freebsd-nq/sys/cddl/dev/fbt/fbt_powerpc.c
Justin Hibbits 80a5635c8b Add FBT for PowerPC DTrace. Also, clean up the DTrace assembly code,
much of which is not necessary for PowerPC.

The FBT module can likely be factored into 3 separate files: common,
intel, and powerpc, rather than duplicating most of the code between
the x86 and PowerPC flavors.

All DTrace modules for PowerPC will be MFC'd together once Fasttrap is
completed.
2013-03-18 05:30:18 +00:00

1322 lines
31 KiB
C

/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*
* Portions Copyright 2006-2008 John Birrell jb@freebsd.org
* Portions Copyright 2013 Justin Hibbits jhibbits@freebsd.org
*
* $FreeBSD$
*
*/
/*
* Copyright 2006 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
#include <sys/cdefs.h>
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/conf.h>
#include <sys/cpuvar.h>
#include <sys/fcntl.h>
#include <sys/filio.h>
#include <sys/kdb.h>
#include <sys/kernel.h>
#include <sys/kmem.h>
#include <sys/kthread.h>
#include <sys/limits.h>
#include <sys/linker.h>
#include <sys/lock.h>
#include <sys/malloc.h>
#include <sys/module.h>
#include <sys/mutex.h>
#include <sys/pcpu.h>
#include <sys/poll.h>
#include <sys/proc.h>
#include <sys/selinfo.h>
#include <sys/smp.h>
#include <sys/syscall.h>
#include <sys/sysent.h>
#include <sys/sysproto.h>
#include <sys/uio.h>
#include <sys/unistd.h>
#include <machine/stdarg.h>
#include <sys/dtrace.h>
#include <sys/dtrace_bsd.h>
static MALLOC_DEFINE(M_FBT, "fbt", "Function Boundary Tracing");
#define FBT_PATCHVAL 0x7c810808
#define FBT_MFLR_R0 0x7c0802a6
#define FBT_MTLR_R0 0x7c0803a6
#define FBT_BLR 0x4e800020
#define FBT_BCTR 0x4e800030
#define FBT_BRANCH 0x48000000
#define FBT_BR_MASK 0x03fffffc
#define FBT_IS_JUMP(instr) ((instr & ~FBT_BR_MASK) == FBT_BRANCH)
static d_open_t fbt_open;
static int fbt_unload(void);
static void fbt_getargdesc(void *, dtrace_id_t, void *, dtrace_argdesc_t *);
static void fbt_provide_module(void *, modctl_t *);
static void fbt_destroy(void *, dtrace_id_t, void *);
static void fbt_enable(void *, dtrace_id_t, void *);
static void fbt_disable(void *, dtrace_id_t, void *);
static void fbt_load(void *);
static void fbt_suspend(void *, dtrace_id_t, void *);
static void fbt_resume(void *, dtrace_id_t, void *);
#define FBT_ENTRY "entry"
#define FBT_RETURN "return"
#define FBT_ADDR2NDX(addr) ((((uintptr_t)(addr)) >> 4) & fbt_probetab_mask)
#define FBT_PROBETAB_SIZE 0x8000 /* 32k entries -- 128K total */
static struct cdevsw fbt_cdevsw = {
.d_version = D_VERSION,
.d_open = fbt_open,
.d_name = "fbt",
};
static dtrace_pattr_t fbt_attr = {
{ DTRACE_STABILITY_EVOLVING, DTRACE_STABILITY_EVOLVING, DTRACE_CLASS_COMMON },
{ DTRACE_STABILITY_PRIVATE, DTRACE_STABILITY_PRIVATE, DTRACE_CLASS_UNKNOWN },
{ DTRACE_STABILITY_PRIVATE, DTRACE_STABILITY_PRIVATE, DTRACE_CLASS_ISA },
{ DTRACE_STABILITY_EVOLVING, DTRACE_STABILITY_EVOLVING, DTRACE_CLASS_COMMON },
{ DTRACE_STABILITY_PRIVATE, DTRACE_STABILITY_PRIVATE, DTRACE_CLASS_ISA },
};
static dtrace_pops_t fbt_pops = {
NULL,
fbt_provide_module,
fbt_enable,
fbt_disable,
fbt_suspend,
fbt_resume,
fbt_getargdesc,
NULL,
NULL,
fbt_destroy
};
typedef struct fbt_probe {
struct fbt_probe *fbtp_hashnext;
uint32_t *fbtp_patchpoint;
int8_t fbtp_rval;
uint32_t fbtp_patchval;
uint32_t fbtp_savedval;
uintptr_t fbtp_roffset;
dtrace_id_t fbtp_id;
const char *fbtp_name;
modctl_t *fbtp_ctl;
int fbtp_loadcnt;
int fbtp_primary;
int fbtp_invop_cnt;
int fbtp_symindx;
struct fbt_probe *fbtp_next;
} fbt_probe_t;
static struct cdev *fbt_cdev;
static dtrace_provider_id_t fbt_id;
static fbt_probe_t **fbt_probetab;
static int fbt_probetab_size;
static int fbt_probetab_mask;
static int fbt_verbose = 0;
static int
fbt_invop(uintptr_t addr, uintptr_t *stack, uintptr_t rval)
{
struct trapframe *frame = (struct trapframe *)stack;
solaris_cpu_t *cpu = &solaris_cpu[curcpu];
fbt_probe_t *fbt = fbt_probetab[FBT_ADDR2NDX(addr)];
uintptr_t tmp;
for (; fbt != NULL; fbt = fbt->fbtp_hashnext) {
if ((uintptr_t)fbt->fbtp_patchpoint == addr) {
fbt->fbtp_invop_cnt++;
if (fbt->fbtp_roffset == 0) {
cpu->cpu_dtrace_caller = addr;
dtrace_probe(fbt->fbtp_id, frame->fixreg[3],
frame->fixreg[4], frame->fixreg[5],
frame->fixreg[6], frame->fixreg[7]);
cpu->cpu_dtrace_caller = 0;
} else {
dtrace_probe(fbt->fbtp_id, fbt->fbtp_roffset,
rval, 0, 0, 0);
/*
* The caller doesn't have the fbt item, so
* fixup tail calls here.
*/
if (fbt->fbtp_rval == DTRACE_INVOP_JUMP) {
frame->srr0 = (uintptr_t)fbt->fbtp_patchpoint;
tmp = fbt->fbtp_savedval & FBT_BR_MASK;
/* Sign extend. */
if (tmp & 0x02000000)
tmp |= 0xFC000000;
frame->srr0 += tmp;
}
cpu->cpu_dtrace_caller = 0;
}
return (fbt->fbtp_rval);
}
}
return (0);
}
static int
fbt_provide_module_function(linker_file_t lf, int symindx,
linker_symval_t *symval, void *opaque)
{
char *modname = opaque;
const char *name = symval->name;
fbt_probe_t *fbt, *retfbt;
int j;
int size;
u_int32_t *instr, *limit;
if (strncmp(name, "dtrace_", 7) == 0 &&
strncmp(name, "dtrace_safe_", 12) != 0) {
/*
* Anything beginning with "dtrace_" may be called
* from probe context unless it explicitly indicates
* that it won't be called from probe context by
* using the prefix "dtrace_safe_".
*/
return (0);
}
if (name[0] == '_' && name[1] == '_')
return (0);
size = symval->size;
instr = (u_int32_t *) symval->value;
limit = (u_int32_t *) symval->value + symval->size;
for (; instr < limit; instr++)
if (*instr == FBT_MFLR_R0)
break;
if (*instr != FBT_MFLR_R0);
return (0);
fbt = malloc(sizeof (fbt_probe_t), M_FBT, M_WAITOK | M_ZERO);
fbt->fbtp_name = name;
fbt->fbtp_id = dtrace_probe_create(fbt_id, modname,
name, FBT_ENTRY, 3, fbt);
fbt->fbtp_patchpoint = instr;
fbt->fbtp_ctl = lf;
fbt->fbtp_loadcnt = lf->loadcnt;
fbt->fbtp_savedval = *instr;
fbt->fbtp_patchval = FBT_PATCHVAL;
fbt->fbtp_rval = DTRACE_INVOP_MFLR_R0;
fbt->fbtp_symindx = symindx;
fbt->fbtp_hashnext = fbt_probetab[FBT_ADDR2NDX(instr)];
fbt_probetab[FBT_ADDR2NDX(instr)] = fbt;
lf->fbt_nentries++;
retfbt = NULL;
again:
if (instr >= limit)
return (0);
/*
* We (desperately) want to avoid erroneously instrumenting a
* jump table To determine if we're looking at a true instruction
* sequence or an inline jump table that happens to contain the same
* byte sequences, we resort to some heuristic sleeze: we treat this
* instruction as being contained within a pointer, and see if that
* pointer points to within the body of the function. If it does, we
* refuse to instrument it.
*/
{
uint32_t *ptr;
ptr = *(uint32_t **)instr;
if (ptr >= (uint32_t *) symval->value && ptr < limit) {
instr++;
goto again;
}
}
if (*instr == FBT_MFLR_R0)
return (0);
if (*instr != FBT_MTLR_R0) {
instr++;
goto again;
}
instr++;
for (j = 0; j < 12 && instr < limit; j++, instr++) {
if ((*instr == FBT_BCTR) || (*instr == FBT_BLR) |
FBT_IS_JUMP(*instr))
break;
}
if (!(*instr == FBT_BCTR || *instr == FBT_BLR || FBT_IS_JUMP(*instr)))
goto again;
/*
* We have a winner!
*/
fbt = malloc(sizeof (fbt_probe_t), M_FBT, M_WAITOK | M_ZERO);
fbt->fbtp_name = name;
if (retfbt == NULL) {
fbt->fbtp_id = dtrace_probe_create(fbt_id, modname,
name, FBT_RETURN, 3, fbt);
} else {
retfbt->fbtp_next = fbt;
fbt->fbtp_id = retfbt->fbtp_id;
}
retfbt = fbt;
fbt->fbtp_patchpoint = instr;
fbt->fbtp_ctl = lf;
fbt->fbtp_loadcnt = lf->loadcnt;
fbt->fbtp_symindx = symindx;
if (*instr == FBT_BCTR)
fbt->fbtp_rval = DTRACE_INVOP_BCTR;
else if (*instr == FBT_BLR)
fbt->fbtp_rval = DTRACE_INVOP_RET;
else
fbt->fbtp_rval = DTRACE_INVOP_JUMP;
fbt->fbtp_savedval = *instr;
fbt->fbtp_patchval = FBT_PATCHVAL;
fbt->fbtp_hashnext = fbt_probetab[FBT_ADDR2NDX(instr)];
fbt_probetab[FBT_ADDR2NDX(instr)] = fbt;
lf->fbt_nentries++;
instr += size;
goto again;
}
static void
fbt_provide_module(void *arg, modctl_t *lf)
{
char modname[MAXPATHLEN];
int i;
size_t len;
strlcpy(modname, lf->filename, sizeof(modname));
len = strlen(modname);
if (len > 3 && strcmp(modname + len - 3, ".ko") == 0)
modname[len - 3] = '\0';
/*
* Employees of dtrace and their families are ineligible. Void
* where prohibited.
*/
if (strcmp(modname, "dtrace") == 0)
return;
/*
* The cyclic timer subsystem can be built as a module and DTrace
* depends on that, so it is ineligible too.
*/
if (strcmp(modname, "cyclic") == 0)
return;
/*
* To register with DTrace, a module must list 'dtrace' as a
* dependency in order for the kernel linker to resolve
* symbols like dtrace_register(). All modules with such a
* dependency are ineligible for FBT tracing.
*/
for (i = 0; i < lf->ndeps; i++)
if (strncmp(lf->deps[i]->filename, "dtrace", 6) == 0)
return;
if (lf->fbt_nentries) {
/*
* This module has some FBT entries allocated; we're afraid
* to screw with it.
*/
return;
}
/*
* List the functions in the module and the symbol values.
*/
(void) linker_file_function_listall(lf, fbt_provide_module_function, modname);
}
static void
fbt_destroy(void *arg, dtrace_id_t id, void *parg)
{
fbt_probe_t *fbt = parg, *next, *hash, *last;
modctl_t *ctl;
int ndx;
do {
ctl = fbt->fbtp_ctl;
ctl->fbt_nentries--;
/*
* Now we need to remove this probe from the fbt_probetab.
*/
ndx = FBT_ADDR2NDX(fbt->fbtp_patchpoint);
last = NULL;
hash = fbt_probetab[ndx];
while (hash != fbt) {
ASSERT(hash != NULL);
last = hash;
hash = hash->fbtp_hashnext;
}
if (last != NULL) {
last->fbtp_hashnext = fbt->fbtp_hashnext;
} else {
fbt_probetab[ndx] = fbt->fbtp_hashnext;
}
next = fbt->fbtp_next;
free(fbt, M_FBT);
fbt = next;
} while (fbt != NULL);
}
static void
fbt_enable(void *arg, dtrace_id_t id, void *parg)
{
fbt_probe_t *fbt = parg;
modctl_t *ctl = fbt->fbtp_ctl;
ctl->nenabled++;
/*
* Now check that our modctl has the expected load count. If it
* doesn't, this module must have been unloaded and reloaded -- and
* we're not going to touch it.
*/
if (ctl->loadcnt != fbt->fbtp_loadcnt) {
if (fbt_verbose) {
printf("fbt is failing for probe %s "
"(module %s reloaded)",
fbt->fbtp_name, ctl->filename);
}
return;
}
for (; fbt != NULL; fbt = fbt->fbtp_next) {
*fbt->fbtp_patchpoint = fbt->fbtp_patchval;
}
}
static void
fbt_disable(void *arg, dtrace_id_t id, void *parg)
{
fbt_probe_t *fbt = parg;
modctl_t *ctl = fbt->fbtp_ctl;
ASSERT(ctl->nenabled > 0);
ctl->nenabled--;
if ((ctl->loadcnt != fbt->fbtp_loadcnt))
return;
for (; fbt != NULL; fbt = fbt->fbtp_next)
*fbt->fbtp_patchpoint = fbt->fbtp_savedval;
}
static void
fbt_suspend(void *arg, dtrace_id_t id, void *parg)
{
fbt_probe_t *fbt = parg;
modctl_t *ctl = fbt->fbtp_ctl;
ASSERT(ctl->nenabled > 0);
if ((ctl->loadcnt != fbt->fbtp_loadcnt))
return;
for (; fbt != NULL; fbt = fbt->fbtp_next)
*fbt->fbtp_patchpoint = fbt->fbtp_savedval;
}
static void
fbt_resume(void *arg, dtrace_id_t id, void *parg)
{
fbt_probe_t *fbt = parg;
modctl_t *ctl = fbt->fbtp_ctl;
ASSERT(ctl->nenabled > 0);
if ((ctl->loadcnt != fbt->fbtp_loadcnt))
return;
for (; fbt != NULL; fbt = fbt->fbtp_next)
*fbt->fbtp_patchpoint = fbt->fbtp_patchval;
}
static int
fbt_ctfoff_init(modctl_t *lf, linker_ctf_t *lc)
{
const Elf_Sym *symp = lc->symtab;;
const char *name;
const ctf_header_t *hp = (const ctf_header_t *) lc->ctftab;
const uint8_t *ctfdata = lc->ctftab + sizeof(ctf_header_t);
int i;
uint32_t *ctfoff;
uint32_t objtoff = hp->cth_objtoff;
uint32_t funcoff = hp->cth_funcoff;
ushort_t info;
ushort_t vlen;
/* Sanity check. */
if (hp->cth_magic != CTF_MAGIC) {
printf("Bad magic value in CTF data of '%s'\n",lf->pathname);
return (EINVAL);
}
if (lc->symtab == NULL) {
printf("No symbol table in '%s'\n",lf->pathname);
return (EINVAL);
}
if ((ctfoff = malloc(sizeof(uint32_t) * lc->nsym, M_LINKER, M_WAITOK)) == NULL)
return (ENOMEM);
*lc->ctfoffp = ctfoff;
for (i = 0; i < lc->nsym; i++, ctfoff++, symp++) {
if (symp->st_name == 0 || symp->st_shndx == SHN_UNDEF) {
*ctfoff = 0xffffffff;
continue;
}
if (symp->st_name < lc->strcnt)
name = lc->strtab + symp->st_name;
else
name = "(?)";
switch (ELF_ST_TYPE(symp->st_info)) {
case STT_OBJECT:
if (objtoff >= hp->cth_funcoff ||
(symp->st_shndx == SHN_ABS && symp->st_value == 0)) {
*ctfoff = 0xffffffff;
break;
}
*ctfoff = objtoff;
objtoff += sizeof (ushort_t);
break;
case STT_FUNC:
if (funcoff >= hp->cth_typeoff) {
*ctfoff = 0xffffffff;
break;
}
*ctfoff = funcoff;
info = *((const ushort_t *)(ctfdata + funcoff));
vlen = CTF_INFO_VLEN(info);
/*
* If we encounter a zero pad at the end, just skip it.
* Otherwise skip over the function and its return type
* (+2) and the argument list (vlen).
*/
if (CTF_INFO_KIND(info) == CTF_K_UNKNOWN && vlen == 0)
funcoff += sizeof (ushort_t); /* skip pad */
else
funcoff += sizeof (ushort_t) * (vlen + 2);
break;
default:
*ctfoff = 0xffffffff;
break;
}
}
return (0);
}
static ssize_t
fbt_get_ctt_size(uint8_t version, const ctf_type_t *tp, ssize_t *sizep,
ssize_t *incrementp)
{
ssize_t size, increment;
if (version > CTF_VERSION_1 &&
tp->ctt_size == CTF_LSIZE_SENT) {
size = CTF_TYPE_LSIZE(tp);
increment = sizeof (ctf_type_t);
} else {
size = tp->ctt_size;
increment = sizeof (ctf_stype_t);
}
if (sizep)
*sizep = size;
if (incrementp)
*incrementp = increment;
return (size);
}
static int
fbt_typoff_init(linker_ctf_t *lc)
{
const ctf_header_t *hp = (const ctf_header_t *) lc->ctftab;
const ctf_type_t *tbuf;
const ctf_type_t *tend;
const ctf_type_t *tp;
const uint8_t *ctfdata = lc->ctftab + sizeof(ctf_header_t);
int ctf_typemax = 0;
uint32_t *xp;
ulong_t pop[CTF_K_MAX + 1] = { 0 };
/* Sanity check. */
if (hp->cth_magic != CTF_MAGIC)
return (EINVAL);
tbuf = (const ctf_type_t *) (ctfdata + hp->cth_typeoff);
tend = (const ctf_type_t *) (ctfdata + hp->cth_stroff);
int child = hp->cth_parname != 0;
/*
* We make two passes through the entire type section. In this first
* pass, we count the number of each type and the total number of types.
*/
for (tp = tbuf; tp < tend; ctf_typemax++) {
ushort_t kind = CTF_INFO_KIND(tp->ctt_info);
ulong_t vlen = CTF_INFO_VLEN(tp->ctt_info);
ssize_t size, increment;
size_t vbytes;
uint_t n;
(void) fbt_get_ctt_size(hp->cth_version, tp, &size, &increment);
switch (kind) {
case CTF_K_INTEGER:
case CTF_K_FLOAT:
vbytes = sizeof (uint_t);
break;
case CTF_K_ARRAY:
vbytes = sizeof (ctf_array_t);
break;
case CTF_K_FUNCTION:
vbytes = sizeof (ushort_t) * (vlen + (vlen & 1));
break;
case CTF_K_STRUCT:
case CTF_K_UNION:
if (size < CTF_LSTRUCT_THRESH) {
ctf_member_t *mp = (ctf_member_t *)
((uintptr_t)tp + increment);
vbytes = sizeof (ctf_member_t) * vlen;
for (n = vlen; n != 0; n--, mp++)
child |= CTF_TYPE_ISCHILD(mp->ctm_type);
} else {
ctf_lmember_t *lmp = (ctf_lmember_t *)
((uintptr_t)tp + increment);
vbytes = sizeof (ctf_lmember_t) * vlen;
for (n = vlen; n != 0; n--, lmp++)
child |=
CTF_TYPE_ISCHILD(lmp->ctlm_type);
}
break;
case CTF_K_ENUM:
vbytes = sizeof (ctf_enum_t) * vlen;
break;
case CTF_K_FORWARD:
/*
* For forward declarations, ctt_type is the CTF_K_*
* kind for the tag, so bump that population count too.
* If ctt_type is unknown, treat the tag as a struct.
*/
if (tp->ctt_type == CTF_K_UNKNOWN ||
tp->ctt_type >= CTF_K_MAX)
pop[CTF_K_STRUCT]++;
else
pop[tp->ctt_type]++;
/*FALLTHRU*/
case CTF_K_UNKNOWN:
vbytes = 0;
break;
case CTF_K_POINTER:
case CTF_K_TYPEDEF:
case CTF_K_VOLATILE:
case CTF_K_CONST:
case CTF_K_RESTRICT:
child |= CTF_TYPE_ISCHILD(tp->ctt_type);
vbytes = 0;
break;
default:
printf("%s(%d): detected invalid CTF kind -- %u\n", __func__, __LINE__, kind);
return (EIO);
}
tp = (ctf_type_t *)((uintptr_t)tp + increment + vbytes);
pop[kind]++;
}
*lc->typlenp = ctf_typemax;
if ((xp = malloc(sizeof(uint32_t) * ctf_typemax, M_LINKER, M_ZERO | M_WAITOK)) == NULL)
return (ENOMEM);
*lc->typoffp = xp;
/* type id 0 is used as a sentinel value */
*xp++ = 0;
/*
* In the second pass, fill in the type offset.
*/
for (tp = tbuf; tp < tend; xp++) {
ushort_t kind = CTF_INFO_KIND(tp->ctt_info);
ulong_t vlen = CTF_INFO_VLEN(tp->ctt_info);
ssize_t size, increment;
size_t vbytes;
uint_t n;
(void) fbt_get_ctt_size(hp->cth_version, tp, &size, &increment);
switch (kind) {
case CTF_K_INTEGER:
case CTF_K_FLOAT:
vbytes = sizeof (uint_t);
break;
case CTF_K_ARRAY:
vbytes = sizeof (ctf_array_t);
break;
case CTF_K_FUNCTION:
vbytes = sizeof (ushort_t) * (vlen + (vlen & 1));
break;
case CTF_K_STRUCT:
case CTF_K_UNION:
if (size < CTF_LSTRUCT_THRESH) {
ctf_member_t *mp = (ctf_member_t *)
((uintptr_t)tp + increment);
vbytes = sizeof (ctf_member_t) * vlen;
for (n = vlen; n != 0; n--, mp++)
child |= CTF_TYPE_ISCHILD(mp->ctm_type);
} else {
ctf_lmember_t *lmp = (ctf_lmember_t *)
((uintptr_t)tp + increment);
vbytes = sizeof (ctf_lmember_t) * vlen;
for (n = vlen; n != 0; n--, lmp++)
child |=
CTF_TYPE_ISCHILD(lmp->ctlm_type);
}
break;
case CTF_K_ENUM:
vbytes = sizeof (ctf_enum_t) * vlen;
break;
case CTF_K_FORWARD:
case CTF_K_UNKNOWN:
vbytes = 0;
break;
case CTF_K_POINTER:
case CTF_K_TYPEDEF:
case CTF_K_VOLATILE:
case CTF_K_CONST:
case CTF_K_RESTRICT:
vbytes = 0;
break;
default:
printf("%s(%d): detected invalid CTF kind -- %u\n", __func__, __LINE__, kind);
return (EIO);
}
*xp = (uint32_t)((uintptr_t) tp - (uintptr_t) ctfdata);
tp = (ctf_type_t *)((uintptr_t)tp + increment + vbytes);
}
return (0);
}
/*
* CTF Declaration Stack
*
* In order to implement ctf_type_name(), we must convert a type graph back
* into a C type declaration. Unfortunately, a type graph represents a storage
* class ordering of the type whereas a type declaration must obey the C rules
* for operator precedence, and the two orderings are frequently in conflict.
* For example, consider these CTF type graphs and their C declarations:
*
* CTF_K_POINTER -> CTF_K_FUNCTION -> CTF_K_INTEGER : int (*)()
* CTF_K_POINTER -> CTF_K_ARRAY -> CTF_K_INTEGER : int (*)[]
*
* In each case, parentheses are used to raise operator * to higher lexical
* precedence, so the string form of the C declaration cannot be constructed by
* walking the type graph links and forming the string from left to right.
*
* The functions in this file build a set of stacks from the type graph nodes
* corresponding to the C operator precedence levels in the appropriate order.
* The code in ctf_type_name() can then iterate over the levels and nodes in
* lexical precedence order and construct the final C declaration string.
*/
typedef struct ctf_list {
struct ctf_list *l_prev; /* previous pointer or tail pointer */
struct ctf_list *l_next; /* next pointer or head pointer */
} ctf_list_t;
#define ctf_list_prev(elem) ((void *)(((ctf_list_t *)(elem))->l_prev))
#define ctf_list_next(elem) ((void *)(((ctf_list_t *)(elem))->l_next))
typedef enum {
CTF_PREC_BASE,
CTF_PREC_POINTER,
CTF_PREC_ARRAY,
CTF_PREC_FUNCTION,
CTF_PREC_MAX
} ctf_decl_prec_t;
typedef struct ctf_decl_node {
ctf_list_t cd_list; /* linked list pointers */
ctf_id_t cd_type; /* type identifier */
uint_t cd_kind; /* type kind */
uint_t cd_n; /* type dimension if array */
} ctf_decl_node_t;
typedef struct ctf_decl {
ctf_list_t cd_nodes[CTF_PREC_MAX]; /* declaration node stacks */
int cd_order[CTF_PREC_MAX]; /* storage order of decls */
ctf_decl_prec_t cd_qualp; /* qualifier precision */
ctf_decl_prec_t cd_ordp; /* ordered precision */
char *cd_buf; /* buffer for output */
char *cd_ptr; /* buffer location */
char *cd_end; /* buffer limit */
size_t cd_len; /* buffer space required */
int cd_err; /* saved error value */
} ctf_decl_t;
/*
* Simple doubly-linked list append routine. This implementation assumes that
* each list element contains an embedded ctf_list_t as the first member.
* An additional ctf_list_t is used to store the head (l_next) and tail
* (l_prev) pointers. The current head and tail list elements have their
* previous and next pointers set to NULL, respectively.
*/
static void
ctf_list_append(ctf_list_t *lp, void *new)
{
ctf_list_t *p = lp->l_prev; /* p = tail list element */
ctf_list_t *q = new; /* q = new list element */
lp->l_prev = q;
q->l_prev = p;
q->l_next = NULL;
if (p != NULL)
p->l_next = q;
else
lp->l_next = q;
}
/*
* Prepend the specified existing element to the given ctf_list_t. The
* existing pointer should be pointing at a struct with embedded ctf_list_t.
*/
static void
ctf_list_prepend(ctf_list_t *lp, void *new)
{
ctf_list_t *p = new; /* p = new list element */
ctf_list_t *q = lp->l_next; /* q = head list element */
lp->l_next = p;
p->l_prev = NULL;
p->l_next = q;
if (q != NULL)
q->l_prev = p;
else
lp->l_prev = p;
}
static void
ctf_decl_init(ctf_decl_t *cd, char *buf, size_t len)
{
int i;
bzero(cd, sizeof (ctf_decl_t));
for (i = CTF_PREC_BASE; i < CTF_PREC_MAX; i++)
cd->cd_order[i] = CTF_PREC_BASE - 1;
cd->cd_qualp = CTF_PREC_BASE;
cd->cd_ordp = CTF_PREC_BASE;
cd->cd_buf = buf;
cd->cd_ptr = buf;
cd->cd_end = buf + len;
}
static void
ctf_decl_fini(ctf_decl_t *cd)
{
ctf_decl_node_t *cdp, *ndp;
int i;
for (i = CTF_PREC_BASE; i < CTF_PREC_MAX; i++) {
for (cdp = ctf_list_next(&cd->cd_nodes[i]);
cdp != NULL; cdp = ndp) {
ndp = ctf_list_next(cdp);
free(cdp, M_FBT);
}
}
}
static const ctf_type_t *
ctf_lookup_by_id(linker_ctf_t *lc, ctf_id_t type)
{
const ctf_type_t *tp;
uint32_t offset;
uint32_t *typoff = *lc->typoffp;
if (type >= *lc->typlenp) {
printf("%s(%d): type %d exceeds max %ld\n",__func__,__LINE__,(int) type,*lc->typlenp);
return(NULL);
}
/* Check if the type isn't cross-referenced. */
if ((offset = typoff[type]) == 0) {
printf("%s(%d): type %d isn't cross referenced\n",__func__,__LINE__, (int) type);
return(NULL);
}
tp = (const ctf_type_t *)(lc->ctftab + offset + sizeof(ctf_header_t));
return (tp);
}
static void
fbt_array_info(linker_ctf_t *lc, ctf_id_t type, ctf_arinfo_t *arp)
{
const ctf_header_t *hp = (const ctf_header_t *) lc->ctftab;
const ctf_type_t *tp;
const ctf_array_t *ap;
ssize_t increment;
bzero(arp, sizeof(*arp));
if ((tp = ctf_lookup_by_id(lc, type)) == NULL)
return;
if (CTF_INFO_KIND(tp->ctt_info) != CTF_K_ARRAY)
return;
(void) fbt_get_ctt_size(hp->cth_version, tp, NULL, &increment);
ap = (const ctf_array_t *)((uintptr_t)tp + increment);
arp->ctr_contents = ap->cta_contents;
arp->ctr_index = ap->cta_index;
arp->ctr_nelems = ap->cta_nelems;
}
static const char *
ctf_strptr(linker_ctf_t *lc, int name)
{
const ctf_header_t *hp = (const ctf_header_t *) lc->ctftab;;
const char *strp = "";
if (name < 0 || name >= hp->cth_strlen)
return(strp);
strp = (const char *)(lc->ctftab + hp->cth_stroff + name + sizeof(ctf_header_t));
return (strp);
}
static void
ctf_decl_push(ctf_decl_t *cd, linker_ctf_t *lc, ctf_id_t type)
{
ctf_decl_node_t *cdp;
ctf_decl_prec_t prec;
uint_t kind, n = 1;
int is_qual = 0;
const ctf_type_t *tp;
ctf_arinfo_t ar;
if ((tp = ctf_lookup_by_id(lc, type)) == NULL) {
cd->cd_err = ENOENT;
return;
}
switch (kind = CTF_INFO_KIND(tp->ctt_info)) {
case CTF_K_ARRAY:
fbt_array_info(lc, type, &ar);
ctf_decl_push(cd, lc, ar.ctr_contents);
n = ar.ctr_nelems;
prec = CTF_PREC_ARRAY;
break;
case CTF_K_TYPEDEF:
if (ctf_strptr(lc, tp->ctt_name)[0] == '\0') {
ctf_decl_push(cd, lc, tp->ctt_type);
return;
}
prec = CTF_PREC_BASE;
break;
case CTF_K_FUNCTION:
ctf_decl_push(cd, lc, tp->ctt_type);
prec = CTF_PREC_FUNCTION;
break;
case CTF_K_POINTER:
ctf_decl_push(cd, lc, tp->ctt_type);
prec = CTF_PREC_POINTER;
break;
case CTF_K_VOLATILE:
case CTF_K_CONST:
case CTF_K_RESTRICT:
ctf_decl_push(cd, lc, tp->ctt_type);
prec = cd->cd_qualp;
is_qual++;
break;
default:
prec = CTF_PREC_BASE;
}
if ((cdp = malloc(sizeof (ctf_decl_node_t), M_FBT, M_WAITOK)) == NULL) {
cd->cd_err = EAGAIN;
return;
}
cdp->cd_type = type;
cdp->cd_kind = kind;
cdp->cd_n = n;
if (ctf_list_next(&cd->cd_nodes[prec]) == NULL)
cd->cd_order[prec] = cd->cd_ordp++;
/*
* Reset cd_qualp to the highest precedence level that we've seen so
* far that can be qualified (CTF_PREC_BASE or CTF_PREC_POINTER).
*/
if (prec > cd->cd_qualp && prec < CTF_PREC_ARRAY)
cd->cd_qualp = prec;
/*
* C array declarators are ordered inside out so prepend them. Also by
* convention qualifiers of base types precede the type specifier (e.g.
* const int vs. int const) even though the two forms are equivalent.
*/
if (kind == CTF_K_ARRAY || (is_qual && prec == CTF_PREC_BASE))
ctf_list_prepend(&cd->cd_nodes[prec], cdp);
else
ctf_list_append(&cd->cd_nodes[prec], cdp);
}
static void
ctf_decl_sprintf(ctf_decl_t *cd, const char *format, ...)
{
size_t len = (size_t)(cd->cd_end - cd->cd_ptr);
va_list ap;
size_t n;
va_start(ap, format);
n = vsnprintf(cd->cd_ptr, len, format, ap);
va_end(ap);
cd->cd_ptr += MIN(n, len);
cd->cd_len += n;
}
static ssize_t
fbt_type_name(linker_ctf_t *lc, ctf_id_t type, char *buf, size_t len)
{
ctf_decl_t cd;
ctf_decl_node_t *cdp;
ctf_decl_prec_t prec, lp, rp;
int ptr, arr;
uint_t k;
if (lc == NULL && type == CTF_ERR)
return (-1); /* simplify caller code by permitting CTF_ERR */
ctf_decl_init(&cd, buf, len);
ctf_decl_push(&cd, lc, type);
if (cd.cd_err != 0) {
ctf_decl_fini(&cd);
return (-1);
}
/*
* If the type graph's order conflicts with lexical precedence order
* for pointers or arrays, then we need to surround the declarations at
* the corresponding lexical precedence with parentheses. This can
* result in either a parenthesized pointer (*) as in int (*)() or
* int (*)[], or in a parenthesized pointer and array as in int (*[])().
*/
ptr = cd.cd_order[CTF_PREC_POINTER] > CTF_PREC_POINTER;
arr = cd.cd_order[CTF_PREC_ARRAY] > CTF_PREC_ARRAY;
rp = arr ? CTF_PREC_ARRAY : ptr ? CTF_PREC_POINTER : -1;
lp = ptr ? CTF_PREC_POINTER : arr ? CTF_PREC_ARRAY : -1;
k = CTF_K_POINTER; /* avoid leading whitespace (see below) */
for (prec = CTF_PREC_BASE; prec < CTF_PREC_MAX; prec++) {
for (cdp = ctf_list_next(&cd.cd_nodes[prec]);
cdp != NULL; cdp = ctf_list_next(cdp)) {
const ctf_type_t *tp =
ctf_lookup_by_id(lc, cdp->cd_type);
const char *name = ctf_strptr(lc, tp->ctt_name);
if (k != CTF_K_POINTER && k != CTF_K_ARRAY)
ctf_decl_sprintf(&cd, " ");
if (lp == prec) {
ctf_decl_sprintf(&cd, "(");
lp = -1;
}
switch (cdp->cd_kind) {
case CTF_K_INTEGER:
case CTF_K_FLOAT:
case CTF_K_TYPEDEF:
ctf_decl_sprintf(&cd, "%s", name);
break;
case CTF_K_POINTER:
ctf_decl_sprintf(&cd, "*");
break;
case CTF_K_ARRAY:
ctf_decl_sprintf(&cd, "[%u]", cdp->cd_n);
break;
case CTF_K_FUNCTION:
ctf_decl_sprintf(&cd, "()");
break;
case CTF_K_STRUCT:
case CTF_K_FORWARD:
ctf_decl_sprintf(&cd, "struct %s", name);
break;
case CTF_K_UNION:
ctf_decl_sprintf(&cd, "union %s", name);
break;
case CTF_K_ENUM:
ctf_decl_sprintf(&cd, "enum %s", name);
break;
case CTF_K_VOLATILE:
ctf_decl_sprintf(&cd, "volatile");
break;
case CTF_K_CONST:
ctf_decl_sprintf(&cd, "const");
break;
case CTF_K_RESTRICT:
ctf_decl_sprintf(&cd, "restrict");
break;
}
k = cdp->cd_kind;
}
if (rp == prec)
ctf_decl_sprintf(&cd, ")");
}
ctf_decl_fini(&cd);
return (cd.cd_len);
}
static void
fbt_getargdesc(void *arg __unused, dtrace_id_t id __unused, void *parg, dtrace_argdesc_t *desc)
{
const ushort_t *dp;
fbt_probe_t *fbt = parg;
linker_ctf_t lc;
modctl_t *ctl = fbt->fbtp_ctl;
int ndx = desc->dtargd_ndx;
int symindx = fbt->fbtp_symindx;
uint32_t *ctfoff;
uint32_t offset;
ushort_t info, kind, n;
desc->dtargd_ndx = DTRACE_ARGNONE;
/* Get a pointer to the CTF data and it's length. */
if (linker_ctf_get(ctl, &lc) != 0)
/* No CTF data? Something wrong? *shrug* */
return;
/* Check if this module hasn't been initialised yet. */
if (*lc.ctfoffp == NULL) {
/*
* Initialise the CTF object and function symindx to
* byte offset array.
*/
if (fbt_ctfoff_init(ctl, &lc) != 0)
return;
/* Initialise the CTF type to byte offset array. */
if (fbt_typoff_init(&lc) != 0)
return;
}
ctfoff = *lc.ctfoffp;
if (ctfoff == NULL || *lc.typoffp == NULL)
return;
/* Check if the symbol index is out of range. */
if (symindx >= lc.nsym)
return;
/* Check if the symbol isn't cross-referenced. */
if ((offset = ctfoff[symindx]) == 0xffffffff)
return;
dp = (const ushort_t *)(lc.ctftab + offset + sizeof(ctf_header_t));
info = *dp++;
kind = CTF_INFO_KIND(info);
n = CTF_INFO_VLEN(info);
if (kind == CTF_K_UNKNOWN && n == 0) {
printf("%s(%d): Unknown function!\n",__func__,__LINE__);
return;
}
if (kind != CTF_K_FUNCTION) {
printf("%s(%d): Expected a function!\n",__func__,__LINE__);
return;
}
/* Check if the requested argument doesn't exist. */
if (ndx >= n)
return;
/* Skip the return type and arguments up to the one requested. */
dp += ndx + 1;
if (fbt_type_name(&lc, *dp, desc->dtargd_native, sizeof(desc->dtargd_native)) > 0)
desc->dtargd_ndx = ndx;
return;
}
static void
fbt_load(void *dummy)
{
/* Create the /dev/dtrace/fbt entry. */
fbt_cdev = make_dev(&fbt_cdevsw, 0, UID_ROOT, GID_WHEEL, 0600,
"dtrace/fbt");
/* Default the probe table size if not specified. */
if (fbt_probetab_size == 0)
fbt_probetab_size = FBT_PROBETAB_SIZE;
/* Choose the hash mask for the probe table. */
fbt_probetab_mask = fbt_probetab_size - 1;
/* Allocate memory for the probe table. */
fbt_probetab =
malloc(fbt_probetab_size * sizeof (fbt_probe_t *), M_FBT, M_WAITOK | M_ZERO);
dtrace_invop_add(fbt_invop);
if (dtrace_register("fbt", &fbt_attr, DTRACE_PRIV_USER,
NULL, &fbt_pops, NULL, &fbt_id) != 0)
return;
}
static int
fbt_unload()
{
int error = 0;
/* De-register the invalid opcode handler. */
dtrace_invop_remove(fbt_invop);
/* De-register this DTrace provider. */
if ((error = dtrace_unregister(fbt_id)) != 0)
return (error);
/* Free the probe table. */
free(fbt_probetab, M_FBT);
fbt_probetab = NULL;
fbt_probetab_mask = 0;
destroy_dev(fbt_cdev);
return (error);
}
static int
fbt_modevent(module_t mod __unused, int type, void *data __unused)
{
int error = 0;
switch (type) {
case MOD_LOAD:
break;
case MOD_UNLOAD:
break;
case MOD_SHUTDOWN:
break;
default:
error = EOPNOTSUPP;
break;
}
return (error);
}
static int
fbt_open(struct cdev *dev __unused, int oflags __unused, int devtype __unused, struct thread *td __unused)
{
return (0);
}
SYSINIT(fbt_load, SI_SUB_DTRACE_PROVIDER, SI_ORDER_ANY, fbt_load, NULL);
SYSUNINIT(fbt_unload, SI_SUB_DTRACE_PROVIDER, SI_ORDER_ANY, fbt_unload, NULL);
DEV_MODULE(fbt, fbt_modevent, NULL);
MODULE_VERSION(fbt, 1);
MODULE_DEPEND(fbt, dtrace, 1, 1, 1);
MODULE_DEPEND(fbt, opensolaris, 1, 1, 1);