TARGET_SIGEV_PAD_SIZE ((TARGET_SIGEV_MAX_SIZE \
- TARGET_SIGEV_PREAMBLE_SIZE) \
/ sizeof(int32_t))
struct target_sigevent {
target_sigval_t sigev_value;
abi_int sigev_signo;
abi_int sigev_notify;
union {
abi_int _pad[TARGET_SIGEV_PAD_SIZE];
abi_int _tid;
/* The kernel (and thus QEMU) never looks at these;
* they're only used as part of the ABI between a
* userspace program and libc.
*/
struct {
abi_ulong _function;
abi_ulong _attribute;
} _sigev_thread;
} _sigev_un;
};
struct target_user_cap_header {
uint32_t version;
int pid;
};
struct target_user_cap_data {
uint32_t effective;
uint32_t permitted;
uint32_t inheritable;
};
linux-user: Fix syslog() syscall support There are currently several problems related to syslog() support. For example, if the second argument "bufp" of target syslog() syscall is NULL, the current implementation always returns error code EFAULT. However, NULL is a perfectly valid value for the second argument for many use cases of this syscall. This is, for example, visible from this excerpt of man page for syslog(2): > EINVAL Bad arguments (e.g., bad type; or for type 2, 3, or 4, buf is > NULL, or len is less than zero; or for type 8, the level is > outside the range 1 to 8). Moreover, the argument "bufp" is ignored for all cases of values of the first argument, except 2, 3 and 4. This means that for such cases (the first argument is not 2, 3 or 4), there is no need to pass "buf" between host and target, and it can be set to NULL while calling host's syslog(), without loss of emulation accuracy. Note also that if "bufp" is NULL and the first argument is 2, 3 or 4, the correct returned error code is EINVAL, not EFAULT. All these details are reflected in this patch. "#ifdef TARGET_NR_syslog" is also proprerly inserted when needed. Support for Qemu's "-strace" switch for syslog() syscall is included too. LTP tests syslog11 and syslog12 pass with this patch (while fail without it), on any platform. Changes to original patch by Riku Voipio: fixed error paths in TARGET_SYSLOG_ACTION_READ_ALL to match http://lxr.free-electrons.com/source/kernel/printk/printk.c?v=4.7#L1335 Should fix also the build error in: https://lists.gnu.org/archive/html/qemu-devel/2016-10/msg03721.html Signed-off-by: Aleksandar Markovic <aleksandar.markovic@imgtec.com> Signed-off-by: Riku Voipio <riku.voipio@linaro.org>
2016-09-22 19:56:58 +03:00
/* from kernel's include/linux/syslog.h */
/* Close the log. Currently a NOP. */
#define TARGET_SYSLOG_ACTION_CLOSE 0
/* Open the log. Currently a NOP. */
#define TARGET_SYSLOG_ACTION_OPEN 1
/* Read from the log. */
#define TARGET_SYSLOG_ACTION_READ 2
/* Read all messages remaining in the ring buffer. */
#define TARGET_SYSLOG_ACTION_READ_ALL 3
/* Read and clear all messages remaining in the ring buffer */
#define TARGET_SYSLOG_ACTION_READ_CLEAR 4
/* Clear ring buffer. */
#define TARGET_SYSLOG_ACTION_CLEAR 5
/* Disable printk's to console */
#define TARGET_SYSLOG_ACTION_CONSOLE_OFF 6
/* Enable printk's to console */
#define TARGET_SYSLOG_ACTION_CONSOLE_ON 7
/* Set level of messages printed to console */
#define TARGET_SYSLOG_ACTION_CONSOLE_LEVEL 8
/* Return number of unread characters in the log buffer */
#define TARGET_SYSLOG_ACTION_SIZE_UNREAD 9
/* Return size of the log buffer */
#define TARGET_SYSLOG_ACTION_SIZE_BUFFER 10
linux-user: Add support for translation of statx() syscall Implement support for translation of system call statx(). The implementation is based on "best effort" approach: if host is capable of executing statx(), host statx() is used. If not, the implementation includes invoking a more mature system call fstatat() on the host side to achieve as close as possible functionality. Support for statx() in kernel and glibc was, however, introduced at different points of time (the difference is more than a year): - kernel: Linux 4.11 (30 April 2017) - glibc: glibc 2.28 (1 Aug 2018) In this patch, the availability of statx() support is established via __NR_statx (if it is defined, statx() is considered available). This coincedes with statx() introduction in kernel. However, the structure statx definition may not be available in any header for hosts with glibc older than 2.28 (and it is, by design, to be defined in one of glibc headers), even though the full statx() functionality may be supported in kernel. Hence, a structure "target_statx" is defined in this patch, to remove that dependency on glibc headers, and to use statx() functionality as soon as the host kernel is capable of supporting it. Such statx structure definition is used for both target and host structures statx (of course, this doesn't mean the endian arrangement is the same on target and host - the endian conversion is done in all necessary cases). Signed-off-by: Aleksandar Rikalo <arikalo@wavecomp.com> Signed-off-by: Aleksandar Markovic <amarkovic@wavecomp.com> Reviewed-by: Laurent Vivier <laurent@vivier.eu> Message-Id: <1561718618-20218-2-git-send-email-aleksandar.markovic@rt-rk.com> Signed-off-by: Laurent Vivier <laurent@vivier.eu>
2019-06-28 13:43:34 +03:00
struct target_statx_timestamp {
int64_t tv_sec;
uint32_t tv_nsec;
int32_t __reserved;
};
struct target_statx {
/* 0x00 */
uint32_t stx_mask; /* What results were written [uncond] */
uint32_t stx_blksize; /* Preferred general I/O size [uncond] */
uint64_t stx_attributes; /* Flags conveying information about the file */
/* 0x10 */
uint32_t stx_nlink; /* Number of hard links */
uint32_t stx_uid; /* User ID of owner */
uint32_t stx_gid; /* Group ID of owner */
uint16_t stx_mode; /* File mode */
uint16_t __spare0[1];
/* 0x20 */
uint64_t stx_ino; /* Inode number */
uint64_t stx_size; /* File size */
uint64_t stx_blocks; /* Number of 512-byte blocks allocated */
uint64_t stx_attributes_mask; /* Mask to show what is supported */
/* 0x40 */
struct target_statx_timestamp stx_atime; /* Last access time */
struct target_statx_timestamp stx_btime; /* File creation time */
struct target_statx_timestamp stx_ctime; /* Last attribute change time */
struct target_statx_timestamp stx_mtime; /* Last data modification time */
/* 0x80 */
uint32_t stx_rdev_major; /* Device ID of special file [if bdev/cdev] */
uint32_t stx_rdev_minor;
uint32_t stx_dev_major; /* ID of device containing file [uncond] */
uint32_t stx_dev_minor;
/* 0x90 */
uint64_t __spare2[14]; /* Spare space for future expansion */
/* 0x100 */
};
/* from kernel's include/linux/sched/types.h */
struct target_sched_attr {
abi_uint size;
abi_uint sched_policy;
abi_ullong sched_flags;
abi_int sched_nice;
abi_uint sched_priority;
abi_ullong sched_runtime;
abi_ullong sched_deadline;
abi_ullong sched_period;
abi_uint sched_util_min;
abi_uint sched_util_max;
};
struct target_sched_param {
abi_int sched_priority;
};
#endif