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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-05-06 01:02:30 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2024-05-06 01:02:30 +0000
commit76cb841cb886eef6b3bee341a2266c76578724ad (patch)
treef5892e5ba6cc11949952a6ce4ecbe6d516d6ce58 /Documentation/powerpc
parentInitial commit. (diff)
downloadlinux-76cb841cb886eef6b3bee341a2266c76578724ad.tar.xz
linux-76cb841cb886eef6b3bee341a2266c76578724ad.zip
Adding upstream version 4.19.249.upstream/4.19.249
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'Documentation/powerpc')
-rw-r--r--Documentation/powerpc/00-INDEX34
-rw-r--r--Documentation/powerpc/DAWR-POWER9.txt58
-rw-r--r--Documentation/powerpc/bootwrapper.txt141
-rw-r--r--Documentation/powerpc/cpu_families.txt221
-rw-r--r--Documentation/powerpc/cpu_features.txt56
-rw-r--r--Documentation/powerpc/cxl.txt449
-rw-r--r--Documentation/powerpc/cxlflash.txt429
-rw-r--r--Documentation/powerpc/dscr.txt83
-rw-r--r--Documentation/powerpc/eeh-pci-error-recovery.txt334
-rw-r--r--Documentation/powerpc/firmware-assisted-dump.txt277
-rw-r--r--Documentation/powerpc/hvcs.txt567
-rw-r--r--Documentation/powerpc/mpc52xx.txt39
-rw-r--r--Documentation/powerpc/pci_iov_resource_on_powernv.txt301
-rw-r--r--Documentation/powerpc/pmu-ebb.txt137
-rw-r--r--Documentation/powerpc/ptrace.txt151
-rw-r--r--Documentation/powerpc/qe_firmware.txt295
-rw-r--r--Documentation/powerpc/syscall64-abi.txt105
-rw-r--r--Documentation/powerpc/transactional_memory.txt244
18 files changed, 3921 insertions, 0 deletions
diff --git a/Documentation/powerpc/00-INDEX b/Documentation/powerpc/00-INDEX
new file mode 100644
index 000000000..9dc845cf7
--- /dev/null
+++ b/Documentation/powerpc/00-INDEX
@@ -0,0 +1,34 @@
+Index of files in Documentation/powerpc. If you think something about
+Linux/PPC needs an entry here, needs correction or you've written one
+please mail me.
+ Cort Dougan (cort@fsmlabs.com)
+
+00-INDEX
+ - this file
+bootwrapper.txt
+ - Information on how the powerpc kernel is wrapped for boot on various
+ different platforms.
+cpu_features.txt
+ - info on how we support a variety of CPUs with minimal compile-time
+ options.
+cxl.txt
+ - Overview of the CXL driver.
+eeh-pci-error-recovery.txt
+ - info on PCI Bus EEH Error Recovery
+firmware-assisted-dump.txt
+ - Documentation on the firmware assisted dump mechanism "fadump".
+hvcs.txt
+ - IBM "Hypervisor Virtual Console Server" Installation Guide
+mpc52xx.txt
+ - Linux 2.6.x on MPC52xx family
+pmu-ebb.txt
+ - Description of the API for using the PMU with Event Based Branches.
+qe_firmware.txt
+ - describes the layout of firmware binaries for the Freescale QUICC
+ Engine and the code that parses and uploads the microcode therein.
+ptrace.txt
+ - Information on the ptrace interfaces for hardware debug registers.
+transactional_memory.txt
+ - Overview of the Power8 transactional memory support.
+dscr.txt
+ - Overview DSCR (Data Stream Control Register) support.
diff --git a/Documentation/powerpc/DAWR-POWER9.txt b/Documentation/powerpc/DAWR-POWER9.txt
new file mode 100644
index 000000000..2feaa6619
--- /dev/null
+++ b/Documentation/powerpc/DAWR-POWER9.txt
@@ -0,0 +1,58 @@
+DAWR issues on POWER9
+============================
+
+On POWER9 the DAWR can cause a checkstop if it points to cache
+inhibited (CI) memory. Currently Linux has no way to disinguish CI
+memory when configuring the DAWR, so (for now) the DAWR is disabled by
+this commit:
+
+ commit 9654153158d3e0684a1bdb76dbababdb7111d5a0
+ Author: Michael Neuling <mikey@neuling.org>
+ Date: Tue Mar 27 15:37:24 2018 +1100
+ powerpc: Disable DAWR in the base POWER9 CPU features
+
+Technical Details:
+============================
+
+DAWR has 6 different ways of being set.
+1) ptrace
+2) h_set_mode(DAWR)
+3) h_set_dabr()
+4) kvmppc_set_one_reg()
+5) xmon
+
+For ptrace, we now advertise zero breakpoints on POWER9 via the
+PPC_PTRACE_GETHWDBGINFO call. This results in GDB falling back to
+software emulation of the watchpoint (which is slow).
+
+h_set_mode(DAWR) and h_set_dabr() will now return an error to the
+guest on a POWER9 host. Current Linux guests ignore this error, so
+they will silently not get the DAWR.
+
+kvmppc_set_one_reg() will store the value in the vcpu but won't
+actually set it on POWER9 hardware. This is done so we don't break
+migration from POWER8 to POWER9, at the cost of silently losing the
+DAWR on the migration.
+
+For xmon, the 'bd' command will return an error on P9.
+
+Consequences for users
+============================
+
+For GDB watchpoints (ie 'watch' command) on POWER9 bare metal , GDB
+will accept the command. Unfortunately since there is no hardware
+support for the watchpoint, GDB will software emulate the watchpoint
+making it run very slowly.
+
+The same will also be true for any guests started on a POWER9
+host. The watchpoint will fail and GDB will fall back to software
+emulation.
+
+If a guest is started on a POWER8 host, GDB will accept the watchpoint
+and configure the hardware to use the DAWR. This will run at full
+speed since it can use the hardware emulation. Unfortunately if this
+guest is migrated to a POWER9 host, the watchpoint will be lost on the
+POWER9. Loads and stores to the watchpoint locations will not be
+trapped in GDB. The watchpoint is remembered, so if the guest is
+migrated back to the POWER8 host, it will start working again.
+
diff --git a/Documentation/powerpc/bootwrapper.txt b/Documentation/powerpc/bootwrapper.txt
new file mode 100644
index 000000000..d60fced5e
--- /dev/null
+++ b/Documentation/powerpc/bootwrapper.txt
@@ -0,0 +1,141 @@
+The PowerPC boot wrapper
+------------------------
+Copyright (C) Secret Lab Technologies Ltd.
+
+PowerPC image targets compresses and wraps the kernel image (vmlinux) with
+a boot wrapper to make it usable by the system firmware. There is no
+standard PowerPC firmware interface, so the boot wrapper is designed to
+be adaptable for each kind of image that needs to be built.
+
+The boot wrapper can be found in the arch/powerpc/boot/ directory. The
+Makefile in that directory has targets for all the available image types.
+The different image types are used to support all of the various firmware
+interfaces found on PowerPC platforms. OpenFirmware is the most commonly
+used firmware type on general purpose PowerPC systems from Apple, IBM and
+others. U-Boot is typically found on embedded PowerPC hardware, but there
+are a handful of other firmware implementations which are also popular. Each
+firmware interface requires a different image format.
+
+The boot wrapper is built from the makefile in arch/powerpc/boot/Makefile and
+it uses the wrapper script (arch/powerpc/boot/wrapper) to generate target
+image. The details of the build system is discussed in the next section.
+Currently, the following image format targets exist:
+
+ cuImage.%: Backwards compatible uImage for older version of
+ U-Boot (for versions that don't understand the device
+ tree). This image embeds a device tree blob inside
+ the image. The boot wrapper, kernel and device tree
+ are all embedded inside the U-Boot uImage file format
+ with boot wrapper code that extracts data from the old
+ bd_info structure and loads the data into the device
+ tree before jumping into the kernel.
+ Because of the series of #ifdefs found in the
+ bd_info structure used in the old U-Boot interfaces,
+ cuImages are platform specific. Each specific
+ U-Boot platform has a different platform init file
+ which populates the embedded device tree with data
+ from the platform specific bd_info file. The platform
+ specific cuImage platform init code can be found in
+ arch/powerpc/boot/cuboot.*.c. Selection of the correct
+ cuImage init code for a specific board can be found in
+ the wrapper structure.
+ dtbImage.%: Similar to zImage, except device tree blob is embedded
+ inside the image instead of provided by firmware. The
+ output image file can be either an elf file or a flat
+ binary depending on the platform.
+ dtbImages are used on systems which do not have an
+ interface for passing a device tree directly.
+ dtbImages are similar to simpleImages except that
+ dtbImages have platform specific code for extracting
+ data from the board firmware, but simpleImages do not
+ talk to the firmware at all.
+ PlayStation 3 support uses dtbImage. So do Embedded
+ Planet boards using the PlanetCore firmware. Board
+ specific initialization code is typically found in a
+ file named arch/powerpc/boot/<platform>.c; but this
+ can be overridden by the wrapper script.
+ simpleImage.%: Firmware independent compressed image that does not
+ depend on any particular firmware interface and embeds
+ a device tree blob. This image is a flat binary that
+ can be loaded to any location in RAM and jumped to.
+ Firmware cannot pass any configuration data to the
+ kernel with this image type and it depends entirely on
+ the embedded device tree for all information.
+ The simpleImage is useful for booting systems with
+ an unknown firmware interface or for booting from
+ a debugger when no firmware is present (such as on
+ the Xilinx Virtex platform). The only assumption that
+ simpleImage makes is that RAM is correctly initialized
+ and that the MMU is either off or has RAM mapped to
+ base address 0.
+ simpleImage also supports inserting special platform
+ specific initialization code to the start of the bootup
+ sequence. The virtex405 platform uses this feature to
+ ensure that the cache is invalidated before caching
+ is enabled. Platform specific initialization code is
+ added as part of the wrapper script and is keyed on
+ the image target name. For example, all
+ simpleImage.virtex405-* targets will add the
+ virtex405-head.S initialization code (This also means
+ that the dts file for virtex405 targets should be
+ named (virtex405-<board>.dts). Search the wrapper
+ script for 'virtex405' and see the file
+ arch/powerpc/boot/virtex405-head.S for details.
+ treeImage.%; Image format for used with OpenBIOS firmware found
+ on some ppc4xx hardware. This image embeds a device
+ tree blob inside the image.
+ uImage: Native image format used by U-Boot. The uImage target
+ does not add any boot code. It just wraps a compressed
+ vmlinux in the uImage data structure. This image
+ requires a version of U-Boot that is able to pass
+ a device tree to the kernel at boot. If using an older
+ version of U-Boot, then you need to use a cuImage
+ instead.
+ zImage.%: Image format which does not embed a device tree.
+ Used by OpenFirmware and other firmware interfaces
+ which are able to supply a device tree. This image
+ expects firmware to provide the device tree at boot.
+ Typically, if you have general purpose PowerPC
+ hardware then you want this image format.
+
+Image types which embed a device tree blob (simpleImage, dtbImage, treeImage,
+and cuImage) all generate the device tree blob from a file in the
+arch/powerpc/boot/dts/ directory. The Makefile selects the correct device
+tree source based on the name of the target. Therefore, if the kernel is
+built with 'make treeImage.walnut simpleImage.virtex405-ml403', then the
+build system will use arch/powerpc/boot/dts/walnut.dts to build
+treeImage.walnut and arch/powerpc/boot/dts/virtex405-ml403.dts to build
+the simpleImage.virtex405-ml403.
+
+Two special targets called 'zImage' and 'zImage.initrd' also exist. These
+targets build all the default images as selected by the kernel configuration.
+Default images are selected by the boot wrapper Makefile
+(arch/powerpc/boot/Makefile) by adding targets to the $image-y variable. Look
+at the Makefile to see which default image targets are available.
+
+How it is built
+---------------
+arch/powerpc is designed to support multiplatform kernels, which means
+that a single vmlinux image can be booted on many different target boards.
+It also means that the boot wrapper must be able to wrap for many kinds of
+images on a single build. The design decision was made to not use any
+conditional compilation code (#ifdef, etc) in the boot wrapper source code.
+All of the boot wrapper pieces are buildable at any time regardless of the
+kernel configuration. Building all the wrapper bits on every kernel build
+also ensures that obscure parts of the wrapper are at the very least compile
+tested in a large variety of environments.
+
+The wrapper is adapted for different image types at link time by linking in
+just the wrapper bits that are appropriate for the image type. The 'wrapper
+script' (found in arch/powerpc/boot/wrapper) is called by the Makefile and
+is responsible for selecting the correct wrapper bits for the image type.
+The arguments are well documented in the script's comment block, so they
+are not repeated here. However, it is worth mentioning that the script
+uses the -p (platform) argument as the main method of deciding which wrapper
+bits to compile in. Look for the large 'case "$platform" in' block in the
+middle of the script. This is also the place where platform specific fixups
+can be selected by changing the link order.
+
+In particular, care should be taken when working with cuImages. cuImage
+wrapper bits are very board specific and care should be taken to make sure
+the target you are trying to build is supported by the wrapper bits.
diff --git a/Documentation/powerpc/cpu_families.txt b/Documentation/powerpc/cpu_families.txt
new file mode 100644
index 000000000..fc08e22fe
--- /dev/null
+++ b/Documentation/powerpc/cpu_families.txt
@@ -0,0 +1,221 @@
+CPU Families
+============
+
+This document tries to summarise some of the different cpu families that exist
+and are supported by arch/powerpc.
+
+
+Book3S (aka sPAPR)
+------------------
+
+ - Hash MMU
+ - Mix of 32 & 64 bit
+
+ +--------------+ +----------------+
+ | Old POWER | --------------> | RS64 (threads) |
+ +--------------+ +----------------+
+ |
+ |
+ v
+ +--------------+ +----------------+ +------+
+ | 601 | --------------> | 603 | ---> | e300 |
+ +--------------+ +----------------+ +------+
+ | |
+ | |
+ v v
+ +--------------+ +----------------+ +-------+
+ | 604 | | 750 (G3) | ---> | 750CX |
+ +--------------+ +----------------+ +-------+
+ | | |
+ | | |
+ v v v
+ +--------------+ +----------------+ +-------+
+ | 620 (64 bit) | | 7400 | | 750CL |
+ +--------------+ +----------------+ +-------+
+ | | |
+ | | |
+ v v v
+ +--------------+ +----------------+ +-------+
+ | POWER3/630 | | 7410 | | 750FX |
+ +--------------+ +----------------+ +-------+
+ | |
+ | |
+ v v
+ +--------------+ +----------------+
+ | POWER3+ | | 7450 |
+ +--------------+ +----------------+
+ | |
+ | |
+ v v
+ +--------------+ +----------------+
+ | POWER4 | | 7455 |
+ +--------------+ +----------------+
+ | |
+ | |
+ v v
+ +--------------+ +-------+ +----------------+
+ | POWER4+ | --> | 970 | | 7447 |
+ +--------------+ +-------+ +----------------+
+ | | |
+ | | |
+ v v v
+ +--------------+ +-------+ +----------------+
+ | POWER5 | | 970FX | | 7448 |
+ +--------------+ +-------+ +----------------+
+ | | |
+ | | |
+ v v v
+ +--------------+ +-------+ +----------------+
+ | POWER5+ | | 970MP | | e600 |
+ +--------------+ +-------+ +----------------+
+ |
+ |
+ v
+ +--------------+
+ | POWER5++ |
+ +--------------+
+ |
+ |
+ v
+ +--------------+ +-------+
+ | POWER6 | <-?-> | Cell |
+ +--------------+ +-------+
+ |
+ |
+ v
+ +--------------+
+ | POWER7 |
+ +--------------+
+ |
+ |
+ v
+ +--------------+
+ | POWER7+ |
+ +--------------+
+ |
+ |
+ v
+ +--------------+
+ | POWER8 |
+ +--------------+
+
+
+ +---------------+
+ | PA6T (64 bit) |
+ +---------------+
+
+
+IBM BookE
+---------
+
+ - Software loaded TLB.
+ - All 32 bit
+
+ +--------------+
+ | 401 |
+ +--------------+
+ |
+ |
+ v
+ +--------------+
+ | 403 |
+ +--------------+
+ |
+ |
+ v
+ +--------------+
+ | 405 |
+ +--------------+
+ |
+ |
+ v
+ +--------------+
+ | 440 |
+ +--------------+
+ |
+ |
+ v
+ +--------------+ +----------------+
+ | 450 | --> | BG/P |
+ +--------------+ +----------------+
+ |
+ |
+ v
+ +--------------+
+ | 460 |
+ +--------------+
+ |
+ |
+ v
+ +--------------+
+ | 476 |
+ +--------------+
+
+
+Motorola/Freescale 8xx
+----------------------
+
+ - Software loaded with hardware assist.
+ - All 32 bit
+
+ +-------------+
+ | MPC8xx Core |
+ +-------------+
+
+
+Freescale BookE
+---------------
+
+ - Software loaded TLB.
+ - e6500 adds HW loaded indirect TLB entries.
+ - Mix of 32 & 64 bit
+
+ +--------------+
+ | e200 |
+ +--------------+
+
+
+ +--------------------------------+
+ | e500 |
+ +--------------------------------+
+ |
+ |
+ v
+ +--------------------------------+
+ | e500v2 |
+ +--------------------------------+
+ |
+ |
+ v
+ +--------------------------------+
+ | e500mc (Book3e) |
+ +--------------------------------+
+ |
+ |
+ v
+ +--------------------------------+
+ | e5500 (64 bit) |
+ +--------------------------------+
+ |
+ |
+ v
+ +--------------------------------+
+ | e6500 (HW TLB) (Multithreaded) |
+ +--------------------------------+
+
+
+IBM A2 core
+-----------
+
+ - Book3E, software loaded TLB + HW loaded indirect TLB entries.
+ - 64 bit
+
+ +--------------+ +----------------+
+ | A2 core | --> | WSP |
+ +--------------+ +----------------+
+ |
+ |
+ v
+ +--------------+
+ | BG/Q |
+ +--------------+
diff --git a/Documentation/powerpc/cpu_features.txt b/Documentation/powerpc/cpu_features.txt
new file mode 100644
index 000000000..ae09df872
--- /dev/null
+++ b/Documentation/powerpc/cpu_features.txt
@@ -0,0 +1,56 @@
+Hollis Blanchard <hollis@austin.ibm.com>
+5 Jun 2002
+
+This document describes the system (including self-modifying code) used in the
+PPC Linux kernel to support a variety of PowerPC CPUs without requiring
+compile-time selection.
+
+Early in the boot process the ppc32 kernel detects the current CPU type and
+chooses a set of features accordingly. Some examples include Altivec support,
+split instruction and data caches, and if the CPU supports the DOZE and NAP
+sleep modes.
+
+Detection of the feature set is simple. A list of processors can be found in
+arch/powerpc/kernel/cputable.c. The PVR register is masked and compared with
+each value in the list. If a match is found, the cpu_features of cur_cpu_spec
+is assigned to the feature bitmask for this processor and a __setup_cpu
+function is called.
+
+C code may test 'cur_cpu_spec[smp_processor_id()]->cpu_features' for a
+particular feature bit. This is done in quite a few places, for example
+in ppc_setup_l2cr().
+
+Implementing cpufeatures in assembly is a little more involved. There are
+several paths that are performance-critical and would suffer if an array
+index, structure dereference, and conditional branch were added. To avoid the
+performance penalty but still allow for runtime (rather than compile-time) CPU
+selection, unused code is replaced by 'nop' instructions. This nop'ing is
+based on CPU 0's capabilities, so a multi-processor system with non-identical
+processors will not work (but such a system would likely have other problems
+anyways).
+
+After detecting the processor type, the kernel patches out sections of code
+that shouldn't be used by writing nop's over it. Using cpufeatures requires
+just 2 macros (found in arch/powerpc/include/asm/cputable.h), as seen in head.S
+transfer_to_handler:
+
+ #ifdef CONFIG_ALTIVEC
+ BEGIN_FTR_SECTION
+ mfspr r22,SPRN_VRSAVE /* if G4, save vrsave register value */
+ stw r22,THREAD_VRSAVE(r23)
+ END_FTR_SECTION_IFSET(CPU_FTR_ALTIVEC)
+ #endif /* CONFIG_ALTIVEC */
+
+If CPU 0 supports Altivec, the code is left untouched. If it doesn't, both
+instructions are replaced with nop's.
+
+The END_FTR_SECTION macro has two simpler variations: END_FTR_SECTION_IFSET
+and END_FTR_SECTION_IFCLR. These simply test if a flag is set (in
+cur_cpu_spec[0]->cpu_features) or is cleared, respectively. These two macros
+should be used in the majority of cases.
+
+The END_FTR_SECTION macros are implemented by storing information about this
+code in the '__ftr_fixup' ELF section. When do_cpu_ftr_fixups
+(arch/powerpc/kernel/misc.S) is invoked, it will iterate over the records in
+__ftr_fixup, and if the required feature is not present it will loop writing
+nop's from each BEGIN_FTR_SECTION to END_FTR_SECTION.
diff --git a/Documentation/powerpc/cxl.txt b/Documentation/powerpc/cxl.txt
new file mode 100644
index 000000000..c5e8d5098
--- /dev/null
+++ b/Documentation/powerpc/cxl.txt
@@ -0,0 +1,449 @@
+Coherent Accelerator Interface (CXL)
+====================================
+
+Introduction
+============
+
+ The coherent accelerator interface is designed to allow the
+ coherent connection of accelerators (FPGAs and other devices) to a
+ POWER system. These devices need to adhere to the Coherent
+ Accelerator Interface Architecture (CAIA).
+
+ IBM refers to this as the Coherent Accelerator Processor Interface
+ or CAPI. In the kernel it's referred to by the name CXL to avoid
+ confusion with the ISDN CAPI subsystem.
+
+ Coherent in this context means that the accelerator and CPUs can
+ both access system memory directly and with the same effective
+ addresses.
+
+
+Hardware overview
+=================
+
+ POWER8/9 FPGA
+ +----------+ +---------+
+ | | | |
+ | CPU | | AFU |
+ | | | |
+ | | | |
+ | | | |
+ +----------+ +---------+
+ | PHB | | |
+ | +------+ | PSL |
+ | | CAPP |<------>| |
+ +---+------+ PCIE +---------+
+
+ The POWER8/9 chip has a Coherently Attached Processor Proxy (CAPP)
+ unit which is part of the PCIe Host Bridge (PHB). This is managed
+ by Linux by calls into OPAL. Linux doesn't directly program the
+ CAPP.
+
+ The FPGA (or coherently attached device) consists of two parts.
+ The POWER Service Layer (PSL) and the Accelerator Function Unit
+ (AFU). The AFU is used to implement specific functionality behind
+ the PSL. The PSL, among other things, provides memory address
+ translation services to allow each AFU direct access to userspace
+ memory.
+
+ The AFU is the core part of the accelerator (eg. the compression,
+ crypto etc function). The kernel has no knowledge of the function
+ of the AFU. Only userspace interacts directly with the AFU.
+
+ The PSL provides the translation and interrupt services that the
+ AFU needs. This is what the kernel interacts with. For example, if
+ the AFU needs to read a particular effective address, it sends
+ that address to the PSL, the PSL then translates it, fetches the
+ data from memory and returns it to the AFU. If the PSL has a
+ translation miss, it interrupts the kernel and the kernel services
+ the fault. The context to which this fault is serviced is based on
+ who owns that acceleration function.
+
+ POWER8 <-----> PSL Version 8 is compliant to the CAIA Version 1.0.
+ POWER9 <-----> PSL Version 9 is compliant to the CAIA Version 2.0.
+ This PSL Version 9 provides new features such as:
+ * Interaction with the nest MMU on the P9 chip.
+ * Native DMA support.
+ * Supports sending ASB_Notify messages for host thread wakeup.
+ * Supports Atomic operations.
+ * ....
+
+ Cards with a PSL9 won't work on a POWER8 system and cards with a
+ PSL8 won't work on a POWER9 system.
+
+AFU Modes
+=========
+
+ There are two programming modes supported by the AFU. Dedicated
+ and AFU directed. AFU may support one or both modes.
+
+ When using dedicated mode only one MMU context is supported. In
+ this mode, only one userspace process can use the accelerator at
+ time.
+
+ When using AFU directed mode, up to 16K simultaneous contexts can
+ be supported. This means up to 16K simultaneous userspace
+ applications may use the accelerator (although specific AFUs may
+ support fewer). In this mode, the AFU sends a 16 bit context ID
+ with each of its requests. This tells the PSL which context is
+ associated with each operation. If the PSL can't translate an
+ operation, the ID can also be accessed by the kernel so it can
+ determine the userspace context associated with an operation.
+
+
+MMIO space
+==========
+
+ A portion of the accelerator MMIO space can be directly mapped
+ from the AFU to userspace. Either the whole space can be mapped or
+ just a per context portion. The hardware is self describing, hence
+ the kernel can determine the offset and size of the per context
+ portion.
+
+
+Interrupts
+==========
+
+ AFUs may generate interrupts that are destined for userspace. These
+ are received by the kernel as hardware interrupts and passed onto
+ userspace by a read syscall documented below.
+
+ Data storage faults and error interrupts are handled by the kernel
+ driver.
+
+
+Work Element Descriptor (WED)
+=============================
+
+ The WED is a 64-bit parameter passed to the AFU when a context is
+ started. Its format is up to the AFU hence the kernel has no
+ knowledge of what it represents. Typically it will be the
+ effective address of a work queue or status block where the AFU
+ and userspace can share control and status information.
+
+
+
+
+User API
+========
+
+1. AFU character devices
+
+ For AFUs operating in AFU directed mode, two character device
+ files will be created. /dev/cxl/afu0.0m will correspond to a
+ master context and /dev/cxl/afu0.0s will correspond to a slave
+ context. Master contexts have access to the full MMIO space an
+ AFU provides. Slave contexts have access to only the per process
+ MMIO space an AFU provides.
+
+ For AFUs operating in dedicated process mode, the driver will
+ only create a single character device per AFU called
+ /dev/cxl/afu0.0d. This will have access to the entire MMIO space
+ that the AFU provides (like master contexts in AFU directed).
+
+ The types described below are defined in include/uapi/misc/cxl.h
+
+ The following file operations are supported on both slave and
+ master devices.
+
+ A userspace library libcxl is available here:
+ https://github.com/ibm-capi/libcxl
+ This provides a C interface to this kernel API.
+
+open
+----
+
+ Opens the device and allocates a file descriptor to be used with
+ the rest of the API.
+
+ A dedicated mode AFU only has one context and only allows the
+ device to be opened once.
+
+ An AFU directed mode AFU can have many contexts, the device can be
+ opened once for each context that is available.
+
+ When all available contexts are allocated the open call will fail
+ and return -ENOSPC.
+
+ Note: IRQs need to be allocated for each context, which may limit
+ the number of contexts that can be created, and therefore
+ how many times the device can be opened. The POWER8 CAPP
+ supports 2040 IRQs and 3 are used by the kernel, so 2037 are
+ left. If 1 IRQ is needed per context, then only 2037
+ contexts can be allocated. If 4 IRQs are needed per context,
+ then only 2037/4 = 509 contexts can be allocated.
+
+
+ioctl
+-----
+
+ CXL_IOCTL_START_WORK:
+ Starts the AFU context and associates it with the current
+ process. Once this ioctl is successfully executed, all memory
+ mapped into this process is accessible to this AFU context
+ using the same effective addresses. No additional calls are
+ required to map/unmap memory. The AFU memory context will be
+ updated as userspace allocates and frees memory. This ioctl
+ returns once the AFU context is started.
+
+ Takes a pointer to a struct cxl_ioctl_start_work:
+
+ struct cxl_ioctl_start_work {
+ __u64 flags;
+ __u64 work_element_descriptor;
+ __u64 amr;
+ __s16 num_interrupts;
+ __s16 reserved1;
+ __s32 reserved2;
+ __u64 reserved3;
+ __u64 reserved4;
+ __u64 reserved5;
+ __u64 reserved6;
+ };
+
+ flags:
+ Indicates which optional fields in the structure are
+ valid.
+
+ work_element_descriptor:
+ The Work Element Descriptor (WED) is a 64-bit argument
+ defined by the AFU. Typically this is an effective
+ address pointing to an AFU specific structure
+ describing what work to perform.
+
+ amr:
+ Authority Mask Register (AMR), same as the powerpc
+ AMR. This field is only used by the kernel when the
+ corresponding CXL_START_WORK_AMR value is specified in
+ flags. If not specified the kernel will use a default
+ value of 0.
+
+ num_interrupts:
+ Number of userspace interrupts to request. This field
+ is only used by the kernel when the corresponding
+ CXL_START_WORK_NUM_IRQS value is specified in flags.
+ If not specified the minimum number required by the
+ AFU will be allocated. The min and max number can be
+ obtained from sysfs.
+
+ reserved fields:
+ For ABI padding and future extensions
+
+ CXL_IOCTL_GET_PROCESS_ELEMENT:
+ Get the current context id, also known as the process element.
+ The value is returned from the kernel as a __u32.
+
+
+mmap
+----
+
+ An AFU may have an MMIO space to facilitate communication with the
+ AFU. If it does, the MMIO space can be accessed via mmap. The size
+ and contents of this area are specific to the particular AFU. The
+ size can be discovered via sysfs.
+
+ In AFU directed mode, master contexts are allowed to map all of
+ the MMIO space and slave contexts are allowed to only map the per
+ process MMIO space associated with the context. In dedicated
+ process mode the entire MMIO space can always be mapped.
+
+ This mmap call must be done after the START_WORK ioctl.
+
+ Care should be taken when accessing MMIO space. Only 32 and 64-bit
+ accesses are supported by POWER8. Also, the AFU will be designed
+ with a specific endianness, so all MMIO accesses should consider
+ endianness (recommend endian(3) variants like: le64toh(),
+ be64toh() etc). These endian issues equally apply to shared memory
+ queues the WED may describe.
+
+
+read
+----
+
+ Reads events from the AFU. Blocks if no events are pending
+ (unless O_NONBLOCK is supplied). Returns -EIO in the case of an
+ unrecoverable error or if the card is removed.
+
+ read() will always return an integral number of events.
+
+ The buffer passed to read() must be at least 4K bytes.
+
+ The result of the read will be a buffer of one or more events,
+ each event is of type struct cxl_event, of varying size.
+
+ struct cxl_event {
+ struct cxl_event_header header;
+ union {
+ struct cxl_event_afu_interrupt irq;
+ struct cxl_event_data_storage fault;
+ struct cxl_event_afu_error afu_error;
+ };
+ };
+
+ The struct cxl_event_header is defined as:
+
+ struct cxl_event_header {
+ __u16 type;
+ __u16 size;
+ __u16 process_element;
+ __u16 reserved1;
+ };
+
+ type:
+ This defines the type of event. The type determines how
+ the rest of the event is structured. These types are
+ described below and defined by enum cxl_event_type.
+
+ size:
+ This is the size of the event in bytes including the
+ struct cxl_event_header. The start of the next event can
+ be found at this offset from the start of the current
+ event.
+
+ process_element:
+ Context ID of the event.
+
+ reserved field:
+ For future extensions and padding.
+
+ If the event type is CXL_EVENT_AFU_INTERRUPT then the event
+ structure is defined as:
+
+ struct cxl_event_afu_interrupt {
+ __u16 flags;
+ __u16 irq; /* Raised AFU interrupt number */
+ __u32 reserved1;
+ };
+
+ flags:
+ These flags indicate which optional fields are present
+ in this struct. Currently all fields are mandatory.
+
+ irq:
+ The IRQ number sent by the AFU.
+
+ reserved field:
+ For future extensions and padding.
+
+ If the event type is CXL_EVENT_DATA_STORAGE then the event
+ structure is defined as:
+
+ struct cxl_event_data_storage {
+ __u16 flags;
+ __u16 reserved1;
+ __u32 reserved2;
+ __u64 addr;
+ __u64 dsisr;
+ __u64 reserved3;
+ };
+
+ flags:
+ These flags indicate which optional fields are present in
+ this struct. Currently all fields are mandatory.
+
+ address:
+ The address that the AFU unsuccessfully attempted to
+ access. Valid accesses will be handled transparently by the
+ kernel but invalid accesses will generate this event.
+
+ dsisr:
+ This field gives information on the type of fault. It is a
+ copy of the DSISR from the PSL hardware when the address
+ fault occurred. The form of the DSISR is as defined in the
+ CAIA.
+
+ reserved fields:
+ For future extensions
+
+ If the event type is CXL_EVENT_AFU_ERROR then the event structure
+ is defined as:
+
+ struct cxl_event_afu_error {
+ __u16 flags;
+ __u16 reserved1;
+ __u32 reserved2;
+ __u64 error;
+ };
+
+ flags:
+ These flags indicate which optional fields are present in
+ this struct. Currently all fields are Mandatory.
+
+ error:
+ Error status from the AFU. Defined by the AFU.
+
+ reserved fields:
+ For future extensions and padding
+
+
+2. Card character device (powerVM guest only)
+
+ In a powerVM guest, an extra character device is created for the
+ card. The device is only used to write (flash) a new image on the
+ FPGA accelerator. Once the image is written and verified, the
+ device tree is updated and the card is reset to reload the updated
+ image.
+
+open
+----
+
+ Opens the device and allocates a file descriptor to be used with
+ the rest of the API. The device can only be opened once.
+
+ioctl
+-----
+
+CXL_IOCTL_DOWNLOAD_IMAGE:
+CXL_IOCTL_VALIDATE_IMAGE:
+ Starts and controls flashing a new FPGA image. Partial
+ reconfiguration is not supported (yet), so the image must contain
+ a copy of the PSL and AFU(s). Since an image can be quite large,
+ the caller may have to iterate, splitting the image in smaller
+ chunks.
+
+ Takes a pointer to a struct cxl_adapter_image:
+ struct cxl_adapter_image {
+ __u64 flags;
+ __u64 data;
+ __u64 len_data;
+ __u64 len_image;
+ __u64 reserved1;
+ __u64 reserved2;
+ __u64 reserved3;
+ __u64 reserved4;
+ };
+
+ flags:
+ These flags indicate which optional fields are present in
+ this struct. Currently all fields are mandatory.
+
+ data:
+ Pointer to a buffer with part of the image to write to the
+ card.
+
+ len_data:
+ Size of the buffer pointed to by data.
+
+ len_image:
+ Full size of the image.
+
+
+Sysfs Class
+===========
+
+ A cxl sysfs class is added under /sys/class/cxl to facilitate
+ enumeration and tuning of the accelerators. Its layout is
+ described in Documentation/ABI/testing/sysfs-class-cxl
+
+
+Udev rules
+==========
+
+ The following udev rules could be used to create a symlink to the
+ most logical chardev to use in any programming mode (afuX.Yd for
+ dedicated, afuX.Ys for afu directed), since the API is virtually
+ identical for each:
+
+ SUBSYSTEM=="cxl", ATTRS{mode}=="dedicated_process", SYMLINK="cxl/%b"
+ SUBSYSTEM=="cxl", ATTRS{mode}=="afu_directed", \
+ KERNEL=="afu[0-9]*.[0-9]*s", SYMLINK="cxl/%b"
diff --git a/Documentation/powerpc/cxlflash.txt b/Documentation/powerpc/cxlflash.txt
new file mode 100644
index 000000000..a64bdaa0a
--- /dev/null
+++ b/Documentation/powerpc/cxlflash.txt
@@ -0,0 +1,429 @@
+Introduction
+============
+
+ The IBM Power architecture provides support for CAPI (Coherent
+ Accelerator Power Interface), which is available to certain PCIe slots
+ on Power 8 systems. CAPI can be thought of as a special tunneling
+ protocol through PCIe that allow PCIe adapters to look like special
+ purpose co-processors which can read or write an application's
+ memory and generate page faults. As a result, the host interface to
+ an adapter running in CAPI mode does not require the data buffers to
+ be mapped to the device's memory (IOMMU bypass) nor does it require
+ memory to be pinned.
+
+ On Linux, Coherent Accelerator (CXL) kernel services present CAPI
+ devices as a PCI device by implementing a virtual PCI host bridge.
+ This abstraction simplifies the infrastructure and programming
+ model, allowing for drivers to look similar to other native PCI
+ device drivers.
+
+ CXL provides a mechanism by which user space applications can
+ directly talk to a device (network or storage) bypassing the typical
+ kernel/device driver stack. The CXL Flash Adapter Driver enables a
+ user space application direct access to Flash storage.
+
+ The CXL Flash Adapter Driver is a kernel module that sits in the
+ SCSI stack as a low level device driver (below the SCSI disk and
+ protocol drivers) for the IBM CXL Flash Adapter. This driver is
+ responsible for the initialization of the adapter, setting up the
+ special path for user space access, and performing error recovery. It
+ communicates directly the Flash Accelerator Functional Unit (AFU)
+ as described in Documentation/powerpc/cxl.txt.
+
+ The cxlflash driver supports two, mutually exclusive, modes of
+ operation at the device (LUN) level:
+
+ - Any flash device (LUN) can be configured to be accessed as a
+ regular disk device (i.e.: /dev/sdc). This is the default mode.
+
+ - Any flash device (LUN) can be configured to be accessed from
+ user space with a special block library. This mode further
+ specifies the means of accessing the device and provides for
+ either raw access to the entire LUN (referred to as direct
+ or physical LUN access) or access to a kernel/AFU-mediated
+ partition of the LUN (referred to as virtual LUN access). The
+ segmentation of a disk device into virtual LUNs is assisted
+ by special translation services provided by the Flash AFU.
+
+Overview
+========
+
+ The Coherent Accelerator Interface Architecture (CAIA) introduces a
+ concept of a master context. A master typically has special privileges
+ granted to it by the kernel or hypervisor allowing it to perform AFU
+ wide management and control. The master may or may not be involved
+ directly in each user I/O, but at the minimum is involved in the
+ initial setup before the user application is allowed to send requests
+ directly to the AFU.
+
+ The CXL Flash Adapter Driver establishes a master context with the
+ AFU. It uses memory mapped I/O (MMIO) for this control and setup. The
+ Adapter Problem Space Memory Map looks like this:
+
+ +-------------------------------+
+ | 512 * 64 KB User MMIO |
+ | (per context) |
+ | User Accessible |
+ +-------------------------------+
+ | 512 * 128 B per context |
+ | Provisioning and Control |
+ | Trusted Process accessible |
+ +-------------------------------+
+ | 64 KB Global |
+ | Trusted Process accessible |
+ +-------------------------------+
+
+ This driver configures itself into the SCSI software stack as an
+ adapter driver. The driver is the only entity that is considered a
+ Trusted Process to program the Provisioning and Control and Global
+ areas in the MMIO Space shown above. The master context driver
+ discovers all LUNs attached to the CXL Flash adapter and instantiates
+ scsi block devices (/dev/sdb, /dev/sdc etc.) for each unique LUN
+ seen from each path.
+
+ Once these scsi block devices are instantiated, an application
+ written to a specification provided by the block library may get
+ access to the Flash from user space (without requiring a system call).
+
+ This master context driver also provides a series of ioctls for this
+ block library to enable this user space access. The driver supports
+ two modes for accessing the block device.
+
+ The first mode is called a virtual mode. In this mode a single scsi
+ block device (/dev/sdb) may be carved up into any number of distinct
+ virtual LUNs. The virtual LUNs may be resized as long as the sum of
+ the sizes of all the virtual LUNs, along with the meta-data associated
+ with it does not exceed the physical capacity.
+
+ The second mode is called the physical mode. In this mode a single
+ block device (/dev/sdb) may be opened directly by the block library
+ and the entire space for the LUN is available to the application.
+
+ Only the physical mode provides persistence of the data. i.e. The
+ data written to the block device will survive application exit and
+ restart and also reboot. The virtual LUNs do not persist (i.e. do
+ not survive after the application terminates or the system reboots).
+
+
+Block library API
+=================
+
+ Applications intending to get access to the CXL Flash from user
+ space should use the block library, as it abstracts the details of
+ interfacing directly with the cxlflash driver that are necessary for
+ performing administrative actions (i.e.: setup, tear down, resize).
+ The block library can be thought of as a 'user' of services,
+ implemented as IOCTLs, that are provided by the cxlflash driver
+ specifically for devices (LUNs) operating in user space access
+ mode. While it is not a requirement that applications understand
+ the interface between the block library and the cxlflash driver,
+ a high-level overview of each supported service (IOCTL) is provided
+ below.
+
+ The block library can be found on GitHub:
+ http://github.com/open-power/capiflash
+
+
+CXL Flash Driver LUN IOCTLs
+===========================
+
+ Users, such as the block library, that wish to interface with a flash
+ device (LUN) via user space access need to use the services provided
+ by the cxlflash driver. As these services are implemented as ioctls,
+ a file descriptor handle must first be obtained in order to establish
+ the communication channel between a user and the kernel. This file
+ descriptor is obtained by opening the device special file associated
+ with the scsi disk device (/dev/sdb) that was created during LUN
+ discovery. As per the location of the cxlflash driver within the
+ SCSI protocol stack, this open is actually not seen by the cxlflash
+ driver. Upon successful open, the user receives a file descriptor
+ (herein referred to as fd1) that should be used for issuing the
+ subsequent ioctls listed below.
+
+ The structure definitions for these IOCTLs are available in:
+ uapi/scsi/cxlflash_ioctl.h
+
+DK_CXLFLASH_ATTACH
+------------------
+
+ This ioctl obtains, initializes, and starts a context using the CXL
+ kernel services. These services specify a context id (u16) by which
+ to uniquely identify the context and its allocated resources. The
+ services additionally provide a second file descriptor (herein
+ referred to as fd2) that is used by the block library to initiate
+ memory mapped I/O (via mmap()) to the CXL flash device and poll for
+ completion events. This file descriptor is intentionally installed by
+ this driver and not the CXL kernel services to allow for intermediary
+ notification and access in the event of a non-user-initiated close(),
+ such as a killed process. This design point is described in further
+ detail in the description for the DK_CXLFLASH_DETACH ioctl.
+
+ There are a few important aspects regarding the "tokens" (context id
+ and fd2) that are provided back to the user:
+
+ - These tokens are only valid for the process under which they
+ were created. The child of a forked process cannot continue
+ to use the context id or file descriptor created by its parent
+ (see DK_CXLFLASH_VLUN_CLONE for further details).
+
+ - These tokens are only valid for the lifetime of the context and
+ the process under which they were created. Once either is
+ destroyed, the tokens are to be considered stale and subsequent
+ usage will result in errors.
+
+ - A valid adapter file descriptor (fd2 >= 0) is only returned on
+ the initial attach for a context. Subsequent attaches to an
+ existing context (DK_CXLFLASH_ATTACH_REUSE_CONTEXT flag present)
+ do not provide the adapter file descriptor as it was previously
+ made known to the application.
+
+ - When a context is no longer needed, the user shall detach from
+ the context via the DK_CXLFLASH_DETACH ioctl. When this ioctl
+ returns with a valid adapter file descriptor and the return flag
+ DK_CXLFLASH_APP_CLOSE_ADAP_FD is present, the application _must_
+ close the adapter file descriptor following a successful detach.
+
+ - When this ioctl returns with a valid fd2 and the return flag
+ DK_CXLFLASH_APP_CLOSE_ADAP_FD is present, the application _must_
+ close fd2 in the following circumstances:
+
+ + Following a successful detach of the last user of the context
+ + Following a successful recovery on the context's original fd2
+ + In the child process of a fork(), following a clone ioctl,
+ on the fd2 associated with the source context
+
+ - At any time, a close on fd2 will invalidate the tokens. Applications
+ should exercise caution to only close fd2 when appropriate (outlined
+ in the previous bullet) to avoid premature loss of I/O.
+
+DK_CXLFLASH_USER_DIRECT
+-----------------------
+ This ioctl is responsible for transitioning the LUN to direct
+ (physical) mode access and configuring the AFU for direct access from
+ user space on a per-context basis. Additionally, the block size and
+ last logical block address (LBA) are returned to the user.
+
+ As mentioned previously, when operating in user space access mode,
+ LUNs may be accessed in whole or in part. Only one mode is allowed
+ at a time and if one mode is active (outstanding references exist),
+ requests to use the LUN in a different mode are denied.
+
+ The AFU is configured for direct access from user space by adding an
+ entry to the AFU's resource handle table. The index of the entry is
+ treated as a resource handle that is returned to the user. The user
+ is then able to use the handle to reference the LUN during I/O.
+
+DK_CXLFLASH_USER_VIRTUAL
+------------------------
+ This ioctl is responsible for transitioning the LUN to virtual mode
+ of access and configuring the AFU for virtual access from user space
+ on a per-context basis. Additionally, the block size and last logical
+ block address (LBA) are returned to the user.
+
+ As mentioned previously, when operating in user space access mode,
+ LUNs may be accessed in whole or in part. Only one mode is allowed
+ at a time and if one mode is active (outstanding references exist),
+ requests to use the LUN in a different mode are denied.
+
+ The AFU is configured for virtual access from user space by adding
+ an entry to the AFU's resource handle table. The index of the entry
+ is treated as a resource handle that is returned to the user. The
+ user is then able to use the handle to reference the LUN during I/O.
+
+ By default, the virtual LUN is created with a size of 0. The user
+ would need to use the DK_CXLFLASH_VLUN_RESIZE ioctl to adjust the grow
+ the virtual LUN to a desired size. To avoid having to perform this
+ resize for the initial creation of the virtual LUN, the user has the
+ option of specifying a size as part of the DK_CXLFLASH_USER_VIRTUAL
+ ioctl, such that when success is returned to the user, the
+ resource handle that is provided is already referencing provisioned
+ storage. This is reflected by the last LBA being a non-zero value.
+
+ When a LUN is accessible from more than one port, this ioctl will
+ return with the DK_CXLFLASH_ALL_PORTS_ACTIVE return flag set. This
+ provides the user with a hint that I/O can be retried in the event
+ of an I/O error as the LUN can be reached over multiple paths.
+
+DK_CXLFLASH_VLUN_RESIZE
+-----------------------
+ This ioctl is responsible for resizing a previously created virtual
+ LUN and will fail if invoked upon a LUN that is not in virtual
+ mode. Upon success, an updated last LBA is returned to the user
+ indicating the new size of the virtual LUN associated with the
+ resource handle.
+
+ The partitioning of virtual LUNs is jointly mediated by the cxlflash
+ driver and the AFU. An allocation table is kept for each LUN that is
+ operating in the virtual mode and used to program a LUN translation
+ table that the AFU references when provided with a resource handle.
+
+ This ioctl can return -EAGAIN if an AFU sync operation takes too long.
+ In addition to returning a failure to user, cxlflash will also schedule
+ an asynchronous AFU reset. Should the user choose to retry the operation,
+ it is expected to succeed. If this ioctl fails with -EAGAIN, the user
+ can either retry the operation or treat it as a failure.
+
+DK_CXLFLASH_RELEASE
+-------------------
+ This ioctl is responsible for releasing a previously obtained
+ reference to either a physical or virtual LUN. This can be
+ thought of as the inverse of the DK_CXLFLASH_USER_DIRECT or
+ DK_CXLFLASH_USER_VIRTUAL ioctls. Upon success, the resource handle
+ is no longer valid and the entry in the resource handle table is
+ made available to be used again.
+
+ As part of the release process for virtual LUNs, the virtual LUN
+ is first resized to 0 to clear out and free the translation tables
+ associated with the virtual LUN reference.
+
+DK_CXLFLASH_DETACH
+------------------
+ This ioctl is responsible for unregistering a context with the
+ cxlflash driver and release outstanding resources that were
+ not explicitly released via the DK_CXLFLASH_RELEASE ioctl. Upon
+ success, all "tokens" which had been provided to the user from the
+ DK_CXLFLASH_ATTACH onward are no longer valid.
+
+ When the DK_CXLFLASH_APP_CLOSE_ADAP_FD flag was returned on a successful
+ attach, the application _must_ close the fd2 associated with the context
+ following the detach of the final user of the context.
+
+DK_CXLFLASH_VLUN_CLONE
+----------------------
+ This ioctl is responsible for cloning a previously created
+ context to a more recently created context. It exists solely to
+ support maintaining user space access to storage after a process
+ forks. Upon success, the child process (which invoked the ioctl)
+ will have access to the same LUNs via the same resource handle(s)
+ as the parent, but under a different context.
+
+ Context sharing across processes is not supported with CXL and
+ therefore each fork must be met with establishing a new context
+ for the child process. This ioctl simplifies the state management
+ and playback required by a user in such a scenario. When a process
+ forks, child process can clone the parents context by first creating
+ a context (via DK_CXLFLASH_ATTACH) and then using this ioctl to
+ perform the clone from the parent to the child.
+
+ The clone itself is fairly simple. The resource handle and lun
+ translation tables are copied from the parent context to the child's
+ and then synced with the AFU.
+
+ When the DK_CXLFLASH_APP_CLOSE_ADAP_FD flag was returned on a successful
+ attach, the application _must_ close the fd2 associated with the source
+ context (still resident/accessible in the parent process) following the
+ clone. This is to avoid a stale entry in the file descriptor table of the
+ child process.
+
+ This ioctl can return -EAGAIN if an AFU sync operation takes too long.
+ In addition to returning a failure to user, cxlflash will also schedule
+ an asynchronous AFU reset. Should the user choose to retry the operation,
+ it is expected to succeed. If this ioctl fails with -EAGAIN, the user
+ can either retry the operation or treat it as a failure.
+
+DK_CXLFLASH_VERIFY
+------------------
+ This ioctl is used to detect various changes such as the capacity of
+ the disk changing, the number of LUNs visible changing, etc. In cases
+ where the changes affect the application (such as a LUN resize), the
+ cxlflash driver will report the changed state to the application.
+
+ The user calls in when they want to validate that a LUN hasn't been
+ changed in response to a check condition. As the user is operating out
+ of band from the kernel, they will see these types of events without
+ the kernel's knowledge. When encountered, the user's architected
+ behavior is to call in to this ioctl, indicating what they want to
+ verify and passing along any appropriate information. For now, only
+ verifying a LUN change (ie: size different) with sense data is
+ supported.
+
+DK_CXLFLASH_RECOVER_AFU
+-----------------------
+ This ioctl is used to drive recovery (if such an action is warranted)
+ of a specified user context. Any state associated with the user context
+ is re-established upon successful recovery.
+
+ User contexts are put into an error condition when the device needs to
+ be reset or is terminating. Users are notified of this error condition
+ by seeing all 0xF's on an MMIO read. Upon encountering this, the
+ architected behavior for a user is to call into this ioctl to recover
+ their context. A user may also call into this ioctl at any time to
+ check if the device is operating normally. If a failure is returned
+ from this ioctl, the user is expected to gracefully clean up their
+ context via release/detach ioctls. Until they do, the context they
+ hold is not relinquished. The user may also optionally exit the process
+ at which time the context/resources they held will be freed as part of
+ the release fop.
+
+ When the DK_CXLFLASH_APP_CLOSE_ADAP_FD flag was returned on a successful
+ attach, the application _must_ unmap and close the fd2 associated with the
+ original context following this ioctl returning success and indicating that
+ the context was recovered (DK_CXLFLASH_RECOVER_AFU_CONTEXT_RESET).
+
+DK_CXLFLASH_MANAGE_LUN
+----------------------
+ This ioctl is used to switch a LUN from a mode where it is available
+ for file-system access (legacy), to a mode where it is set aside for
+ exclusive user space access (superpipe). In case a LUN is visible
+ across multiple ports and adapters, this ioctl is used to uniquely
+ identify each LUN by its World Wide Node Name (WWNN).
+
+
+CXL Flash Driver Host IOCTLs
+============================
+
+ Each host adapter instance that is supported by the cxlflash driver
+ has a special character device associated with it to enable a set of
+ host management function. These character devices are hosted in a
+ class dedicated for cxlflash and can be accessed via /dev/cxlflash/*.
+
+ Applications can be written to perform various functions using the
+ host ioctl APIs below.
+
+ The structure definitions for these IOCTLs are available in:
+ uapi/scsi/cxlflash_ioctl.h
+
+HT_CXLFLASH_LUN_PROVISION
+-------------------------
+ This ioctl is used to create and delete persistent LUNs on cxlflash
+ devices that lack an external LUN management interface. It is only
+ valid when used with AFUs that support the LUN provision capability.
+
+ When sufficient space is available, LUNs can be created by specifying
+ the target port to host the LUN and a desired size in 4K blocks. Upon
+ success, the LUN ID and WWID of the created LUN will be returned and
+ the SCSI bus can be scanned to detect the change in LUN topology. Note
+ that partial allocations are not supported. Should a creation fail due
+ to a space issue, the target port can be queried for its current LUN
+ geometry.
+
+ To remove a LUN, the device must first be disassociated from the Linux
+ SCSI subsystem. The LUN deletion can then be initiated by specifying a
+ target port and LUN ID. Upon success, the LUN geometry associated with
+ the port will be updated to reflect new number of provisioned LUNs and
+ available capacity.
+
+ To query the LUN geometry of a port, the target port is specified and
+ upon success, the following information is presented:
+
+ - Maximum number of provisioned LUNs allowed for the port
+ - Current number of provisioned LUNs for the port
+ - Maximum total capacity of provisioned LUNs for the port (4K blocks)
+ - Current total capacity of provisioned LUNs for the port (4K blocks)
+
+ With this information, the number of available LUNs and capacity can be
+ can be calculated.
+
+HT_CXLFLASH_AFU_DEBUG
+---------------------
+ This ioctl is used to debug AFUs by supporting a command pass-through
+ interface. It is only valid when used with AFUs that support the AFU
+ debug capability.
+
+ With exception of buffer management, AFU debug commands are opaque to
+ cxlflash and treated as pass-through. For debug commands that do require
+ data transfer, the user supplies an adequately sized data buffer and must
+ specify the data transfer direction with respect to the host. There is a
+ maximum transfer size of 256K imposed. Note that partial read completions
+ are not supported - when errors are experienced with a host read data
+ transfer, the data buffer is not copied back to the user.
diff --git a/Documentation/powerpc/dscr.txt b/Documentation/powerpc/dscr.txt
new file mode 100644
index 000000000..ece300c64
--- /dev/null
+++ b/Documentation/powerpc/dscr.txt
@@ -0,0 +1,83 @@
+ DSCR (Data Stream Control Register)
+ ================================================
+
+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 prefetches . This document here provides an overview of kernel
+support for DSCR, related kernel objects, it's functionalities and exported
+user interface.
+
+(A) Data Structures:
+
+ (1) thread_struct:
+ dscr /* Thread DSCR value */
+ dscr_inherit /* Thread has changed default DSCR */
+
+ (2) PACA:
+ dscr_default /* per-CPU DSCR default value */
+
+ (3) sysfs.c:
+ dscr_default /* System DSCR default value */
+
+(B) Scheduler Changes:
+
+ Scheduler will write the per-CPU DSCR default which is stored in the
+ CPU's PACA value into the register if the thread has dscr_inherit value
+ cleared which means that it has not changed the default DSCR till now.
+ If the dscr_inherit value is set which means that it has changed the
+ default DSCR value, scheduler will write the changed value which will
+ now be contained in thread struct's dscr into the register instead of
+ the per-CPU default PACA based DSCR value.
+
+ NOTE: Please note here that the system wide global DSCR value never
+ gets used directly in the scheduler process context switch at all.
+
+(C) SYSFS Interface:
+
+ Global DSCR default: /sys/devices/system/cpu/dscr_default
+ CPU specific DSCR default: /sys/devices/system/cpu/cpuN/dscr
+
+ Changing the global DSCR default in the sysfs will change all the CPU
+ specific DSCR defaults immediately in their PACA structures. Again if
+ the current process has the dscr_inherit clear, it also writes the new
+ value into every CPU's DSCR register right away and updates the current
+ thread's DSCR value as well.
+
+ 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.
+
+(D) User Space Instructions:
+
+ The DSCR register can be accessed in the user space using any of these
+ two SPR numbers available for that purpose.
+
+ (1) Problem state SPR: 0x03 (Un-privileged, POWER8 only)
+ (2) Privileged state SPR: 0x11 (Privileged)
+
+ Accessing DSCR through privileged SPR number (0x11) from user space
+ works, as it is emulated following an illegal instruction exception
+ inside the kernel. Both mfspr and mtspr instructions are emulated.
+
+ Accessing DSCR through user level SPR (0x03) from user space will first
+ create a facility unavailable exception. Inside this exception handler
+ 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.
+
+(E) Specifics about 'dscr_inherit':
+
+ The thread struct element 'dscr_inherit' represents whether the thread
+ in question has attempted and changed the DSCR itself using any of the
+ following methods. This element signifies whether the thread wants to
+ use the CPU default DSCR value or its own changed DSCR value in the
+ kernel.
+
+ (1) mtspr instruction (SPR number 0x03)
+ (2) mtspr instruction (SPR number 0x11)
+ (3) ptrace interface (Explicitly set user DSCR value)
+
+ Any child of the process created after this event in the process inherits
+ this same behaviour as well.
diff --git a/Documentation/powerpc/eeh-pci-error-recovery.txt b/Documentation/powerpc/eeh-pci-error-recovery.txt
new file mode 100644
index 000000000..678189280
--- /dev/null
+++ b/Documentation/powerpc/eeh-pci-error-recovery.txt
@@ -0,0 +1,334 @@
+
+
+ PCI Bus EEH Error Recovery
+ --------------------------
+ Linas Vepstas
+ <linas@austin.ibm.com>
+ 12 January 2005
+
+
+Overview:
+---------
+The IBM POWER-based pSeries and iSeries computers include PCI bus
+controller chips that have extended capabilities for detecting and
+reporting a large variety of PCI bus error conditions. These features
+go under the name of "EEH", for "Enhanced Error Handling". The EEH
+hardware features allow PCI bus errors to be cleared and a PCI
+card to be "rebooted", without also having to reboot the operating
+system.
+
+This is in contrast to traditional PCI error handling, where the
+PCI chip is wired directly to the CPU, and an error would cause
+a CPU machine-check/check-stop condition, halting the CPU entirely.
+Another "traditional" technique is to ignore such errors, which
+can lead to data corruption, both of user data or of kernel data,
+hung/unresponsive adapters, or system crashes/lockups. Thus,
+the idea behind EEH is that the operating system can become more
+reliable and robust by protecting it from PCI errors, and giving
+the OS the ability to "reboot"/recover individual PCI devices.
+
+Future systems from other vendors, based on the PCI-E specification,
+may contain similar features.
+
+
+Causes of EEH Errors
+--------------------
+EEH was originally designed to guard against hardware failure, such
+as PCI cards dying from heat, humidity, dust, vibration and bad
+electrical connections. The vast majority of EEH errors seen in
+"real life" are due to either poorly seated PCI cards, or,
+unfortunately quite commonly, due to device driver bugs, device firmware
+bugs, and sometimes PCI card hardware bugs.
+
+The most common software bug, is one that causes the device to
+attempt to DMA to a location in system memory that has not been
+reserved for DMA access for that card. This is a powerful feature,
+as it prevents what; otherwise, would have been silent memory
+corruption caused by the bad DMA. A number of device driver
+bugs have been found and fixed in this way over the past few
+years. Other possible causes of EEH errors include data or
+address line parity errors (for example, due to poor electrical
+connectivity due to a poorly seated card), and PCI-X split-completion
+errors (due to software, device firmware, or device PCI hardware bugs).
+The vast majority of "true hardware failures" can be cured by
+physically removing and re-seating the PCI card.
+
+
+Detection and Recovery
+----------------------
+In the following discussion, a generic overview of how to detect
+and recover from EEH errors will be presented. This is followed
+by an overview of how the current implementation in the Linux
+kernel does it. The actual implementation is subject to change,
+and some of the finer points are still being debated. These
+may in turn be swayed if or when other architectures implement
+similar functionality.
+
+When a PCI Host Bridge (PHB, the bus controller connecting the
+PCI bus to the system CPU electronics complex) detects a PCI error
+condition, it will "isolate" the affected PCI card. Isolation
+will block all writes (either to the card from the system, or
+from the card to the system), and it will cause all reads to
+return all-ff's (0xff, 0xffff, 0xffffffff for 8/16/32-bit reads).
+This value was chosen because it is the same value you would
+get if the device was physically unplugged from the slot.
+This includes access to PCI memory, I/O space, and PCI config
+space. Interrupts; however, will continued to be delivered.
+
+Detection and recovery are performed with the aid of ppc64
+firmware. The programming interfaces in the Linux kernel
+into the firmware are referred to as RTAS (Run-Time Abstraction
+Services). The Linux kernel does not (should not) access
+the EEH function in the PCI chipsets directly, primarily because
+there are a number of different chipsets out there, each with
+different interfaces and quirks. The firmware provides a
+uniform abstraction layer that will work with all pSeries
+and iSeries hardware (and be forwards-compatible).
+
+If the OS or device driver suspects that a PCI slot has been
+EEH-isolated, there is a firmware call it can make to determine if
+this is the case. If so, then the device driver should put itself
+into a consistent state (given that it won't be able to complete any
+pending work) and start recovery of the card. Recovery normally
+would consist of resetting the PCI device (holding the PCI #RST
+line high for two seconds), followed by setting up the device
+config space (the base address registers (BAR's), latency timer,
+cache line size, interrupt line, and so on). This is followed by a
+reinitialization of the device driver. In a worst-case scenario,
+the power to the card can be toggled, at least on hot-plug-capable
+slots. In principle, layers far above the device driver probably
+do not need to know that the PCI card has been "rebooted" in this
+way; ideally, there should be at most a pause in Ethernet/disk/USB
+I/O while the card is being reset.
+
+If the card cannot be recovered after three or four resets, the
+kernel/device driver should assume the worst-case scenario, that the
+card has died completely, and report this error to the sysadmin.
+In addition, error messages are reported through RTAS and also through
+syslogd (/var/log/messages) to alert the sysadmin of PCI resets.
+The correct way to deal with failed adapters is to use the standard
+PCI hotplug tools to remove and replace the dead card.
+
+
+Current PPC64 Linux EEH Implementation
+--------------------------------------
+At this time, a generic EEH recovery mechanism has been implemented,
+so that individual device drivers do not need to be modified to support
+EEH recovery. This generic mechanism piggy-backs on the PCI hotplug
+infrastructure, and percolates events up through the userspace/udev
+infrastructure. Following is a detailed description of how this is
+accomplished.
+
+EEH must be enabled in the PHB's very early during the boot process,
+and if a PCI slot is hot-plugged. The former is performed by
+eeh_init() in arch/powerpc/platforms/pseries/eeh.c, and the later by
+drivers/pci/hotplug/pSeries_pci.c calling in to the eeh.c code.
+EEH must be enabled before a PCI scan of the device can proceed.
+Current Power5 hardware will not work unless EEH is enabled;
+although older Power4 can run with it disabled. Effectively,
+EEH can no longer be turned off. PCI devices *must* be
+registered with the EEH code; the EEH code needs to know about
+the I/O address ranges of the PCI device in order to detect an
+error. Given an arbitrary address, the routine
+pci_get_device_by_addr() will find the pci device associated
+with that address (if any).
+
+The default arch/powerpc/include/asm/io.h macros readb(), inb(), insb(),
+etc. include a check to see if the i/o read returned all-0xff's.
+If so, these make a call to eeh_dn_check_failure(), which in turn
+asks the firmware if the all-ff's value is the sign of a true EEH
+error. If it is not, processing continues as normal. The grand
+total number of these false alarms or "false positives" can be
+seen in /proc/ppc64/eeh (subject to change). Normally, almost
+all of these occur during boot, when the PCI bus is scanned, where
+a large number of 0xff reads are part of the bus scan procedure.
+
+If a frozen slot is detected, code in
+arch/powerpc/platforms/pseries/eeh.c will print a stack trace to
+syslog (/var/log/messages). This stack trace has proven to be very
+useful to device-driver authors for finding out at what point the EEH
+error was detected, as the error itself usually occurs slightly
+beforehand.
+
+Next, it uses the Linux kernel notifier chain/work queue mechanism to
+allow any interested parties to find out about the failure. Device
+drivers, or other parts of the kernel, can use
+eeh_register_notifier(struct notifier_block *) to find out about EEH
+events. The event will include a pointer to the pci device, the
+device node and some state info. Receivers of the event can "do as
+they wish"; the default handler will be described further in this
+section.
+
+To assist in the recovery of the device, eeh.c exports the
+following functions:
+
+rtas_set_slot_reset() -- assert the PCI #RST line for 1/8th of a second
+rtas_configure_bridge() -- ask firmware to configure any PCI bridges
+ located topologically under the pci slot.
+eeh_save_bars() and eeh_restore_bars(): save and restore the PCI
+ config-space info for a device and any devices under it.
+
+
+A handler for the EEH notifier_block events is implemented in
+drivers/pci/hotplug/pSeries_pci.c, called handle_eeh_events().
+It saves the device BAR's and then calls rpaphp_unconfig_pci_adapter().
+This last call causes the device driver for the card to be stopped,
+which causes uevents to go out to user space. This triggers
+user-space scripts that might issue commands such as "ifdown eth0"
+for ethernet cards, and so on. This handler then sleeps for 5 seconds,
+hoping to give the user-space scripts enough time to complete.
+It then resets the PCI card, reconfigures the device BAR's, and
+any bridges underneath. It then calls rpaphp_enable_pci_slot(),
+which restarts the device driver and triggers more user-space
+events (for example, calling "ifup eth0" for ethernet cards).
+
+
+Device Shutdown and User-Space Events
+-------------------------------------
+This section documents what happens when a pci slot is unconfigured,
+focusing on how the device driver gets shut down, and on how the
+events get delivered to user-space scripts.
+
+Following is an example sequence of events that cause a device driver
+close function to be called during the first phase of an EEH reset.
+The following sequence is an example of the pcnet32 device driver.
+
+ rpa_php_unconfig_pci_adapter (struct slot *) // in rpaphp_pci.c
+ {
+ calls
+ pci_remove_bus_device (struct pci_dev *) // in /drivers/pci/remove.c
+ {
+ calls
+ pci_destroy_dev (struct pci_dev *)
+ {
+ calls
+ device_unregister (&dev->dev) // in /drivers/base/core.c
+ {
+ calls
+ device_del (struct device *)
+ {
+ calls
+ bus_remove_device() // in /drivers/base/bus.c
+ {
+ calls
+ device_release_driver()
+ {
+ calls
+ struct device_driver->remove() which is just
+ pci_device_remove() // in /drivers/pci/pci_driver.c
+ {
+ calls
+ struct pci_driver->remove() which is just
+ pcnet32_remove_one() // in /drivers/net/pcnet32.c
+ {
+ calls
+ unregister_netdev() // in /net/core/dev.c
+ {
+ calls
+ dev_close() // in /net/core/dev.c
+ {
+ calls dev->stop();
+ which is just pcnet32_close() // in pcnet32.c
+ {
+ which does what you wanted
+ to stop the device
+ }
+ }
+ }
+ which
+ frees pcnet32 device driver memory
+ }
+ }}}}}}
+
+
+ in drivers/pci/pci_driver.c,
+ struct device_driver->remove() is just pci_device_remove()
+ which calls struct pci_driver->remove() which is pcnet32_remove_one()
+ which calls unregister_netdev() (in net/core/dev.c)
+ which calls dev_close() (in net/core/dev.c)
+ which calls dev->stop() which is pcnet32_close()
+ which then does the appropriate shutdown.
+
+---
+Following is the analogous stack trace for events sent to user-space
+when the pci device is unconfigured.
+
+rpa_php_unconfig_pci_adapter() { // in rpaphp_pci.c
+ calls
+ pci_remove_bus_device (struct pci_dev *) { // in /drivers/pci/remove.c
+ calls
+ pci_destroy_dev (struct pci_dev *) {
+ calls
+ device_unregister (&dev->dev) { // in /drivers/base/core.c
+ calls
+ device_del(struct device * dev) { // in /drivers/base/core.c
+ calls
+ kobject_del() { //in /libs/kobject.c
+ calls
+ kobject_uevent() { // in /libs/kobject.c
+ calls
+ kset_uevent() { // in /lib/kobject.c
+ calls
+ kset->uevent_ops->uevent() // which is really just
+ a call to
+ dev_uevent() { // in /drivers/base/core.c
+ calls
+ dev->bus->uevent() which is really just a call to
+ pci_uevent () { // in drivers/pci/hotplug.c
+ which prints device name, etc....
+ }
+ }
+ then kobject_uevent() sends a netlink uevent to userspace
+ --> userspace uevent
+ (during early boot, nobody listens to netlink events and
+ kobject_uevent() executes uevent_helper[], which runs the
+ event process /sbin/hotplug)
+ }
+ }
+ kobject_del() then calls sysfs_remove_dir(), which would
+ trigger any user-space daemon that was watching /sysfs,
+ and notice the delete event.
+
+
+Pro's and Con's of the Current Design
+-------------------------------------
+There are several issues with the current EEH software recovery design,
+which may be addressed in future revisions. But first, note that the
+big plus of the current design is that no changes need to be made to
+individual device drivers, so that the current design throws a wide net.
+The biggest negative of the design is that it potentially disturbs
+network daemons and file systems that didn't need to be disturbed.
+
+-- A minor complaint is that resetting the network card causes
+ user-space back-to-back ifdown/ifup burps that potentially disturb
+ network daemons, that didn't need to even know that the pci
+ card was being rebooted.
+
+-- A more serious concern is that the same reset, for SCSI devices,
+ causes havoc to mounted file systems. Scripts cannot post-facto
+ unmount a file system without flushing pending buffers, but this
+ is impossible, because I/O has already been stopped. Thus,
+ ideally, the reset should happen at or below the block layer,
+ so that the file systems are not disturbed.
+
+ Reiserfs does not tolerate errors returned from the block device.
+ Ext3fs seems to be tolerant, retrying reads/writes until it does
+ succeed. Both have been only lightly tested in this scenario.
+
+ The SCSI-generic subsystem already has built-in code for performing
+ SCSI device resets, SCSI bus resets, and SCSI host-bus-adapter
+ (HBA) resets. These are cascaded into a chain of attempted
+ resets if a SCSI command fails. These are completely hidden
+ from the block layer. It would be very natural to add an EEH
+ reset into this chain of events.
+
+-- If a SCSI error occurs for the root device, all is lost unless
+ the sysadmin had the foresight to run /bin, /sbin, /etc, /var
+ and so on, out of ramdisk/tmpfs.
+
+
+Conclusions
+-----------
+There's forward progress ...
+
+
diff --git a/Documentation/powerpc/firmware-assisted-dump.txt b/Documentation/powerpc/firmware-assisted-dump.txt
new file mode 100644
index 000000000..bdd344aa1
--- /dev/null
+++ b/Documentation/powerpc/firmware-assisted-dump.txt
@@ -0,0 +1,277 @@
+
+ Firmware-Assisted Dump
+ ------------------------
+ July 2011
+
+The goal of firmware-assisted dump is to enable the dump of
+a crashed system, and to do so from a fully-reset system, and
+to minimize the total elapsed time until the system is back
+in production use.
+
+- Firmware assisted dump (fadump) infrastructure is intended to replace
+ the existing phyp assisted dump.
+- Fadump uses the same firmware interfaces and memory reservation model
+ as phyp assisted dump.
+- Unlike phyp dump, fadump exports the memory dump through /proc/vmcore
+ in the ELF format in the same way as kdump. This helps us reuse the
+ kdump infrastructure for dump capture and filtering.
+- Unlike phyp dump, userspace tool does not need to refer any sysfs
+ interface while reading /proc/vmcore.
+- Unlike phyp dump, fadump allows user to release all the memory reserved
+ for dump, with a single operation of echo 1 > /sys/kernel/fadump_release_mem.
+- Once enabled through kernel boot parameter, fadump can be
+ started/stopped through /sys/kernel/fadump_registered interface (see
+ sysfs files section below) and can be easily integrated with kdump
+ service start/stop init scripts.
+
+Comparing with kdump or other strategies, firmware-assisted
+dump offers several strong, practical advantages:
+
+-- Unlike kdump, the system has been reset, and loaded
+ with a fresh copy of the kernel. In particular,
+ PCI and I/O devices have been reinitialized and are
+ in a clean, consistent state.
+-- Once the dump is copied out, the memory that held the dump
+ is immediately available to the running kernel. And therefore,
+ unlike kdump, fadump doesn't need a 2nd reboot to get back
+ the system to the production configuration.
+
+The above can only be accomplished by coordination with,
+and assistance from the Power firmware. The procedure is
+as follows:
+
+-- The first kernel registers the sections of memory with the
+ Power firmware for dump preservation during OS initialization.
+ These registered sections of memory are reserved by the first
+ kernel during early boot.
+
+-- When a system crashes, the Power firmware will save
+ the low memory (boot memory of size larger of 5% of system RAM
+ or 256MB) of RAM to the previous registered region. It will
+ also save system registers, and hardware PTE's.
+
+ NOTE: The term 'boot memory' means size of the low memory chunk
+ that is required for a kernel to boot successfully when
+ booted with restricted memory. By default, the boot memory
+ size will be the larger of 5% of system RAM or 256MB.
+ Alternatively, user can also specify boot memory size
+ through boot parameter 'crashkernel=' which will override
+ the default calculated size. Use this option if default
+ boot memory size is not sufficient for second kernel to
+ boot successfully. For syntax of crashkernel= parameter,
+ refer to Documentation/kdump/kdump.txt. If any offset is
+ provided in crashkernel= parameter, it will be ignored
+ as fadump uses a predefined offset to reserve memory
+ for boot memory dump preservation in case of a crash.
+
+-- After the low memory (boot memory) area has been saved, the
+ firmware will reset PCI and other hardware state. It will
+ *not* clear the RAM. It will then launch the bootloader, as
+ normal.
+
+-- The freshly booted kernel will notice that there is a new
+ node (ibm,dump-kernel) in the device tree, indicating that
+ there is crash data available from a previous boot. During
+ the early boot OS will reserve rest of the memory above
+ boot memory size effectively booting with restricted memory
+ size. This will make sure that the second kernel will not
+ touch any of the dump memory area.
+
+-- User-space tools will read /proc/vmcore to obtain the contents
+ of memory, which holds the previous crashed kernel dump in ELF
+ format. The userspace tools may copy this info to disk, or
+ network, nas, san, iscsi, etc. as desired.
+
+-- Once the userspace tool is done saving dump, it will echo
+ '1' to /sys/kernel/fadump_release_mem to release the reserved
+ memory back to general use, except the memory required for
+ next firmware-assisted dump registration.
+
+ e.g.
+ # echo 1 > /sys/kernel/fadump_release_mem
+
+Please note that the firmware-assisted dump feature
+is only available on Power6 and above systems with recent
+firmware versions.
+
+Implementation details:
+----------------------
+
+During boot, a check is made to see if firmware supports
+this feature on that particular machine. If it does, then
+we check to see if an active dump is waiting for us. If yes
+then everything but boot memory size of RAM is reserved during
+early boot (See Fig. 2). This area is released once we finish
+collecting the dump from user land scripts (e.g. kdump scripts)
+that are run. If there is dump data, then the
+/sys/kernel/fadump_release_mem file is created, and the reserved
+memory is held.
+
+If there is no waiting dump data, then only the memory required
+to hold CPU state, HPTE region, boot memory dump and elfcore
+header, is usually reserved at an offset greater than boot memory
+size (see Fig. 1). This area is *not* released: this region will
+be kept permanently reserved, so that it can act as a receptacle
+for a copy of the boot memory content in addition to CPU state
+and HPTE region, in the case a crash does occur.
+
+ o Memory Reservation during first kernel
+
+ Low memory Top of memory
+ 0 boot memory size |
+ | | |<--Reserved dump area -->| |
+ V V | Permanent Reservation | V
+ +-----------+----------/ /---+---+----+-----------+----+------+
+ | | |CPU|HPTE| DUMP |ELF | |
+ +-----------+----------/ /---+---+----+-----------+----+------+
+ | ^
+ | |
+ \ /
+ -------------------------------------------
+ Boot memory content gets transferred to
+ reserved area by firmware at the time of
+ crash
+ Fig. 1
+
+ o Memory Reservation during second kernel after crash
+
+ Low memory Top of memory
+ 0 boot memory size |
+ | |<------------- Reserved dump area ----------- -->|
+ V V V
+ +-----------+----------/ /---+---+----+-----------+----+------+
+ | | |CPU|HPTE| DUMP |ELF | |
+ +-----------+----------/ /---+---+----+-----------+----+------+
+ | |
+ V V
+ Used by second /proc/vmcore
+ kernel to boot
+ Fig. 2
+
+Currently the dump will be copied from /proc/vmcore to a
+a new file upon user intervention. The dump data available through
+/proc/vmcore will be in ELF format. Hence the existing kdump
+infrastructure (kdump scripts) to save the dump works fine with
+minor modifications.
+
+The tools to examine the dump will be same as the ones
+used for kdump.
+
+How to enable firmware-assisted dump (fadump):
+-------------------------------------
+
+1. Set config option CONFIG_FA_DUMP=y and build kernel.
+2. Boot into linux kernel with 'fadump=on' kernel cmdline option.
+3. Optionally, user can also set 'crashkernel=' kernel cmdline
+ to specify size of the memory to reserve for boot memory dump
+ preservation.
+
+NOTE: 1. 'fadump_reserve_mem=' parameter has been deprecated. Instead
+ use 'crashkernel=' to specify size of the memory to reserve
+ for boot memory dump preservation.
+ 2. If firmware-assisted dump fails to reserve memory then it
+ will fallback to existing kdump mechanism if 'crashkernel='
+ option is set at kernel cmdline.
+
+Sysfs/debugfs files:
+------------
+
+Firmware-assisted dump feature uses sysfs file system to hold
+the control files and debugfs file to display memory reserved region.
+
+Here is the list of files under kernel sysfs:
+
+ /sys/kernel/fadump_enabled
+
+ This is used to display the fadump status.
+ 0 = fadump is disabled
+ 1 = fadump is enabled
+
+ This interface can be used by kdump init scripts to identify if
+ fadump is enabled in the kernel and act accordingly.
+
+ /sys/kernel/fadump_registered
+
+ This is used to display the fadump registration status as well
+ as to control (start/stop) the fadump registration.
+ 0 = fadump is not registered.
+ 1 = fadump is registered and ready to handle system crash.
+
+ To register fadump echo 1 > /sys/kernel/fadump_registered and
+ echo 0 > /sys/kernel/fadump_registered for un-register and stop the
+ fadump. Once the fadump is un-registered, the system crash will not
+ be handled and vmcore will not be captured. This interface can be
+ easily integrated with kdump service start/stop.
+
+ /sys/kernel/fadump_release_mem
+
+ This file is available only when fadump is active during
+ second kernel. This is used to release the reserved memory
+ region that are held for saving crash dump. To release the
+ reserved memory echo 1 to it:
+
+ echo 1 > /sys/kernel/fadump_release_mem
+
+ After echo 1, the content of the /sys/kernel/debug/powerpc/fadump_region
+ file will change to reflect the new memory reservations.
+
+ The existing userspace tools (kdump infrastructure) can be easily
+ enhanced to use this interface to release the memory reserved for
+ dump and continue without 2nd reboot.
+
+Here is the list of files under powerpc debugfs:
+(Assuming debugfs is mounted on /sys/kernel/debug directory.)
+
+ /sys/kernel/debug/powerpc/fadump_region
+
+ This file shows the reserved memory regions if fadump is
+ enabled otherwise this file is empty. The output format
+ is:
+ <region>: [<start>-<end>] <reserved-size> bytes, Dumped: <dump-size>
+
+ e.g.
+ Contents when fadump is registered during first kernel
+
+ # cat /sys/kernel/debug/powerpc/fadump_region
+ CPU : [0x0000006ffb0000-0x0000006fff001f] 0x40020 bytes, Dumped: 0x0
+ HPTE: [0x0000006fff0020-0x0000006fff101f] 0x1000 bytes, Dumped: 0x0
+ DUMP: [0x0000006fff1020-0x0000007fff101f] 0x10000000 bytes, Dumped: 0x0
+
+ Contents when fadump is active during second kernel
+
+ # cat /sys/kernel/debug/powerpc/fadump_region
+ CPU : [0x0000006ffb0000-0x0000006fff001f] 0x40020 bytes, Dumped: 0x40020
+ HPTE: [0x0000006fff0020-0x0000006fff101f] 0x1000 bytes, Dumped: 0x1000
+ DUMP: [0x0000006fff1020-0x0000007fff101f] 0x10000000 bytes, Dumped: 0x10000000
+ : [0x00000010000000-0x0000006ffaffff] 0x5ffb0000 bytes, Dumped: 0x5ffb0000
+
+NOTE: Please refer to Documentation/filesystems/debugfs.txt on
+ how to mount the debugfs filesystem.
+
+
+TODO:
+-----
+ o Need to come up with the better approach to find out more
+ accurate boot memory size that is required for a kernel to
+ boot successfully when booted with restricted memory.
+ o The fadump implementation introduces a fadump crash info structure
+ in the scratch area before the ELF core header. The idea of introducing
+ this structure is to pass some important crash info data to the second
+ kernel which will help second kernel to populate ELF core header with
+ correct data before it gets exported through /proc/vmcore. The current
+ design implementation does not address a possibility of introducing
+ additional fields (in future) to this structure without affecting
+ compatibility. Need to come up with the better approach to address this.
+ The possible approaches are:
+ 1. Introduce version field for version tracking, bump up the version
+ whenever a new field is added to the structure in future. The version
+ field can be used to find out what fields are valid for the current
+ version of the structure.
+ 2. Reserve the area of predefined size (say PAGE_SIZE) for this
+ structure and have unused area as reserved (initialized to zero)
+ for future field additions.
+ The advantage of approach 1 over 2 is we don't need to reserve extra space.
+---
+Author: Mahesh Salgaonkar <mahesh@linux.vnet.ibm.com>
+This document is based on the original documentation written for phyp
+assisted dump by Linas Vepstas and Manish Ahuja.
diff --git a/Documentation/powerpc/hvcs.txt b/Documentation/powerpc/hvcs.txt
new file mode 100644
index 000000000..a730ca5a0
--- /dev/null
+++ b/Documentation/powerpc/hvcs.txt
@@ -0,0 +1,567 @@
+===========================================================================
+ HVCS
+ IBM "Hypervisor Virtual Console Server" Installation Guide
+ for Linux Kernel 2.6.4+
+ Copyright (C) 2004 IBM Corporation
+
+===========================================================================
+NOTE:Eight space tabs are the optimum editor setting for reading this file.
+===========================================================================
+
+ Author(s) : Ryan S. Arnold <rsa@us.ibm.com>
+ Date Created: March, 02, 2004
+ Last Changed: August, 24, 2004
+
+---------------------------------------------------------------------------
+Table of contents:
+
+ 1. Driver Introduction:
+ 2. System Requirements
+ 3. Build Options:
+ 3.1 Built-in:
+ 3.2 Module:
+ 4. Installation:
+ 5. Connection:
+ 6. Disconnection:
+ 7. Configuration:
+ 8. Questions & Answers:
+ 9. Reporting Bugs:
+
+---------------------------------------------------------------------------
+1. Driver Introduction:
+
+This is the device driver for the IBM Hypervisor Virtual Console Server,
+"hvcs". The IBM hvcs provides a tty driver interface to allow Linux user
+space applications access to the system consoles of logically partitioned
+operating systems (Linux and AIX) running on the same partitioned Power5
+ppc64 system. Physical hardware consoles per partition are not practical
+on this hardware so system consoles are accessed by this driver using
+firmware interfaces to virtual terminal devices.
+
+---------------------------------------------------------------------------
+2. System Requirements:
+
+This device driver was written using 2.6.4 Linux kernel APIs and will only
+build and run on kernels of this version or later.
+
+This driver was written to operate solely on IBM Power5 ppc64 hardware
+though some care was taken to abstract the architecture dependent firmware
+calls from the driver code.
+
+Sysfs must be mounted on the system so that the user can determine which
+major and minor numbers are associated with each vty-server. Directions
+for sysfs mounting are outside the scope of this document.
+
+---------------------------------------------------------------------------
+3. Build Options:
+
+The hvcs driver registers itself as a tty driver. The tty layer
+dynamically allocates a block of major and minor numbers in a quantity
+requested by the registering driver. The hvcs driver asks the tty layer
+for 64 of these major/minor numbers by default to use for hvcs device node
+entries.
+
+If the default number of device entries is adequate then this driver can be
+built into the kernel. If not, the default can be over-ridden by inserting
+the driver as a module with insmod parameters.
+
+---------------------------------------------------------------------------
+3.1 Built-in:
+
+The following menuconfig example demonstrates selecting to build this
+driver into the kernel.
+
+ Device Drivers --->
+ Character devices --->
+ <*> IBM Hypervisor Virtual Console Server Support
+
+Begin the kernel make process.
+
+---------------------------------------------------------------------------
+3.2 Module:
+
+The following menuconfig example demonstrates selecting to build this
+driver as a kernel module.
+
+ Device Drivers --->
+ Character devices --->
+ <M> IBM Hypervisor Virtual Console Server Support
+
+The make process will build the following kernel modules:
+
+ hvcs.ko
+ hvcserver.ko
+
+To insert the module with the default allocation execute the following
+commands in the order they appear:
+
+ insmod hvcserver.ko
+ insmod hvcs.ko
+
+The hvcserver module contains architecture specific firmware calls and must
+be inserted first, otherwise the hvcs module will not find some of the
+symbols it expects.
+
+To override the default use an insmod parameter as follows (requesting 4
+tty devices as an example):
+
+ insmod hvcs.ko hvcs_parm_num_devs=4
+
+There is a maximum number of dev entries that can be specified on insmod.
+We think that 1024 is currently a decent maximum number of server adapters
+to allow. This can always be changed by modifying the constant in the
+source file before building.
+
+NOTE: The length of time it takes to insmod the driver seems to be related
+to the number of tty interfaces the registering driver requests.
+
+In order to remove the driver module execute the following command:
+
+ rmmod hvcs.ko
+
+The recommended method for installing hvcs as a module is to use depmod to
+build a current modules.dep file in /lib/modules/`uname -r` and then
+execute:
+
+modprobe hvcs hvcs_parm_num_devs=4
+
+The modules.dep file indicates that hvcserver.ko needs to be inserted
+before hvcs.ko and modprobe uses this file to smartly insert the modules in
+the proper order.
+
+The following modprobe command is used to remove hvcs and hvcserver in the
+proper order:
+
+modprobe -r hvcs
+
+---------------------------------------------------------------------------
+4. Installation:
+
+The tty layer creates sysfs entries which contain the major and minor
+numbers allocated for the hvcs driver. The following snippet of "tree"
+output of the sysfs directory shows where these numbers are presented:
+
+ sys/
+ |-- *other sysfs base dirs*
+ |
+ |-- class
+ | |-- *other classes of devices*
+ | |
+ | `-- tty
+ | |-- *other tty devices*
+ | |
+ | |-- hvcs0
+ | | `-- dev
+ | |-- hvcs1
+ | | `-- dev
+ | |-- hvcs2
+ | | `-- dev
+ | |-- hvcs3
+ | | `-- dev
+ | |
+ | |-- *other tty devices*
+ |
+ |-- *other sysfs base dirs*
+
+For the above examples the following output is a result of cat'ing the
+"dev" entry in the hvcs directory:
+
+ Pow5:/sys/class/tty/hvcs0/ # cat dev
+ 254:0
+
+ Pow5:/sys/class/tty/hvcs1/ # cat dev
+ 254:1
+
+ Pow5:/sys/class/tty/hvcs2/ # cat dev
+ 254:2
+
+ Pow5:/sys/class/tty/hvcs3/ # cat dev
+ 254:3
+
+The output from reading the "dev" attribute is the char device major and
+minor numbers that the tty layer has allocated for this driver's use. Most
+systems running hvcs will already have the device entries created or udev
+will do it automatically.
+
+Given the example output above, to manually create a /dev/hvcs* node entry
+mknod can be used as follows:
+
+ mknod /dev/hvcs0 c 254 0
+ mknod /dev/hvcs1 c 254 1
+ mknod /dev/hvcs2 c 254 2
+ mknod /dev/hvcs3 c 254 3
+
+Using mknod to manually create the device entries makes these device nodes
+persistent. Once created they will exist prior to the driver insmod.
+
+Attempting to connect an application to /dev/hvcs* prior to insertion of
+the hvcs module will result in an error message similar to the following:
+
+ "/dev/hvcs*: No such device".
+
+NOTE: Just because there is a device node present doesn't mean that there
+is a vty-server device configured for that node.
+
+---------------------------------------------------------------------------
+5. Connection
+
+Since this driver controls devices that provide a tty interface a user can
+interact with the device node entries using any standard tty-interactive
+method (e.g. "cat", "dd", "echo"). The intent of this driver however, is
+to provide real time console interaction with a Linux partition's console,
+which requires the use of applications that provide bi-directional,
+interactive I/O with a tty device.
+
+Applications (e.g. "minicom" and "screen") that act as terminal emulators
+or perform terminal type control sequence conversion on the data being
+passed through them are NOT acceptable for providing interactive console
+I/O. These programs often emulate antiquated terminal types (vt100 and
+ANSI) and expect inbound data to take the form of one of these supported
+terminal types but they either do not convert, or do not _adequately_
+convert, outbound data into the terminal type of the terminal which invoked
+them (though screen makes an attempt and can apparently be configured with
+much termcap wrestling.)
+
+For this reason kermit and cu are two of the recommended applications for
+interacting with a Linux console via an hvcs device. These programs simply
+act as a conduit for data transfer to and from the tty device. They do not
+require inbound data to take the form of a particular terminal type, nor do
+they cook outbound data to a particular terminal type.
+
+In order to ensure proper functioning of console applications one must make
+sure that once connected to a /dev/hvcs console that the console's $TERM
+env variable is set to the exact terminal type of the terminal emulator
+used to launch the interactive I/O application. If one is using xterm and
+kermit to connect to /dev/hvcs0 when the console prompt becomes available
+one should "export TERM=xterm" on the console. This tells ncurses
+applications that are invoked from the console that they should output
+control sequences that xterm can understand.
+
+As a precautionary measure an hvcs user should always "exit" from their
+session before disconnecting an application such as kermit from the device
+node. If this is not done, the next user to connect to the console will
+continue using the previous user's logged in session which includes
+using the $TERM variable that the previous user supplied.
+
+Hotplug add and remove of vty-server adapters affects which /dev/hvcs* node
+is used to connect to each vty-server adapter. In order to determine which
+vty-server adapter is associated with which /dev/hvcs* node a special sysfs
+attribute has been added to each vty-server sysfs entry. This entry is
+called "index" and showing it reveals an integer that refers to the
+/dev/hvcs* entry to use to connect to that device. For instance cating the
+index attribute of vty-server adapter 30000004 shows the following.
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000004 # cat index
+ 2
+
+This index of '2' means that in order to connect to vty-server adapter
+30000004 the user should interact with /dev/hvcs2.
+
+It should be noted that due to the system hotplug I/O capabilities of a
+system the /dev/hvcs* entry that interacts with a particular vty-server
+adapter is not guaranteed to remain the same across system reboots. Look
+in the Q & A section for more on this issue.
+
+---------------------------------------------------------------------------
+6. Disconnection
+
+As a security feature to prevent the delivery of stale data to an
+unintended target the Power5 system firmware disables the fetching of data
+and discards that data when a connection between a vty-server and a vty has
+been severed. As an example, when a vty-server is immediately disconnected
+from a vty following output of data to the vty the vty adapter may not have
+enough time between when it received the data interrupt and when the
+connection was severed to fetch the data from firmware before the fetch is
+disabled by firmware.
+
+When hvcs is being used to serve consoles this behavior is not a huge issue
+because the adapter stays connected for large amounts of time following
+almost all data writes. When hvcs is being used as a tty conduit to tunnel
+data between two partitions [see Q & A below] this is a huge problem
+because the standard Linux behavior when cat'ing or dd'ing data to a device
+is to open the tty, send the data, and then close the tty. If this driver
+manually terminated vty-server connections on tty close this would close
+the vty-server and vty connection before the target vty has had a chance to
+fetch the data.
+
+Additionally, disconnecting a vty-server and vty only on module removal or
+adapter removal is impractical because other vty-servers in other
+partitions may require the usage of the target vty at any time.
+
+Due to this behavioral restriction disconnection of vty-servers from the
+connected vty is a manual procedure using a write to a sysfs attribute
+outlined below, on the other hand the initial vty-server connection to a
+vty is established automatically by this driver. Manual vty-server
+connection is never required.
+
+In order to terminate the connection between a vty-server and vty the
+"vterm_state" sysfs attribute within each vty-server's sysfs entry is used.
+Reading this attribute reveals the current connection state of the
+vty-server adapter. A zero means that the vty-server is not connected to a
+vty. A one indicates that a connection is active.
+
+Writing a '0' (zero) to the vterm_state attribute will disconnect the VTERM
+connection between the vty-server and target vty ONLY if the vterm_state
+previously read '1'. The write directive is ignored if the vterm_state
+read '0' or if any value other than '0' was written to the vterm_state
+attribute. The following example will show the method used for verifying
+the vty-server connection status and disconnecting a vty-server connection.
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000004 # cat vterm_state
+ 1
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000004 # echo 0 > vterm_state
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000004 # cat vterm_state
+ 0
+
+All vty-server connections are automatically terminated when the device is
+hotplug removed and when the module is removed.
+
+---------------------------------------------------------------------------
+7. Configuration
+
+Each vty-server has a sysfs entry in the /sys/devices/vio directory, which
+is symlinked in several other sysfs tree directories, notably under the
+hvcs driver entry, which looks like the following example:
+
+ Pow5:/sys/bus/vio/drivers/hvcs # ls
+ . .. 30000003 30000004 rescan
+
+By design, firmware notifies the hvcs driver of vty-server lifetimes and
+partner vty removals but not the addition of partner vtys. Since an HMC
+Super Admin can add partner info dynamically we have provided the hvcs
+driver sysfs directory with the "rescan" update attribute which will query
+firmware and update the partner info for all the vty-servers that this
+driver manages. Writing a '1' to the attribute triggers the update. An
+explicit example follows:
+
+ Pow5:/sys/bus/vio/drivers/hvcs # echo 1 > rescan
+
+Reading the attribute will indicate a state of '1' or '0'. A one indicates
+that an update is in process. A zero indicates that an update has
+completed or was never executed.
+
+Vty-server entries in this directory are a 32 bit partition unique unit
+address that is created by firmware. An example vty-server sysfs entry
+looks like the following:
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000004 # ls
+ . current_vty devspec name partner_vtys
+ .. index partner_clcs vterm_state
+
+Each entry is provided, by default with a "name" attribute. Reading the
+"name" attribute will reveal the device type as shown in the following
+example:
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000003 # cat name
+ vty-server
+
+Each entry is also provided, by default, with a "devspec" attribute which
+reveals the full device specification when read, as shown in the following
+example:
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000004 # cat devspec
+ /vdevice/vty-server@30000004
+
+Each vty-server sysfs dir is provided with two read-only attributes that
+provide lists of easily parsed partner vty data: "partner_vtys" and
+"partner_clcs".
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000004 # cat partner_vtys
+ 30000000
+ 30000001
+ 30000002
+ 30000000
+ 30000000
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000004 # cat partner_clcs
+ U5112.428.103048A-V3-C0
+ U5112.428.103048A-V3-C2
+ U5112.428.103048A-V3-C3
+ U5112.428.103048A-V4-C0
+ U5112.428.103048A-V5-C0
+
+Reading partner_vtys returns a list of partner vtys. Vty unit address
+numbering is only per-partition-unique so entries will frequently repeat.
+
+Reading partner_clcs returns a list of "converged location codes" which are
+composed of a system serial number followed by "-V*", where the '*' is the
+target partition number, and "-C*", where the '*' is the slot of the
+adapter. The first vty partner corresponds to the first clc item, the
+second vty partner to the second clc item, etc.
+
+A vty-server can only be connected to a single vty at a time. The entry,
+"current_vty" prints the clc of the currently selected partner vty when
+read.
+
+The current_vty can be changed by writing a valid partner clc to the entry
+as in the following example:
+
+ Pow5:/sys/bus/vio/drivers/hvcs/30000004 # echo U5112.428.10304
+ 8A-V4-C0 > current_vty
+
+Changing the current_vty when a vty-server is already connected to a vty
+does not affect the current connection. The change takes effect when the
+currently open connection is freed.
+
+Information on the "vterm_state" attribute was covered earlier on the
+chapter entitled "disconnection".
+
+---------------------------------------------------------------------------
+8. Questions & Answers:
+===========================================================================
+Q: What are the security concerns involving hvcs?
+
+A: There are three main security concerns:
+
+ 1. The creator of the /dev/hvcs* nodes has the ability to restrict
+ the access of the device entries to certain users or groups. It
+ may be best to create a special hvcs group privilege for providing
+ access to system consoles.
+
+ 2. To provide network security when grabbing the console it is
+ suggested that the user connect to the console hosting partition
+ using a secure method, such as SSH or sit at a hardware console.
+
+ 3. Make sure to exit the user session when done with a console or
+ the next vty-server connection (which may be from another
+ partition) will experience the previously logged in session.
+
+---------------------------------------------------------------------------
+Q: How do I multiplex a console that I grab through hvcs so that other
+people can see it:
+
+A: You can use "screen" to directly connect to the /dev/hvcs* device and
+setup a session on your machine with the console group privileges. As
+pointed out earlier by default screen doesn't provide the termcap settings
+for most terminal emulators to provide adequate character conversion from
+term type "screen" to others. This means that curses based programs may
+not display properly in screen sessions.
+
+---------------------------------------------------------------------------
+Q: Why are the colors all messed up?
+Q: Why are the control characters acting strange or not working?
+Q: Why is the console output all strange and unintelligible?
+
+A: Please see the preceding section on "Connection" for a discussion of how
+applications can affect the display of character control sequences.
+Additionally, just because you logged into the console using and xterm
+doesn't mean someone else didn't log into the console with the HMC console
+(vt320) before you and leave the session logged in. The best thing to do
+is to export TERM to the terminal type of your terminal emulator when you
+get the console. Additionally make sure to "exit" the console before you
+disconnect from the console. This will ensure that the next user gets
+their own TERM type set when they login.
+
+---------------------------------------------------------------------------
+Q: When I try to CONNECT kermit to an hvcs device I get:
+"Sorry, can't open connection: /dev/hvcs*"What is happening?
+
+A: Some other Power5 console mechanism has a connection to the vty and
+isn't giving it up. You can try to force disconnect the consoles from the
+HMC by right clicking on the partition and then selecting "close terminal".
+Otherwise you have to hunt down the people who have console authority. It
+is possible that you already have the console open using another kermit
+session and just forgot about it. Please review the console options for
+Power5 systems to determine the many ways a system console can be held.
+
+OR
+
+A: Another user may not have a connectivity method currently attached to a
+/dev/hvcs device but the vterm_state may reveal that they still have the
+vty-server connection established. They need to free this using the method
+outlined in the section on "Disconnection" in order for others to connect
+to the target vty.
+
+OR
+
+A: The user profile you are using to execute kermit probably doesn't have
+permissions to use the /dev/hvcs* device.
+
+OR
+
+A: You probably haven't inserted the hvcs.ko module yet but the /dev/hvcs*
+entry still exists (on systems without udev).
+
+OR
+
+A: There is not a corresponding vty-server device that maps to an existing
+/dev/hvcs* entry.
+
+---------------------------------------------------------------------------
+Q: When I try to CONNECT kermit to an hvcs device I get:
+"Sorry, write access to UUCP lockfile directory denied."
+
+A: The /dev/hvcs* entry you have specified doesn't exist where you said it
+does? Maybe you haven't inserted the module (on systems with udev).
+
+---------------------------------------------------------------------------
+Q: If I already have one Linux partition installed can I use hvcs on said
+partition to provide the console for the install of a second Linux
+partition?
+
+A: Yes granted that your are connected to the /dev/hvcs* device using
+kermit or cu or some other program that doesn't provide terminal emulation.
+
+---------------------------------------------------------------------------
+Q: Can I connect to more than one partition's console at a time using this
+driver?
+
+A: Yes. Of course this means that there must be more than one vty-server
+configured for this partition and each must point to a disconnected vty.
+
+---------------------------------------------------------------------------
+Q: Does the hvcs driver support dynamic (hotplug) addition of devices?
+
+A: Yes, if you have dlpar and hotplug enabled for your system and it has
+been built into the kernel the hvcs drivers is configured to dynamically
+handle additions of new devices and removals of unused devices.
+
+---------------------------------------------------------------------------
+Q: For some reason /dev/hvcs* doesn't map to the same vty-server adapter
+after a reboot. What happened?
+
+A: Assignment of vty-server adapters to /dev/hvcs* entries is always done
+in the order that the adapters are exposed. Due to hotplug capabilities of
+this driver assignment of hotplug added vty-servers may be in a different
+order than how they would be exposed on module load. Rebooting or
+reloading the module after dynamic addition may result in the /dev/hvcs*
+and vty-server coupling changing if a vty-server adapter was added in a
+slot between two other vty-server adapters. Refer to the section above
+on how to determine which vty-server goes with which /dev/hvcs* node.
+Hint; look at the sysfs "index" attribute for the vty-server.
+
+---------------------------------------------------------------------------
+Q: Can I use /dev/hvcs* as a conduit to another partition and use a tty
+device on that partition as the other end of the pipe?
+
+A: Yes, on Power5 platforms the hvc_console driver provides a tty interface
+for extra /dev/hvc* devices (where /dev/hvc0 is most likely the console).
+In order to get a tty conduit working between the two partitions the HMC
+Super Admin must create an additional "serial server" for the target
+partition with the HMC gui which will show up as /dev/hvc* when the target
+partition is rebooted.
+
+The HMC Super Admin then creates an additional "serial client" for the
+current partition and points this at the target partition's newly created
+"serial server" adapter (remember the slot). This shows up as an
+additional /dev/hvcs* device.
+
+Now a program on the target system can be configured to read or write to
+/dev/hvc* and another program on the current partition can be configured to
+read or write to /dev/hvcs*. Now you have a tty conduit between two
+partitions.
+
+---------------------------------------------------------------------------
+9. Reporting Bugs:
+
+The proper channel for reporting bugs is either through the Linux OS
+distribution company that provided your OS or by posting issues to the
+PowerPC development mailing list at:
+
+linuxppc-dev@lists.ozlabs.org
+
+This request is to provide a documented and searchable public exchange
+of the problems and solutions surrounding this driver for the benefit of
+all users.
diff --git a/Documentation/powerpc/mpc52xx.txt b/Documentation/powerpc/mpc52xx.txt
new file mode 100644
index 000000000..0d540a31e
--- /dev/null
+++ b/Documentation/powerpc/mpc52xx.txt
@@ -0,0 +1,39 @@
+Linux 2.6.x on MPC52xx family
+-----------------------------
+
+For the latest info, go to http://www.246tNt.com/mpc52xx/
+
+To compile/use :
+
+ - U-Boot:
+ # <edit Makefile to set ARCH=ppc & CROSS_COMPILE=... ( also EXTRAVERSION
+ if you wish to ).
+ # make lite5200_defconfig
+ # make uImage
+
+ then, on U-boot:
+ => tftpboot 200000 uImage
+ => tftpboot 400000 pRamdisk
+ => bootm 200000 400000
+
+ - DBug:
+ # <edit Makefile to set ARCH=ppc & CROSS_COMPILE=... ( also EXTRAVERSION
+ if you wish to ).
+ # make lite5200_defconfig
+ # cp your_initrd.gz arch/ppc/boot/images/ramdisk.image.gz
+ # make zImage.initrd
+ # make
+
+ then in DBug:
+ DBug> dn -i zImage.initrd.lite5200
+
+
+Some remarks :
+ - The port is named mpc52xxx, and config options are PPC_MPC52xx. The MGT5100
+ is not supported, and I'm not sure anyone is interesting in working on it
+ so. I didn't took 5xxx because there's apparently a lot of 5xxx that have
+ nothing to do with the MPC5200. I also included the 'MPC' for the same
+ reason.
+ - Of course, I inspired myself from the 2.4 port. If you think I forgot to
+ mention you/your company in the copyright of some code, I'll correct it
+ ASAP.
diff --git a/Documentation/powerpc/pci_iov_resource_on_powernv.txt b/Documentation/powerpc/pci_iov_resource_on_powernv.txt
new file mode 100644
index 000000000..b55c5cd83
--- /dev/null
+++ b/Documentation/powerpc/pci_iov_resource_on_powernv.txt
@@ -0,0 +1,301 @@
+Wei Yang <weiyang@linux.vnet.ibm.com>
+Benjamin Herrenschmidt <benh@au1.ibm.com>
+Bjorn Helgaas <bhelgaas@google.com>
+26 Aug 2014
+
+This document describes the requirement from hardware for PCI MMIO resource
+sizing and assignment on PowerKVM and how generic PCI code handles this
+requirement. The first two sections describe the concepts of Partitionable
+Endpoints and the implementation on P8 (IODA2). The next two sections talks
+about considerations on enabling SRIOV on IODA2.
+
+1. Introduction to Partitionable Endpoints
+
+A Partitionable Endpoint (PE) is a way to group the various resources
+associated with a device or a set of devices to provide isolation between
+partitions (i.e., filtering of DMA, MSIs etc.) and to provide a mechanism
+to freeze a device that is causing errors in order to limit the possibility
+of propagation of bad data.
+
+There is thus, in HW, a table of PE states that contains a pair of "frozen"
+state bits (one for MMIO and one for DMA, they get set together but can be
+cleared independently) for each PE.
+
+When a PE is frozen, all stores in any direction are dropped and all loads
+return all 1's value. MSIs are also blocked. There's a bit more state that
+captures things like the details of the error that caused the freeze etc., but
+that's not critical.
+
+The interesting part is how the various PCIe transactions (MMIO, DMA, ...)
+are matched to their corresponding PEs.
+
+The following section provides a rough description of what we have on P8
+(IODA2). Keep in mind that this is all per PHB (PCI host bridge). Each PHB
+is a completely separate HW entity that replicates the entire logic, so has
+its own set of PEs, etc.
+
+2. Implementation of Partitionable Endpoints on P8 (IODA2)
+
+P8 supports up to 256 Partitionable Endpoints per PHB.
+
+ * Inbound
+
+ For DMA, MSIs and inbound PCIe error messages, we have a table (in
+ memory but accessed in HW by the chip) that provides a direct
+ correspondence between a PCIe RID (bus/dev/fn) with a PE number.
+ We call this the RTT.
+
+ - For DMA we then provide an entire address space for each PE that can
+ contain two "windows", depending on the value of PCI address bit 59.
+ Each window can be configured to be remapped via a "TCE table" (IOMMU
+ translation table), which has various configurable characteristics
+ not described here.
+
+ - For MSIs, we have two windows in the address space (one at the top of
+ the 32-bit space and one much higher) which, via a combination of the
+ address and MSI value, will result in one of the 2048 interrupts per
+ bridge being triggered. There's a PE# in the interrupt controller
+ descriptor table as well which is compared with the PE# obtained from
+ the RTT to "authorize" the device to emit that specific interrupt.
+
+ - Error messages just use the RTT.
+
+ * Outbound. That's where the tricky part is.
+
+ Like other PCI host bridges, the Power8 IODA2 PHB supports "windows"
+ from the CPU address space to the PCI address space. There is one M32
+ window and sixteen M64 windows. They have different characteristics.
+ First what they have in common: they forward a configurable portion of
+ the CPU address space to the PCIe bus and must be naturally aligned
+ power of two in size. The rest is different:
+
+ - The M32 window:
+
+ * Is limited to 4GB in size.
+
+ * Drops the top bits of the address (above the size) and replaces
+ them with a configurable value. This is typically used to generate
+ 32-bit PCIe accesses. We configure that window at boot from FW and
+ don't touch it from Linux; it's usually set to forward a 2GB
+ portion of address space from the CPU to PCIe
+ 0x8000_0000..0xffff_ffff. (Note: The top 64KB are actually
+ reserved for MSIs but this is not a problem at this point; we just
+ need to ensure Linux doesn't assign anything there, the M32 logic
+ ignores that however and will forward in that space if we try).
+
+ * It is divided into 256 segments of equal size. A table in the chip
+ maps each segment to a PE#. That allows portions of the MMIO space
+ to be assigned to PEs on a segment granularity. For a 2GB window,
+ the segment granularity is 2GB/256 = 8MB.
+
+ Now, this is the "main" window we use in Linux today (excluding
+ SR-IOV). We basically use the trick of forcing the bridge MMIO windows
+ onto a segment alignment/granularity so that the space behind a bridge
+ can be assigned to a PE.
+
+ Ideally we would like to be able to have individual functions in PEs
+ but that would mean using a completely different address allocation
+ scheme where individual function BARs can be "grouped" to fit in one or
+ more segments.
+
+ - The M64 windows:
+
+ * Must be at least 256MB in size.
+
+ * Do not translate addresses (the address on PCIe is the same as the
+ address on the PowerBus). There is a way to also set the top 14
+ bits which are not conveyed by PowerBus but we don't use this.
+
+ * Can be configured to be segmented. When not segmented, we can
+ specify the PE# for the entire window. When segmented, a window
+ has 256 segments; however, there is no table for mapping a segment
+ to a PE#. The segment number *is* the PE#.
+
+ * Support overlaps. If an address is covered by multiple windows,
+ there's a defined ordering for which window applies.
+
+ We have code (fairly new compared to the M32 stuff) that exploits that
+ for large BARs in 64-bit space:
+
+ We configure an M64 window to cover the entire region of address space
+ that has been assigned by FW for the PHB (about 64GB, ignore the space
+ for the M32, it comes out of a different "reserve"). We configure it
+ as segmented.
+
+ Then we do the same thing as with M32, using the bridge alignment
+ trick, to match to those giant segments.
+
+ Since we cannot remap, we have two additional constraints:
+
+ - We do the PE# allocation *after* the 64-bit space has been assigned
+ because the addresses we use directly determine the PE#. We then
+ update the M32 PE# for the devices that use both 32-bit and 64-bit
+ spaces or assign the remaining PE# to 32-bit only devices.
+
+ - We cannot "group" segments in HW, so if a device ends up using more
+ than one segment, we end up with more than one PE#. There is a HW
+ mechanism to make the freeze state cascade to "companion" PEs but
+ that only works for PCIe error messages (typically used so that if
+ you freeze a switch, it freezes all its children). So we do it in
+ SW. We lose a bit of effectiveness of EEH in that case, but that's
+ the best we found. So when any of the PEs freezes, we freeze the
+ other ones for that "domain". We thus introduce the concept of
+ "master PE" which is the one used for DMA, MSIs, etc., and "secondary
+ PEs" that are used for the remaining M64 segments.
+
+ We would like to investigate using additional M64 windows in "single
+ PE" mode to overlay over specific BARs to work around some of that, for
+ example for devices with very large BARs, e.g., GPUs. It would make
+ sense, but we haven't done it yet.
+
+3. Considerations for SR-IOV on PowerKVM
+
+ * SR-IOV Background
+
+ The PCIe SR-IOV feature allows a single Physical Function (PF) to
+ support several Virtual Functions (VFs). Registers in the PF's SR-IOV
+ Capability control the number of VFs and whether they are enabled.
+
+ When VFs are enabled, they appear in Configuration Space like normal
+ PCI devices, but the BARs in VF config space headers are unusual. For
+ a non-VF device, software uses BARs in the config space header to
+ discover the BAR sizes and assign addresses for them. For VF devices,
+ software uses VF BAR registers in the *PF* SR-IOV Capability to
+ discover sizes and assign addresses. The BARs in the VF's config space
+ header are read-only zeros.
+
+ When a VF BAR in the PF SR-IOV Capability is programmed, it sets the
+ base address for all the corresponding VF(n) BARs. For example, if the
+ PF SR-IOV Capability is programmed to enable eight VFs, and it has a
+ 1MB VF BAR0, the address in that VF BAR sets the base of an 8MB region.
+ This region is divided into eight contiguous 1MB regions, each of which
+ is a BAR0 for one of the VFs. Note that even though the VF BAR
+ describes an 8MB region, the alignment requirement is for a single VF,
+ i.e., 1MB in this example.
+
+ There are several strategies for isolating VFs in PEs:
+
+ - M32 window: There's one M32 window, and it is split into 256
+ equally-sized segments. The finest granularity possible is a 256MB
+ window with 1MB segments. VF BARs that are 1MB or larger could be
+ mapped to separate PEs in this window. Each segment can be
+ individually mapped to a PE via the lookup table, so this is quite
+ flexible, but it works best when all the VF BARs are the same size. If
+ they are different sizes, the entire window has to be small enough that
+ the segment size matches the smallest VF BAR, which means larger VF
+ BARs span several segments.
+
+ - Non-segmented M64 window: A non-segmented M64 window is mapped entirely
+ to a single PE, so it could only isolate one VF.
+
+ - Single segmented M64 windows: A segmented M64 window could be used just
+ like the M32 window, but the segments can't be individually mapped to
+ PEs (the segment number is the PE#), so there isn't as much
+ flexibility. A VF with multiple BARs would have to be in a "domain" of
+ multiple PEs, which is not as well isolated as a single PE.
+
+ - Multiple segmented M64 windows: As usual, each window is split into 256
+ equally-sized segments, and the segment number is the PE#. But if we
+ use several M64 windows, they can be set to different base addresses
+ and different segment sizes. If we have VFs that each have a 1MB BAR
+ and a 32MB BAR, we could use one M64 window to assign 1MB segments and
+ another M64 window to assign 32MB segments.
+
+ Finally, the plan to use M64 windows for SR-IOV, which will be described
+ more in the next two sections. For a given VF BAR, we need to
+ effectively reserve the entire 256 segments (256 * VF BAR size) and
+ position the VF BAR to start at the beginning of a free range of
+ segments/PEs inside that M64 window.
+
+ The goal is of course to be able to give a separate PE for each VF.
+
+ The IODA2 platform has 16 M64 windows, which are used to map MMIO
+ range to PE#. Each M64 window defines one MMIO range and this range is
+ divided into 256 segments, with each segment corresponding to one PE.
+
+ We decide to leverage this M64 window to map VFs to individual PEs, since
+ SR-IOV VF BARs are all the same size.
+
+ But doing so introduces another problem: total_VFs is usually smaller
+ than the number of M64 window segments, so if we map one VF BAR directly
+ to one M64 window, some part of the M64 window will map to another
+ device's MMIO range.
+
+ IODA supports 256 PEs, so segmented windows contain 256 segments, so if
+ total_VFs is less than 256, we have the situation in Figure 1.0, where
+ segments [total_VFs, 255] of the M64 window may map to some MMIO range on
+ other devices:
+
+ 0 1 total_VFs - 1
+ +------+------+- -+------+------+
+ | | | ... | | |
+ +------+------+- -+------+------+
+
+ VF(n) BAR space
+
+ 0 1 total_VFs - 1 255
+ +------+------+- -+------+------+- -+------+------+
+ | | | ... | | | ... | | |
+ +------+------+- -+------+------+- -+------+------+
+
+ M64 window
+
+ Figure 1.0 Direct map VF(n) BAR space
+
+ Our current solution is to allocate 256 segments even if the VF(n) BAR
+ space doesn't need that much, as shown in Figure 1.1:
+
+ 0 1 total_VFs - 1 255
+ +------+------+- -+------+------+- -+------+------+
+ | | | ... | | | ... | | |
+ +------+------+- -+------+------+- -+------+------+
+
+ VF(n) BAR space + extra
+
+ 0 1 total_VFs - 1 255
+ +------+------+- -+------+------+- -+------+------+
+ | | | ... | | | ... | | |
+ +------+------+- -+------+------+- -+------+------+
+
+ M64 window
+
+ Figure 1.1 Map VF(n) BAR space + extra
+
+ Allocating the extra space ensures that the entire M64 window will be
+ assigned to this one SR-IOV device and none of the space will be
+ available for other devices. Note that this only expands the space
+ reserved in software; there are still only total_VFs VFs, and they only
+ respond to segments [0, total_VFs - 1]. There's nothing in hardware that
+ responds to segments [total_VFs, 255].
+
+4. Implications for the Generic PCI Code
+
+The PCIe SR-IOV spec requires that the base of the VF(n) BAR space be
+aligned to the size of an individual VF BAR.
+
+In IODA2, the MMIO address determines the PE#. If the address is in an M32
+window, we can set the PE# by updating the table that translates segments
+to PE#s. Similarly, if the address is in an unsegmented M64 window, we can
+set the PE# for the window. But if it's in a segmented M64 window, the
+segment number is the PE#.
+
+Therefore, the only way to control the PE# for a VF is to change the base
+of the VF(n) BAR space in the VF BAR. If the PCI core allocates the exact
+amount of space required for the VF(n) BAR space, the VF BAR value is fixed
+and cannot be changed.
+
+On the other hand, if the PCI core allocates additional space, the VF BAR
+value can be changed as long as the entire VF(n) BAR space remains inside
+the space allocated by the core.
+
+Ideally the segment size will be the same as an individual VF BAR size.
+Then each VF will be in its own PE. The VF BARs (and therefore the PE#s)
+are contiguous. If VF0 is in PE(x), then VF(n) is in PE(x+n). If we
+allocate 256 segments, there are (256 - numVFs) choices for the PE# of VF0.
+
+If the segment size is smaller than the VF BAR size, it will take several
+segments to cover a VF BAR, and a VF will be in several PEs. This is
+possible, but the isolation isn't as good, and it reduces the number of PE#
+choices because instead of consuming only numVFs segments, the VF(n) BAR
+space will consume (numVFs * n) segments. That means there aren't as many
+available segments for adjusting base of the VF(n) BAR space.
diff --git a/Documentation/powerpc/pmu-ebb.txt b/Documentation/powerpc/pmu-ebb.txt
new file mode 100644
index 000000000..73cd163db
--- /dev/null
+++ b/Documentation/powerpc/pmu-ebb.txt
@@ -0,0 +1,137 @@
+PMU Event Based Branches
+========================
+
+Event Based Branches (EBBs) are a feature which allows the hardware to
+branch directly to a specified user space address when certain events occur.
+
+The full specification is available in Power ISA v2.07:
+
+ https://www.power.org/documentation/power-isa-version-2-07/
+
+One type of event for which EBBs can be configured is PMU exceptions. This
+document describes the API for configuring the Power PMU to generate EBBs,
+using the Linux perf_events API.
+
+
+Terminology
+-----------
+
+Throughout this document we will refer to an "EBB event" or "EBB events". This
+just refers to a struct perf_event which has set the "EBB" flag in its
+attr.config. All events which can be configured on the hardware PMU are
+possible "EBB events".
+
+
+Background
+----------
+
+When a PMU EBB occurs it is delivered to the currently running process. As such
+EBBs can only sensibly be used by programs for self-monitoring.
+
+It is a feature of the perf_events API that events can be created on other
+processes, subject to standard permission checks. This is also true of EBB
+events, however unless the target process enables EBBs (via mtspr(BESCR)) no
+EBBs will ever be delivered.
+
+This makes it possible for a process to enable EBBs for itself, but not
+actually configure any events. At a later time another process can come along
+and attach an EBB event to the process, which will then cause EBBs to be
+delivered to the first process. It's not clear if this is actually useful.
+
+
+When the PMU is configured for EBBs, all PMU interrupts are delivered to the
+user process. This means once an EBB event is scheduled on the PMU, no non-EBB
+events can be configured. This means that EBB events can not be run
+concurrently with regular 'perf' commands, or any other perf events.
+
+It is however safe to run 'perf' commands on a process which is using EBBs. The
+kernel will in general schedule the EBB event, and perf will be notified that
+its events could not run.
+
+The exclusion between EBB events and regular events is implemented using the
+existing "pinned" and "exclusive" attributes of perf_events. This means EBB
+events will be given priority over other events, unless they are also pinned.
+If an EBB event and a regular event are both pinned, then whichever is enabled
+first will be scheduled and the other will be put in error state. See the
+section below titled "Enabling an EBB event" for more information.
+
+
+Creating an EBB event
+---------------------
+
+To request that an event is counted using EBB, the event code should have bit
+63 set.
+
+EBB events must be created with a particular, and restrictive, set of
+attributes - this is so that they interoperate correctly with the rest of the
+perf_events subsystem.
+
+An EBB event must be created with the "pinned" and "exclusive" attributes set.
+Note that if you are creating a group of EBB events, only the leader can have
+these attributes set.
+
+An EBB event must NOT set any of the "inherit", "sample_period", "freq" or
+"enable_on_exec" attributes.
+
+An EBB event must be attached to a task. This is specified to perf_event_open()
+by passing a pid value, typically 0 indicating the current task.
+
+All events in a group must agree on whether they want EBB. That is all events
+must request EBB, or none may request EBB.
+
+EBB events must specify the PMC they are to be counted on. This ensures
+userspace is able to reliably determine which PMC the event is scheduled on.
+
+
+Enabling an EBB event
+---------------------
+
+Once an EBB event has been successfully opened, it must be enabled with the
+perf_events API. This can be achieved either via the ioctl() interface, or the
+prctl() interface.
+
+However, due to the design of the perf_events API, enabling an event does not
+guarantee that it has been scheduled on the PMU. To ensure that the EBB event
+has been scheduled on the PMU, you must perform a read() on the event. If the
+read() returns EOF, then the event has not been scheduled and EBBs are not
+enabled.
+
+This behaviour occurs because the EBB event is pinned and exclusive. When the
+EBB event is enabled it will force all other non-pinned events off the PMU. In
+this case the enable will be successful. However if there is already an event
+pinned on the PMU then the enable will not be successful.
+
+
+Reading an EBB event
+--------------------
+
+It is possible to read() from an EBB event. However the results are
+meaningless. Because interrupts are being delivered to the user process the
+kernel is not able to count the event, and so will return a junk value.
+
+
+Closing an EBB event
+--------------------
+
+When an EBB event is finished with, you can close it using close() as for any
+regular event. If this is the last EBB event the PMU will be deconfigured and
+no further PMU EBBs will be delivered.
+
+
+EBB Handler
+-----------
+
+The EBB handler is just regular userspace code, however it must be written in
+the style of an interrupt handler. When the handler is entered all registers
+are live (possibly) and so must be saved somehow before the handler can invoke
+other code.
+
+It's up to the program how to handle this. For C programs a relatively simple
+option is to create an interrupt frame on the stack and save registers there.
+
+Fork
+----
+
+EBB events are not inherited across fork. If the child process wishes to use
+EBBs it should open a new event for itself. Similarly the EBB state in
+BESCR/EBBHR/EBBRR is cleared across fork().
diff --git a/Documentation/powerpc/ptrace.txt b/Documentation/powerpc/ptrace.txt
new file mode 100644
index 000000000..99c5ce88d
--- /dev/null
+++ b/Documentation/powerpc/ptrace.txt
@@ -0,0 +1,151 @@
+GDB intends to support the following hardware debug features of BookE
+processors:
+
+4 hardware breakpoints (IAC)
+2 hardware watchpoints (read, write and read-write) (DAC)
+2 value conditions for the hardware watchpoints (DVC)
+
+For that, we need to extend ptrace so that GDB can query and set these
+resources. Since we're extending, we're trying to create an interface
+that's extendable and that covers both BookE and server processors, so
+that GDB doesn't need to special-case each of them. We added the
+following 3 new ptrace requests.
+
+1. PTRACE_PPC_GETHWDEBUGINFO
+
+Query for GDB to discover the hardware debug features. The main info to
+be returned here is the minimum alignment for the hardware watchpoints.
+BookE processors don't have restrictions here, but server processors have
+an 8-byte alignment restriction for hardware watchpoints. We'd like to avoid
+adding special cases to GDB based on what it sees in AUXV.
+
+Since we're at it, we added other useful info that the kernel can return to
+GDB: this query will return the number of hardware breakpoints, hardware
+watchpoints and whether it supports a range of addresses and a condition.
+The query will fill the following structure provided by the requesting process:
+
+struct ppc_debug_info {
+ unit32_t version;
+ unit32_t num_instruction_bps;
+ unit32_t num_data_bps;
+ unit32_t num_condition_regs;
+ unit32_t data_bp_alignment;
+ unit32_t sizeof_condition; /* size of the DVC register */
+ uint64_t features; /* bitmask of the individual flags */
+};
+
+features will have bits indicating whether there is support for:
+
+#define PPC_DEBUG_FEATURE_INSN_BP_RANGE 0x1
+#define PPC_DEBUG_FEATURE_INSN_BP_MASK 0x2
+#define PPC_DEBUG_FEATURE_DATA_BP_RANGE 0x4
+#define PPC_DEBUG_FEATURE_DATA_BP_MASK 0x8
+#define PPC_DEBUG_FEATURE_DATA_BP_DAWR 0x10
+
+2. PTRACE_SETHWDEBUG
+
+Sets a hardware breakpoint or watchpoint, according to the provided structure:
+
+struct ppc_hw_breakpoint {
+ uint32_t version;
+#define PPC_BREAKPOINT_TRIGGER_EXECUTE 0x1
+#define PPC_BREAKPOINT_TRIGGER_READ 0x2
+#define PPC_BREAKPOINT_TRIGGER_WRITE 0x4
+ uint32_t trigger_type; /* only some combinations allowed */
+#define PPC_BREAKPOINT_MODE_EXACT 0x0
+#define PPC_BREAKPOINT_MODE_RANGE_INCLUSIVE 0x1
+#define PPC_BREAKPOINT_MODE_RANGE_EXCLUSIVE 0x2
+#define PPC_BREAKPOINT_MODE_MASK 0x3
+ uint32_t addr_mode; /* address match mode */
+
+#define PPC_BREAKPOINT_CONDITION_MODE 0x3
+#define PPC_BREAKPOINT_CONDITION_NONE 0x0
+#define PPC_BREAKPOINT_CONDITION_AND 0x1
+#define PPC_BREAKPOINT_CONDITION_EXACT 0x1 /* different name for the same thing as above */
+#define PPC_BREAKPOINT_CONDITION_OR 0x2
+#define PPC_BREAKPOINT_CONDITION_AND_OR 0x3
+#define PPC_BREAKPOINT_CONDITION_BE_ALL 0x00ff0000 /* byte enable bits */
+#define PPC_BREAKPOINT_CONDITION_BE(n) (1<<((n)+16))
+ uint32_t condition_mode; /* break/watchpoint condition flags */
+
+ uint64_t addr;
+ uint64_t addr2;
+ uint64_t condition_value;
+};
+
+A request specifies one event, not necessarily just one register to be set.
+For instance, if the request is for a watchpoint with a condition, both the
+DAC and DVC registers will be set in the same request.
+
+With this GDB can ask for all kinds of hardware breakpoints and watchpoints
+that the BookE supports. COMEFROM breakpoints available in server processors
+are not contemplated, but that is out of the scope of this work.
+
+ptrace will return an integer (handle) uniquely identifying the breakpoint or
+watchpoint just created. This integer will be used in the PTRACE_DELHWDEBUG
+request to ask for its removal. Return -ENOSPC if the requested breakpoint
+can't be allocated on the registers.
+
+Some examples of using the structure to:
+
+- set a breakpoint in the first breakpoint register
+
+ p.version = PPC_DEBUG_CURRENT_VERSION;
+ p.trigger_type = PPC_BREAKPOINT_TRIGGER_EXECUTE;
+ p.addr_mode = PPC_BREAKPOINT_MODE_EXACT;
+ p.condition_mode = PPC_BREAKPOINT_CONDITION_NONE;
+ p.addr = (uint64_t) address;
+ p.addr2 = 0;
+ p.condition_value = 0;
+
+- set a watchpoint which triggers on reads in the second watchpoint register
+
+ p.version = PPC_DEBUG_CURRENT_VERSION;
+ p.trigger_type = PPC_BREAKPOINT_TRIGGER_READ;
+ p.addr_mode = PPC_BREAKPOINT_MODE_EXACT;
+ p.condition_mode = PPC_BREAKPOINT_CONDITION_NONE;
+ p.addr = (uint64_t) address;
+ p.addr2 = 0;
+ p.condition_value = 0;
+
+- set a watchpoint which triggers only with a specific value
+
+ p.version = PPC_DEBUG_CURRENT_VERSION;
+ p.trigger_type = PPC_BREAKPOINT_TRIGGER_READ;
+ p.addr_mode = PPC_BREAKPOINT_MODE_EXACT;
+ p.condition_mode = PPC_BREAKPOINT_CONDITION_AND | PPC_BREAKPOINT_CONDITION_BE_ALL;
+ p.addr = (uint64_t) address;
+ p.addr2 = 0;
+ p.condition_value = (uint64_t) condition;
+
+- set a ranged hardware breakpoint
+
+ p.version = PPC_DEBUG_CURRENT_VERSION;
+ p.trigger_type = PPC_BREAKPOINT_TRIGGER_EXECUTE;
+ p.addr_mode = PPC_BREAKPOINT_MODE_RANGE_INCLUSIVE;
+ p.condition_mode = PPC_BREAKPOINT_CONDITION_NONE;
+ p.addr = (uint64_t) begin_range;
+ p.addr2 = (uint64_t) end_range;
+ p.condition_value = 0;
+
+- set a watchpoint in server processors (BookS)
+
+ p.version = 1;
+ p.trigger_type = PPC_BREAKPOINT_TRIGGER_RW;
+ p.addr_mode = PPC_BREAKPOINT_MODE_RANGE_INCLUSIVE;
+ or
+ p.addr_mode = PPC_BREAKPOINT_MODE_EXACT;
+
+ p.condition_mode = PPC_BREAKPOINT_CONDITION_NONE;
+ p.addr = (uint64_t) begin_range;
+ /* For PPC_BREAKPOINT_MODE_RANGE_INCLUSIVE addr2 needs to be specified, where
+ * addr2 - addr <= 8 Bytes.
+ */
+ p.addr2 = (uint64_t) end_range;
+ p.condition_value = 0;
+
+3. PTRACE_DELHWDEBUG
+
+Takes an integer which identifies an existing breakpoint or watchpoint
+(i.e., the value returned from PTRACE_SETHWDEBUG), and deletes the
+corresponding breakpoint or watchpoint..
diff --git a/Documentation/powerpc/qe_firmware.txt b/Documentation/powerpc/qe_firmware.txt
new file mode 100644
index 000000000..e7ac24aec
--- /dev/null
+++ b/Documentation/powerpc/qe_firmware.txt
@@ -0,0 +1,295 @@
+ Freescale QUICC Engine Firmware Uploading
+ -----------------------------------------
+
+(c) 2007 Timur Tabi <timur at freescale.com>,
+ Freescale Semiconductor
+
+Table of Contents
+=================
+
+ I - Software License for Firmware
+
+ II - Microcode Availability
+
+ III - Description and Terminology
+
+ IV - Microcode Programming Details
+
+ V - Firmware Structure Layout
+
+ VI - Sample Code for Creating Firmware Files
+
+Revision Information
+====================
+
+November 30, 2007: Rev 1.0 - Initial version
+
+I - Software License for Firmware
+=================================
+
+Each firmware file comes with its own software license. For information on
+the particular license, please see the license text that is distributed with
+the firmware.
+
+II - Microcode Availability
+===========================
+
+Firmware files are distributed through various channels. Some are available on
+http://opensource.freescale.com. For other firmware files, please contact
+your Freescale representative or your operating system vendor.
+
+III - Description and Terminology
+================================
+
+In this document, the term 'microcode' refers to the sequence of 32-bit
+integers that compose the actual QE microcode.
+
+The term 'firmware' refers to a binary blob that contains the microcode as
+well as other data that
+
+ 1) describes the microcode's purpose
+ 2) describes how and where to upload the microcode
+ 3) specifies the values of various registers
+ 4) includes additional data for use by specific device drivers
+
+Firmware files are binary files that contain only a firmware.
+
+IV - Microcode Programming Details
+===================================
+
+The QE architecture allows for only one microcode present in I-RAM for each
+RISC processor. To replace any current microcode, a full QE reset (which
+disables the microcode) must be performed first.
+
+QE microcode is uploaded using the following procedure:
+
+1) The microcode is placed into I-RAM at a specific location, using the
+ IRAM.IADD and IRAM.IDATA registers.
+
+2) The CERCR.CIR bit is set to 0 or 1, depending on whether the firmware
+ needs split I-RAM. Split I-RAM is only meaningful for SOCs that have
+ QEs with multiple RISC processors, such as the 8360. Splitting the I-RAM
+ allows each processor to run a different microcode, effectively creating an
+ asymmetric multiprocessing (AMP) system.
+
+3) The TIBCR trap registers are loaded with the addresses of the trap handlers
+ in the microcode.
+
+4) The RSP.ECCR register is programmed with the value provided.
+
+5) If necessary, device drivers that need the virtual traps and extended mode
+ data will use them.
+
+Virtual Microcode Traps
+
+These virtual traps are conditional branches in the microcode. These are
+"soft" provisional introduced in the ROMcode in order to enable higher
+flexibility and save h/w traps If new features are activated or an issue is
+being fixed in the RAM package utilizing they should be activated. This data
+structure signals the microcode which of these virtual traps is active.
+
+This structure contains 6 words that the application should copy to some
+specific been defined. This table describes the structure.
+
+ ---------------------------------------------------------------
+ | Offset in | | Destination Offset | Size of |
+ | array | Protocol | within PRAM | Operand |
+ --------------------------------------------------------------|
+ | 0 | Ethernet | 0xF8 | 4 bytes |
+ | | interworking | | |
+ ---------------------------------------------------------------
+ | 4 | ATM | 0xF8 | 4 bytes |
+ | | interworking | | |
+ ---------------------------------------------------------------
+ | 8 | PPP | 0xF8 | 4 bytes |
+ | | interworking | | |
+ ---------------------------------------------------------------
+ | 12 | Ethernet RX | 0x22 | 1 byte |
+ | | Distributor Page | | |
+ ---------------------------------------------------------------
+ | 16 | ATM Globtal | 0x28 | 1 byte |
+ | | Params Table | | |
+ ---------------------------------------------------------------
+ | 20 | Insert Frame | 0xF8 | 4 bytes |
+ ---------------------------------------------------------------
+
+
+Extended Modes
+
+This is a double word bit array (64 bits) that defines special functionality
+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:
+
+ -----------------------------------------------------------------------
+ | Bit # | Name | Description |
+ -----------------------------------------------------------------------
+ | 0 | General | Indicates that prior to each host command |
+ | | push command | given by the application, the software must |
+ | | | assert a special host command (push command)|
+ | | | CECDR = 0x00800000. |
+ | | | CECR = 0x01c1000f. |
+ -----------------------------------------------------------------------
+ | 1 | UCC ATM | Indicates that after issuing ATM RX INIT |
+ | | RX INIT | command, the host must issue another special|
+ | | push command | command (push command) and immediately |
+ | | | following that re-issue the ATM RX INIT |
+ | | | command. (This makes the sequence of |
+ | | | initializing the ATM receiver a sequence of |
+ | | | three host commands) |
+ | | | CECDR = 0x00800000. |
+ | | | CECR = 0x01c1000f. |
+ -----------------------------------------------------------------------
+ | 2 | Add/remove | Indicates that following the specific host |
+ | | command | command: "Add/Remove entry in Hash Lookup |
+ | | validation | Table" used in Interworking setup, the user |
+ | | | must issue another command. |
+ | | | CECDR = 0xce000003. |
+ | | | CECR = 0x01c10f58. |
+ -----------------------------------------------------------------------
+ | 3 | General push | Indicates that the s/w has to initialize |
+ | | command | some pointers in the Ethernet thread pages |
+ | | | which are used when Header Compression is |
+ | | | activated. The full details of these |
+ | | | pointers is located in the software drivers.|
+ -----------------------------------------------------------------------
+ | 4 | General push | Indicates that after issuing Ethernet TX |
+ | | command | INIT command, user must issue this command |
+ | | | for each SNUM of Ethernet TX thread. |
+ | | | CECDR = 0x00800003. |
+ | | | CECR = 0x7'b{0}, 8'b{Enet TX thread SNUM}, |
+ | | | 1'b{1}, 12'b{0}, 4'b{1} |
+ -----------------------------------------------------------------------
+ | 5 - 31 | N/A | Reserved, set to zero. |
+ -----------------------------------------------------------------------
+
+V - Firmware Structure Layout
+==============================
+
+QE microcode from Freescale is typically provided as a header file. This
+header file contains macros that define the microcode binary itself as well as
+some other data used in uploading that microcode. The format of these files
+do not lend themselves to simple inclusion into other code. Hence,
+the need for a more portable format. This section defines that format.
+
+Instead of distributing a header file, the microcode and related data are
+embedded into a binary blob. This blob is passed to the qe_upload_firmware()
+function, which parses the blob and performs everything necessary to upload
+the microcode.
+
+All integers are big-endian. See the comments for function
+qe_upload_firmware() for up-to-date implementation information.
+
+This structure supports versioning, where the version of the structure is
+embedded into the structure itself. To ensure forward and backwards
+compatibility, all versions of the structure must use the same 'qe_header'
+structure at the beginning.
+
+'header' (type: struct qe_header):
+ The 'length' field is the size, in bytes, of the entire structure,
+ including all the microcode embedded in it, as well as the CRC (if
+ present).
+
+ The 'magic' field is an array of three bytes that contains the letters
+ 'Q', 'E', and 'F'. This is an identifier that indicates that this
+ structure is a QE Firmware structure.
+
+ The 'version' field is a single byte that indicates the version of this
+ structure. If the layout of the structure should ever need to be
+ changed to add support for additional types of microcode, then the
+ version number should also be changed.
+
+The 'id' field is a null-terminated string(suitable for printing) that
+identifies the firmware.
+
+The 'count' field indicates the number of 'microcode' structures. There
+must be one and only one 'microcode' structure for each RISC processor.
+Therefore, this field also represents the number of RISC processors for this
+SOC.
+
+The 'soc' structure contains the SOC numbers and revisions used to match
+the microcode to the SOC itself. Normally, the microcode loader should
+check the data in this structure with the SOC number and revisions, and
+only upload the microcode if there's a match. However, this check is not
+made on all platforms.
+
+Although it is not recommended, you can specify '0' in the soc.model
+field to skip matching SOCs altogether.
+
+The 'model' field is a 16-bit number that matches the actual SOC. The
+'major' and 'minor' fields are the major and minor revision numbers,
+respectively, of the SOC.
+
+For example, to match the 8323, revision 1.0:
+ soc.model = 8323
+ soc.major = 1
+ soc.minor = 0
+
+'padding' is necessary for structure alignment. This field ensures that the
+'extended_modes' field is aligned on a 64-bit boundary.
+
+'extended_modes' is a bitfield that defines special functionality which has an
+impact on the device drivers. Each bit has its own impact and has special
+instructions for the driver associated with it. This field is stored in
+the QE library and available to any driver that calles qe_get_firmware_info().
+
+'vtraps' is an array of 8 words that contain virtual trap values for each
+virtual traps. As with 'extended_modes', this field is stored in the QE
+library and available to any driver that calles qe_get_firmware_info().
+
+'microcode' (type: struct qe_microcode):
+ For each RISC processor there is one 'microcode' structure. The first
+ 'microcode' structure is for the first RISC, and so on.
+
+ The 'id' field is a null-terminated string suitable for printing that
+ identifies this particular microcode.
+
+ 'traps' is an array of 16 words that contain hardware trap values
+ for each of the 16 traps. If trap[i] is 0, then this particular
+ trap is to be ignored (i.e. not written to TIBCR[i]). The entire value
+ is written as-is to the TIBCR[i] register, so be sure to set the EN
+ and T_IBP bits if necessary.
+
+ 'eccr' is the value to program into the ECCR register.
+
+ 'iram_offset' is the offset into IRAM to start writing the
+ microcode.
+
+ 'count' is the number of 32-bit words in the microcode.
+
+ 'code_offset' is the offset, in bytes, from the beginning of this
+ structure where the microcode itself can be found. The first
+ microcode binary should be located immediately after the 'microcode'
+ array.
+
+ 'major', 'minor', and 'revision' are the major, minor, and revision
+ version numbers, respectively, of the microcode. If all values are 0,
+ then these fields are ignored.
+
+ 'reserved' is necessary for structure alignment. Since 'microcode'
+ is an array, the 64-bit 'extended_modes' field needs to be aligned
+ on a 64-bit boundary, and this can only happen if the size of
+ 'microcode' is a multiple of 8 bytes. To ensure that, we add
+ 'reserved'.
+
+After the last microcode is a 32-bit CRC. It can be calculated using
+this algorithm:
+
+u32 crc32(const u8 *p, unsigned int len)
+{
+ unsigned int i;
+ u32 crc = 0;
+
+ while (len--) {
+ crc ^= *p++;
+ for (i = 0; i < 8; i++)
+ crc = (crc >> 1) ^ ((crc & 1) ? 0xedb88320 : 0);
+ }
+ return crc;
+}
+
+VI - Sample Code for Creating Firmware Files
+============================================
+
+A Python program that creates firmware binaries from the header files normally
+distributed by Freescale can be found on http://opensource.freescale.com.
diff --git a/Documentation/powerpc/syscall64-abi.txt b/Documentation/powerpc/syscall64-abi.txt
new file mode 100644
index 000000000..fa716a0d8
--- /dev/null
+++ b/Documentation/powerpc/syscall64-abi.txt
@@ -0,0 +1,105 @@
+===============================================
+Power Architecture 64-bit Linux system call ABI
+===============================================
+
+syscall
+=======
+
+syscall calling sequence[*] matches the Power Architecture 64-bit ELF ABI
+specification C function calling sequence, including register preservation
+rules, with the following differences.
+
+[*] Some syscalls (typically low-level management functions) may have
+ different calling sequences (e.g., rt_sigreturn).
+
+Parameters and return value
+---------------------------
+The system call number is specified in r0.
+
+There is a maximum of 6 integer parameters to a syscall, passed in r3-r8.
+
+Both a return value and a return error code are returned. cr0.SO is the return
+error code, and r3 is the return value or error code. When cr0.SO is clear,
+the syscall succeeded and r3 is the return value. When cr0.SO is set, the
+syscall failed and r3 is the error code that generally corresponds to errno.
+
+Stack
+-----
+System calls do not modify the caller's stack frame. For example, the caller's
+stack frame LR and CR save fields are not used.
+
+Register preservation rules
+---------------------------
+Register preservation rules match the ELF ABI calling sequence with the
+following differences:
+
+r0: Volatile. (System call number.)
+r3: Volatile. (Parameter 1, and return value.)
+r4-r8: Volatile. (Parameters 2-6.)
+cr0: Volatile (cr0.SO is the return error condition)
+cr1, cr5-7: Nonvolatile.
+lr: Nonvolatile.
+
+All floating point and vector data registers as well as control and status
+registers are nonvolatile.
+
+Invocation
+----------
+The syscall is performed with the sc instruction, and returns with execution
+continuing at the instruction following the sc instruction.
+
+Transactional Memory
+--------------------
+Syscall behavior can change if the processor is in transactional or suspended
+transaction state, and the syscall can affect the behavior of the transaction.
+
+If the processor is in suspended state when a syscall is made, the syscall
+will be performed as normal, and will return as normal. The syscall will be
+performed in suspended state, so its side effects will be persistent according
+to the usual transactional memory semantics. A syscall may or may not result
+in the transaction being doomed by hardware.
+
+If the processor is in transactional state when a syscall is made, then the
+behavior depends on the presence of PPC_FEATURE2_HTM_NOSC in the AT_HWCAP2 ELF
+auxiliary vector.
+
+- If present, which is the case for newer kernels, then the syscall will not
+ be performed and the transaction will be doomed by the kernel with the
+ failure code TM_CAUSE_SYSCALL | TM_CAUSE_PERSISTENT in the TEXASR SPR.
+
+- If not present (older kernels), then the kernel will suspend the
+ transactional state and the syscall will proceed as in the case of a
+ suspended state syscall, and will resume the transactional state before
+ returning to the caller. This case is not well defined or supported, so this
+ behavior should not be relied upon.
+
+
+vsyscall
+========
+
+vsyscall calling sequence matches the syscall calling sequence, with the
+following differences. Some vsyscalls may have different calling sequences.
+
+Parameters and return value
+---------------------------
+r0 is not used as an input. The vsyscall is selected by its address.
+
+Stack
+-----
+The vsyscall may or may not use the caller's stack frame save areas.
+
+Register preservation rules
+---------------------------
+r0: Volatile.
+cr1, cr5-7: Volatile.
+lr: Volatile.
+
+Invocation
+----------
+The vsyscall is performed with a branch-with-link instruction to the vsyscall
+function address.
+
+Transactional Memory
+--------------------
+vsyscalls will run in the same transactional state as the caller. A vsyscall
+may or may not result in the transaction being doomed by hardware.
diff --git a/Documentation/powerpc/transactional_memory.txt b/Documentation/powerpc/transactional_memory.txt
new file mode 100644
index 000000000..52c023e14
--- /dev/null
+++ b/Documentation/powerpc/transactional_memory.txt
@@ -0,0 +1,244 @@
+Transactional Memory support
+============================
+
+POWER kernel support for this feature is currently limited to supporting
+its use by user programs. It is not currently used by the kernel itself.
+
+This file aims to sum up how it is supported by Linux and what behaviour you
+can expect from your user programs.
+
+
+Basic overview
+==============
+
+Hardware Transactional Memory is supported on POWER8 processors, and is a
+feature that enables a different form of atomic memory access. Several new
+instructions are presented to delimit transactions; transactions are
+guaranteed to either complete atomically or roll back and undo any partial
+changes.
+
+A simple transaction looks like this:
+
+begin_move_money:
+ tbegin
+ beq abort_handler
+
+ ld r4, SAVINGS_ACCT(r3)
+ ld r5, CURRENT_ACCT(r3)
+ subi r5, r5, 1
+ addi r4, r4, 1
+ std r4, SAVINGS_ACCT(r3)
+ std r5, CURRENT_ACCT(r3)
+
+ tend
+
+ b continue
+
+abort_handler:
+ ... test for odd failures ...
+
+ /* Retry the transaction if it failed because it conflicted with
+ * someone else: */
+ b begin_move_money
+
+
+The 'tbegin' instruction denotes the start point, and 'tend' the end point.
+Between these points the processor is in 'Transactional' state; any memory
+references will complete in one go if there are no conflicts with other
+transactional or non-transactional accesses within the system. In this
+example, the transaction completes as though it were normal straight-line code
+IF no other processor has touched SAVINGS_ACCT(r3) or CURRENT_ACCT(r3); an
+atomic move of money from the current account to the savings account has been
+performed. Even though the normal ld/std instructions are used (note no
+lwarx/stwcx), either *both* SAVINGS_ACCT(r3) and CURRENT_ACCT(r3) will be
+updated, or neither will be updated.
+
+If, in the meantime, there is a conflict with the locations accessed by the
+transaction, the transaction will be aborted by the CPU. Register and memory
+state will roll back to that at the 'tbegin', and control will continue from
+'tbegin+4'. The branch to abort_handler will be taken this second time; the
+abort handler can check the cause of the failure, and retry.
+
+Checkpointed registers include all GPRs, FPRs, VRs/VSRs, LR, CCR/CR, CTR, FPCSR
+and a few other status/flag regs; see the ISA for details.
+
+Causes of transaction aborts
+============================
+
+- Conflicts with cache lines used by other processors
+- Signals
+- Context switches
+- See the ISA for full documentation of everything that will abort transactions.
+
+
+Syscalls
+========
+
+Syscalls made from within an active transaction will not be performed and the
+transaction will be doomed by the kernel with the failure code TM_CAUSE_SYSCALL
+| TM_CAUSE_PERSISTENT.
+
+Syscalls made from within a suspended transaction are performed as normal and
+the transaction is not explicitly doomed by the kernel. However, what the
+kernel does to perform the syscall may result in the transaction being doomed
+by the hardware. The syscall is performed in suspended mode so any side
+effects will be persistent, independent of transaction success or failure. No
+guarantees are provided by the kernel about which syscalls will affect
+transaction success.
+
+Care must be taken when relying on syscalls to abort during active transactions
+if the calls are made via a library. Libraries may cache values (which may
+give the appearance of success) or perform operations that cause transaction
+failure before entering the kernel (which may produce different failure codes).
+Examples are glibc's getpid() and lazy symbol resolution.
+
+
+Signals
+=======
+
+Delivery of signals (both sync and async) during transactions provides a second
+thread state (ucontext/mcontext) to represent the second transactional register
+state. Signal delivery 'treclaim's to capture both register states, so signals
+abort transactions. The usual ucontext_t passed to the signal handler
+represents the checkpointed/original register state; the signal appears to have
+arisen at 'tbegin+4'.
+
+If the sighandler ucontext has uc_link set, a second ucontext has been
+delivered. For future compatibility the MSR.TS field should be checked to
+determine the transactional state -- if so, the second ucontext in uc->uc_link
+represents the active transactional registers at the point of the signal.
+
+For 64-bit processes, uc->uc_mcontext.regs->msr is a full 64-bit MSR and its TS
+field shows the transactional mode.
+
+For 32-bit processes, the mcontext's MSR register is only 32 bits; the top 32
+bits are stored in the MSR of the second ucontext, i.e. in
+uc->uc_link->uc_mcontext.regs->msr. The top word contains the transactional
+state TS.
+
+However, basic signal handlers don't need to be aware of transactions
+and simply returning from the handler will deal with things correctly:
+
+Transaction-aware signal handlers can read the transactional register state
+from the second ucontext. This will be necessary for crash handlers to
+determine, for example, the address of the instruction causing the SIGSEGV.
+
+Example signal handler:
+
+ void crash_handler(int sig, siginfo_t *si, void *uc)
+ {
+ ucontext_t *ucp = uc;
+ ucontext_t *transactional_ucp = ucp->uc_link;
+
+ if (ucp_link) {
+ u64 msr = ucp->uc_mcontext.regs->msr;
+ /* May have transactional ucontext! */
+#ifndef __powerpc64__
+ msr |= ((u64)transactional_ucp->uc_mcontext.regs->msr) << 32;
+#endif
+ if (MSR_TM_ACTIVE(msr)) {
+ /* Yes, we crashed during a transaction. Oops. */
+ fprintf(stderr, "Transaction to be restarted at 0x%llx, but "
+ "crashy instruction was at 0x%llx\n",
+ ucp->uc_mcontext.regs->nip,
+ transactional_ucp->uc_mcontext.regs->nip);
+ }
+ }
+
+ fix_the_problem(ucp->dar);
+ }
+
+When in an active transaction that takes a signal, we need to be careful with
+the stack. It's possible that the stack has moved back up after the tbegin.
+The obvious case here is when the tbegin is called inside a function that
+returns before a tend. In this case, the stack is part of the checkpointed
+transactional memory state. If we write over this non transactionally or in
+suspend, we are in trouble because if we get a tm abort, the program counter and
+stack pointer will be back at the tbegin but our in memory stack won't be valid
+anymore.
+
+To avoid this, when taking a signal in an active transaction, we need to use
+the stack pointer from the checkpointed state, rather than the speculated
+state. This ensures that the signal context (written tm suspended) will be
+written below the stack required for the rollback. The transaction is aborted
+because of the treclaim, so any memory written between the tbegin and the
+signal will be rolled back anyway.
+
+For signals taken in non-TM or suspended mode, we use the
+normal/non-checkpointed stack pointer.
+
+Any transaction initiated inside a sighandler and suspended on return
+from the sighandler to the kernel will get reclaimed and discarded.
+
+Failure cause codes used by kernel
+==================================
+
+These are defined in <asm/reg.h>, and distinguish different reasons why the
+kernel aborted a transaction:
+
+ TM_CAUSE_RESCHED Thread was rescheduled.
+ TM_CAUSE_TLBI Software TLB invalid.
+ TM_CAUSE_FAC_UNAV FP/VEC/VSX unavailable trap.
+ TM_CAUSE_SYSCALL Syscall from active transaction.
+ TM_CAUSE_SIGNAL Signal delivered.
+ TM_CAUSE_MISC Currently unused.
+ TM_CAUSE_ALIGNMENT Alignment fault.
+ TM_CAUSE_EMULATE Emulation that touched memory.
+
+These can be checked by the user program's abort handler as TEXASR[0:7]. If
+bit 7 is set, it indicates that the error is consider persistent. For example
+a TM_CAUSE_ALIGNMENT will be persistent while a TM_CAUSE_RESCHED will not.
+
+GDB
+===
+
+GDB and ptrace are not currently TM-aware. If one stops during a transaction,
+it looks like the transaction has just started (the checkpointed state is
+presented). The transaction cannot then be continued and will take the failure
+handler route. Furthermore, the transactional 2nd register state will be
+inaccessible. GDB can currently be used on programs using TM, but not sensibly
+in parts within transactions.
+
+POWER9
+======
+
+TM on POWER9 has issues with storing the complete register state. This
+is described in this commit:
+
+ commit 4bb3c7a0208fc13ca70598efd109901a7cd45ae7
+ Author: Paul Mackerras <paulus@ozlabs.org>
+ Date: Wed Mar 21 21:32:01 2018 +1100
+ KVM: PPC: Book3S HV: Work around transactional memory bugs in POWER9
+
+To account for this different POWER9 chips have TM enabled in
+different ways.
+
+On POWER9N DD2.01 and below, TM is disabled. ie
+HWCAP2[PPC_FEATURE2_HTM] is not set.
+
+On POWER9N DD2.1 TM is configured by firmware to always abort a
+transaction when tm suspend occurs. So tsuspend will cause a
+transaction to be aborted and rolled back. Kernel exceptions will also
+cause the transaction to be aborted and rolled back and the exception
+will not occur. If userspace constructs a sigcontext that enables TM
+suspend, the sigcontext will be rejected by the kernel. This mode is
+advertised to users with HWCAP2[PPC_FEATURE2_HTM_NO_SUSPEND] set.
+HWCAP2[PPC_FEATURE2_HTM] is not set in this mode.
+
+On POWER9N DD2.2 and above, KVM and POWERVM emulate TM for guests (as
+described in commit 4bb3c7a0208f), hence TM is enabled for guests
+ie. HWCAP2[PPC_FEATURE2_HTM] is set for guest userspace. Guests that
+makes heavy use of TM suspend (tsuspend or kernel suspend) will result
+in traps into the hypervisor and hence will suffer a performance
+degradation. Host userspace has TM disabled
+ie. HWCAP2[PPC_FEATURE2_HTM] is not set. (although we make enable it
+at some point in the future if we bring the emulation into host
+userspace context switching).
+
+POWER9C DD1.2 and above are only available with POWERVM and hence
+Linux only runs as a guest. On these systems TM is emulated like on
+POWER9N DD2.2.
+
+Guest migration from POWER8 to POWER9 will work with POWER9N DD2.2 and
+POWER9C DD1.2. Since earlier POWER9 processors don't support TM
+emulation, migration from POWER8 to POWER9 is not supported there.