gem5/kern/tru64/tru64.hh
Kevin Lim 70b35bab57 Changes to put all the misc regs within the misc reg file. This includes the FPCR, Uniq, lock flag, lock addr, and IPRs.
They are now accessed by calling readMiscReg()/setMiscReg() on the XC.  Old IPR accesses are supported by using readMiscRegWithEffect() and setMiscRegWithEffect() (names may change in the future).

arch/alpha/alpha_memory.cc:
    Change accesses to IPR to go through the XC.
arch/alpha/ev5.cc:
    Change accesses for IPRs to go through the misc regs.
arch/alpha/isa/decoder.isa:
    Change accesses to IPRs to go through the misc regs.  readIpr() and setIpr() are now changed to calls to readMiscRegWithEffect() and setMiscRegWithEffect().
arch/alpha/isa/fp.isa:
    Change accesses to IPRs and Fpcr to go through the misc regs.
arch/alpha/isa/main.isa:
    Add support for all misc regs being accessed through readMiscReg() and setMiscReg().  Instead of readUniq and readFpcr, they are replaced by calls with Uniq_DepTag and Fpcr_DepTag passed in as the register index.
arch/alpha/isa_traits.hh:
    Change the MiscRegFile to a class that handles all accesses to MiscRegs, which in Alpha include the FPCR, Uniq, Lock Addr, Lock Flag, and IPRs.
    Two flavors of accesses are supported: normal register reads/writes, and reads/writes with effect.  The latter are basically the original read/write IPR functions, while the former are normal reads/writes.

    The lock flag and lock addr registers are added to the dependence tags in order to support being accessed through the misc regs.
arch/alpha/stacktrace.cc:
cpu/simple/cpu.cc:
dev/sinic.cc:
    Change accesses to the IPRs to go through the XC.
arch/alpha/vtophys.cc:
    Change access to the IPR to go through the XC.
arch/isa_parser.py:
    Change generation of code for control registers to use the readMiscReg and setMiscReg functions.
base/remote_gdb.cc:
    Change accesses to the IPR to go through the XC.
cpu/exec_context.hh:
    Use the miscRegs to access the lock addr, lock flag, and other misc registers.
cpu/o3/alpha_cpu.hh:
cpu/simple/cpu.hh:
    Support interface for reading and writing misc registers, which replaces readUniq, readFpcr, readIpr, and their set functions.
cpu/o3/alpha_cpu_impl.hh:
    Change accesses to the IPRs to go through the miscRegs.
    For now comment out some of the accesses to the misc regs until the proxy exec context is completed.
cpu/o3/alpha_dyn_inst.hh:
    Change accesses to misc regs to use readMiscReg and setMiscReg.
cpu/o3/alpha_dyn_inst_impl.hh:
    Remove old misc reg accessors.
cpu/o3/cpu.cc:
    Comment out old misc reg accesses until the proxy exec context is completed.
cpu/o3/cpu.hh:
    Change accesses to the misc regs.
cpu/o3/regfile.hh:
    Remove old access methods for the misc regs, replace them with readMiscReg and setMiscReg.  They are dummy functions for now until the proxy exec context is completed.
kern/kernel_stats.cc:
kern/system_events.cc:
    Have accesses to the IPRs go through the XC.
kern/tru64/tru64.hh:
    Have accesses to the misc regs use the new access methods.

--HG--
extra : convert_revision : e32e0a3fe99522e17294bbe106ff5591cb1a9d76
2006-02-27 11:44:35 -05:00

1324 lines
45 KiB
C++

/*
* Copyright (c) 2001-2005 The Regents of The University of Michigan
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef __TRU64_HH__
#define __TRU64_HH__
#include "config/full_system.hh"
#if FULL_SYSTEM
class Tru64 {};
#else //!FULL_SYSTEM
#include <sys/types.h>
#include <sys/stat.h>
#if defined(__OpenBSD__) || defined(__APPLE__) || defined(__FreeBSD__)
#include <sys/param.h>
#include <sys/mount.h>
#else
#include <sys/statfs.h>
#endif
#include <dirent.h>
#include <errno.h>
#include <fcntl.h>
#include <string.h> // for memset()
#include <unistd.h>
#include "cpu/base.hh"
#include "sim/root.hh"
#include "sim/syscall_emul.hh"
using namespace std;
typedef struct stat global_stat;
typedef struct statfs global_statfs;
typedef struct dirent global_dirent;
///
/// This class encapsulates the types, structures, constants,
/// functions, and syscall-number mappings specific to the Alpha Tru64
/// syscall interface.
///
class Tru64 {
public:
//@{
/// Basic Tru64 types.
typedef uint64_t size_t;
typedef uint64_t off_t;
typedef uint16_t nlink_t;
typedef int32_t dev_t;
typedef uint32_t uid_t;
typedef uint32_t gid_t;
typedef uint32_t time_t;
typedef uint32_t mode_t;
typedef uint32_t ino_t;
typedef struct { int val[2]; } quad;
typedef quad fsid_t;
//@}
//@{
/// open(2) flag values.
static const int TGT_O_RDONLY = 00000000;
static const int TGT_O_WRONLY = 00000001;
static const int TGT_O_RDWR = 00000002;
static const int TGT_O_NONBLOCK = 00000004;
static const int TGT_O_APPEND = 00000010;
static const int TGT_O_CREAT = 00001000;
static const int TGT_O_TRUNC = 00002000;
static const int TGT_O_EXCL = 00004000;
static const int TGT_O_NOCTTY = 00010000;
static const int TGT_O_SYNC = 00040000;
static const int TGT_O_DRD = 00100000;
static const int TGT_O_DIRECTIO = 00200000;
static const int TGT_O_CACHE = 00400000;
static const int TGT_O_DSYNC = 02000000;
static const int TGT_O_RSYNC = 04000000;
//@}
/// This table maps the target open() flags to the corresponding
/// host open() flags.
static OpenFlagTransTable openFlagTable[];
/// Number of entries in openFlagTable[].
static const int NUM_OPEN_FLAGS;
/// Stat buffer. Note that Tru64 v5.0+ use a new "F64" stat
/// structure, and a new set of syscall numbers for stat calls.
/// On some hosts (notably Linux) define st_atime, st_mtime, and
/// st_ctime as macros, so we append an X to get around this.
struct F64_stat {
dev_t st_dev; //!< st_dev
int32_t st_retired1; //!< st_retired1
mode_t st_mode; //!< st_mode
nlink_t st_nlink; //!< st_nlink
uint16_t st_nlink_reserved; //!< st_nlink_reserved
uid_t st_uid; //!< st_uid
gid_t st_gid; //!< st_gid
dev_t st_rdev; //!< st_rdev
dev_t st_ldev; //!< st_ldev
off_t st_size; //!< st_size
time_t st_retired2; //!< st_retired2
int32_t st_uatime; //!< st_uatime
time_t st_retired3; //!< st_retired3
int32_t st_umtime; //!< st_umtime
time_t st_retired4; //!< st_retired4
int32_t st_uctime; //!< st_uctime
int32_t st_retired5; //!< st_retired5
int32_t st_retired6; //!< st_retired6
uint32_t st_flags; //!< st_flags
uint32_t st_gen; //!< st_gen
uint64_t st_spare[4]; //!< st_spare[4]
ino_t st_ino; //!< st_ino
int32_t st_ino_reserved; //!< st_ino_reserved
time_t st_atimeX; //!< st_atime
int32_t st_atime_reserved; //!< st_atime_reserved
time_t st_mtimeX; //!< st_mtime
int32_t st_mtime_reserved; //!< st_mtime_reserved
time_t st_ctimeX; //!< st_ctime
int32_t st_ctime_reserved; //!< st_ctime_reserved
uint64_t st_blksize; //!< st_blksize
uint64_t st_blocks; //!< st_blocks
};
/// Old Tru64 v4.x stat struct.
/// Tru64 maintains backwards compatibility with v4.x by
/// implementing another set of stat functions using the old
/// structure definition and binding them to the old syscall
/// numbers.
struct pre_F64_stat {
dev_t st_dev;
ino_t st_ino;
mode_t st_mode;
nlink_t st_nlink;
uid_t st_uid;
gid_t st_gid;
dev_t st_rdev;
off_t st_size;
time_t st_atimeX;
int32_t st_uatime;
time_t st_mtimeX;
int32_t st_umtime;
time_t st_ctimeX;
int32_t st_uctime;
uint32_t st_blksize;
int32_t st_blocks;
uint32_t st_flags;
uint32_t st_gen;
};
/// For statfs().
struct F64_statfs {
int16_t f_type;
int16_t f_flags;
int32_t f_retired1;
int32_t f_retired2;
int32_t f_retired3;
int32_t f_retired4;
int32_t f_retired5;
int32_t f_retired6;
int32_t f_retired7;
fsid_t f_fsid;
int32_t f_spare[9];
char f_retired8[90];
char f_retired9[90];
uint64_t dummy[10]; // was union mount_info mount_info;
uint64_t f_flags2;
int64_t f_spare2[14];
int64_t f_fsize;
int64_t f_bsize;
int64_t f_blocks;
int64_t f_bfree;
int64_t f_bavail;
int64_t f_files;
int64_t f_ffree;
char f_mntonname[1024];
char f_mntfromname[1024];
};
/// For old Tru64 v4.x statfs()
struct pre_F64_statfs {
int16_t f_type;
int16_t f_flags;
int32_t f_fsize;
int32_t f_bsize;
int32_t f_blocks;
int32_t f_bfree;
int32_t f_bavail;
int32_t f_files;
int32_t f_ffree;
fsid_t f_fsid;
int32_t f_spare[9];
char f_mntonname[90];
char f_mntfromname[90];
uint64_t dummy[10]; // was union mount_info mount_info;
};
/// For getdirentries().
struct dirent
{
ino_t d_ino; //!< file number of entry
uint16_t d_reclen; //!< length of this record
uint16_t d_namlen; //!< length of string in d_name
char d_name[256]; //!< dummy name length
};
/// Length of strings in struct utsname (plus 1 for null char).
static const int _SYS_NMLN = 32;
/// Interface struct for uname().
struct utsname {
char sysname[_SYS_NMLN]; //!< System name.
char nodename[_SYS_NMLN]; //!< Node name.
char release[_SYS_NMLN]; //!< OS release.
char version[_SYS_NMLN]; //!< OS version.
char machine[_SYS_NMLN]; //!< Machine type.
};
//@{
/// ioctl() command codes.
static const unsigned TIOCGETP = 0x40067408;
static const unsigned TIOCSETP = 0x80067409;
static const unsigned TIOCSETN = 0x8006740a;
static const unsigned TIOCSETC = 0x80067411;
static const unsigned TIOCGETC = 0x40067412;
static const unsigned FIONREAD = 0x4004667f;
static const unsigned TIOCISATTY = 0x2000745e;
// TIOCGETS not defined in tru64, so I made up a number
static const unsigned TIOCGETS = 0x40000000;
static const unsigned TIOCGETA = 0x402c7413;
//@}
/// Resource enumeration for getrlimit().
enum rlimit_resources {
TGT_RLIMIT_CPU = 0,
TGT_RLIMIT_FSIZE = 1,
TGT_RLIMIT_DATA = 2,
TGT_RLIMIT_STACK = 3,
TGT_RLIMIT_CORE = 4,
TGT_RLIMIT_RSS = 5,
TGT_RLIMIT_NOFILE = 6,
TGT_RLIMIT_AS = 7,
TGT_RLIMIT_VMEM = 7
};
/// Limit struct for getrlimit/setrlimit.
struct rlimit {
uint64_t rlim_cur; //!< soft limit
uint64_t rlim_max; //!< hard limit
};
/// For mmap().
static const unsigned TGT_MAP_ANONYMOUS = 0x10;
//@{
/// For getsysinfo().
static const unsigned GSI_PLATFORM_NAME = 103; //!< platform name as string
static const unsigned GSI_CPU_INFO = 59; //!< CPU information
static const unsigned GSI_PROC_TYPE = 60; //!< get proc_type
static const unsigned GSI_MAX_CPU = 30; //!< max # cpu's on this machine
static const unsigned GSI_CPUS_IN_BOX = 55; //!< number of CPUs in system
static const unsigned GSI_PHYSMEM = 19; //!< Physical memory in KB
static const unsigned GSI_CLK_TCK = 42; //!< clock freq in Hz
//@}
/// For getsysinfo() GSI_CPU_INFO option.
struct cpu_info {
uint32_t current_cpu; //!< current_cpu
uint32_t cpus_in_box; //!< cpus_in_box
uint32_t cpu_type; //!< cpu_type
uint32_t ncpus; //!< ncpus
uint64_t cpus_present; //!< cpus_present
uint64_t cpus_running; //!< cpus_running
uint64_t cpu_binding; //!< cpu_binding
uint64_t cpu_ex_binding; //!< cpu_ex_binding
uint32_t mhz; //!< mhz
uint32_t unused[3]; //!< future expansion
};
//@{
/// For setsysinfo().
static const unsigned SSI_IEEE_FP_CONTROL = 14; //!< ieee_set_fp_control()
//@}
/// For gettimeofday.
struct timeval {
uint32_t tv_sec; //!< seconds
uint32_t tv_usec; //!< microseconds
};
//@{
/// For getrusage().
static const int TGT_RUSAGE_THREAD = 1;
static const int TGT_RUSAGE_SELF = 0;
static const int TGT_RUSAGE_CHILDREN = -1;
//@}
/// For getrusage().
struct rusage {
struct timeval ru_utime; //!< user time used
struct timeval ru_stime; //!< system time used
uint64_t ru_maxrss; //!< ru_maxrss
uint64_t ru_ixrss; //!< integral shared memory size
uint64_t ru_idrss; //!< integral unshared data "
uint64_t ru_isrss; //!< integral unshared stack "
uint64_t ru_minflt; //!< page reclaims - total vmfaults
uint64_t ru_majflt; //!< page faults
uint64_t ru_nswap; //!< swaps
uint64_t ru_inblock; //!< block input operations
uint64_t ru_oublock; //!< block output operations
uint64_t ru_msgsnd; //!< messages sent
uint64_t ru_msgrcv; //!< messages received
uint64_t ru_nsignals; //!< signals received
uint64_t ru_nvcsw; //!< voluntary context switches
uint64_t ru_nivcsw; //!< involuntary "
};
/// For sigreturn().
struct sigcontext {
int64_t sc_onstack; //!< sigstack state to restore
int64_t sc_mask; //!< signal mask to restore
int64_t sc_pc; //!< pc at time of signal
int64_t sc_ps; //!< psl to retore
int64_t sc_regs[32]; //!< processor regs 0 to 31
int64_t sc_ownedfp; //!< fp has been used
int64_t sc_fpregs[32]; //!< fp regs 0 to 31
uint64_t sc_fpcr; //!< floating point control reg
uint64_t sc_fp_control; //!< software fpcr
int64_t sc_reserved1; //!< reserved for kernel
uint32_t sc_kreserved1; //!< reserved for kernel
uint32_t sc_kreserved2; //!< reserved for kernel
size_t sc_ssize; //!< stack size
caddr_t sc_sbase; //!< stack start
uint64_t sc_traparg_a0; //!< a0 argument to trap on exc
uint64_t sc_traparg_a1; //!< a1 argument to trap on exc
uint64_t sc_traparg_a2; //!< a2 argument to trap on exc
uint64_t sc_fp_trap_pc; //!< imprecise pc
uint64_t sc_fp_trigger_sum; //!< Exception summary at trigg
uint64_t sc_fp_trigger_inst; //!< Instruction at trigger pc
};
/// For table().
static const int TBL_SYSINFO = 12;
/// For table().
struct tbl_sysinfo {
uint64_t si_user; //!< User time
uint64_t si_nice; //!< Nice time
uint64_t si_sys; //!< System time
uint64_t si_idle; //!< Idle time
uint64_t si_hz; //!< hz
uint64_t si_phz; //!< phz
uint64_t si_boottime; //!< Boot time in seconds
uint64_t wait; //!< Wait time
uint32_t si_max_procs; //!< rpb->rpb_numprocs
uint32_t pad; //!< padding
};
/// For stack_create.
struct vm_stack {
// was void *
Addr address; //!< address hint
size_t rsize; //!< red zone size
size_t ysize; //!< yellow zone size
size_t gsize; //!< green zone size
size_t swap; //!< amount of swap to reserve
size_t incr; //!< growth increment
uint64_t align; //!< address alignment
uint64_t flags; //!< MAP_FIXED etc.
// was struct memalloc_attr *
Addr attr; //!< allocation policy
uint64_t reserved; //!< reserved
};
/// Return values for nxm calls.
enum {
KERN_NOT_RECEIVER = 7,
KERN_NOT_IN_SET = 12
};
/// For nxm_task_init.
static const int NXM_TASK_INIT_VP = 2; //!< initial thread is VP
/// Task attribute structure.
struct nxm_task_attr {
int64_t nxm_callback; //!< nxm_callback
unsigned int nxm_version; //!< nxm_version
unsigned short nxm_uniq_offset; //!< nxm_uniq_offset
unsigned short flags; //!< flags
int nxm_quantum; //!< nxm_quantum
int pad1; //!< pad1
int64_t pad2; //!< pad2
};
/// Signal set.
typedef uint64_t sigset_t;
/// Thread state shared between user & kernel.
struct ushared_state {
sigset_t sigmask; //!< thread signal mask
sigset_t sig; //!< thread pending mask
// struct nxm_pth_state *
Addr pth_id; //!< out-of-line state
int flags; //!< shared flags
#define US_SIGSTACK 0x1 // thread called sigaltstack
#define US_ONSTACK 0x2 // thread is running on altstack
#define US_PROFILE 0x4 // thread called profil
#define US_SYSCALL 0x8 // thread in syscall
#define US_TRAP 0x10 // thread has trapped
#define US_YELLOW 0x20 // thread has mellowed yellow
#define US_YZONE 0x40 // thread has zoned out
#define US_FP_OWNED 0x80 // thread used floating point
int cancel_state; //!< thread's cancelation state
#define US_CANCEL 0x1 // cancel pending
#define US_NOCANCEL 0X2 // synch cancel disabled
#define US_SYS_NOCANCEL 0x4 // syscall cancel disabled
#define US_ASYNC_NOCANCEL 0x8 // asynch cancel disabled
#define US_CANCEL_BITS (US_NOCANCEL|US_SYS_NOCANCEL|US_ASYNC_NOCANCEL)
#define US_CANCEL_MASK (US_CANCEL|US_NOCANCEL|US_SYS_NOCANCEL| \
US_ASYNC_NOCANCEL)
// These are semi-shared. They are always visible to
// the kernel but are never context-switched by the library.
int nxm_ssig; //!< scheduler's synchronous signals
int reserved1; //!< reserved1
int64_t nxm_active; //!< scheduler active
int64_t reserved2; //!< reserved2
};
struct nxm_sched_state {
struct ushared_state nxm_u; //!< state own by user thread
unsigned int nxm_bits; //!< scheduler state / slot
int nxm_quantum; //!< quantum count-down value
int nxm_set_quantum; //!< quantum reset value
int nxm_sysevent; //!< syscall state
// struct nxm_upcall *
Addr nxm_uc_ret; //!< stack ptr of null thread
// void *
Addr nxm_tid; //!< scheduler's thread id
int64_t nxm_va; //!< page fault address
// struct nxm_pth_state *
Addr nxm_pthid; //!< id of null thread
uint64_t nxm_bound_pcs_count; //!< bound PCS thread count
int64_t pad[2]; //!< pad
};
/// nxm_shared.
struct nxm_shared {
int64_t nxm_callback; //!< address of upcall routine
unsigned int nxm_version; //!< version number
unsigned short nxm_uniq_offset; //!< correction factor for TEB
unsigned short pad1; //!< pad1
int64_t space[2]; //!< future growth
struct nxm_sched_state nxm_ss[1]; //!< array of shared areas
};
/// nxm_slot_state_t.
enum nxm_slot_state_t {
NXM_SLOT_AVAIL,
NXM_SLOT_BOUND,
NXM_SLOT_UNBOUND,
NXM_SLOT_EMPTY
};
/// nxm_config_info
struct nxm_config_info {
int nxm_nslots_per_rad; //!< max number of VP slots per RAD
int nxm_nrads; //!< max number of RADs
// nxm_slot_state_t *
Addr nxm_slot_state; //!< per-VP slot state
// struct nxm_shared *
Addr nxm_rad[1]; //!< per-RAD shared areas
};
/// For nxm_thread_create.
enum nxm_thread_type {
NXM_TYPE_SCS = 0,
NXM_TYPE_VP = 1,
NXM_TYPE_MANAGER = 2
};
/// Thread attributes.
struct nxm_thread_attr {
int version; //!< version
int type; //!< type
int cancel_flags; //!< cancel_flags
int priority; //!< priority
int policy; //!< policy
int signal_type; //!< signal_type
// void *
Addr pthid; //!< pthid
sigset_t sigmask; //!< sigmask
/// Initial register values.
struct {
uint64_t pc; //!< pc
uint64_t sp; //!< sp
uint64_t a0; //!< a0
} registers;
uint64_t pad2[2]; //!< pad2
};
/// Helper function to convert a host stat buffer to a target stat
/// buffer. Also copies the target buffer out to the simulated
/// memory space. Used by stat(), fstat(), and lstat().
template <class T>
static void
copyOutStatBuf(FunctionalMemory *mem, Addr addr, global_stat *host)
{
TypedBufferArg<T> tgt(addr);
tgt->st_dev = htog(host->st_dev);
tgt->st_ino = htog(host->st_ino);
tgt->st_mode = htog(host->st_mode);
tgt->st_nlink = htog(host->st_nlink);
tgt->st_uid = htog(host->st_uid);
tgt->st_gid = htog(host->st_gid);
tgt->st_rdev = htog(host->st_rdev);
tgt->st_size = htog(host->st_size);
tgt->st_atimeX = htog(host->st_atime);
tgt->st_mtimeX = htog(host->st_mtime);
tgt->st_ctimeX = htog(host->st_ctime);
tgt->st_blksize = htog(host->st_blksize);
tgt->st_blocks = htog(host->st_blocks);
tgt.copyOut(mem);
}
/// Helper function to convert a host statfs buffer to a target statfs
/// buffer. Also copies the target buffer out to the simulated
/// memory space. Used by statfs() and fstatfs().
template <class T>
static void
copyOutStatfsBuf(FunctionalMemory *mem, Addr addr, global_statfs *host)
{
TypedBufferArg<T> tgt(addr);
#if defined(__OpenBSD__) || defined(__APPLE__) || defined(__FreeBSD__)
tgt->f_type = 0;
#else
tgt->f_type = htog(host->f_type);
#endif
tgt->f_bsize = htog(host->f_bsize);
tgt->f_blocks = htog(host->f_blocks);
tgt->f_bfree = htog(host->f_bfree);
tgt->f_bavail = htog(host->f_bavail);
tgt->f_files = htog(host->f_files);
tgt->f_ffree = htog(host->f_ffree);
// Is this as string normally?
memcpy(&tgt->f_fsid, &host->f_fsid, sizeof(host->f_fsid));
tgt.copyOut(mem);
}
class F64 {
public:
static void copyOutStatBuf(FunctionalMemory *mem, Addr addr,
global_stat *host)
{
Tru64::copyOutStatBuf<Tru64::F64_stat>(mem, addr, host);
}
static void copyOutStatfsBuf(FunctionalMemory *mem, Addr addr,
global_statfs *host)
{
Tru64::copyOutStatfsBuf<Tru64::F64_statfs>(mem, addr, host);
}
};
class PreF64 {
public:
static void copyOutStatBuf(FunctionalMemory *mem, Addr addr,
global_stat *host)
{
Tru64::copyOutStatBuf<Tru64::pre_F64_stat>(mem, addr, host);
}
static void copyOutStatfsBuf(FunctionalMemory *mem, Addr addr,
global_statfs *host)
{
Tru64::copyOutStatfsBuf<Tru64::pre_F64_statfs>(mem, addr, host);
}
};
/// Helper function to convert a host stat buffer to an old pre-F64
/// (4.x) target stat buffer. Also copies the target buffer out to
/// the simulated memory space. Used by pre_F64_stat(),
/// pre_F64_fstat(), and pre_F64_lstat().
static void
copyOutPreF64StatBuf(FunctionalMemory *mem, Addr addr, struct stat *host)
{
TypedBufferArg<Tru64::pre_F64_stat> tgt(addr);
tgt->st_dev = htog(host->st_dev);
tgt->st_ino = htog(host->st_ino);
tgt->st_mode = htog(host->st_mode);
tgt->st_nlink = htog(host->st_nlink);
tgt->st_uid = htog(host->st_uid);
tgt->st_gid = htog(host->st_gid);
tgt->st_rdev = htog(host->st_rdev);
tgt->st_size = htog(host->st_size);
tgt->st_atimeX = htog(host->st_atime);
tgt->st_mtimeX = htog(host->st_mtime);
tgt->st_ctimeX = htog(host->st_ctime);
tgt->st_blksize = htog(host->st_blksize);
tgt->st_blocks = htog(host->st_blocks);
tgt.copyOut(mem);
}
/// The target system's hostname.
static const char *hostname;
/// Target getdirentries() handler.
static SyscallReturn
getdirentriesFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
#ifdef __CYGWIN__
panic("getdirent not implemented on cygwin!");
#else
int fd = process->sim_fd(xc->getSyscallArg(0));
Addr tgt_buf = xc->getSyscallArg(1);
int tgt_nbytes = xc->getSyscallArg(2);
Addr tgt_basep = xc->getSyscallArg(3);
char * const host_buf = new char[tgt_nbytes];
// just pass basep through uninterpreted.
TypedBufferArg<int64_t> basep(tgt_basep);
basep.copyIn(xc->mem);
long host_basep = (off_t)htog((int64_t)*basep);
int host_result = getdirentries(fd, host_buf, tgt_nbytes, &host_basep);
// check for error
if (host_result < 0) {
delete [] host_buf;
return -errno;
}
// no error: copy results back to target space
Addr tgt_buf_ptr = tgt_buf;
char *host_buf_ptr = host_buf;
char *host_buf_end = host_buf + host_result;
while (host_buf_ptr < host_buf_end) {
global_dirent *host_dp = (global_dirent *)host_buf_ptr;
int namelen = strlen(host_dp->d_name);
// Actual size includes padded string rounded up for alignment.
// Subtract 256 for dummy char array in Tru64::dirent definition.
// Add 1 to namelen for terminating null char.
int tgt_bufsize = sizeof(Tru64::dirent) - 256 + roundUp(namelen+1, 8);
TypedBufferArg<Tru64::dirent> tgt_dp(tgt_buf_ptr, tgt_bufsize);
tgt_dp->d_ino = host_dp->d_ino;
tgt_dp->d_reclen = tgt_bufsize;
tgt_dp->d_namlen = namelen;
strcpy(tgt_dp->d_name, host_dp->d_name);
tgt_dp.copyOut(xc->mem);
tgt_buf_ptr += tgt_bufsize;
host_buf_ptr += host_dp->d_reclen;
}
delete [] host_buf;
*basep = htog((int64_t)host_basep);
basep.copyOut(xc->mem);
return tgt_buf_ptr - tgt_buf;
#endif
}
/// Target sigreturn() handler.
static SyscallReturn
sigreturnFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
using TheISA::RegFile;
RegFile *regs = &xc->regs;
TypedBufferArg<Tru64::sigcontext> sc(xc->getSyscallArg(0));
sc.copyIn(xc->mem);
// Restore state from sigcontext structure.
// Note that we'll advance PC <- NPC before the end of the cycle,
// so we need to restore the desired PC into NPC.
// The current regs->pc will get clobbered.
regs->npc = htog(sc->sc_pc);
for (int i = 0; i < 31; ++i) {
regs->intRegFile[i] = htog(sc->sc_regs[i]);
regs->floatRegFile.q[i] = htog(sc->sc_fpregs[i]);
}
xc->setMiscReg(TheISA::Fpcr_DepTag, htog(sc->sc_fpcr));
return 0;
}
/// Target table() handler.
static SyscallReturn
tableFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
int id = xc->getSyscallArg(0); // table ID
int index = xc->getSyscallArg(1); // index into table
// arg 2 is buffer pointer; type depends on table ID
int nel = xc->getSyscallArg(3); // number of elements
int lel = xc->getSyscallArg(4); // expected element size
switch (id) {
case Tru64::TBL_SYSINFO: {
if (index != 0 || nel != 1 || lel != sizeof(Tru64::tbl_sysinfo))
return -EINVAL;
TypedBufferArg<Tru64::tbl_sysinfo> elp(xc->getSyscallArg(2));
const int clk_hz = one_million;
elp->si_user = htog(curTick / (Clock::Frequency / clk_hz));
elp->si_nice = htog(0);
elp->si_sys = htog(0);
elp->si_idle = htog(0);
elp->wait = htog(0);
elp->si_hz = htog(clk_hz);
elp->si_phz = htog(clk_hz);
elp->si_boottime = htog(seconds_since_epoch); // seconds since epoch?
elp->si_max_procs = htog(process->numCpus());
elp.copyOut(xc->mem);
return 0;
}
default:
cerr << "table(): id " << id << " unknown." << endl;
return -EINVAL;
}
}
//
// Mach syscalls -- identified by negated syscall numbers
//
/// Create a stack region for a thread.
static SyscallReturn
stack_createFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
TypedBufferArg<Tru64::vm_stack> argp(xc->getSyscallArg(0));
argp.copyIn(xc->mem);
// if the user chose an address, just let them have it. Otherwise
// pick one for them.
if (htog(argp->address) == 0) {
argp->address = htog(process->next_thread_stack_base);
int stack_size = (htog(argp->rsize) + htog(argp->ysize) +
htog(argp->gsize));
process->next_thread_stack_base -= stack_size;
argp.copyOut(xc->mem);
}
return 0;
}
/// NXM library version stamp.
static
const int NXM_LIB_VERSION = 301003;
/// This call sets up the interface between the user and kernel
/// schedulers by creating a shared-memory region. The shared memory
/// region has several structs, some global, some per-RAD, some per-VP.
static SyscallReturn
nxm_task_initFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
TypedBufferArg<Tru64::nxm_task_attr> attrp(xc->getSyscallArg(0));
TypedBufferArg<Addr> configptr_ptr(xc->getSyscallArg(1));
attrp.copyIn(xc->mem);
if (gtoh(attrp->nxm_version) != NXM_LIB_VERSION) {
cerr << "nxm_task_init: thread library version mismatch! "
<< "got " << attrp->nxm_version
<< ", expected " << NXM_LIB_VERSION << endl;
abort();
}
if (gtoh(attrp->flags) != Tru64::NXM_TASK_INIT_VP) {
cerr << "nxm_task_init: bad flag value " << attrp->flags
<< " (expected " << Tru64::NXM_TASK_INIT_VP << ")" << endl;
abort();
}
const Addr base_addr = 0x12000; // was 0x3f0000000LL;
Addr cur_addr = base_addr; // next addresses to use
// first comes the config_info struct
Addr config_addr = cur_addr;
cur_addr += sizeof(Tru64::nxm_config_info);
// next comes the per-cpu state vector
Addr slot_state_addr = cur_addr;
int slot_state_size =
process->numCpus() * sizeof(Tru64::nxm_slot_state_t);
cur_addr += slot_state_size;
// now the per-RAD state struct (we only support one RAD)
cur_addr = 0x14000; // bump up addr for alignment
Addr rad_state_addr = cur_addr;
int rad_state_size =
(sizeof(Tru64::nxm_shared)
+ (process->numCpus()-1) * sizeof(Tru64::nxm_sched_state));
cur_addr += rad_state_size;
// now initialize a config_info struct and copy it out to user space
TypedBufferArg<Tru64::nxm_config_info> config(config_addr);
config->nxm_nslots_per_rad = htog(process->numCpus());
config->nxm_nrads = htog(1); // only one RAD in our system!
config->nxm_slot_state = htog(slot_state_addr);
config->nxm_rad[0] = htog(rad_state_addr);
config.copyOut(xc->mem);
// initialize the slot_state array and copy it out
TypedBufferArg<Tru64::nxm_slot_state_t> slot_state(slot_state_addr,
slot_state_size);
for (int i = 0; i < process->numCpus(); ++i) {
// CPU 0 is bound to the calling process; all others are available
// XXX this code should have an endian conversion, but I don't think
// it works anyway
slot_state[i] =
(i == 0) ? Tru64::NXM_SLOT_BOUND : Tru64::NXM_SLOT_AVAIL;
}
slot_state.copyOut(xc->mem);
// same for the per-RAD "shared" struct. Note that we need to
// allocate extra bytes for the per-VP array which is embedded at
// the end.
TypedBufferArg<Tru64::nxm_shared> rad_state(rad_state_addr,
rad_state_size);
rad_state->nxm_callback = attrp->nxm_callback;
rad_state->nxm_version = attrp->nxm_version;
rad_state->nxm_uniq_offset = attrp->nxm_uniq_offset;
for (int i = 0; i < process->numCpus(); ++i) {
Tru64::nxm_sched_state *ssp = &rad_state->nxm_ss[i];
ssp->nxm_u.sigmask = htog(0);
ssp->nxm_u.sig = htog(0);
ssp->nxm_u.flags = htog(0);
ssp->nxm_u.cancel_state = htog(0);
ssp->nxm_u.nxm_ssig = 0;
ssp->nxm_bits = htog(0);
ssp->nxm_quantum = attrp->nxm_quantum;
ssp->nxm_set_quantum = attrp->nxm_quantum;
ssp->nxm_sysevent = htog(0);
if (i == 0) {
uint64_t uniq = xc->readMiscReg(TheISA::Uniq_DepTag);
ssp->nxm_u.pth_id = htog(uniq + gtoh(attrp->nxm_uniq_offset));
ssp->nxm_u.nxm_active = htog(uniq | 1);
}
else {
ssp->nxm_u.pth_id = htog(0);
ssp->nxm_u.nxm_active = htog(0);
}
}
rad_state.copyOut(xc->mem);
//
// copy pointer to shared config area out to user
//
*configptr_ptr = htog(config_addr);
configptr_ptr.copyOut(xc->mem);
// Register this as a valid address range with the process
process->nxm_start = base_addr;
process->nxm_end = cur_addr;
return 0;
}
/// Initialize execution context.
static void
init_exec_context(ExecContext *ec,
Tru64::nxm_thread_attr *attrp, uint64_t uniq_val)
{
memset(&ec->regs, 0, sizeof(ec->regs));
ec->regs.intRegFile[TheISA::ArgumentReg0] = gtoh(attrp->registers.a0);
ec->regs.intRegFile[27/*t12*/] = gtoh(attrp->registers.pc);
ec->regs.intRegFile[TheISA::StackPointerReg] = gtoh(attrp->registers.sp);
ec->setMiscReg(TheISA::Uniq_DepTag, uniq_val);
ec->regs.pc = gtoh(attrp->registers.pc);
ec->regs.npc = gtoh(attrp->registers.pc) + sizeof(TheISA::MachInst);
ec->activate();
}
/// Create thread.
static SyscallReturn
nxm_thread_createFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
TypedBufferArg<Tru64::nxm_thread_attr> attrp(xc->getSyscallArg(0));
TypedBufferArg<uint64_t> kidp(xc->getSyscallArg(1));
int thread_index = xc->getSyscallArg(2);
// get attribute args
attrp.copyIn(xc->mem);
if (gtoh(attrp->version) != NXM_LIB_VERSION) {
cerr << "nxm_thread_create: thread library version mismatch! "
<< "got " << attrp->version
<< ", expected " << NXM_LIB_VERSION << endl;
abort();
}
if (thread_index < 0 | thread_index > process->numCpus()) {
cerr << "nxm_thread_create: bad thread index " << thread_index
<< endl;
abort();
}
// On a real machine, the per-RAD shared structure is in
// shared memory, so both the user and kernel can get at it.
// We don't have that luxury, so we just copy it in and then
// back out again.
int rad_state_size =
(sizeof(Tru64::nxm_shared) +
(process->numCpus()-1) * sizeof(Tru64::nxm_sched_state));
TypedBufferArg<Tru64::nxm_shared> rad_state(0x14000,
rad_state_size);
rad_state.copyIn(xc->mem);
uint64_t uniq_val = gtoh(attrp->pthid) - gtoh(rad_state->nxm_uniq_offset);
if (gtoh(attrp->type) == Tru64::NXM_TYPE_MANAGER) {
// DEC pthreads seems to always create one of these (in
// addition to N application threads), but we don't use it,
// so don't bother creating it.
// This is supposed to be a port number. Make something up.
*kidp = htog(99);
kidp.copyOut(xc->mem);
return 0;
} else if (gtoh(attrp->type) == Tru64::NXM_TYPE_VP) {
// A real "virtual processor" kernel thread. Need to fork
// this thread on another CPU.
Tru64::nxm_sched_state *ssp = &rad_state->nxm_ss[thread_index];
if (gtoh(ssp->nxm_u.nxm_active) != 0)
return (int) Tru64::KERN_NOT_RECEIVER;
ssp->nxm_u.pth_id = attrp->pthid;
ssp->nxm_u.nxm_active = htog(uniq_val | 1);
rad_state.copyOut(xc->mem);
Addr slot_state_addr = 0x12000 + sizeof(Tru64::nxm_config_info);
int slot_state_size =
process->numCpus() * sizeof(Tru64::nxm_slot_state_t);
TypedBufferArg<Tru64::nxm_slot_state_t>
slot_state(slot_state_addr,
slot_state_size);
slot_state.copyIn(xc->mem);
if (slot_state[thread_index] != Tru64::NXM_SLOT_AVAIL) {
cerr << "nxm_thread_createFunc: requested VP slot "
<< thread_index << " not available!" << endl;
fatal("");
}
// XXX This should have an endian conversion but I think this code
// doesn't work anyway
slot_state[thread_index] = Tru64::NXM_SLOT_BOUND;
slot_state.copyOut(xc->mem);
// Find a free simulator execution context.
for (int i = 0; i < process->numCpus(); ++i) {
ExecContext *xc = process->execContexts[i];
if (xc->status() == ExecContext::Unallocated) {
// inactive context... grab it
init_exec_context(xc, attrp, uniq_val);
// This is supposed to be a port number, but we'll try
// and get away with just sticking the thread index
// here.
*kidp = htog(thread_index);
kidp.copyOut(xc->mem);
return 0;
}
}
// fell out of loop... no available inactive context
cerr << "nxm_thread_create: no idle contexts available." << endl;
abort();
} else {
cerr << "nxm_thread_create: can't handle thread type "
<< attrp->type << endl;
abort();
}
return 0;
}
/// Thread idle call (like yield()).
static SyscallReturn
nxm_idleFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
return 0;
}
/// Block thread.
static SyscallReturn
nxm_thread_blockFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
uint64_t tid = xc->getSyscallArg(0);
uint64_t secs = xc->getSyscallArg(1);
uint64_t flags = xc->getSyscallArg(2);
uint64_t action = xc->getSyscallArg(3);
uint64_t usecs = xc->getSyscallArg(4);
cout << xc->cpu->name() << ": nxm_thread_block " << tid << " " << secs
<< " " << flags << " " << action << " " << usecs << endl;
return 0;
}
/// block.
static SyscallReturn
nxm_blockFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
Addr uaddr = xc->getSyscallArg(0);
uint64_t val = xc->getSyscallArg(1);
uint64_t secs = xc->getSyscallArg(2);
uint64_t usecs = xc->getSyscallArg(3);
uint64_t flags = xc->getSyscallArg(4);
BaseCPU *cpu = xc->cpu;
cout << cpu->name() << ": nxm_block "
<< hex << uaddr << dec << " " << val
<< " " << secs << " " << usecs
<< " " << flags << endl;
return 0;
}
/// Unblock thread.
static SyscallReturn
nxm_unblockFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
Addr uaddr = xc->getSyscallArg(0);
cout << xc->cpu->name() << ": nxm_unblock "
<< hex << uaddr << dec << endl;
return 0;
}
/// Switch thread priority.
static SyscallReturn
swtch_priFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
// Attempts to switch to another runnable thread (if there is
// one). Returns false if there are no other threads to run
// (i.e., the thread can reasonably spin-wait) or true if there
// are other threads.
//
// Since we assume at most one "kernel" thread per CPU, it's
// always safe to return false here.
return 0; //false;
}
/// Activate exec context waiting on a channel. Just activate one
/// by default.
static int
activate_waiting_context(Addr uaddr, Process *process,
bool activate_all = false)
{
int num_activated = 0;
list<Process::WaitRec>::iterator i = process->waitList.begin();
list<Process::WaitRec>::iterator end = process->waitList.end();
while (i != end && (num_activated == 0 || activate_all)) {
if (i->waitChan == uaddr) {
// found waiting process: make it active
ExecContext *newCtx = i->waitingContext;
assert(newCtx->status() == ExecContext::Suspended);
newCtx->activate();
// get rid of this record
i = process->waitList.erase(i);
++num_activated;
} else {
++i;
}
}
return num_activated;
}
/// M5 hacked-up lock acquire.
static void
m5_lock_mutex(Addr uaddr, Process *process, ExecContext *xc)
{
TypedBufferArg<uint64_t> lockp(uaddr);
lockp.copyIn(xc->mem);
if (gtoh(*lockp) == 0) {
// lock is free: grab it
*lockp = htog(1);
lockp.copyOut(xc->mem);
} else {
// lock is busy: disable until free
process->waitList.push_back(Process::WaitRec(uaddr, xc));
xc->suspend();
}
}
/// M5 unlock call.
static void
m5_unlock_mutex(Addr uaddr, Process *process, ExecContext *xc)
{
TypedBufferArg<uint64_t> lockp(uaddr);
lockp.copyIn(xc->mem);
assert(*lockp != 0);
// Check for a process waiting on the lock.
int num_waiting = activate_waiting_context(uaddr, process);
// clear lock field if no waiting context is taking over the lock
if (num_waiting == 0) {
*lockp = 0;
lockp.copyOut(xc->mem);
}
}
/// Lock acquire syscall handler.
static SyscallReturn
m5_mutex_lockFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
Addr uaddr = xc->getSyscallArg(0);
m5_lock_mutex(uaddr, process, xc);
// Return 0 since we will always return to the user with the lock
// acquired. We will just keep the context inactive until that is
// true.
return 0;
}
/// Try lock (non-blocking).
static SyscallReturn
m5_mutex_trylockFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
Addr uaddr = xc->getSyscallArg(0);
TypedBufferArg<uint64_t> lockp(uaddr);
lockp.copyIn(xc->mem);
if (gtoh(*lockp) == 0) {
// lock is free: grab it
*lockp = htog(1);
lockp.copyOut(xc->mem);
return 0;
} else {
return 1;
}
}
/// Unlock syscall handler.
static SyscallReturn
m5_mutex_unlockFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
Addr uaddr = xc->getSyscallArg(0);
m5_unlock_mutex(uaddr, process, xc);
return 0;
}
/// Signal ocndition.
static SyscallReturn
m5_cond_signalFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
Addr cond_addr = xc->getSyscallArg(0);
// Wake up one process waiting on the condition variable.
activate_waiting_context(cond_addr, process);
return 0;
}
/// Wake up all processes waiting on the condition variable.
static SyscallReturn
m5_cond_broadcastFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
Addr cond_addr = xc->getSyscallArg(0);
activate_waiting_context(cond_addr, process, true);
return 0;
}
/// Wait on a condition.
static SyscallReturn
m5_cond_waitFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
Addr cond_addr = xc->getSyscallArg(0);
Addr lock_addr = xc->getSyscallArg(1);
TypedBufferArg<uint64_t> condp(cond_addr);
TypedBufferArg<uint64_t> lockp(lock_addr);
// user is supposed to acquire lock before entering
lockp.copyIn(xc->mem);
assert(gtoh(*lockp) != 0);
m5_unlock_mutex(lock_addr, process, xc);
process->waitList.push_back(Process::WaitRec(cond_addr, xc));
xc->suspend();
return 0;
}
/// Thread exit.
static SyscallReturn
m5_thread_exitFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
assert(xc->status() == ExecContext::Active);
xc->deallocate();
return 0;
}
/// Indirect syscall invocation (call #0).
static SyscallReturn
indirectSyscallFunc(SyscallDesc *desc, int callnum, Process *process,
ExecContext *xc)
{
int new_callnum = xc->getSyscallArg(0);
LiveProcess *lp = dynamic_cast<LiveProcess*>(process);
assert(lp);
for (int i = 0; i < 5; ++i)
xc->setSyscallArg(i, xc->getSyscallArg(i+1));
SyscallDesc *new_desc = lp->getDesc(new_callnum);
if (desc == NULL)
fatal("Syscall %d out of range", callnum);
new_desc->doSyscall(new_callnum, process, xc);
return 0;
}
}; // class Tru64
#endif // FULL_SYSTEM
#endif // __TRU64_HH__