Commit e2701603 authored by Linus Torvalds's avatar Linus Torvalds

Merge tag 'docs-for-linus' of git://git.lwn.net/linux-2.6

Pull documentation updates from Jonathan Corbet:
 "There's been a fair amount going on in the docs tree this time around,
  including:

   - Support for reproducible document builds, from Ben Hutchings and
     company.

   - The ability to automatically generate cross-reference links within
     a single DocBook book and embedded descriptions for large
     structures.  From Danilo Cesar Lemes de Paula.

   - A new document on how to add a system call from David Drysdale.

   - Chameleon bus documentation from Johannes Thumshirn.

  ...plus the usual collection of improvements, typo fixes, and more"

* tag 'docs-for-linus' of git://git.lwn.net/linux-2.6: (39 commits)
  Documentation, add kernel-parameters.txt entry for dis_ucode_ldr
  Documentation/x86: Rename IRQSTACKSIZE to IRQ_STACK_SIZE
  Documentation/Intel-IOMMU.txt: Modify definition of DRHD
  docs: update HOWTO for 3.x -> 4.x versioning
  kernel-doc: ignore unneeded attribute information
  scripts/kernel-doc: Adding cross-reference links to html documentation.
  DocBook: Fix non-determinstic installation of duplicate man pages
  Documentation: minor typo fix in mailbox.txt
  Documentation: describe how to add a system call
  doc: Add more workqueue functions to the documentation
  ARM: keystone: add documentation for SoCs and EVMs
  scripts/kernel-doc Allow struct arguments documentation in struct body
  SubmittingPatches: remove stray quote character
  Revert "DocBook: Avoid building man pages repeatedly and inconsistently"
  Documentation: Minor changes to men-chameleon-bus.txt
  Doc: fix trivial typo in SubmittingPatches
  MAINTAINERS: Direct Documentation/DocBook/media properly
  Documentation: installed man pages don't need to be executable
  fix Evolution submenu name in email-clients.txt
  Documentation: Add MCB documentation
  ...
parents 22629b6d ce14c583
......@@ -929,13 +929,11 @@ The C Programming Language, Second Edition
by Brian W. Kernighan and Dennis M. Ritchie.
Prentice Hall, Inc., 1988.
ISBN 0-13-110362-8 (paperback), 0-13-110370-9 (hardback).
URL: http://cm.bell-labs.com/cm/cs/cbook/
The Practice of Programming
by Brian W. Kernighan and Rob Pike.
Addison-Wesley, Inc., 1999.
ISBN 0-201-61586-X.
URL: http://cm.bell-labs.com/cm/cs/tpop/
GNU manuals - where in compliance with K&R and this text - for cpp, gcc,
gcc internals and indent, all available from http://www.gnu.org/manual/
......
......@@ -56,14 +56,17 @@ htmldocs: $(HTML)
MAN := $(patsubst %.xml, %.9, $(BOOKS))
mandocs: $(MAN)
find $(obj)/man -name '*.9' | xargs gzip -f
find $(obj)/man -name '*.9' | xargs gzip -nf
installmandocs: mandocs
mkdir -p /usr/local/man/man9/
install $(obj)/man/*.9.gz /usr/local/man/man9/
find $(obj)/man -name '*.9.gz' -printf '%h %f\n' | \
sort -k 2 -k 1 | uniq -f 1 | sed -e 's: :/:' | \
xargs install -m 644 -t /usr/local/man/man9/
###
#External programs used
KERNELDOCXMLREF = $(srctree)/scripts/kernel-doc-xml-ref
KERNELDOC = $(srctree)/scripts/kernel-doc
DOCPROC = $(objtree)/scripts/docproc
......@@ -89,7 +92,7 @@ define rule_docproc
) > $(dir $@).$(notdir $@).cmd
endef
%.xml: %.tmpl $(KERNELDOC) $(DOCPROC) FORCE
%.xml: %.tmpl $(KERNELDOC) $(DOCPROC) $(KERNELDOCXMLREF) FORCE
$(call if_changed_rule,docproc)
# Tell kbuild to always build the programs
......@@ -140,7 +143,20 @@ quiet_cmd_db2html = HTML $@
echo '<a HREF="$(patsubst %.html,%,$(notdir $@))/index.html"> \
$(patsubst %.html,%,$(notdir $@))</a><p>' > $@
%.html: %.xml
###
# Rules to create an aux XML and .db, and use them to re-process the DocBook XML
# to fill internal hyperlinks
gen_aux_xml = :
quiet_gen_aux_xml = echo ' XMLREF $@'
silent_gen_aux_xml = :
%.aux.xml: %.xml
@$($(quiet)gen_aux_xml)
@rm -rf $@
@(cat $< | egrep "^<refentry id" | egrep -o "\".*\"" | cut -f 2 -d \" > $<.db)
@$(KERNELDOCXMLREF) -db $<.db $< > $@
.PRECIOUS: %.aux.xml
%.html: %.aux.xml
@(which xmlto > /dev/null 2>&1) || \
(echo "*** You need to install xmlto ***"; \
exit 1)
......@@ -150,12 +166,12 @@ quiet_cmd_db2html = HTML $@
cp $(PNG-$(basename $(notdir $@))) $(patsubst %.html,%,$@); fi
quiet_cmd_db2man = MAN $@
cmd_db2man = if grep -q refentry $<; then xmlto man $(XMLTOFLAGS) -o $(obj)/man $< ; fi
cmd_db2man = if grep -q refentry $<; then xmlto man $(XMLTOFLAGS) -o $(obj)/man/$(*F) $< ; fi
%.9 : %.xml
@(which xmlto > /dev/null 2>&1) || \
(echo "*** You need to install xmlto ***"; \
exit 1)
$(Q)mkdir -p $(obj)/man
$(Q)mkdir -p $(obj)/man/$(*F)
$(call cmd,db2man)
@touch $@
......@@ -218,6 +234,9 @@ clean-files := $(DOCBOOKS) \
$(patsubst %.xml, %.pdf, $(DOCBOOKS)) \
$(patsubst %.xml, %.html, $(DOCBOOKS)) \
$(patsubst %.xml, %.9, $(DOCBOOKS)) \
$(patsubst %.xml, %.aux.xml, $(DOCBOOKS)) \
$(patsubst %.xml, %.xml.db, $(DOCBOOKS)) \
$(patsubst %.xml, %.xml, $(DOCBOOKS)) \
$(index)
clean-dirs := $(patsubst %.xml,%,$(DOCBOOKS)) man
......
......@@ -66,6 +66,7 @@
!Ekernel/time/hrtimer.c
</sect1>
<sect1><title>Workqueues and Kevents</title>
!Iinclude/linux/workqueue.h
!Ekernel/workqueue.c
</sect1>
<sect1><title>Internal Functions</title>
......
......@@ -5,6 +5,7 @@
<param name="funcsynopsis.tabular.threshold">80</param>
<param name="callout.graphics">0</param>
<!-- <param name="paper.type">A4</param> -->
<param name="generate.consistent.ids">1</param>
<param name="generate.section.toc.level">2</param>
<param name="use.id.as.filename">1</param>
</stylesheet>
......@@ -218,16 +218,16 @@ The development process
Linux kernel development process currently consists of a few different
main kernel "branches" and lots of different subsystem-specific kernel
branches. These different branches are:
- main 3.x kernel tree
- 3.x.y -stable kernel tree
- 3.x -git kernel patches
- main 4.x kernel tree
- 4.x.y -stable kernel tree
- 4.x -git kernel patches
- subsystem specific kernel trees and patches
- the 3.x -next kernel tree for integration tests
- the 4.x -next kernel tree for integration tests
3.x kernel tree
4.x kernel tree
-----------------
3.x kernels are maintained by Linus Torvalds, and can be found on
kernel.org in the pub/linux/kernel/v3.x/ directory. Its development
4.x kernels are maintained by Linus Torvalds, and can be found on
kernel.org in the pub/linux/kernel/v4.x/ directory. Its development
process is as follows:
- As soon as a new kernel is released a two weeks window is open,
during this period of time maintainers can submit big diffs to
......@@ -262,20 +262,20 @@ mailing list about kernel releases:
released according to perceived bug status, not according to a
preconceived timeline."
3.x.y -stable kernel tree
4.x.y -stable kernel tree
---------------------------
Kernels with 3-part versions are -stable kernels. They contain
relatively small and critical fixes for security problems or significant
regressions discovered in a given 3.x kernel.
regressions discovered in a given 4.x kernel.
This is the recommended branch for users who want the most recent stable
kernel and are not interested in helping test development/experimental
versions.
If no 3.x.y kernel is available, then the highest numbered 3.x
If no 4.x.y kernel is available, then the highest numbered 4.x
kernel is the current stable kernel.
3.x.y are maintained by the "stable" team <stable@vger.kernel.org>, and
4.x.y are maintained by the "stable" team <stable@vger.kernel.org>, and
are released as needs dictate. The normal release period is approximately
two weeks, but it can be longer if there are no pressing problems. A
security-related problem, instead, can cause a release to happen almost
......@@ -285,7 +285,7 @@ The file Documentation/stable_kernel_rules.txt in the kernel tree
documents what kinds of changes are acceptable for the -stable tree, and
how the release process works.
3.x -git patches
4.x -git patches
------------------
These are daily snapshots of Linus' kernel tree which are managed in a
git repository (hence the name.) These patches are usually released
......@@ -317,9 +317,9 @@ revisions to it, and maintainers can mark patches as under review,
accepted, or rejected. Most of these patchwork sites are listed at
http://patchwork.kernel.org/.
3.x -next kernel tree for integration tests
4.x -next kernel tree for integration tests
---------------------------------------------
Before updates from subsystem trees are merged into the mainline 3.x
Before updates from subsystem trees are merged into the mainline 4.x
tree, they need to be integration-tested. For this purpose, a special
testing repository exists into which virtually all subsystem trees are
pulled on an almost daily basis:
......
......@@ -10,7 +10,7 @@ This guide gives a quick cheat sheet for some basic understanding.
Some Keywords
DMAR - DMA remapping
DRHD - DMA Engine Reporting Structure
DRHD - DMA Remapping Hardware Unit Definition
RMRR - Reserved memory Region Reporting Structure
ZLR - Zero length reads from PCI devices
IOVA - IO Virtual address.
......
......@@ -90,11 +90,11 @@ patch.
Make sure your patch does not include any extra files which do not
belong in a patch submission. Make sure to review your patch -after-
generated it with diff(1), to ensure accuracy.
generating it with diff(1), to ensure accuracy.
If your changes produce a lot of deltas, you need to split them into
individual patches which modify things in logical stages; see section
#3. This will facilitate easier reviewing by other kernel developers,
#3. This will facilitate review by other kernel developers,
very important if you want your patch accepted.
If you're using git, "git rebase -i" can help you with this process. If
......@@ -267,7 +267,7 @@ You should always copy the appropriate subsystem maintainer(s) on any patch
to code that they maintain; look through the MAINTAINERS file and the
source code revision history to see who those maintainers are. The
script scripts/get_maintainer.pl can be very useful at this step. If you
cannot find a maintainer for the subsystem your are working on, Andrew
cannot find a maintainer for the subsystem you are working on, Andrew
Morton (akpm@linux-foundation.org) serves as a maintainer of last resort.
You should also normally choose at least one mailing list to receive a copy
......@@ -340,7 +340,7 @@ on the changes you are submitting. It is important for a kernel
developer to be able to "quote" your changes, using standard e-mail
tools, so that they may comment on specific portions of your code.
For this reason, all patches should be submitting e-mail "inline".
For this reason, all patches should be submitted by e-mail "inline".
WARNING: Be wary of your editor's word-wrap corrupting your patch,
if you choose to cut-n-paste your patch.
......@@ -739,7 +739,7 @@ interest on a single line; it should look something like:
git://jdelvare.pck.nerim.net/jdelvare-2.6 i2c-for-linus
to get these changes:"
to get these changes:
A pull request should also include an overall message saying what will be
included in the request, a "git shortlog" listing of the patches
......@@ -796,7 +796,7 @@ NO!!!! No more huge patch bombs to linux-kernel@vger.kernel.org people!
<https://lkml.org/lkml/2005/7/11/336>
Kernel Documentation/CodingStyle:
<http://users.sosdg.org/~qiyong/lxr/source/Documentation/CodingStyle>
<Documentation/CodingStyle>
Linus Torvalds's mail on the canonical patch format:
<http://lkml.org/lkml/2005/4/7/183>
......
Adding a New System Call
========================
This document describes what's involved in adding a new system call to the
Linux kernel, over and above the normal submission advice in
Documentation/SubmittingPatches.
System Call Alternatives
------------------------
The first thing to consider when adding a new system call is whether one of
the alternatives might be suitable instead. Although system calls are the
most traditional and most obvious interaction points between userspace and the
kernel, there are other possibilities -- choose what fits best for your
interface.
- If the operations involved can be made to look like a filesystem-like
object, it may make more sense to create a new filesystem or device. This
also makes it easier to encapsulate the new functionality in a kernel module
rather than requiring it to be built into the main kernel.
- If the new functionality involves operations where the kernel notifies
userspace that something has happened, then returning a new file
descriptor for the relevant object allows userspace to use
poll/select/epoll to receive that notification.
- However, operations that don't map to read(2)/write(2)-like operations
have to be implemented as ioctl(2) requests, which can lead to a
somewhat opaque API.
- If you're just exposing runtime system information, a new node in sysfs
(see Documentation/filesystems/sysfs.txt) or the /proc filesystem may be
more appropriate. However, access to these mechanisms requires that the
relevant filesystem is mounted, which might not always be the case (e.g.
in a namespaced/sandboxed/chrooted environment). Avoid adding any API to
debugfs, as this is not considered a 'production' interface to userspace.
- If the operation is specific to a particular file or file descriptor, then
an additional fcntl(2) command option may be more appropriate. However,
fcntl(2) is a multiplexing system call that hides a lot of complexity, so
this option is best for when the new function is closely analogous to
existing fcntl(2) functionality, or the new functionality is very simple
(for example, getting/setting a simple flag related to a file descriptor).
- If the operation is specific to a particular task or process, then an
additional prctl(2) command option may be more appropriate. As with
fcntl(2), this system call is a complicated multiplexor so is best reserved
for near-analogs of existing prctl() commands or getting/setting a simple
flag related to a process.
Designing the API: Planning for Extension
-----------------------------------------
A new system call forms part of the API of the kernel, and has to be supported
indefinitely. As such, it's a very good idea to explicitly discuss the
interface on the kernel mailing list, and it's important to plan for future
extensions of the interface.
(The syscall table is littered with historical examples where this wasn't done,
together with the corresponding follow-up system calls -- eventfd/eventfd2,
dup2/dup3, inotify_init/inotify_init1, pipe/pipe2, renameat/renameat2 -- so
learn from the history of the kernel and plan for extensions from the start.)
For simpler system calls that only take a couple of arguments, the preferred
way to allow for future extensibility is to include a flags argument to the
system call. To make sure that userspace programs can safely use flags
between kernel versions, check whether the flags value holds any unknown
flags, and reject the system call (with EINVAL) if it does:
if (flags & ~(THING_FLAG1 | THING_FLAG2 | THING_FLAG3))
return -EINVAL;
(If no flags values are used yet, check that the flags argument is zero.)
For more sophisticated system calls that involve a larger number of arguments,
it's preferred to encapsulate the majority of the arguments into a structure
that is passed in by pointer. Such a structure can cope with future extension
by including a size argument in the structure:
struct xyzzy_params {
u32 size; /* userspace sets p->size = sizeof(struct xyzzy_params) */
u32 param_1;
u64 param_2;
u64 param_3;
};
As long as any subsequently added field, say param_4, is designed so that a
zero value gives the previous behaviour, then this allows both directions of
version mismatch:
- To cope with a later userspace program calling an older kernel, the kernel
code should check that any memory beyond the size of the structure that it
expects is zero (effectively checking that param_4 == 0).
- To cope with an older userspace program calling a newer kernel, the kernel
code can zero-extend a smaller instance of the structure (effectively
setting param_4 = 0).
See perf_event_open(2) and the perf_copy_attr() function (in
kernel/events/core.c) for an example of this approach.
Designing the API: Other Considerations
---------------------------------------
If your new system call allows userspace to refer to a kernel object, it
should use a file descriptor as the handle for that object -- don't invent a
new type of userspace object handle when the kernel already has mechanisms and
well-defined semantics for using file descriptors.
If your new xyzzy(2) system call does return a new file descriptor, then the
flags argument should include a value that is equivalent to setting O_CLOEXEC
on the new FD. This makes it possible for userspace to close the timing
window between xyzzy() and calling fcntl(fd, F_SETFD, FD_CLOEXEC), where an
unexpected fork() and execve() in another thread could leak a descriptor to
the exec'ed program. (However, resist the temptation to re-use the actual value
of the O_CLOEXEC constant, as it is architecture-specific and is part of a
numbering space of O_* flags that is fairly full.)
If your system call returns a new file descriptor, you should also consider
what it means to use the poll(2) family of system calls on that file
descriptor. Making a file descriptor ready for reading or writing is the
normal way for the kernel to indicate to userspace that an event has
occurred on the corresponding kernel object.
If your new xyzzy(2) system call involves a filename argument:
int sys_xyzzy(const char __user *path, ..., unsigned int flags);
you should also consider whether an xyzzyat(2) version is more appropriate:
int sys_xyzzyat(int dfd, const char __user *path, ..., unsigned int flags);
This allows more flexibility for how userspace specifies the file in question;
in particular it allows userspace to request the functionality for an
already-opened file descriptor using the AT_EMPTY_PATH flag, effectively giving
an fxyzzy(3) operation for free:
- xyzzyat(AT_FDCWD, path, ..., 0) is equivalent to xyzzy(path,...)
- xyzzyat(fd, "", ..., AT_EMPTY_PATH) is equivalent to fxyzzy(fd, ...)
(For more details on the rationale of the *at() calls, see the openat(2) man
page; for an example of AT_EMPTY_PATH, see the statat(2) man page.)
If your new xyzzy(2) system call involves a parameter describing an offset
within a file, make its type loff_t so that 64-bit offsets can be supported
even on 32-bit architectures.
If your new xyzzy(2) system call involves privileged functionality, it needs
to be governed by the appropriate Linux capability bit (checked with a call to
capable()), as described in the capabilities(7) man page. Choose an existing
capability bit that governs related functionality, but try to avoid combining
lots of only vaguely related functions together under the same bit, as this
goes against capabilities' purpose of splitting the power of root. In
particular, avoid adding new uses of the already overly-general CAP_SYS_ADMIN
capability.
If your new xyzzy(2) system call manipulates a process other than the calling
process, it should be restricted (using a call to ptrace_may_access()) so that
only a calling process with the same permissions as the target process, or
with the necessary capabilities, can manipulate the target process.
Finally, be aware that some non-x86 architectures have an easier time if
system call parameters that are explicitly 64-bit fall on odd-numbered
arguments (i.e. parameter 1, 3, 5), to allow use of contiguous pairs of 32-bit
registers. (This concern does not apply if the arguments are part of a
structure that's passed in by pointer.)
Proposing the API
-----------------
To make new system calls easy to review, it's best to divide up the patchset
into separate chunks. These should include at least the following items as
distinct commits (each of which is described further below):
- The core implementation of the system call, together with prototypes,
generic numbering, Kconfig changes and fallback stub implementation.
- Wiring up of the new system call for one particular architecture, usually
x86 (including all of x86_64, x86_32 and x32).
- A demonstration of the use of the new system call in userspace via a
selftest in tools/testing/selftests/.
- A draft man-page for the new system call, either as plain text in the
cover letter, or as a patch to the (separate) man-pages repository.
New system call proposals, like any change to the kernel's API, should always
be cc'ed to linux-api@vger.kernel.org.
Generic System Call Implementation
----------------------------------
The main entry point for your new xyzzy(2) system call will be called
sys_xyzzy(), but you add this entry point with the appropriate
SYSCALL_DEFINEn() macro rather than explicitly. The 'n' indicates the number
of arguments to the system call, and the macro takes the system call name
followed by the (type, name) pairs for the parameters as arguments. Using
this macro allows metadata about the new system call to be made available for
other tools.
The new entry point also needs a corresponding function prototype, in
include/linux/syscalls.h, marked as asmlinkage to match the way that system
calls are invoked:
asmlinkage long sys_xyzzy(...);
Some architectures (e.g. x86) have their own architecture-specific syscall
tables, but several other architectures share a generic syscall table. Add your
new system call to the generic list by adding an entry to the list in
include/uapi/asm-generic/unistd.h:
#define __NR_xyzzy 292
__SYSCALL(__NR_xyzzy, sys_xyzzy)
Also update the __NR_syscalls count to reflect the additional system call, and
note that if multiple new system calls are added in the same merge window,
your new syscall number may get adjusted to resolve conflicts.
The file kernel/sys_ni.c provides a fallback stub implementation of each system
call, returning -ENOSYS. Add your new system call here too:
cond_syscall(sys_xyzzy);
Your new kernel functionality, and the system call that controls it, should
normally be optional, so add a CONFIG option (typically to init/Kconfig) for
it. As usual for new CONFIG options:
- Include a description of the new functionality and system call controlled
by the option.
- Make the option depend on EXPERT if it should be hidden from normal users.
- Make any new source files implementing the function dependent on the CONFIG
option in the Makefile (e.g. "obj-$(CONFIG_XYZZY_SYSCALL) += xyzzy.c").
- Double check that the kernel still builds with the new CONFIG option turned
off.
To summarize, you need a commit that includes:
- CONFIG option for the new function, normally in init/Kconfig
- SYSCALL_DEFINEn(xyzzy, ...) for the entry point
- corresponding prototype in include/linux/syscalls.h
- generic table entry in include/uapi/asm-generic/unistd.h
- fallback stub in kernel/sys_ni.c
x86 System Call Implementation
------------------------------
To wire up your new system call for x86 platforms, you need to update the
master syscall tables. Assuming your new system call isn't special in some
way (see below), this involves a "common" entry (for x86_64 and x32) in
arch/x86/entry/syscalls/syscall_64.tbl:
333 common xyzzy sys_xyzzy
and an "i386" entry in arch/x86/entry/syscalls/syscall_32.tbl:
380 i386 xyzzy sys_xyzzy
Again, these numbers are liable to be changed if there are conflicts in the
relevant merge window.
Compatibility System Calls (Generic)
------------------------------------
For most system calls the same 64-bit implementation can be invoked even when
the userspace program is itself 32-bit; even if the system call's parameters
include an explicit pointer, this is handled transparently.
However, there are a couple of situations where a compatibility layer is
needed to cope with size differences between 32-bit and 64-bit.
The first is if the 64-bit kernel also supports 32-bit userspace programs, and
so needs to parse areas of (__user) memory that could hold either 32-bit or
64-bit values. In particular, this is needed whenever a system call argument
is:
- a pointer to a pointer
- a pointer to a struct containing a pointer (e.g. struct iovec __user *)
- a pointer to a varying sized integral type (time_t, off_t, long, ...)
- a pointer to a struct containing a varying sized integral type.
The second situation that requires a compatibility layer is if one of the
system call's arguments has a type that is explicitly 64-bit even on a 32-bit
architecture, for example loff_t or __u64. In this case, a value that arrives
at a 64-bit kernel from a 32-bit application will be split into two 32-bit
values, which then need to be re-assembled in the compatibility layer.
(Note that a system call argument that's a pointer to an explicit 64-bit type
does *not* need a compatibility layer; for example, splice(2)'s arguments of
type loff_t __user * do not trigger the need for a compat_ system call.)
The compatibility version of the system call is called compat_sys_xyzzy(), and
is added with the COMPAT_SYSCALL_DEFINEn() macro, analogously to
SYSCALL_DEFINEn. This version of the implementation runs as part of a 64-bit
kernel, but expects to receive 32-bit parameter values and does whatever is
needed to deal with them. (Typically, the compat_sys_ version converts the
values to 64-bit versions and either calls on to the sys_ version, or both of
them call a common inner implementation function.)
The compat entry point also needs a corresponding function prototype, in
include/linux/compat.h, marked as asmlinkage to match the way that system
calls are invoked:
asmlinkage long compat_sys_xyzzy(...);
If the system call involves a structure that is laid out differently on 32-bit
and 64-bit systems, say struct xyzzy_args, then the include/linux/compat.h
header file should also include a compat version of the structure (struct
compat_xyzzy_args) where each variable-size field has the appropriate compat_
type that corresponds to the type in struct xyzzy_args. The
compat_sys_xyzzy() routine can then use this compat_ structure to parse the
arguments from a 32-bit invocation.
For example, if there are fields:
struct xyzzy_args {
const char __user *ptr;
__kernel_long_t varying_val;
u64 fixed_val;
/* ... */
};
in struct xyzzy_args, then struct compat_xyzzy_args would have:
struct compat_xyzzy_args {
compat_uptr_t ptr;
compat_long_t varying_val;
u64 fixed_val;
/* ... */
};
The generic system call list also needs adjusting to allow for the compat
version; the entry in include/uapi/asm-generic/unistd.h should use
__SC_COMP rather than __SYSCALL:
#define __NR_xyzzy 292
__SC_COMP(__NR_xyzzy, sys_xyzzy, compat_sys_xyzzy)
To summarize, you need:
- a COMPAT_SYSCALL_DEFINEn(xyzzy, ...) for the compat entry point
- corresponding prototype in include/linux/compat.h
- (if needed) 32-bit mapping struct in include/linux/compat.h
- instance of __SC_COMP not __SYSCALL in include/uapi/asm-generic/unistd.h
Compatibility System Calls (x86)
--------------------------------
To wire up the x86 architecture of a system call with a compatibility version,
the entries in the syscall tables need to be adjusted.
First, the entry in arch/x86/entry/syscalls/syscall_32.tbl gets an extra
column to indicate that a 32-bit userspace program running on a 64-bit kernel
should hit the compat entry point:
380 i386 xyzzy sys_xyzzy compat_sys_xyzzy
Second, you need to figure out what should happen for the x32 ABI version of
the new system call. There's a choice here: the layout of the arguments
should either match the 64-bit version or the 32-bit version.
If there's a pointer-to-a-pointer involved, the decision is easy: x32 is
ILP32, so the layout should match the 32-bit version, and the entry in
arch/x86/entry/syscalls/syscall_64.tbl is split so that x32 programs hit the
compatibility wrapper:
333 64 xyzzy sys_xyzzy
...
555 x32 xyzzy compat_sys_xyzzy
If no pointers are involved, then it is preferable to re-use the 64-bit system
call for the x32 ABI (and consequently the entry in
arch/x86/entry/syscalls/syscall_64.tbl is unchanged).
In either case, you should check that the types involved in your argument
layout do indeed map exactly from x32 (-mx32) to either the 32-bit (-m32) or
64-bit (-m64) equivalents.
System Calls Returning Elsewhere
--------------------------------
For most system calls, once the system call is complete the user program
continues exactly where it left off -- at the next instruction, with the
stack the same and most of the registers the same as before the system call,
and with the same virtual memory space.
However, a few system calls do things differently. They might return to a
different location (rt_sigreturn) or change the memory space (fork/vfork/clone)
or even architecture (execve/execveat) of the program.
To allow for this, the kernel implementation of the system call may need to
save and restore additional registers to the kernel stack, allowing complete
control of where and how execution continues after the system call.
This is arch-specific, but typically involves defining assembly entry points
that save/restore additional registers and invoke the real system call entry
point.
For x86_64, this is implemented as a stub_xyzzy entry point in
arch/x86/entry/entry_64.S, and the entry in the syscall table
(arch/x86/entry/syscalls/syscall_64.tbl) is adjusted to match:
333 common xyzzy stub_xyzzy
The equivalent for 32-bit programs running on a 64-bit kernel is normally
called stub32_xyzzy and implemented in arch/x86/entry/entry_64_compat.S,
with the corresponding syscall table adjustment in
arch/x86/entry/syscalls/syscall_32.tbl:
380 i386 xyzzy sys_xyzzy stub32_xyzzy
If the system call needs a compatibility layer (as in the previous section)
then the stub32_ version needs to call on to the compat_sys_ version of the
system call rather than the native 64-bit version. Also, if the x32 ABI
implementation is not common with the x86_64 version, then its syscall
table will also need to invoke a stub that calls on to the compat_sys_
version.
For completeness, it's also nice to set up a mapping so that user-mode Linux
still works -- its syscall table will reference stub_xyzzy, but the UML build
doesn't include arch/x86/entry/entry_64.S implementation (because UML
simulates registers etc). Fixing this is as simple as adding a #define to
arch/x86/um/sys_call_table_64.c:
#define stub_xyzzy sys_xyzzy
Other Details
-------------
Most of the kernel treats system calls in a generic way, but there is the
occasional exception that may need updating for your particular system call.
The audit subsystem is one such special case; it includes (arch-specific)
functions that classify some special types of system call -- specifically
file open (open/openat), program execution (execve/exeveat) or socket
multiplexor (socketcall) operations. If your new system call is analogous to
one of these, then the audit system should be updated.
More generally, if there is an existing system call that is analogous to your
new system call, it's worth doing a kernel-wide grep for the existing system
call to check there are no other special cases.
Testing
-------
A new system call should obviously be tested; it is also useful to provide
reviewers with a demonstration of how user space programs will use the system
call. A good way to combine these aims is to include a simple self-test
program in a new directory under tools/testing/selftests/.
For a new system call, there will obviously be no libc wrapper function and so
the test will need to invoke it using syscall(); also, if the system call
involves a new userspace-visible structure, the corresponding header will need
to be installed to compile the test.
Make sure the selftest runs successfully on all supported architectures. For
example, check that it works when compiled as an x86_64 (-m64), x86_32 (-m32)
and x32 (-mx32) ABI program.
For more extensive and thorough testing of new functionality, you should also
consider adding tests to the Linux Test Project, or to the xfstests project
for filesystem-related changes.
- https://linux-test-project.github.io/
- git://git.kernel.org/pub/scm/fs/xfs/xfstests-dev.git
Man Page
--------
All new system calls should come with a complete man page, ideally using groff
markup, but plain text will do. If groff is used, it's helpful to include a
pre-rendered ASCII version of the man page in the cover email for the
patchset, for the convenience of reviewers.
The man page should be cc'ed to linux-man@vger.kernel.org
For more details, see https://www.kernel.org/doc/man-pages/patches.html
References and Sources
----------------------
- LWN article from Michael Kerrisk on use of flags argument in system calls:
https://lwn.net/Articles/585415/
- LWN article from Michael Kerrisk on how to handle unknown flags in a system
call: https://lwn.net/Articles/588444/
- LWN article from Jake Edge describing constraints on 64-bit system call
arguments: https://lwn.net/Articles/311630/
- Pair of LWN articles from David Drysdale that describe the system call
implementation paths in detail for v3.14:
- https://lwn.net/Articles/604287/
- https://lwn.net/Articles/604515/
- Architecture-specific requirements for system calls are discussed in the
syscall(2) man-page:
http://man7.org/linux/man-pages/man2/syscall.2.html#NOTES
- Collated emails from Linus Torvalds discussing the problems with ioctl():
http://yarchive.net/comp/linux/ioctl.html
- "How to not invent kernel interfaces", Arnd Bergmann,
http://www.ukuug.org/events/linux2007/2007/papers/Bergmann.pdf
- LWN article from Michael Kerrisk on avoiding new uses of CAP_SYS_ADMIN:
https://lwn.net/Articles/486306/
- Recommendation from Andrew Morton that all related information for a new
system call should come in the same email thread:
https://lkml.org/lkml/2014/7/24/641
- Recommendation from Michael Kerrisk that a new system call should come with
a man page: https://lkml.org/lkml/2014/6/13/309
- Suggestion from Thomas Gleixner that x86 wire-up should be in a separate
commit: https://lkml.org/lkml/2014/11/19/254
- Suggestion from Greg Kroah-Hartman that it's good for new system calls to
come with a man-page & selftest: https://lkml.org/lkml/2014/3/19/710
- Discussion from Michael Kerrisk of new system call vs. prctl(2) extension:
https://lkml.org/lkml/2014/6/3/411
- Suggestion from Ingo Molnar that system calls that involve multiple
arguments should encapsulate those arguments in a struct, which includes a
size field for future extensibility: https://lkml.org/lkml/2015/7/30/117
- Numbering oddities arising from (re-)use of O_* numbering space flags:
- commit 75069f2b5bfb ("vfs: renumber FMODE_NONOTIFY and add to uniqueness
check")
- commit 12ed2e36c98a ("fanotify: FMODE_NONOTIFY and __O_SYNC in sparc
conflict")
- commit bb458c644a59 ("Safer ABI for O_TMPFILE")
- Discussion from Matthew Wilcox about restrictions on 64-bit arguments:
https://lkml.org/lkml/2008/12/12/187
- Recommendation from Greg Kroah-Hartman that unknown flags should be
policed: https://lkml.org/lkml/2014/7/17/577
- Recommendation from Linus Torvalds that x32 system calls should prefer
compatibility with 64-bit versions rather than 32-bit versions:
https://lkml.org/lkml/2011/8/31/244
......@@ -15,6 +15,7 @@ executing kernel.
1. Non-Secure mode
Address: sysram_ns_base_addr
Offset Value Purpose
=============================================================================
......@@ -28,6 +29,7 @@ Offset Value Purpose
2. Secure mode
Address: sysram_base_addr
Offset Value Purpose
=============================================================================
......@@ -40,14 +42,25 @@ Offset Value Purpose
Address: pmu_base_addr
Offset Value Purpose
=============================================================================
0x0800 exynos_cpu_resume AFTR
0x0800 exynos_cpu_resume AFTR, suspend
0x0800 mcpm_entry_point (Exynos542x with MCPM) AFTR, suspend
0x0804 0xfcba0d10 (Magic cookie) AFTR
0x0804 0x00000bad (Magic cookie) System suspend
0x0814 exynos4_secondary_startup (Exynos4210 r1.1) Secondary CPU boot
0x0818 0xfcba0d10 (Magic cookie, Exynos4210 r1.1) AFTR
0x081C exynos_cpu_resume (Exynos4210 r1.1) AFTR
3. Other (regardless of secure/non-secure mode)
Address: pmu_base_addr
Offset Value Purpose
=============================================================================
0x0908 Non-zero (only Exynos3250) Secondary CPU boot up indicator
4. Glossary
AFTR - ARM Off Top Running, a low power mode, Cortex cores and many other
modules are power gated, except the TOP modules
MCPM - Multi-Cluster Power Management
TI Keystone Linux Overview
--------------------------
Introduction
------------
Keystone range of SoCs are based on ARM Cortex-A15 MPCore Processors
and c66x DSP cores. This document describes essential information required
for users to run Linux on Keystone based EVMs from Texas Instruments.
Following SoCs & EVMs are currently supported:-
------------ K2HK SoC and EVM --------------------------------------------------
a.k.a Keystone 2 Hawking/Kepler SoC
TCI6636K2H & TCI6636K2K: See documentation at
http://www.ti.com/product/tci6638k2k
http://www.ti.com/product/tci6638k2h
EVM:
http://www.advantech.com/Support/TI-EVM/EVMK2HX_sd.aspx
------------ K2E SoC and EVM ---------------------------------------------------
a.k.a Keystone 2 Edison SoC
K2E - 66AK2E05: See documentation at
http://www.ti.com/product/66AK2E05/technicaldocuments
EVM:
https://www.einfochips.com/index.php/partnerships/texas-instruments/k2e-evm.html
------------ K2L SoC and EVM ---------------------------------------------------
a.k.a Keystone 2 Lamarr SoC
K2L - TCI6630K2L: See documentation at
http://www.ti.com/product/TCI6630K2L/technicaldocuments
EVM:
https://www.einfochips.com/index.php/partnerships/texas-instruments/k2l-evm.html
Configuration
-------------
All of the K2 SoCs/EVMs share a common defconfig, keystone_defconfig and same
image is used to boot on individual EVMs. The platform configuration is
specified through DTS. Following are the DTS used:-
K2HK EVM : k2hk-evm.dts
K2E EVM : k2e-evm.dts
K2L EVM : k2l-evm.dts
The device tree documentation for the keystone machines are located at
Documentation/devicetree/bindings/arm/keystone/keystone.txt
Known issues & workaround
-------------------------
Some of the device drivers used on keystone are re-used from that from
DaVinci and other TI SoCs. These device drivers may use clock APIs directly.
Some of the keystone specific drivers such as netcp uses run time power
management API instead to enable clock. As this API has limitations on
keystone, following workaround is needed to boot Linux.
Add 'clk_ignore_unused' to the bootargs env variable in u-boot. Otherwise
clock frameworks will try to disable clocks that are unused and disable
the hardware. This is because netcp related power domain and clock
domains are enabled in u-boot as run time power management API currently
doesn't enable clocks for netcp due to a limitation. This workaround is
expected to be removed in the future when proper API support becomes
available. Until then, this work around is needed.
Document Author
---------------
Murali Karicheri <m-karicheri2@ti.com>
Copyright 2015 Texas Instruments
......@@ -93,7 +93,7 @@ Evolution (GUI)
Some people use this successfully for patches.
When composing mail select: Preformat
from Format->Heading->Preformatted (Ctrl-7)
from Format->Paragraph Style->Preformatted (Ctrl-7)
or the toolbar
Then use:
......
......@@ -135,7 +135,7 @@ Options with (*) are default options and will not show in the mount options.
a metadata B-tree leaf. The value is specified in bytes, optionally
with a K, M, or G suffix, case insensitive. In practice, this value
is limited by the root sector size, with some space unavailable due
to leaf headers. For a 4k sectorsize, max inline data is ~3900 bytes.
to leaf headers. For a 4k sector size, max inline data is ~3900 bytes.
metadata_ratio=<value>
Specify that 1 metadata chunk should be allocated after every <value>
......@@ -194,7 +194,7 @@ Options with (*) are default options and will not show in the mount options.
ssd_spread
Options to control ssd allocation schemes. By default, BTRFS will
enable or disable ssd allocation heuristics depending on whether a
rotational or nonrotational disk is in use. The ssd and nossd options
rotational or non-rotational disk is in use. The ssd and nossd options
can override this autodetection.
The ssd_spread mount option attempts to allocate into big chunks
......
......@@ -51,6 +51,17 @@ operations should be provided; others can be included as needed. Again,
the return value will be a dentry pointer to the created file, NULL for
error, or ERR_PTR(-ENODEV) if debugfs support is missing.
Create a file with an initial size, the following function can be used
instead:
struct dentry *debugfs_create_file_size(const char *name, umode_t mode,
struct dentry *parent, void *data,
const struct file_operations *fops,
loff_t file_size);
file_size is the initial file size. The other parameters are the same
as the function debugfs_create_file.
In a number of cases, the creation of a set of file operations is not
actually necessary; the debugfs code provides a number of helper functions
for simple situations. Files containing a single integer value can be
......@@ -100,6 +111,14 @@ A read on the resulting file will yield either Y (for non-zero values) or
N, followed by a newline. If written to, it will accept either upper- or
lower-case values, or 1 or 0. Any other input will be silently ignored.
Also, atomic_t values can be placed in debugfs with:
struct dentry *debugfs_create_atomic_t(const char *name, umode_t mode,
struct dentry *parent, atomic_t *value)
A read of this file will get atomic_t values, and a write of this file
will set atomic_t values.
Another option is exporting a block of arbitrary binary data, with
this structure and function:
......@@ -147,6 +166,27 @@ The "base" argument may be 0, but you may want to build the reg32 array
using __stringify, and a number of register names (macros) are actually
byte offsets over a base for the register block.
If you want to dump an u32 array in debugfs, you can create file with:
struct dentry *debugfs_create_u32_array(const char *name, umode_t mode,
struct dentry *parent,
u32 *array, u32 elements);
The "array" argument provides data, and the "elements" argument is
the number of elements in the array. Note: Once array is created its
size can not be changed.
There is a helper function to create device related seq_file:
struct dentry *debugfs_create_devm_seqfile(struct device *dev,
const char *name,
struct dentry *parent,
int (*read_fn)(struct seq_file *s,
void *data));
The "dev" argument is the device related to this debugfs file, and
the "read_fn" is a function pointer which to be called to print the
seq_file content.
There are a couple of other directory-oriented helper functions:
......
......@@ -128,7 +128,7 @@ are:
special place-holders for where the extracted documentation should
go.
- scripts/basic/docproc.c
- scripts/docproc.c
This is a program for converting SGML template files into SGML
files. When a file is referenced it is searched for symbols
......
......@@ -910,6 +910,8 @@ bytes respectively. Such letter suffixes can also be entirely omitted.
Disable PIN 1 of APIC timer
Can be useful to work around chipset bugs.
dis_ucode_ldr [X86] Disable the microcode loader.
dma_debug=off If the kernel is compiled with DMA_API_DEBUG support,
this option disables the debugging code at boot.
......
......@@ -51,8 +51,7 @@ struct demo_client {
*/
static void message_from_remote(struct mbox_client *cl, void *mssg)
{
struct demo_client *dc = container_of(mbox_client,
struct demo_client, cl);
struct demo_client *dc = container_of(cl, struct demo_client, cl);
if (dc->async) {
if (is_an_ack(mssg)) {
/* An ACK to our last sample sent */
......@@ -68,8 +67,7 @@ static void message_from_remote(struct mbox_client *cl, void *mssg)
static void sample_sent(struct mbox_client *cl, void *mssg, int r)
{
struct demo_client *dc = container_of(mbox_client,
struct demo_client, cl);
struct demo_client *dc = container_of(cl, struct demo_client, cl);
complete(&dc->c);
}
......
MEN Chameleon Bus
=================
Table of Contents
=================
1 Introduction
1.1 Scope of this Document
1.2 Limitations of the current implementation
2 Architecture
2.1 MEN Chameleon Bus
2.2 Carrier Devices
2.3 Parser
3 Resource handling
3.1 Memory Resources
3.2 IRQs
4 Writing an MCB driver
4.1 The driver structure
4.2 Probing and attaching
4.3 Initializing the driver
1 Introduction
===============
This document describes the architecture and implementation of the MEN
Chameleon Bus (called MCB throughout this document).
1.1 Scope of this Document
---------------------------
This document is intended to be a short overview of the current
implementation and does by no means describe the complete possibilities of MCB
based devices.
1.2 Limitations of the current implementation
----------------------------------------------
The current implementation is limited to PCI and PCIe based carrier devices
that only use a single memory resource and share the PCI legacy IRQ. Not
implemented are:
- Multi-resource MCB devices like the VME Controller or M-Module carrier.
- MCB devices that need another MCB device, like SRAM for a DMA Controller's
buffer descriptors or a video controller's video memory.
- A per-carrier IRQ domain for carrier devices that have one (or more) IRQs
per MCB device like PCIe based carriers with MSI or MSI-X support.
2 Architecture
===============
MCB is divided into 3 functional blocks:
- The MEN Chameleon Bus itself,
- drivers for MCB Carrier Devices and
- the parser for the Chameleon table.
2.1 MEN Chameleon Bus
----------------------
The MEN Chameleon Bus is an artificial bus system that attaches to a so
called Chameleon FPGA device found on some hardware produced my MEN Mikro
Elektronik GmbH. These devices are multi-function devices implemented in a
single FPGA and usually attached via some sort of PCI or PCIe link. Each
FPGA contains a header section describing the content of the FPGA. The
header lists the device id, PCI BAR, offset from the beginning of the PCI
BAR, size in the FPGA, interrupt number and some other properties currently
not handled by the MCB implementation.
2.2 Carrier Devices
--------------------
A carrier device is just an abstraction for the real world physical bus the
Chameleon FPGA is attached to. Some IP Core drivers may need to interact with
properties of the carrier device (like querying the IRQ number of a PCI
device). To provide abstraction from the real hardware bus, an MCB carrier
device provides callback methods to translate the driver's MCB function calls
to hardware related function calls. For example a carrier device may
implement the get_irq() method which can be translated into a hardware bus
query for the IRQ number the device should use.
2.3 Parser
-----------
The parser reads the first 512 bytes of a Chameleon device and parses the
Chameleon table. Currently the parser only supports the Chameleon v2 variant
of the Chameleon table but can easily be adopted to support an older or
possible future variant. While parsing the table's entries new MCB devices
are allocated and their resources are assigned according to the resource
assignment in the Chameleon table. After resource assignment is finished, the
MCB devices are registered at the MCB and thus at the driver core of the
Linux kernel.
3 Resource handling
====================
The current implementation assigns exactly one memory and one IRQ resource
per MCB device. But this is likely going to change in the future.
3.1 Memory Resources
---------------------
Each MCB device has exactly one memory resource, which can be requested from
the MCB bus. This memory resource is the physical address of the MCB device
inside the carrier and is intended to be passed to ioremap() and friends. It
is already requested from the kernel by calling request_mem_region().
3.2 IRQs
---------
Each MCB device has exactly one IRQ resource, which can be requested from the
MCB bus. If a carrier device driver implements the ->get_irq() callback
method, the IRQ number assigned by the carrier device will be returned,
otherwise the IRQ number inside the Chameleon table will be returned. This
number is suitable to be passed to request_irq().
4 Writing an MCB driver
=======================
4.1 The driver structure
-------------------------
Each MCB driver has a structure to identify the device driver as well as
device ids which identify the IP Core inside the FPGA. The driver structure
also contains callback methods which get executed on driver probe and
removal from the system.
static const struct mcb_device_id foo_ids[] = {
{ .device = 0x123 },
{ }
};
MODULE_DEVICE_TABLE(mcb, foo_ids);
static struct mcb_driver foo_driver = {
driver = {
.name = "foo-bar",
.owner = THIS_MODULE,
},
.probe = foo_probe,
.remove = foo_remove,
.id_table = foo_ids,
};
4.2 Probing and attaching
--------------------------
When a driver is loaded and the MCB devices it services are found, the MCB
core will call the driver's probe callback method. When the driver is removed
from the system, the MCB core will call the driver's remove callback method.
static init foo_probe(struct mcb_device *mdev, const struct mcb_device_id *id);
static void foo_remove(struct mcb_device *mdev);
4.3 Initializing the driver
----------------------------
When the kernel is booted or your foo driver module is inserted, you have to
perform driver initialization. Usually it is enough to register your driver
module at the MCB core.
static int __init foo_init(void)
{
return mcb_register_driver(&foo_driver);
}
module_init(foo_init);
static void __exit foo_exit(void)
{
mcb_unregister_driver(&foo_driver);
}
module_exit(foo_exit);
The module_mcb_driver() macro can be used to reduce the above code.
module_mcb_driver(foo_driver);
......@@ -510,7 +510,7 @@ solution for a couple of reasons:
4.1.2 RAW socket option CAN_RAW_ERR_FILTER
As described in chapter 3.4 the CAN interface driver can generate so
As described in chapter 3.3 the CAN interface driver can generate so
called Error Message Frames that can optionally be passed to the user
application in the same way as other CAN frames. The possible
errors are divided into different error classes that may be filtered
......@@ -1152,7 +1152,7 @@ solution for a couple of reasons:
$ ip link set canX type can restart
Note that a restart will also create a CAN error message frame (see
also chapter 3.4).
also chapter 3.3).
6.6 CAN FD (flexible data rate) driver support
......
......@@ -133,7 +133,7 @@ User API
The following file operations are supported on both slave and
master devices.
A userspace library libcxl is avaliable here:
A userspace library libcxl is available here:
https://github.com/ibm-capi/libcxl
This provides a C interface to this kernel API.
......
......@@ -4,7 +4,7 @@
DSCR register in powerpc allows user to have some control of prefetch of data
stream in the processor. Please refer to the ISA documents or related manual
for more detailed information regarding how to use this DSCR to attain this
control of the pefetches . This document here provides an overview of kernel
control of the prefetches . This document here provides an overview of kernel
support for DSCR, related kernel objects, it's functionalities and exported
user interface.
......@@ -44,7 +44,7 @@ user interface.
value into every CPU's DSCR register right away and updates the current
thread's DSCR value as well.
Changing the CPU specif DSCR default value in the sysfs does exactly
Changing the CPU specific DSCR default value in the sysfs does exactly
the same thing as above but unlike the global one above, it just changes
stuff for that particular CPU instead for all the CPUs on the system.
......@@ -62,7 +62,7 @@ user interface.
Accessing DSCR through user level SPR (0x03) from user space will first
create a facility unavailable exception. Inside this exception handler
all mfspr isntruction based read attempts will get emulated and returned
all mfspr instruction based read attempts will get emulated and returned
where as the first mtspr instruction based write attempts will enable
the DSCR facility for the next time around (both for read and write) by
setting DSCR facility in the FSCR register.
......
......@@ -117,7 +117,7 @@ specific been defined. This table describes the structure.
Extended Modes
This is a double word bit array (64 bits) that defines special functionality
which has an impact on the softwarew drivers. Each bit has its own impact
which has an impact on the software drivers. Each bit has its own impact
and has special instructions for the s/w associated with it. This structure is
described in this table:
......
......@@ -125,7 +125,7 @@ The same function may also run the defined echo function
(pps_ktimer_echo(), passing to it the "ptr" pointer) if the user
asked for that... etc..
Please see the file drivers/pps/clients/ktimer.c for example code.
Please see the file drivers/pps/clients/pps-ktimer.c for example code.
SYSFS support
......
......@@ -225,11 +225,11 @@ with your system. To disable them, echo 4 (bit 3) into drop_caches.
extfrag_threshold
This parameter affects whether the kernel will compact memory or direct
reclaim to satisfy a high-order allocation. /proc/extfrag_index shows what
the fragmentation index for each order is in each zone in the system. Values
tending towards 0 imply allocations would fail due to lack of memory,
values towards 1000 imply failures are due to fragmentation and -1 implies
that the allocation will succeed as long as watermarks are met.
reclaim to satisfy a high-order allocation. The extfrag/extfrag_index file in
debugfs shows what the fragmentation index for each order is in each zone in
the system. Values tending towards 0 imply allocations would fail due to lack
of memory, values towards 1000 imply failures are due to fragmentation and -1
implies that the allocation will succeed as long as watermarks are met.
The kernel will not compact memory in a zone if the
fragmentation index is <= extfrag_threshold. The default value is 500.
......
......@@ -16,7 +16,7 @@ associated with each CPU. These stacks are only used while the kernel
is in control on that CPU; when a CPU returns to user space the
specialized stacks contain no useful data. The main CPU stacks are:
* Interrupt stack. IRQSTACKSIZE
* Interrupt stack. IRQ_STACK_SIZE
Used for external hardware interrupts. If this is the first external
hardware interrupt (i.e. not a nested hardware interrupt) then the
......
......@@ -3454,6 +3454,7 @@ X: Documentation/devicetree/
X: Documentation/acpi
X: Documentation/power
X: Documentation/spi
X: Documentation/DocBook/media
T: git git://git.lwn.net/linux-2.6.git docs-next
DOUBLETALK DRIVER
......@@ -6700,6 +6701,7 @@ M: Johannes Thumshirn <morbidrsa@gmail.com>
S: Maintained
F: drivers/mcb/
F: include/linux/mcb.h
F: Documentation/men-chameleon-bus.txt
MEN F21BMC (Board Management Controller)
M: Andreas Werner <andreas.werner@men.de>
......
......@@ -161,7 +161,7 @@ CONFIGURING the kernel:
"make xconfig" X windows (Qt) based configuration tool.
"make gconfig" X windows (Gtk) based configuration tool.
"make gconfig" X windows (GTK+) based configuration tool.
"make oldconfig" Default all questions based on the contents of
your existing ./.config file and asking about
......
......@@ -133,6 +133,30 @@ use strict;
#
# All descriptions can be multiline, except the short function description.
#
# For really longs structs, you can also describe arguments inside the
# body of the struct.
# eg.
# /**
# * struct my_struct - short description
# * @a: first member
# * @b: second member
# *
# * Longer description
# */
# struct my_struct {
# int a;
# int b;
# /**
# * @c: This is longer description of C
# *
# * You can use paragraphs to describe arguments
# * using this method.
# */
# int c;
# };
#
# This should be use only for struct/enum members.
#
# You can also add additional sections. When documenting kernel functions you
# should document the "Context:" of the function, e.g. whether the functions
# can be called form interrupts. Unlike other sections you can end it with an
......@@ -253,11 +277,20 @@ my %highlights = %highlights_man;
my $blankline = $blankline_man;
my $modulename = "Kernel API";
my $function_only = 0;
my $show_not_found = 0;
my @build_time;
if (defined($ENV{'KBUILD_BUILD_TIMESTAMP'}) &&
(my $seconds = `date -d"${ENV{'KBUILD_BUILD_TIMESTAMP'}}" +%s`) ne '') {
@build_time = gmtime($seconds);
} else {
@build_time = localtime;
}
my $man_date = ('January', 'February', 'March', 'April', 'May', 'June',
'July', 'August', 'September', 'October',
'November', 'December')[(localtime)[4]] .
" " . ((localtime)[5]+1900);
my $show_not_found = 0;
'November', 'December')[$build_time[4]] .
" " . ($build_time[5]+1900);
# Essentially these are globals.
# They probably want to be tidied up, made more localised or something.
......@@ -287,9 +320,19 @@ my $lineprefix="";
# 2 - scanning field start.
# 3 - scanning prototype.
# 4 - documentation block
# 5 - gathering documentation outside main block
my $state;
my $in_doc_sect;
# Split Doc State
# 0 - Invalid (Before start or after finish)
# 1 - Is started (the /** was found inside a struct)
# 2 - The @parameter header was found, start accepting multi paragraph text.
# 3 - Finished (the */ was found)
# 4 - Error - Comment without header was found. Spit a warning as it's not
# proper kernel-doc and ignore the rest.
my $split_doc_state;
#declaration types: can be
# 'function', 'struct', 'union', 'enum', 'typedef'
my $decl_type;
......@@ -304,6 +347,9 @@ my $doc_decl = $doc_com . '(\w+)';
my $doc_sect = $doc_com . '([' . $doc_special . ']?[\w\s]+):(.*)';
my $doc_content = $doc_com_body . '(.*)';
my $doc_block = $doc_com . 'DOC:\s*(.*)?';
my $doc_split_start = '^\s*/\*\*\s*$';
my $doc_split_sect = '\s*\*\s*(@[\w\s]+):(.*)';
my $doc_split_end = '^\s*\*/\s*$';
my %constants;
my %parameterdescs;
......@@ -1753,7 +1799,9 @@ sub dump_struct($$) {
# strip kmemcheck_bitfield_{begin,end}.*;
$members =~ s/kmemcheck_bitfield_.*?;//gos;
# strip attributes
$members =~ s/__attribute__\s*\(\([a-z,_\*\s\(\)]*\)\)//i;
$members =~ s/__aligned\s*\([^;]*\)//gos;
$members =~ s/\s*CRYPTO_MINALIGN_ATTR//gos;
create_parameterlist($members, ';', $file);
check_sections($file, $declaration_name, "struct", $sectcheck, $struct_actual, $nested);
......@@ -2181,6 +2229,7 @@ sub reset_state {
$prototype = "";
$state = 0;
$split_doc_state = 0;
}
sub tracepoint_munge($) {
......@@ -2453,7 +2502,6 @@ sub process_file($) {
}
$section = $newsection;
} elsif (/$doc_end/) {
if (($contents ne "") && ($contents ne "\n")) {
dump_section($file, $section, xml_escape($contents));
$section = $section_default;
......@@ -2494,8 +2542,44 @@ sub process_file($) {
print STDERR "Warning(${file}:$.): bad line: $_";
++$warnings;
}
} elsif ($state == 5) { # scanning for split parameters
# First line (state 1) needs to be a @parameter
if ($split_doc_state == 1 && /$doc_split_sect/o) {
$section = $1;
$contents = $2;
if ($contents ne "") {
while ((substr($contents, 0, 1) eq " ") ||
substr($contents, 0, 1) eq "\t") {
$contents = substr($contents, 1);
}
$contents .= "\n";
}
$split_doc_state = 2;
# Documentation block end */
} elsif (/$doc_split_end/) {
if (($contents ne "") && ($contents ne "\n")) {
dump_section($file, $section, xml_escape($contents));
$section = $section_default;
$contents = "";
}
$state = 3;
$split_doc_state = 0;
# Regular text
} elsif (/$doc_content/) {
if ($split_doc_state == 2) {
$contents .= $1 . "\n";
} elsif ($split_doc_state == 1) {
$split_doc_state = 4;
print STDERR "Warning(${file}:$.): ";
print STDERR "Incorrect use of kernel-doc format: $_";
++$warnings;
}
}
} elsif ($state == 3) { # scanning for function '{' (end of prototype)
if ($decl_type eq 'function') {
if (/$doc_split_start/) {
$state = 5;
$split_doc_state = 1;
} elsif ($decl_type eq 'function') {
process_state3_function($_, $file);
} else {
process_state3_type($_, $file);
......@@ -2587,7 +2671,7 @@ $kernelversion = get_kernel_version();
# generate a sequence of code that will splice in highlighting information
# using the s// operator.
foreach my $pattern (keys %highlights) {
foreach my $pattern (sort keys %highlights) {
# print STDERR "scanning pattern:$pattern, highlight:($highlights{$pattern})\n";
$dohighlight .= "\$contents =~ s:$pattern:$highlights{$pattern}:gs;\n";
}
......
#!/usr/bin/perl -w
use strict;
## Copyright (C) 2015 Intel Corporation ##
# ##
## This software falls under the GNU General Public License. ##
## Please read the COPYING file for more information ##
#
#
# This software reads a XML file and a list of valid interal
# references to replace Docbook tags with links.
#
# The list of "valid internal references" must be one-per-line in the following format:
# API-struct-foo
# API-enum-bar
# API-my-function
#
# The software walks over the XML file looking for xml tags representing possible references
# to the Document. Each reference will be cross checked against the "Valid Internal Reference" list. If
# the referece is found it replaces its content by a <link> tag.
#
# usage:
# kernel-doc-xml-ref -db filename
# xml filename > outputfile
# read arguments
if ($#ARGV != 2) {
usage();
}
#Holds the database filename
my $databasefile;
my @database;
#holds the inputfile
my $inputfile;
my $errors = 0;
my %highlights = (
"<function>(.*?)</function>",
"\"<function>\" . convert_function(\$1, \$line) . \"</function>\"",
"<structname>(.*?)</structname>",
"\"<structname>\" . convert_struct(\$1) . \"</structname>\"",
"<funcdef>(.*?)<function>(.*?)</function></funcdef>",
"\"<funcdef>\" . convert_param(\$1) . \"<function>\$2</function></funcdef>\"",
"<paramdef>(.*?)<parameter>(.*?)</parameter></paramdef>",
"\"<paramdef>\" . convert_param(\$1) . \"<parameter>\$2</parameter></paramdef>\"");
while($ARGV[0] =~ m/^-(.*)/) {
my $cmd = shift @ARGV;
if ($cmd eq "-db") {
$databasefile = shift @ARGV
} else {
usage();
}
}
$inputfile = shift @ARGV;
sub open_database {
open (my $handle, '<', $databasefile) or die "Cannot open $databasefile";
chomp(my @lines = <$handle>);
close $handle;
@database = @lines;
}
sub process_file {
open_database();
my $dohighlight;
foreach my $pattern (keys %highlights) {
$dohighlight .= "\$line =~ s:$pattern:$highlights{$pattern}:eg;\n";
}
open(FILE, $inputfile) or die("Could not open $inputfile") or die ("Cannot open $inputfile");
foreach my $line (<FILE>) {
eval $dohighlight;
print $line;
}
}
sub trim($_)
{
my $str = $_[0];
$str =~ s/^\s+|\s+$//g;
return $str
}
sub has_key_defined($_)
{
if ( grep( /^$_[0]$/, @database)) {
return 1;
}
return 0;
}
# Gets a <function> content and add it a hyperlink if possible.
sub convert_function($_)
{
my $arg = $_[0];
my $key = $_[0];
my $line = $_[1];
$key = trim($key);
$key =~ s/[^A-Za-z0-9]/-/g;
$key = "API-" . $key;
# We shouldn't add links to <funcdef> prototype
if (!has_key_defined($key) || $line =~ m/\s+<funcdef/i) {
return $arg;
}
my $head = $arg;
my $tail = "";
if ($arg =~ /(.*?)( ?)$/) {
$head = $1;
$tail = $2;
}
return "<link linkend=\"$key\">$head</link>$tail";
}
# Converting a struct text to link
sub convert_struct($_)
{
my $arg = $_[0];
my $key = $_[0];
$key =~ s/(struct )?(\w)/$2/g;
$key =~ s/[^A-Za-z0-9]/-/g;
$key = "API-struct-" . $key;
if (!has_key_defined($key)) {
return $arg;
}
my ($head, $tail) = split_pointer($arg);
return "<link linkend=\"$key\">$head</link>$tail";
}
# Identify "object *" elements
sub split_pointer($_)
{
my $arg = $_[0];
if ($arg =~ /(.*?)( ?\* ?)/) {
return ($1, $2);
}
return ($arg, "");
}
sub convert_param($_)
{
my $type = $_[0];
my $keyname = convert_key_name($type);
if (!has_key_defined($keyname)) {
return $type;
}
my ($head, $tail) = split_pointer($type);
return "<link linkend=\"$keyname\">$head</link>$tail";
}
# DocBook links are in the API-<TYPE>-<STRUCT-NAME> format
# This method gets an element and returns a valid DocBook reference for it.
sub convert_key_name($_)
{
#Pattern $2 is optional and might be uninitialized
no warnings 'uninitialized';
my $str = $_[0];
$str =~ s/(const|static)? ?(struct)? ?([a-zA-Z0-9_]+) ?(\*|&)?/$2 $3/g ;
# trim
$str =~ s/^\s+|\s+$//g;
# spaces and _ to -
$str =~ s/[^A-Za-z0-9]/-/g;
return "API-" . $str;
}
sub usage {
print "Usage: $0 -db database filename\n";
print " xml source file(s) > outputfile\n";
exit 1;
}
# starting point
process_file();
if ($errors) {
print STDERR "$errors errors\n";
}
exit($errors);
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