/*
* 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
* 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
*/
/*
* Copyright 2009 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
/*
* Copyright 2016 Joyent, Inc.
* Copyright (c) 2013 by Delphix. All rights reserved.
*/
#ifndef _SYS_DTRACE_H
#define _SYS_DTRACE_H
#ifdef __cplusplus
extern "C" {
#endif
/*
* DTrace Dynamic Tracing Software: Kernel Interfaces
*
* Note: The contents of this file are private to the implementation of the
* Solaris system and DTrace subsystem and are subject to change at any time
* without notice. Applications and drivers using these interfaces will fail
* to run on future releases. These interfaces should not be used for any
* purpose except those expressly outlined in dtrace(7D) and libdtrace(3LIB).
* Please refer to the "Solaris Dynamic Tracing Guide" for more information.
*/
#ifndef _ASM
#include <sys/processor.h>
#include <sys/int_limits.h>
/*
* DTrace Universal Constants and Typedefs
*/
typedef enum dtrace_probespec {
/*
* DTrace Intermediate Format (DIF)
*
* The following definitions describe the DTrace Intermediate Format (DIF), a
* a RISC-like instruction set and program encoding used to represent
* predicates and actions that can be bound to DTrace probes. The constants
* below defining the number of available registers are suggested minimums; the
* compiler should use DTRACEIOC_CONF to dynamically obtain the number of
* registers provided by the current DTrace implementation.
*/
#define DIF_SUBR_RAND 0
/*
* A DTrace Intermediate Format Type (DIF Type) is used to represent the types
* of variables, function and associative array arguments, and the return type
* for each DIF object (shown below). It contains a description of the type,
* its size in bytes, and a module identifier.
*/
typedef struct dtrace_diftype {
/*
* A DTrace Intermediate Format variable record is used to describe each of the
* variables referenced by a given DIF object. It contains an integer variable
* identifier along with variable scope and properties, as shown below. The
* size of this structure must be sizeof (int) aligned.
*/
typedef struct dtrace_difv {
/*
* DTrace Actions
*
* The upper byte determines the class of the action; the low bytes determines
* the specific action within that class. The classes of actions are as
* follows:
*
* [ no class ] <= May record process- or kernel-related data
* DTRACEACT_PROC <= Only records process-related data
* DTRACEACT_PROC_DESTRUCTIVE <= Potentially destructive to processes
* DTRACEACT_KERNEL <= Only records kernel-related data
* DTRACEACT_KERNEL_DESTRUCTIVE <= Potentially destructive to the kernel
* DTRACEACT_SPECULATIVE <= Speculation-related action
* DTRACEACT_AGGREGATION <= Aggregating action
*/
#define DTRACEACT_ISDESTRUCTIVE(x) \
(DTRACEACT_CLASS(x) == DTRACEACT_PROC_DESTRUCTIVE || \
#define DTRACEACT_ISSPECULATIVE(x) \
(DTRACEACT_CLASS(x) == DTRACEACT_SPECULATIVE)
#define DTRACEACT_ISPRINTFLIKE(x) \
((x) == DTRACEACT_PRINTF || (x) == DTRACEACT_PRINTA || \
(x) == DTRACEACT_SYSTEM || (x) == DTRACEACT_FREOPEN)
/*
* DTrace Aggregating Actions
*
* These are functions f(x) for which the following is true:
*
* f(f(x_0) U f(x_1) U ... U f(x_n)) = f(x_0 U x_1 U ... U x_n)
*
* where x_n is a set of arbitrary data. Aggregating actions are in their own
* DTrace action class, DTTRACEACT_AGGREGATION. The macros provided here allow
* for easier processing of the aggregation argument and data payload for a few
* aggregating actions (notably: quantize(), lquantize(), and ustack()).
*/
#define DTRACEACT_ISAGG(x) \
(DTRACEACT_CLASS(x) == DTRACEACT_AGGREGATION)
#define DTRACE_QUANTIZE_NBUCKETS \
(buck) == DTRACE_QUANTIZE_ZEROBUCKET ? 0 : \
#define DTRACE_LQUANTIZE_BASESHIFT 0
#define DTRACE_LQUANTIZE_STEP(x) \
(uint16_t)(((x) & DTRACE_LQUANTIZE_STEPMASK) >> \
#define DTRACE_LQUANTIZE_LEVELS(x) \
(uint16_t)(((x) & DTRACE_LQUANTIZE_LEVELMASK) >> \
#define DTRACE_LQUANTIZE_BASE(x) \
(int32_t)(((x) & DTRACE_LQUANTIZE_BASEMASK) >> \
#define DTRACE_LLQUANTIZE_NSTEPSHIFT 0
#define DTRACE_LLQUANTIZE_FACTOR(x) \
(uint16_t)(((x) & DTRACE_LLQUANTIZE_FACTORMASK) >> \
#define DTRACE_LLQUANTIZE_LOW(x) \
(uint16_t)(((x) & DTRACE_LLQUANTIZE_LOWMASK) >> \
#define DTRACE_LLQUANTIZE_HIGH(x) \
(uint16_t)(((x) & DTRACE_LLQUANTIZE_HIGHMASK) >> \
#define DTRACE_LLQUANTIZE_NSTEP(x) \
(uint16_t)(((x) & DTRACE_LLQUANTIZE_NSTEPMASK) >> \
#define DTRACE_USTACK_ARG(x, y) \
#ifndef _LP64
#ifndef _LITTLE_ENDIAN
#else
#endif
#else
#endif
/*
* DTrace Object Format (DOF)
*
* DTrace programs can be persistently encoded in the DOF format so that they
* may be embedded in other programs (for example, in an ELF file) or in the
* dtrace driver configuration file for use in anonymous tracing. The DOF
* format is versioned and extensible so that it can be revised and so that
* internal data structures can be modified or extended compatibly. All DOF
* structures use fixed-size types, so the 32-bit and 64-bit representations
* are identical and consumers can use either data model transparently.
*
* The file layout is structured as follows:
*
* +---------------+-------------------+----- ... ----+---- ... ------+
* | dof_hdr_t | dof_sec_t[ ... ] | loadable | non-loadable |
* | (file header) | (section headers) | section data | section data |
* +---------------+-------------------+----- ... ----+---- ... ------+
* |<------------ dof_hdr.dofh_loadsz --------------->| |
* |<------------ dof_hdr.dofh_filesz ------------------------------->|
*
* The file header stores meta-data including a magic number, data model for
* the instrumentation, data encoding, and properties of the DIF code within.
* The header describes its own size and the size of the section headers. By
* convention, an array of section headers follows the file header, and then
* the data for all loadable sections and unloadable sections. This permits
* consumer code to easily download the headers and all loadable data into the
* DTrace driver in one contiguous chunk, omitting other extraneous sections.
*
* The section headers describe the size, offset, alignment, and section type
* for each section. Sections are described using a set of #defines that tell
* the consumer what kind of data is expected. Sections can contain links to
* other sections by storing a dof_secidx_t, an index into the section header
* array, inside of the section data structures. The section header includes
* an entry size so that sections with data arrays can grow their structures.
*
* The DOF data itself can contain many snippets of DIF (i.e. >1 DIFOs), which
* are represented themselves as a collection of related DOF sections. This
* permits us to change the set of sections associated with a DIFO over time,
* and also permits us to encode DIFOs that contain different sets of sections.
* When a DOF section wants to refer to a DIFO, it stores the dof_secidx_t of a
* section of type DOF_SECT_DIFOHDR. This section's data is then an array of
* dof_secidx_t's which in turn denote the sections associated with this DIFO.
*
* This loose coupling of the file structure (header and sections) to the
* structure of the DTrace program itself (ECB descriptions, action
* descriptions, and DIFOs) permits activities such as relocation processing
* to occur in a single pass without having to understand D program structure.
*
* Finally, strings are always stored in ELF-style string tables along with a
* string table section index and string table offset. Therefore strings in
* DOF are always arbitrary-length and not bound to the current implementation.
*/
typedef struct dof_hdr {
} dof_hdr_t;
#ifdef _LP64
#else
#endif
#ifdef _BIG_ENDIAN
#else
#endif
typedef struct dof_sec {
} dof_sec_t;
#define DOF_SEC_ISLOADABLE(x) \
(((x) == DOF_SECT_ECBDESC) || ((x) == DOF_SECT_PROBEDESC) || \
((x) == DOF_SECT_ACTDESC) || ((x) == DOF_SECT_DIFOHDR) || \
((x) == DOF_SECT_DIF) || ((x) == DOF_SECT_STRTAB) || \
((x) == DOF_SECT_VARTAB) || ((x) == DOF_SECT_RELTAB) || \
((x) == DOF_SECT_TYPTAB) || ((x) == DOF_SECT_URELHDR) || \
((x) == DOF_SECT_KRELHDR) || ((x) == DOF_SECT_OPTDESC) || \
((x) == DOF_SECT_PROVIDER) || ((x) == DOF_SECT_PROBES) || \
((x) == DOF_SECT_PRARGS) || ((x) == DOF_SECT_PROFFS) || \
((x) == DOF_SECT_INTTAB) || ((x) == DOF_SECT_XLTAB) || \
((x) == DOF_SECT_XLMEMBERS) || ((x) == DOF_SECT_XLIMPORT) || \
((x) == DOF_SECT_XLIMPORT) || ((x) == DOF_SECT_XLEXPORT) || \
((x) == DOF_SECT_PREXPORT) || ((x) == DOF_SECT_PRENOFFS))
typedef struct dof_ecbdesc {
typedef struct dof_probedesc {
typedef struct dof_actdesc {
typedef struct dof_difohdr {
typedef struct dof_relohdr {
typedef struct dof_relodesc {
typedef struct dof_optdesc {
typedef struct dof_provider {
typedef struct dof_probe {
} dof_probe_t;
typedef struct dof_xlator {
} dof_xlator_t;
typedef struct dof_xlmember {
typedef struct dof_xlref {
} dof_xlref_t;
/*
* DTrace Intermediate Format Object (DIFO)
*
* A DIFO is used to store the compiled DIF for a D expression, its return
* type, and its string and variable tables. The string table is a single
* buffer of character data into which sets instructions and variable
* references can reference strings using a byte offset. The variable table
* is an array of dtrace_difv_t structures that describe the name and type of
* each variable and the id used in the DIF code. This structure is described
* above in the DIF section of this header file. The DIFO is used at both
* user-level (in the library) and in the kernel, but the structure is never
* passed between the two: the DOF structures form the only interface. As a
* result, the definition can change depending on the presence of _KERNEL.
*/
typedef struct dtrace_difo {
#ifndef _KERNEL
#endif
/*
* DTrace Enabling Description Structures
*
* When DTrace is tracking the description of a DTrace enabling entity (probe,
* predicate, action, ECB, record, etc.), it does so in a description
* structure. These structures all end in "desc", and are used at both
* user-level and in the kernel -- but (with the exception of
* dtrace_probedesc_t) they are never passed between them. Typically,
* user-level will use the description structures when assembling an enabling.
* It will then distill those description structures into a DOF object (see
* above), and send it into the kernel. The kernel will again use the
* description structures to create a description of the enabling as it reads
* the DOF. When the description is complete, the enabling will be actually
* created -- turning it into the structures that represent the enabling
* instead of merely describing it. Not surprisingly, the description
* structures bear a strong resemblance to the DOF structures that act as their
* conduit.
*/
struct dtrace_predicate;
typedef struct dtrace_probedesc {
typedef struct dtrace_repldesc {
typedef struct dtrace_preddesc {
typedef struct dtrace_actdesc {
typedef struct dtrace_ecbdesc {
/*
* DTrace Metadata Description Structures
*
* DTrace separates the trace data stream from the metadata stream. The only
* metadata tokens placed in the data stream are the dtrace_rechdr_t (EPID +
* timestamp) or (in the case of aggregations) aggregation identifiers. To
* determine the structure of the data, DTrace consumers pass the token to the
* kernel, and receive in return a corresponding description of the enabled
* probe (via the dtrace_eprobedesc structure) or the aggregation (via the
* dtrace_aggdesc structure). Both of these structures are expressed in terms
* of record descriptions (via the dtrace_recdesc structure) that describe the
* exact structure of the data. Some record descriptions may also contain a
* format identifier; this additional bit of metadata can be retrieved from the
* kernel, for which a format description is returned via the dtrace_fmtdesc
* structure. Note that all four of these structures must be bitness-neutral
* to allow for a 32-bit DTrace consumer on a 64-bit kernel.
*/
typedef struct dtrace_recdesc {
typedef struct dtrace_eprobedesc {
typedef struct dtrace_aggdesc {
typedef struct dtrace_fmtdesc {
/*
* DTrace Option Interface
*
* Run-time DTrace options are set and retrieved via DOF_SECT_OPTDESC sections
* in a DOF image. The dof_optdesc structure contains an option identifier and
* an option value. The valid option identifiers are found below; the mapping
* between option identifiers and option identifying strings is maintained at
* user-level. Note that the value of DTRACEOPT_UNSET is such that all of the
* following are potentially valid option values: all positive integers, zero
* and negative one. Some options (notably "bufpolicy" and "bufresize") take
* predefined tokens as their values; these are defined with
* DTRACEOPT_{option}_{token}.
*/
/*
* DTrace Buffer Interface
*
* In order to get a snapshot of the principal or aggregation buffer,
* user-level passes a buffer description to the kernel with the dtrace_bufdesc
* structure. This describes which CPU user-level is interested in, and
* where user-level wishes the kernel to snapshot the buffer to (the
* dtbd_data field). The kernel uses the same structure to pass back some
* information regarding the buffer: the size of data actually copied out, the
* number of drops, the number of errors, the offset of the oldest record,
* and the time of the snapshot.
*
* If the buffer policy is a "switch" policy, taking a snapshot of the
* principal buffer has the additional effect of switching the active and
* inactive buffers. Taking a snapshot of the aggregation buffer _always_ has
* the additional effect of switching the active and inactive buffers.
*/
typedef struct dtrace_bufdesc {
/*
* Each record in the buffer (dtbd_data) begins with a header that includes
* the epid and a timestamp. The timestamp is split into two 4-byte parts
* so that we do not require 8-byte alignment.
*/
typedef struct dtrace_rechdr {
((dtrh)->dtrh_timestamp_lo + \
}
/*
* DTrace Status
*
* The status of DTrace is relayed via the dtrace_status structure. This
* structure contains members to count drops other than the capacity drops
* available via the buffer interface (see above). This consists of dynamic
* drops (including capacity dynamic drops, rinsing drops and dirty drops), and
* speculative drops (including capacity speculative drops, drops due to busy
* speculative buffers and drops due to unavailable speculative buffers).
* Additionally, the status structure contains a field to indicate the number
* of "fill"-policy buffers have been filled and a boolean field to indicate
* that exit() has been called. If the dtst_exiting field is non-zero, no
* further data will be generated until tracing is stopped (at which time any
* enablings of the END action will be processed); if user-level sees that
* this field is non-zero, tracing should be stopped as soon as possible.
*/
typedef struct dtrace_status {
/*
* DTrace Configuration
*
* User-level may need to understand some elements of the kernel DTrace
* configuration in order to generate correct DIF. This information is
* conveyed via the dtrace_conf structure.
*/
typedef struct dtrace_conf {
/*
* DTrace Faults
*
* The constants below DTRACEFLT_LIBRARY indicate probe processing faults;
* constants at or above DTRACEFLT_LIBRARY indicate faults in probe
* postprocessing at user-level. Probe processing faults induce an ERROR
* probe and are replicated in unistd.d to allow users' ERROR probes to decode
* the error condition using thse symbolic labels.
*/
/*
* DTrace Argument Types
*
* Because it would waste both space and time, argument types do not reside
* with the probe. In order to determine argument types for args[X]
* variables, the D compiler queries for argument types on a probe-by-probe
* basis. (This optimizes for the common case that arguments are either not
* used or used in an untyped fashion.) Typed arguments are specified with a
* string of the type name in the dtragd_native member of the argument
* description structure. Typed arguments may be further translated to types
* of greater stability; the provider indicates such a translated argument by
* filling in the dtargd_xlate member with the string of the translated type.
* Finally, the provider may indicate which argument value a given argument
* maps to by setting the dtargd_mapping member -- allowing a single argument
* to map to multiple args[X] variables.
*/
typedef struct dtrace_argdesc {
/*
* DTrace Stability Attributes
*
* Each DTrace provider advertises the name and data stability of each of its
* probe description components, as well as its architectural dependencies.
* The D compiler can query the provider attributes (dtrace_pattr_t below) in
* order to compute the properties of an input program and report them.
*/
#define DTRACE_PRIV_ALL \
typedef struct dtrace_ppriv {
typedef struct dtrace_attribute {
typedef struct dtrace_pattr {
typedef struct dtrace_providerdesc {
/*
* DTrace Pseudodevice Interface
*
* DTrace is controlled through ioctl(2)'s to the in-kernel dtrace:dtrace
* pseudodevice driver. These ioctls comprise the user-kernel interface to
* DTrace.
*/
/*
* DTrace Helpers
*
* In general, DTrace establishes probes in processes and takes actions on
* processes without knowing their specific user-level structures. Instead of
* existing in the framework, process-specific knowledge is contained by the
* enabling D program -- which can apply process-specific knowledge by making
* appropriate use of DTrace primitives like copyin() and copyinstr() to
* operate on user-level data. However, there may exist some specific probes
* of particular semantic relevance that the application developer may wish to
* explicitly export. For example, an application may wish to export a probe
* at the point that it begins and ends certain well-defined transactions. In
* addition to providing probes, programs may wish to offer assistance for
* certain actions. For example, in highly dynamic environments (e.g., Java),
* it may be difficult to obtain a stack trace in terms of meaningful symbol
* names (the translation from instruction addresses to corresponding symbol
* names may only be possible in situ); these environments may wish to define
* a series of actions to be applied in situ to obtain a meaningful stack
* trace.
*
* These two mechanisms -- user-level statically defined tracing and assisting
* DTrace actions -- are provided via DTrace _helpers_. Helpers are specified
* via DOF, but unlike enabling DOF, helper DOF may contain definitions of
* providers, probes and their arguments. If a helper wishes to provide
* action assistance, probe descriptions and corresponding DIF actions may be
* specified in the helper DOF. For such helper actions, however, the probe
* description describes the specific helper: all DTrace helpers have the
* provider name "dtrace" and the module name "helper", and the name of the
* helper is contained in the function name (for example, the ustack() helper
* is named "ustack"). Any helper-specific name may be contained in the name
* (for example, if a helper were to have a constructor, it might be named
* "dtrace:helper:<helper>:init"). Helper actions are only called when the
* action that they are helping is taken. Helper actions may only return DIF
* expressions, and may only call the following subroutines:
*
* alloca() <= Allocates memory out of the consumer's scratch space
* bcopy() <= Copies memory to scratch space
* copyin() <= Copies memory from user-level into consumer's scratch
* copyinto() <= Copies memory into a specific location in scratch
* copyinstr() <= Copies a string into a specific location in scratch
*
* Helper actions may only access the following built-in variables:
*
* curthread <= Current kthread_t pointer
* tid <= Current thread identifier
* pid <= Current process identifier
* ppid <= Parent process identifier
* uid <= Current user ID
* gid <= Current group ID
* execname <= Current executable name
* zonename <= Current zone name
*
* Helper actions may not manipulate or allocate dynamic variables, but they
* may have clause-local and statically-allocated global variables. The
* helper action variable state is specific to the helper action -- variables
* used by the helper action may not be accessed outside of the helper
* action, and the helper action may not access variables that like outside
* of it. Helper actions may not load from kernel memory at-large; they are
* restricting to loading current user state (via copyin() and variants) and
* scratch space. As with probe enablings, helper actions are executed in
* program order. The result of the helper action is the result of the last
* executing helper expression.
*
* -- are added by opening the "helper" minor node, and issuing an ioctl(2)
* (DTRACEHIOC_ADDDOF) that specifies the dof_helper_t structure. This
* encapsulates the name and base address of the user-level library or
* executable publishing the helpers and probes as well as the DOF that
* contains the definitions of those helpers and probes.
*
* The DTRACEHIOC_ADD and DTRACEHIOC_REMOVE are left in place for legacy
* helpers and should no longer be used. No other ioctls are valid on the
* helper minor node.
*/
typedef struct dof_helper {
} dof_helper_t;
#ifdef _KERNEL
/*
* DTrace Provider API
*
* The following functions are implemented by the DTrace framework and are
* used to implement separate in-kernel DTrace providers. Common functions
* defined in uts/<isa>/dtrace/dtrace_asm.s or uts/<isa>/dtrace/dtrace_isa.c.
*
* The provider API has two halves: the API that the providers consume from
* DTrace, and the API that providers make available to DTrace.
*
* 1 Framework-to-Provider API
*
* 1.1 Overview
*
* The Framework-to-Provider API is represented by the dtrace_pops structure
* that the provider passes to the framework when registering itself. This
* structure consists of the following members:
*
* dtps_provide() <-- Provide all probes, all modules
* dtps_provide_module() <-- Provide all probes in specified module
* dtps_enable() <-- Enable specified probe
* dtps_disable() <-- Disable specified probe
* dtps_suspend() <-- Suspend specified probe
* dtps_resume() <-- Resume specified probe
* dtps_getargdesc() <-- Get the argument description for args[X]
* dtps_getargval() <-- Get the value for an argX or args[X] variable
* dtps_mode() <-- Return the mode of the fired probe
* dtps_destroy() <-- Destroy all state associated with this probe
*
* 1.2 void dtps_provide(void *arg, const dtrace_probedesc_t *spec)
*
* 1.2.1 Overview
*
* Called to indicate that the provider should provide all probes. If the
* specified description is non-NULL, dtps_provide() is being called because
* no probe matched a specified probe -- if the provider has the ability to
* create custom probes, it may wish to create a probe that matches the
* specified description.
*
* 1.2.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is a pointer to a probe description that the provider may
* wish to consider when creating custom probes. The provider is expected to
* call back into the DTrace framework via dtrace_probe_create() to create
* any necessary probes. dtps_provide() may be called even if the provider
* has made available all probes; the provider should check the return value
* of dtrace_probe_create() to handle this case. Note that the provider need
* not implement both dtps_provide() and dtps_provide_module(); see
* "Arguments and Notes" for dtrace_register(), below.
*
* 1.2.3 Return value
*
* None.
*
* 1.2.4 Caller's context
*
* dtps_provide() is typically called from open() or ioctl() context, but may
* be called from other contexts as well. The DTrace framework is locked in
* such a way that providers may not register or unregister. This means that
* the provider may not call any DTrace API that affects its registration with
* the framework, including dtrace_register(), dtrace_unregister(),
* dtrace_invalidate(), and dtrace_condense(). However, the context is such
* that the provider may (and indeed, is expected to) call probe-related
* DTrace routines, including dtrace_probe_create(), dtrace_probe_lookup(),
* and dtrace_probe_arg().
*
* 1.3 void dtps_provide_module(void *arg, struct modctl *mp)
*
* 1.3.1 Overview
*
* Called to indicate that the provider should provide all probes in the
* specified module.
*
* 1.3.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is a pointer to a modctl structure that indicates the
* module for which probes should be created.
*
* 1.3.3 Return value
*
* None.
*
* 1.3.4 Caller's context
*
* dtps_provide_module() may be called from open() or ioctl() context, but
* may also be called from a module loading context. mod_lock is held, and
* the DTrace framework is locked in such a way that providers may not
* register or unregister. This means that the provider may not call any
* DTrace API that affects its registration with the framework, including
* dtrace_register(), dtrace_unregister(), dtrace_invalidate(), and
* dtrace_condense(). However, the context is such that the provider may (and
* indeed, is expected to) call probe-related DTrace routines, including
* dtrace_probe_create(), dtrace_probe_lookup(), and dtrace_probe_arg(). Note
* that the provider need not implement both dtps_provide() and
* dtps_provide_module(); see "Arguments and Notes" for dtrace_register(),
* below.
*
* 1.4 int dtps_enable(void *arg, dtrace_id_t id, void *parg)
*
* 1.4.1 Overview
*
* Called to enable the specified probe.
*
* 1.4.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is the identifier of the probe to be enabled. The third
* argument is the probe argument as passed to dtrace_probe_create().
* dtps_enable() will be called when a probe transitions from not being
* enabled at all to having one or more ECB. The number of ECBs associated
* with the probe may change without subsequent calls into the provider.
* When the number of ECBs drops to zero, the provider will be explicitly
* told to disable the probe via dtps_disable(). dtrace_probe() should never
* be called for a probe identifier that hasn't been explicitly enabled via
* dtps_enable().
*
* 1.4.3 Return value
*
* On success, dtps_enable() should return 0. On failure, -1 should be
* returned.
*
* 1.4.4 Caller's context
*
* The DTrace framework is locked in such a way that it may not be called
* back into at all. cpu_lock is held. mod_lock is not held and may not
* be acquired.
*
* 1.5 void dtps_disable(void *arg, dtrace_id_t id, void *parg)
*
* 1.5.1 Overview
*
* Called to disable the specified probe.
*
* 1.5.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is the identifier of the probe to be disabled. The third
* argument is the probe argument as passed to dtrace_probe_create().
* dtps_disable() will be called when a probe transitions from being enabled
* to having zero ECBs. dtrace_probe() should never be called for a probe
* identifier that has been explicitly enabled via dtps_disable().
*
* 1.5.3 Return value
*
* None.
*
* 1.5.4 Caller's context
*
* The DTrace framework is locked in such a way that it may not be called
* back into at all. cpu_lock is held. mod_lock is not held and may not
* be acquired.
*
* 1.6 void dtps_suspend(void *arg, dtrace_id_t id, void *parg)
*
* 1.6.1 Overview
*
* Called to suspend the specified enabled probe. This entry point is for
* providers that may need to suspend some or all of their probes when CPUs
* are being powered on or when the boot monitor is being entered for a
* prolonged period of time.
*
* 1.6.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is the identifier of the probe to be suspended. The
* third argument is the probe argument as passed to dtrace_probe_create().
* dtps_suspend will only be called on an enabled probe. Providers that
* provide a dtps_suspend entry point will want to take roughly the action
* that it takes for dtps_disable.
*
* 1.6.3 Return value
*
* None.
*
* 1.6.4 Caller's context
*
* Interrupts are disabled. The DTrace framework is in a state such that the
* specified probe cannot be disabled or destroyed for the duration of
* dtps_suspend(). As interrupts are disabled, the provider is afforded
* little latitude; the provider is expected to do no more than a store to
* memory.
*
* 1.7 void dtps_resume(void *arg, dtrace_id_t id, void *parg)
*
* 1.7.1 Overview
*
* Called to resume the specified enabled probe. This entry point is for
* providers that may need to resume some or all of their probes after the
* completion of an event that induced a call to dtps_suspend().
*
* 1.7.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is the identifier of the probe to be resumed. The
* third argument is the probe argument as passed to dtrace_probe_create().
* dtps_resume will only be called on an enabled probe. Providers that
* provide a dtps_resume entry point will want to take roughly the action
* that it takes for dtps_enable.
*
* 1.7.3 Return value
*
* None.
*
* 1.7.4 Caller's context
*
* Interrupts are disabled. The DTrace framework is in a state such that the
* specified probe cannot be disabled or destroyed for the duration of
* dtps_resume(). As interrupts are disabled, the provider is afforded
* little latitude; the provider is expected to do no more than a store to
* memory.
*
* 1.8 void dtps_getargdesc(void *arg, dtrace_id_t id, void *parg,
* dtrace_argdesc_t *desc)
*
* 1.8.1 Overview
*
* Called to retrieve the argument description for an args[X] variable.
*
* 1.8.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is the identifier of the current probe. The third
* argument is the probe argument as passed to dtrace_probe_create(). The
* fourth argument is a pointer to the argument description. This
* description is both an input and output parameter: it contains the
* index of the desired argument in the dtargd_ndx field, and expects
* the other fields to be filled in upon return. If there is no argument
* corresponding to the specified index, the dtargd_ndx field should be set
* to DTRACE_ARGNONE.
*
* 1.8.3 Return value
*
* None. The dtargd_ndx, dtargd_native, dtargd_xlate and dtargd_mapping
* members of the dtrace_argdesc_t structure are all output values.
*
* 1.8.4 Caller's context
*
* dtps_getargdesc() is called from ioctl() context. mod_lock is held, and
* the DTrace framework is locked in such a way that providers may not
* register or unregister. This means that the provider may not call any
* DTrace API that affects its registration with the framework, including
* dtrace_register(), dtrace_unregister(), dtrace_invalidate(), and
* dtrace_condense().
*
* 1.9 uint64_t dtps_getargval(void *arg, dtrace_id_t id, void *parg,
* int argno, int aframes)
*
* 1.9.1 Overview
*
* Called to retrieve a value for an argX or args[X] variable.
*
* 1.9.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is the identifier of the current probe. The third
* argument is the probe argument as passed to dtrace_probe_create(). The
* fourth argument is the number of the argument (the X in the example in
* 1.9.1). The fifth argument is the number of stack frames that were used
* to get from the actual place in the code that fired the probe to
* dtrace_probe() itself, the so-called artificial frames. This argument may
* be used to descend an appropriate number of frames to find the correct
* values. If this entry point is left NULL, the dtrace_getarg() built-in
* function is used.
*
* 1.9.3 Return value
*
* The value of the argument.
*
* 1.9.4 Caller's context
*
* This is called from within dtrace_probe() meaning that interrupts
* are disabled. No locks should be taken within this entry point.
*
* 1.10 int dtps_mode(void *arg, dtrace_id_t id, void *parg)
*
* 1.10.1 Overview
*
* Called to determine the mode of a fired probe.
*
* 1.10.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is the identifier of the current probe. The third
* argument is the probe argument as passed to dtrace_probe_create(). This
* entry point must not be left NULL for providers whose probes allow for
* mixed mode tracing, that is to say those unanchored probes that can fire
* during kernel- or user-mode execution.
*
* 1.10.3 Return value
*
* A bitwise OR that encapsulates both the mode (either DTRACE_MODE_KERNEL
* or DTRACE_MODE_USER) and the policy when the privilege of the enabling
* is insufficient for that mode (a combination of DTRACE_MODE_NOPRIV_DROP,
* DTRACE_MODE_NOPRIV_RESTRICT, and DTRACE_MODE_LIMITEDPRIV_RESTRICT). If
* DTRACE_MODE_NOPRIV_DROP bit is set, insufficient privilege will result
* in the probe firing being silently ignored for the enabling; if the
* DTRACE_NODE_NOPRIV_RESTRICT bit is set, insufficient privilege will not
* prevent probe processing for the enabling, but restrictions will be in
* place that induce a UPRIV fault upon attempt to examine probe arguments
* or current process state. If the DTRACE_MODE_LIMITEDPRIV_RESTRICT bit
* is set, similar restrictions will be placed upon operation if the
* privilege is sufficient to process the enabling, but does not otherwise
* entitle the enabling to all zones. The DTRACE_MODE_NOPRIV_DROP and
* DTRACE_MODE_NOPRIV_RESTRICT are mutually exclusive (and one of these
* two policies must be specified), but either may be combined (or not)
* with DTRACE_MODE_LIMITEDPRIV_RESTRICT.
*
* 1.10.4 Caller's context
*
* This is called from within dtrace_probe() meaning that interrupts
* are disabled. No locks should be taken within this entry point.
*
* 1.11 void dtps_destroy(void *arg, dtrace_id_t id, void *parg)
*
* 1.11.1 Overview
*
* Called to destroy the specified probe.
*
* 1.11.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_register(). The
* second argument is the identifier of the probe to be destroyed. The third
* argument is the probe argument as passed to dtrace_probe_create(). The
* provider should free all state associated with the probe. The framework
* guarantees that dtps_destroy() is only called for probes that have either
* been disabled via dtps_disable() or were never enabled via dtps_enable().
* Once dtps_disable() has been called for a probe, no further call will be
* made specifying the probe.
*
* 1.11.3 Return value
*
* None.
*
* 1.11.4 Caller's context
*
* The DTrace framework is locked in such a way that it may not be called
* back into at all. mod_lock is held. cpu_lock is not held, and may not be
* acquired.
*
*
* 2 Provider-to-Framework API
*
* 2.1 Overview
*
* The Provider-to-Framework API provides the mechanism for the provider to
* register itself with the DTrace framework, to create probes, to lookup
* probes and (most importantly) to fire probes. The Provider-to-Framework
* consists of:
*
* dtrace_register() <-- Register a provider with the DTrace framework
* dtrace_unregister() <-- Remove a provider's DTrace registration
* dtrace_invalidate() <-- Invalidate the specified provider
* dtrace_condense() <-- Remove a provider's unenabled probes
* dtrace_attached() <-- Indicates whether or not DTrace has attached
* dtrace_probe_create() <-- Create a DTrace probe
* dtrace_probe_lookup() <-- Lookup a DTrace probe based on its name
* dtrace_probe_arg() <-- Return the probe argument for a specific probe
* dtrace_probe() <-- Fire the specified probe
*
* 2.2 int dtrace_register(const char *name, const dtrace_pattr_t *pap,
* uint32_t priv, cred_t *cr, const dtrace_pops_t *pops, void *arg,
* dtrace_provider_id_t *idp)
*
* 2.2.1 Overview
*
* dtrace_register() registers the calling provider with the DTrace
* framework. It should generally be called by DTrace providers in their
* attach(9E) entry point.
*
* 2.2.2 Arguments and Notes
*
* The first argument is the name of the provider. The second argument is a
* pointer to the stability attributes for the provider. The third argument
* is the privilege flags for the provider, and must be some combination of:
*
* DTRACE_PRIV_NONE <= All users may enable probes from this provider
*
* DTRACE_PRIV_PROC <= Any user with privilege of PRIV_DTRACE_PROC may
* enable probes from this provider
*
* DTRACE_PRIV_USER <= Any user with privilege of PRIV_DTRACE_USER may
* enable probes from this provider
*
* DTRACE_PRIV_KERNEL <= Any user with privilege of PRIV_DTRACE_KERNEL
* may enable probes from this provider
*
* DTRACE_PRIV_OWNER <= This flag places an additional constraint on
* the privilege requirements above. These probes
* require either (a) a user ID matching the user
* ID of the cred passed in the fourth argument
* or (b) the PRIV_PROC_OWNER privilege.
*
* DTRACE_PRIV_ZONEOWNER<= This flag places an additional constraint on
* the privilege requirements above. These probes
* require either (a) a zone ID matching the zone
* ID of the cred passed in the fourth argument
* or (b) the PRIV_PROC_ZONE privilege.
*
* Note that these flags designate the _visibility_ of the probes, not
* the conditions under which they may or may not fire.
*
* The fourth argument is the credential that is associated with the
* provider. This argument should be NULL if the privilege flags don't
* include DTRACE_PRIV_OWNER or DTRACE_PRIV_ZONEOWNER. If non-NULL, the
* framework stashes the uid and zoneid represented by this credential
* for use at probe-time, in implicit predicates. These limit visibility
* access them.
*
* The fifth argument is a DTrace provider operations vector, which provides
* the implementation for the Framework-to-Provider API. (See Section 1,
* above.) This must be non-NULL, and each member must be non-NULL. The
* exceptions to this are (1) the dtps_provide() and dtps_provide_module()
* members (if the provider so desires, _one_ of these members may be left
* NULL -- denoting that the provider only implements the other) and (2)
* the dtps_suspend() and dtps_resume() members, which must either both be
* NULL or both be non-NULL.
*
* The sixth argument is a cookie to be specified as the first argument for
* each function in the Framework-to-Provider API. This argument may have
* any value.
*
* The final argument is a pointer to dtrace_provider_id_t. If
* dtrace_register() successfully completes, the provider identifier will be
* stored in the memory pointed to be this argument. This argument must be
* non-NULL.
*
* 2.2.3 Return value
*
* On success, dtrace_register() returns 0 and stores the new provider's
* identifier into the memory pointed to by the idp argument. On failure,
* dtrace_register() returns an errno:
*
* EINVAL The arguments passed to dtrace_register() were somehow invalid.
* This may because a parameter that must be non-NULL was NULL,
* because the name was invalid (either empty or an illegal
* provider name) or because the attributes were invalid.
*
* No other failure code is returned.
*
* 2.2.4 Caller's context
*
* dtrace_register() may induce calls to dtrace_provide(); the provider must
* hold no locks across dtrace_register() that may also be acquired by
* dtrace_provide(). cpu_lock and mod_lock must not be held.
*
* 2.3 int dtrace_unregister(dtrace_provider_t id)
*
* 2.3.1 Overview
*
* Unregisters the specified provider from the DTrace framework. It should
* generally be called by DTrace providers in their detach(9E) entry point.
*
* 2.3.2 Arguments and Notes
*
* The only argument is the provider identifier, as returned from a
* successful call to dtrace_register(). As a result of calling
* dtrace_unregister(), the DTrace framework will call back into the provider
* via the dtps_destroy() entry point. Once dtrace_unregister() successfully
* completes, however, the DTrace framework will no longer make calls through
* the Framework-to-Provider API.
*
* 2.3.3 Return value
*
* On success, dtrace_unregister returns 0. On failure, dtrace_unregister()
* returns an errno:
*
* EBUSY There are currently processes that have the DTrace pseudodevice
* open, or there exists an anonymous enabling that hasn't yet
* been claimed.
*
* No other failure code is returned.
*
* 2.3.4 Caller's context
*
* Because a call to dtrace_unregister() may induce calls through the
* Framework-to-Provider API, the caller may not hold any lock across
* dtrace_register() that is also acquired in any of the Framework-to-
* Provider API functions. Additionally, mod_lock may not be held.
*
* 2.4 void dtrace_invalidate(dtrace_provider_id_t id)
*
* 2.4.1 Overview
*
* Invalidates the specified provider. All subsequent probe lookups for the
* specified provider will fail, but its probes will not be removed.
*
* 2.4.2 Arguments and note
*
* The only argument is the provider identifier, as returned from a
* successful call to dtrace_register(). In general, a provider's probes
* always remain valid; dtrace_invalidate() is a mechanism for invalidating
* an entire provider, regardless of whether or not probes are enabled or
* not. Note that dtrace_invalidate() will _not_ prevent already enabled
* probes from firing -- it will merely prevent any new enablings of the
* provider's probes.
*
* 2.5 int dtrace_condense(dtrace_provider_id_t id)
*
* 2.5.1 Overview
*
* Removes all the unenabled probes for the given provider. This function is
* not unlike dtrace_unregister(), except that it doesn't remove the
* provider just as many of its associated probes as it can.
*
* 2.5.2 Arguments and Notes
*
* As with dtrace_unregister(), the sole argument is the provider identifier
* as returned from a successful call to dtrace_register(). As a result of
* calling dtrace_condense(), the DTrace framework will call back into the
* given provider's dtps_destroy() entry point for each of the provider's
* unenabled probes.
*
* 2.5.3 Return value
*
* Currently, dtrace_condense() always returns 0. However, consumers of this
* function should check the return value as appropriate; its behavior may
* change in the future.
*
* 2.5.4 Caller's context
*
* As with dtrace_unregister(), the caller may not hold any lock across
* dtrace_condense() that is also acquired in the provider's entry points.
* Also, mod_lock may not be held.
*
* 2.6 int dtrace_attached()
*
* 2.6.1 Overview
*
* Indicates whether or not DTrace has attached.
*
* 2.6.2 Arguments and Notes
*
* For most providers, DTrace makes initial contact beyond registration.
* That is, once a provider has registered with DTrace, it waits to hear
* from DTrace to create probes. However, some providers may wish to
* proactively create probes without first being told by DTrace to do so.
* If providers wish to do this, they must first call dtrace_attached() to
* determine if DTrace itself has attached. If dtrace_attached() returns 0,
* the provider must not make any other Provider-to-Framework API call.
*
* 2.6.3 Return value
*
* dtrace_attached() returns 1 if DTrace has attached, 0 otherwise.
*
* 2.7 int dtrace_probe_create(dtrace_provider_t id, const char *mod,
* const char *func, const char *name, int aframes, void *arg)
*
* 2.7.1 Overview
*
* Creates a probe with specified module name, function name, and name.
*
* 2.7.2 Arguments and Notes
*
* The first argument is the provider identifier, as returned from a
* successful call to dtrace_register(). The second, third, and fourth
* arguments are the module name, function name, and probe name,
* respectively. Of these, module name and function name may both be NULL
* (in which case the probe is considered to be unanchored), or they may both
* be non-NULL. The name must be non-NULL, and must point to a non-empty
* string.
*
* The fifth argument is the number of artificial stack frames that will be
* found on the stack when dtrace_probe() is called for the new probe. These
* artificial frames will be automatically be pruned should the stack() or
* stackdepth() functions be called as part of one of the probe's ECBs. If
* the parameter doesn't add an artificial frame, this parameter should be
* zero.
*
* The final argument is a probe argument that will be passed back to the
* provider when a probe-specific operation is called. (e.g., via
* dtps_enable(), dtps_disable(), etc.)
*
* Note that it is up to the provider to be sure that the probe that it
* creates does not already exist -- if the provider is unsure of the probe's
* existence, it should assure its absence with dtrace_probe_lookup() before
* calling dtrace_probe_create().
*
* 2.7.3 Return value
*
* dtrace_probe_create() always succeeds, and always returns the identifier
* of the newly-created probe.
*
* 2.7.4 Caller's context
*
* While dtrace_probe_create() is generally expected to be called from
* non-DTrace contexts. Neither cpu_lock nor mod_lock may be held.
*
* 2.8 dtrace_id_t dtrace_probe_lookup(dtrace_provider_t id, const char *mod,
* const char *func, const char *name)
*
* 2.8.1 Overview
*
* Looks up a probe based on provdider and one or more of module name,
* function name and probe name.
*
* 2.8.2 Arguments and Notes
*
* The first argument is the provider identifier, as returned from a
* successful call to dtrace_register(). The second, third, and fourth
* arguments are the module name, function name, and probe name,
* respectively. Any of these may be NULL; dtrace_probe_lookup() will return
* the identifier of the first probe that is provided by the specified
* provider and matches all of the non-NULL matching criteria.
* dtrace_probe_lookup() is generally used by a provider to be check the
* existence of a probe before creating it with dtrace_probe_create().
*
* 2.8.3 Return value
*
* If the probe exists, returns its identifier. If the probe does not exist,
* return DTRACE_IDNONE.
*
* 2.8.4 Caller's context
*
* While dtrace_probe_lookup() is generally expected to be called from
* other non-DTrace contexts. Neither cpu_lock nor mod_lock may be held.
*
* 2.9 void *dtrace_probe_arg(dtrace_provider_t id, dtrace_id_t probe)
*
* 2.9.1 Overview
*
* Returns the probe argument associated with the specified probe.
*
* 2.9.2 Arguments and Notes
*
* The first argument is the provider identifier, as returned from a
* successful call to dtrace_register(). The second argument is a probe
* identifier, as returned from dtrace_probe_lookup() or
* dtrace_probe_create(). This is useful if a probe has multiple
* provider-specific components to it: the provider can create the probe
* once with provider-specific state, and then add to the state by looking
* up the probe based on probe identifier.
*
* 2.9.3 Return value
*
* Returns the argument associated with the specified probe. If the
* specified probe does not exist, or if the specified probe is not provided
* by the specified provider, NULL is returned.
*
* 2.9.4 Caller's context
*
* While dtrace_probe_arg() is generally expected to be called from
* other non-DTrace contexts. Neither cpu_lock nor mod_lock may be held.
*
* 2.10 void dtrace_probe(dtrace_id_t probe, uintptr_t arg0, uintptr_t arg1,
* uintptr_t arg2, uintptr_t arg3, uintptr_t arg4)
*
* 2.10.1 Overview
*
* The epicenter of DTrace: fires the specified probes with the specified
* arguments.
*
* 2.10.2 Arguments and Notes
*
* The first argument is a probe identifier as returned by
* dtrace_probe_create() or dtrace_probe_lookup(). The second through sixth
* arguments are the values to which the D variables "arg0" through "arg4"
* will be mapped.
*
* dtrace_probe() should be called whenever the specified probe has fired --
* however the provider defines it.
*
* 2.10.3 Return value
*
* None.
*
* 2.10.4 Caller's context
*
* dtrace_probe() may be called in virtually any context: kernel, user,
* interrupt, high-level interrupt, with arbitrary adaptive locks held, with
* dispatcher locks held, with interrupts disabled, etc. The only latitude
* that must be afforded to DTrace is the ability to make calls within
* itself (and to its in-kernel subroutines) and the ability to access
* arbitrary (but mapped) memory. On some platforms, this constrains
* context. For example, on UltraSPARC, dtrace_probe() cannot be called
* from any context in which TL is greater than zero. dtrace_probe() may
* also not be called from any routine which may be called by dtrace_probe()
* -- which includes functions in the DTrace framework and some in-kernel
* DTrace subroutines. All such functions "dtrace_"; providers that
* instrument the kernel arbitrarily should be sure to not instrument these
* routines.
*/
typedef struct dtrace_pops {
extern int dtrace_unregister(dtrace_provider_id_t);
extern int dtrace_condense(dtrace_provider_id_t);
extern void dtrace_invalidate(dtrace_provider_id_t);
const char *, const char *);
const char *, const char *, int, void *);
/*
* DTrace Meta Provider API
*
* The following functions are implemented by the DTrace framework and are
* used to implement meta providers. Meta providers plug into the DTrace
* framework and are used to instantiate new providers on the fly. At
* present, there is only one type of meta provider and only one meta
* provider may be registered with the DTrace framework at a time. The
* sole meta provider type provides user-land static tracing facilities
* by taking meta probe descriptions and adding a corresponding provider
* into the DTrace framework.
*
* 1 Framework-to-Provider
*
* 1.1 Overview
*
* The Framework-to-Provider API is represented by the dtrace_mops structure
* that the meta provider passes to the framework when registering itself as
* a meta provider. This structure consists of the following members:
*
* dtms_create_probe() <-- Add a new probe to a created provider
* dtms_provide_pid() <-- Create a new provider for a given process
* dtms_remove_pid() <-- Remove a previously created provider
*
* 1.2 void dtms_create_probe(void *arg, void *parg,
* dtrace_helper_probedesc_t *probedesc);
*
* 1.2.1 Overview
*
* Called by the DTrace framework to create a new probe in a provider
* created by this meta provider.
*
* 1.2.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_meta_register().
* The second argument is the provider cookie for the associated provider;
* this is obtained from the return value of dtms_provide_pid(). The third
* argument is the helper probe description.
*
* 1.2.3 Return value
*
* None
*
* 1.2.4 Caller's context
*
* dtms_create_probe() is called from either ioctl() or module load context
* in the context of a newly-created provider (that is, a provider that
* is a result of a call to dtms_provide_pid()). The DTrace framework is
* locked in such a way that meta providers may not register or unregister,
* such that no other thread can call into a meta provider operation and that
* atomicity is assured with respect to meta provider operations across
* dtms_provide_pid() and subsequent calls to dtms_create_probe().
* The context is thus effectively single-threaded with respect to the meta
* provider, and that the meta provider cannot call dtrace_meta_register()
* or dtrace_meta_unregister(). However, the context is such that the
* provider may (and is expected to) call provider-related DTrace provider
* APIs including dtrace_probe_create().
*
* 1.3 void *dtms_provide_pid(void *arg, dtrace_meta_provider_t *mprov,
* pid_t pid)
*
* 1.3.1 Overview
*
* Called by the DTrace framework to instantiate a new provider given the
* description of the provider and probes in the mprov argument. The
* meta provider should call dtrace_register() to insert the new provider
* into the DTrace framework.
*
* 1.3.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_meta_register().
* The second argument is a pointer to a structure describing the new
* helper provider. The third argument is the process identifier for
* process associated with this new provider. Note that the name of the
* provider as passed to dtrace_register() should be the contatenation of
* the dtmpb_provname member of the mprov argument and the processs
* identifier as a string.
*
* 1.3.3 Return value
*
* The cookie for the provider that the meta provider creates. This is
* the same value that it passed to dtrace_register().
*
* 1.3.4 Caller's context
*
* dtms_provide_pid() is called from either ioctl() or module load context.
* The DTrace framework is locked in such a way that meta providers may not
* register or unregister. This means that the meta provider cannot call
* dtrace_meta_register() or dtrace_meta_unregister(). However, the context
* is such that the provider may -- and is expected to -- call
* provider-related DTrace provider APIs including dtrace_register().
*
* 1.4 void dtms_remove_pid(void *arg, dtrace_meta_provider_t *mprov,
* pid_t pid)
*
* 1.4.1 Overview
*
* Called by the DTrace framework to remove a provider that had previously
* been instantiated via the dtms_provide_pid() entry point. The meta
* provider need not remove the provider immediately, but this entry
* point indicates that the provider should be removed as soon as possible
* using the dtrace_unregister() API.
*
* 1.4.2 Arguments and notes
*
* The first argument is the cookie as passed to dtrace_meta_register().
* The second argument is a pointer to a structure describing the helper
* provider. The third argument is the process identifier for process
* associated with this new provider.
*
* 1.4.3 Return value
*
* None
*
* 1.4.4 Caller's context
*
* dtms_remove_pid() is called from either ioctl() or exit() context.
* The DTrace framework is locked in such a way that meta providers may not
* register or unregister. This means that the meta provider cannot call
* dtrace_meta_register() or dtrace_meta_unregister(). However, the context
* is such that the provider may -- and is expected to -- call
* provider-related DTrace provider APIs including dtrace_unregister().
*/
typedef struct dtrace_helper_probedesc {
typedef struct dtrace_helper_provdesc {
typedef struct dtrace_mops {
extern int dtrace_meta_register(const char *, const dtrace_mops_t *, void *,
extern int dtrace_meta_unregister(dtrace_meta_provider_id_t);
/*
* DTrace Kernel Hooks
*
* The following functions are implemented by the base kernel and form a set of
* hooks used by the DTrace framework. DTrace hooks are implemented in either
* uts/common/os/dtrace_subr.c, an ISA-specific assembly file, or in a
* uts/<platform>/os/dtrace_subr.c corresponding to each hardware platform.
*/
typedef enum dtrace_vtime_state {
extern void dtrace_vtime_enable_tnf(void);
extern void dtrace_vtime_disable_tnf(void);
extern void dtrace_vtime_enable(void);
extern void dtrace_vtime_disable(void);
struct regs;
extern int (*dtrace_pid_probe_ptr)(struct regs *);
extern int (*dtrace_return_probe_ptr)(struct regs *);
extern void (*dtrace_fasttrap_exec_ptr)(proc_t *);
extern void (*dtrace_fasttrap_exit_ptr)(proc_t *);
typedef void (*dtrace_xcall_t)(void *);
extern dtrace_icookie_t dtrace_interrupt_disable(void);
extern void dtrace_interrupt_enable(dtrace_icookie_t);
extern void dtrace_membar_producer(void);
extern void dtrace_membar_consumer(void);
extern void (*dtrace_cpu_init)(processorid_t);
extern void (*dtrace_modload)(struct modctl *);
extern void (*dtrace_modunload)(struct modctl *);
extern void (*dtrace_helpers_cleanup)(proc_t *);
extern void (*dtrace_cpustart_init)();
extern void (*dtrace_cpustart_fini)();
extern void (*dtrace_closef)();
extern void (*dtrace_debugger_init)();
extern void (*dtrace_debugger_fini)();
extern dtrace_cacheid_t dtrace_predcache_id;
extern hrtime_t dtrace_gethrtime(void);
extern void dtrace_sync(void);
extern void dtrace_vpanic(const char *, __va_list);
extern void dtrace_panic(const char *, ...);
extern int dtrace_safe_defer_signal(void);
extern void dtrace_safe_synchronous_signal(void);
extern int dtrace_mach_aframes(void);
extern void dtrace_invop_callsite(void);
#endif
#ifdef __sparc
extern void dtrace_getfsr(uint64_t *);
#endif
#endif /* _KERNEL */
#endif /* _ASM */
#endif
#ifdef __cplusplus
}
#endif
#endif /* _SYS_DTRACE_H */