Re: [RFC PATCH v2 01/31] Documentation: kvx: Add basic documentation
From: Bagas Sanjaya
Date: Sun Jan 22 2023 - 04:03:13 EST
On Fri, Jan 20, 2023 at 03:09:32PM +0100, Yann Sionneau wrote:
> Add some documentation for the kvx architecture and its Linux port.
"Document the kvx Linux port. The documentation covers design decision,
memory management, exception handling, and SMP."
> Documentation/arch.rst | 1 +
> Documentation/kvx/index.rst | 17 ++
> Documentation/kvx/kvx-exceptions.rst | 256 ++++++++++++++++++++++++
> Documentation/kvx/kvx-iommu.rst | 191 ++++++++++++++++++
> Documentation/kvx/kvx-mmu.rst | 287 +++++++++++++++++++++++++++
> Documentation/kvx/kvx-smp.rst | 39 ++++
> Documentation/kvx/kvx.rst | 273 +++++++++++++++++++++++++
> 7 files changed, 1064 insertions(+)
> create mode 100644 Documentation/kvx/index.rst
> create mode 100644 Documentation/kvx/kvx-exceptions.rst
> create mode 100644 Documentation/kvx/kvx-iommu.rst
> create mode 100644 Documentation/kvx/kvx-mmu.rst
> create mode 100644 Documentation/kvx/kvx-smp.rst
> create mode 100644 Documentation/kvx/kvx.rst
>
The documentation reads a rather odd and unclear to me, so I have to
write the improv:
---- >8 ----
diff --git a/Documentation/kvx/kvx-exceptions.rst b/Documentation/kvx/kvx-exceptions.rst
index 5e01e934192f13..efb162edadb6a0 100644
--- a/Documentation/kvx/kvx-exceptions.rst
+++ b/Documentation/kvx/kvx-exceptions.rst
@@ -1,9 +1,9 @@
-==========
-Exceptions
-==========
+=========================
+Exception handling in kvx
+=========================
On kvx, handlers are set using ``$ev`` (exception vector) register which
-specifies a base address. An offset is added to ``$ev`` upon exception
+specifies the base address. An offset is added to ``$ev`` upon exception
and the result is used as the new ``$pc``.
The offset depends on which exception vector the cpu wants to jump to:
@@ -35,12 +35,13 @@ Interrupts and traps are serviced similarly, ie:
- Jump to handler
- Save all registers
- - Prepare the call (do_IRQ or trap_handler)
+ - Prepare the call (``do_IRQ`` or ``trap_handler``)
- restore all registers
- return from exception
-entry.S file is (as for other architectures) the entry point into the kernel.
-It contains all assembly routines related to interrupts/traps/syscall.
+As in other architectures, ``entry.S`` file is the entry point into the
+kernel. It contains all assembly routines related to
+interrupts/traps/syscall.
Syscall handling
----------------
@@ -51,7 +52,7 @@ a syscall from the kernel.
Syscalls are handled differently than interrupts/exceptions. From an ABI
point of view, syscalls are like function calls: any caller-saved register
-can be clobbered by the syscall. However, syscall parameters are passed
+can be clobberred by the syscall. However, syscall parameters are passed
using registers r0 through r7. These registers must be preserved to avoid
clobberring them before the actual syscall function.
@@ -59,23 +60,23 @@ On syscall from userspace (``scall`` instruction), the processor will put
the syscall number in $es.sn and switch from user to kernel privilege
mode. ``kvx_syscall_handler`` will be called in kernel mode.
-The following steps are then taken:
+Below is the path when executing syscall:
- 1. Switch to kernel stack
- 2. Extract syscall number
- 3. If the syscall number is bogus, set the syscall function to ``sys_ni_syscall``
- 4. If tracing is enabled
+ 1. Switch to kernel stack.
+ 2. Extract syscall number. If it is bogus, set the syscall function to
+ ``sys_ni_syscall``.
+ 3. If tracing is enabled:
- - Jump to ``trace_syscall_enter``
+ - Jump to ``trace_syscall_enter``.
- Save syscall arguments (``r0`` -> ``r7``) on stack in ``pt_regs``.
- Call ``do_trace_syscall_enter`` function.
- 5. Restore syscall arguments since they have been modified by C call
- 6. Call the syscall function
- 7. Save ``$r0`` in ``pt_regs`` since it can be clobberred afterward
- 8. If tracing is enabled, call ``trace_syscall_exit``.
- 9. Call ``work_pending``
- 10. Return to user !
+ 4. Restore syscall arguments since they have been modified by C call.
+ 5. Call the syscall function.
+ 6. Save ``$r0`` in ``pt_regs`` since it can be clobberred afterward.
+ 7. If tracing is enabled, call ``trace_syscall_exit``.
+ 8. Call ``work_pending``.
+ 9. Return to user.
The trace call is handled out of the fast path. All slow path handling
is done in another part of code to avoid messing with the cache.
@@ -84,25 +85,25 @@ Signals
-------
Signals are handled when exiting kernel before returning to user.
-When handling a signal, the path is the following:
+When handling a signal, the execution path is:
- 1. User application is executing normally
- Then any exception happens (syscall, interrupt, trap)
- 2. The exception handling path is taken
- and before returning to user, pending signals are checked
- 3. Signal are handled by ``do_signal``.
- Registers are saved and a special part of the stack is modified
+ 1. User application is executing normally, then any exception happens
+ (syscall, interrupt, trap).
+ 2. The exception handling path is taken and before returning to user,
+ pending signals are checked.
+ 3. Signals are handled by ``do_signal``.
+ 4. Registers are saved and a special part of the stack is modified
to create a trampoline to call ``rt_sigreturn``,
``$spc`` is modified to jump to user signal handler;
``$ra`` is modified to jump to sigreturn trampoline directly after
returning from user signal handler.
- 4. User signal handler is called after ``rfe`` from exception
+ 5. User signal handler is called after ``rfe`` from exception
when returning, ``$ra`` is retored to ``$pc``, resulting in a call
to the syscall trampoline.
- 5. syscall trampoline is executed, leading to rt_sigreturn syscall
- 6. ``rt_sigreturn`` syscall is executed. Previous registers are restored to
+ 6. syscall trampoline is executed, leading to ``rt_sigreturn`` syscall.
+ 7. ``rt_sigreturn`` syscall is executed. Previous registers are restored to
allow returning to user correctly.
- 7. User application is restored at the exact point it was interrupted
+ 8. User application is restored at the exact point it was interrupted
before.
::
@@ -170,12 +171,12 @@ When handling a signal, the path is the following:
Registers handling
------------------
-MMU is disabled in all exceptions paths, during register save and restoration.
-This will prevent from triggering MMU fault (such as TLB miss) which could
-clobber the current register state. Such event can occurs when RWX mode is
-enabled and the memory accessed to save register can trigger a TLB miss.
-Aside from that which is common for all exceptions path, registers are saved
-differently depending on the exception type.
+MMU is disabled in all exceptions paths, during register save and
+restoration. This will prevent triggering MMU fault (such as TLB miss)
+which could clobber the current register state. Such event can occurs when
+RWX mode is enabled and the memory accessed to save register can trigger a
+TLB miss. Aside from that which is common for all exceptions path,
+registers are saved differently depending on the exception type.
Interrupts and traps
--------------------
@@ -196,7 +197,7 @@ saved on the stack in ``pt_regs`` before executing the signal handler and
restored after that. Since only caller-saved registers have been saved before
checking for pending work, callee-saved registers also need to be saved to
restore everything correctly when before returning to user.
-This path is the following (a bit more complicated !)::
+The path is (note: a rather more complicated)::
+------------+
| Save caller| +-----------+ Ret +------------+
@@ -244,13 +245,13 @@ This path is the following (a bit more complicated !)::
Syscalls
--------
-As explained before, for syscalls, we can use whatever callee-saved registers
-we want since syscall are seen as a "classic" call from ABI pov.
-Only different path is the one for clone. For this path, since the child expects
-to find same callee-registers content than his parent, we must save them before
-executing the clone syscall and restore them after that for the child. This is
-done via a redefinition of __sys_clone in assembly which will be called in place
-of the standard sys_clone. This new call will save callee saved registers
-in pt_regs. Parent will return using the syscall standard path. Freshly spawned
-child however will be woken up via ret_from_fork which will restore all
-registers (even if caller saved are not needed).
+As explained before, for syscalls, any arbitrary callee-saved registers can be
+used since syscall are seen as a "classic" call from ABI pov. The only syscall
+with different path is ``clone()``. For this path, since the child expects to
+find same callee-registers content from its parent, these registers must be
+saved before executing ``clone()`` and restore them after it is executed for the
+child. This is done via a redefinition of ``__sys_clone`` in assembly which will
+be called in place of the standard ``__sys_clone``. This new call saves
+callee-saved registers in ``pt_regs``. The parent returns using the syscall
+standard path. Freshly spawned child however is woken up via ``ret_from_fork``
+which restores all registers (even if caller saved are not needed).
diff --git a/Documentation/kvx/kvx-iommu.rst b/Documentation/kvx/kvx-iommu.rst
index 240995d315ce46..cdcfa9e8e21cb4 100644
--- a/Documentation/kvx/kvx-iommu.rst
+++ b/Documentation/kvx/kvx-iommu.rst
@@ -1,41 +1,40 @@
.. SPDX-License-Identifier: GPL-2.0
-=====
-IOMMU
-=====
+=========
+kvx IOMMU
+=========
General Overview
----------------
-To exchange data between device and users through memory, the driver
-has to set up a buffer by doing some kernel allocation. The buffer uses
-virtual address and the physical address is obtained through the MMU.
-When the device wants to access the same physical memory space it uses
-the bus address which is obtained by using the DMA mapping API. The
-Coolidge SoC includes several IOMMUs for clusters, PCIe peripherals,
-SoC peripherals, and more; that will translate this "bus address" into
-a physical one for DMA operations.
+To exchange data between device and users through memory, the driver has to set
+up a buffer by doing some kernel allocation. The buffer uses virtual address and
+the physical address is obtained through the MMU. When the device wants to
+access the same physical memory space it uses the bus address which is obtained
+by using the DMA mapping API. The Coolidge SoC includes several IOMMUs for
+clusters, PCIe peripherals, SoC peripherals, and more; these IOMMUs will
+translate this "bus address" into the physical one for DMA operations.
-Bus addresses are IOVA (I/O Virtual Address) or DMA addresses. These
-addresses can be obtained by calling the allocation functions of the DMA APIs.
-It can also be obtained through classical kernel allocation of physical
-contiguous memory and then calling mapping functions of the DMA API.
+Bus addresses are IOVA (I/O Virtual Address) or DMA addresses. These addresses
+can be obtained by calling the allocation functions of the DMA APIs. It can also
+be obtained through classical allocation of physical contiguous memory and then
+calling mapping functions of the DMA API.
-In order to be able to use the kvx IOMMU we have implemented the IOMMU DMA
-interface in arch/kvx/mm/dma-mapping.c. DMA functions are registered by
-implementing arch_setup_dma_ops() and generic IOMMU functions. Generic IOMMU
-are calling our specific IOMMU functions that adds or remove mappings between
-DMA addresses and physical addresses in the IOMMU TLB.
+In order to be able to use the kvx IOMMU, the necessary IOMMU DMA interface is
+implemented in ``arch/kvx/mm/dma-mapping.c``. DMA functions are registered by
+implementing ``arch_setup_dma_ops()`` and generic IOMMU functions. The latter
+calls kvx-specific IOMMU functions that add or remove mappings between DMA
+addresses and physical addresses in the IOMMU TLB.
-Specific IOMMU functions are defined in the kvx IOMMU driver. The kvx IOMMU
-driver manage two physical hardware IOMMU: one used for TX and one for RX.
-In the next section we described the HW IOMMUs.
+Specific IOMMU functions are defined in the kvx IOMMU driver. Thedriver manages
+two physical hardware IOMMU: one used for TX and one for RX. In the next section
+we described the hardware IOMMUs.
Cluster IOMMUs
--------------
IOMMUs on cluster are used for DMA and cryptographic accelerators.
-There are six IOMMUs connected to the:
+There are six IOMMUs, each connected to:
- cluster DMA tx
- cluster DMA rx
@@ -48,20 +47,18 @@ SoC peripherals IOMMUs
----------------------
Since SoC peripherals are connected to an AXI bus, two IOMMUs are used: one for
-each AXI channel (read and write). These two IOMMUs are shared between all master
-devices and DMA. These two IOMMUs will have the same entries but need to be configured
-independently.
+each AXI channel (read and write). These are shared between all master devices
+and DMA. These have the same entries but need to be configured separately.
PCIe IOMMUs
-----------
-There is a slave IOMMU (read and write from the MPPA to the PCIe endpoint)
-and a master IOMMU (read and write from a PCIe endpoint to system DDR).
-The PCIe root complex and the MSI/MSI-X controller have been designed to use
-the IOMMU feature when enabled. (For example for supporting endpoint that
-support only 32 bits addresses and allow them to access any memory in a
-64 bits address space). For security reason it is highly recommended to
-activate the IOMMU for PCIe.
+There is a slave IOMMU (read and write from the MPPA to the PCIe endpoint) and a
+master IOMMU (read and write from a PCIe endpoint to system memory). The PCIe
+root complex and the MSI/MSI-X controller have been designed to use the IOMMU
+feature when enabled, for example for supporting endpoint that support only
+32-bit addresses and allow them to access any memory in a 64-bit address space).
+For security reason it is highly recommended to activate the IOMMU for PCIe.
IOMMU implementation
--------------------
@@ -102,90 +99,88 @@ and translations that occurs between memory and devices::
+--------------+
-There is also an IOMMU dedicated to the crypto module but this module will not
-be accessed by the operating system.
+There is also an IOMMU dedicated to the crypto module but the operating system
+doesn't access it.
-We will provide one driver to manage IOMMUs RX/TX. All of them will be
-described in the device tree to be able to get their particularities. See
-the example below that describes the relation between IOMMU, DMA and NoC in
-the cluster.
+The kernel provides a driver to manage RX/TX IOMMUs. All of them is described in
+the device tree in detail. See the example below that describes the relation
+between IOMMU, DMA and NoC in the cluster.
-IOMMU is related to a specific bus like PCIe we will be able to specify that
-all peripherals will go through this IOMMU.
+IOMMU is related to a specific bus like PCIe, thus it is preferred to specify
+that all peripherals will go through it.
IOMMU Page table
~~~~~~~~~~~~~~~~
-We need to be able to know which IO virtual addresses (IOVA) are mapped in the
+It is necessary to know which IO virtual addresses (IOVA) are mapped in the
TLB in order to be able to remove entries when a device finishes a transfer and
release memory. This information could be extracted when needed by computing all
sets used by the memory and then reads all sixteen ways and compare them to the
-IOVA but it won't be efficient. We also need to be able to translate an IOVA
-to a physical address as required by the iova_to_phys IOMMU ops that is used
-by DMA. Like previously it can be done by extracting the set from the address
+IOVA but it won't be efficient. It is also necessary to translate an IOVA
+to a physical address as required by the ``iova_to_phys`` IOMMU ops that is used
+by DMA. Again, it can be done by extracting the set from the address
and comparing the IOVA to each sixteen entries of the given set.
-A solution is to keep a page table for the IOMMU. But this method is not
-efficient for reloading an entry of the TLB without the help of an hardware
-page table. So to prevent the need of a refill we will update the TLB when a
-device request access to memory and if there is no more slot available in the
-TLB we will just fail and the device will have to try again later. It is not
-efficient but at least we won't need to manage the refill of the TLB.
+A possible solution is to keep a page table for the IOMMU. However, this method
+is not efficient for reloading an entry of the TLB without the help of an
+hardware page table. Thus, to prevent the need to refill the TLB is updated when
+a device requests access to memory and if there is no more slot available in the
+TLB, the request will just fail and the device will have to try again later. It
+is not efficient but at least managing TLB refill can be avoided.
This limits the total amount of memory that can be used for transfer between
-device and memory (see Limitations section below).
-To be able to manage bigger transfer we can implement the huge page table in
-the Linux kernel and use a page table that match the size of huge page table
-for a given IOMMU (typically the PCIe IOMMU).
+device and memory (see Limitations section below). In order to manage bigger
+transfer, it is required to implement the huge page table size in the Linux
+kernel and use a page table that match the size of huge page table for a given
+IOMMU (typically the PCIe IOMMU).
-As we won't refill the TLB we know that we won't have more than 128*16 entries.
-In this case we can simply keep a table with all possible entries.
+Consequently, the maximum page table entries is 128*16 (2048) and the approach
+to manage IOMMU TLB is to keep a table with all possible entries.
Maintenance interface
~~~~~~~~~~~~~~~~~~~~~
-It is possible to have several "maintainers" for the same IOMMU. The driver is
-using two of them. One that writes the TLB and another interface reads TLB. For
-debug purpose it is possible to display the content of the tlb by using the
-following command in gdb::
+It is possible to have several "maintainers" for the same IOMMU. The driver uses
+two of them: one that writes the TLB and another that reads TLB. For debugging
+purpose it is possible to display the TLB content in gdb by::
gdb> p kvx_iommu_dump_tlb( <iommu addr>, 0)
Since different management interface are used for read and write it is safe to
-execute the above command at any moment.
+execute the above command at any time.
Interrupts
~~~~~~~~~~
IOMMU can have 3 kind of interrupts that corresponds to 3 different types of
-errors (no mapping. protection, parity). When the IOMMU is shared between
-clusters (SoC periph and PCIe) then fifteen IRQs are generated according to the
+errors: no mapping, protection, and parity. When the IOMMU is shared between
+clusters (SoC periph and PCIe), 15 IRQs are generated corresponding to the
configuration of an association table. The association table is indexed by the
-ASN number (9 bits) and the entry of the table is a subscription mask with one
+ASN number (9-bit) and the entry of the table is a subscription mask with one
bit per destination. Currently this is not managed by the driver.
The driver is only managing interrupts for the cluster. The mode used is the
-stall one. So when an interrupt occurs it is managed by the driver. All others
+stall one. Thus, when an interrupt occurs it is managed by the driver. All other
interrupts that occurs are stored and the IOMMU is stalled. When driver cleans
-the first interrupt others will be managed one by one.
+up the first interrupt, other interrupts will be managed sequentially.
ASN (Address Space Number)
~~~~~~~~~~~~~~~~~~~~~~~~~~
This is also know as ASID in some other architecture. Each device will have a
given ASN that will be given through the device tree. As address space is
-managed at the IOMMU domain level we will use one group and one domain per ID.
-ASN are coded on 9 bits.
+managed at the IOMMU domain level one group and one domain per ID is used. ASNs
+are 9-bit encoded.
Device tree
-----------
-Relationships between devices, DMAs and IOMMUs are described in the
-device tree (see `Documentation/devicetree/bindings/iommu/kalray,kvx-iommu.txt`
-for more details).
+Relationships between devices, DMAs and IOMMUs are described in the device tree
+(see ``Documentation/devicetree/bindings/iommu/kalray,kvx-iommu.txt`` for
+details).
Limitations
-----------
-Only supporting 4KB page size will limit the size of mapped memory to 8MB
-because the IOMMU TLB can have at most 128*16 entries.
+Since the kernel only supports 4KB page size, the size of mapped memory is
+limited to 8MB because the IOMMU TLB can have at most 128*16 (2048) entries.
diff --git a/Documentation/kvx/kvx-mmu.rst b/Documentation/kvx/kvx-mmu.rst
index b7186331396c09..ea40acad9969bd 100644
--- a/Documentation/kvx/kvx-mmu.rst
+++ b/Documentation/kvx/kvx-mmu.rst
@@ -1,29 +1,29 @@
.. SPDX-License-Identifier: GPL-2.0
-===
-MMU
-===
+==========================
+kvx Memory Management Unit
+==========================
-Virtual addresses are on 41 bits for kvx when using 64-bit mode.
-To differentiate kernel from user space, we use the high order bit
-(bit 40). When bit 40 is set, then the higher remaining bits must also be
-set to 1. The virtual address must be extended with 1 when the bit 40 is set,
-if not the address must be zero extended. Bit 40 is set for kernel space
-mappings and not set for user space mappings.
+Virtual addresses are on 41 bits for kvx when using 64-bit mode. To
+differentiate kernel from user space, the high order bit (bit 40) is used. When
+it is set, the higher remaining bits must also be set to 1. The virtual address
+must be extended by 1 when the bit 40 is set, otherwise the address must be
+zero extended. Bit 40 is set for kernelspace mappings and not set for userspace
+mappings.
Memory Map
----------
In Linux physical memories are arranged into banks according to the cost of an
-access in term of distance to a memory. As we are UMA architecture we only have
-one bank and thus one node.
+access in term of distance to a memory. As kvx is an UMA architecture there is
+only one bank and thus one node.
A node is divided into several kind of zone. For example if DMA can only access
-a specific area in the physical memory we will define a ZONE_DMA for this purpose.
-In our case we are considering that DMA can access all DDR so we don't have a specific
-zone for this. On 64 bit architecture all DDR can be mapped in virtual kernel space
-so there is no need for a ZONE_HIGHMEM. That means that in our case there is
-only one ZONE_NORMAL. This will be updated if DMA cannot access all memory.
+a specific area in the physical memory, the region is called ``ZONE_DMA``. In
+kvx we assume that DMA can access all memory so we don't have a specific zone
+for this purpose. On 64-bit architecture all memory can be mapped in virtual
+kernel space so ``ZONE_HIGHMEM`` is unnecessary. This implies that there is
+only ``ZONE_NORMAL``. This can change if DMA cannot access all memory.
Currently, the memory mapping is the following for 4KB page:
@@ -42,96 +42,97 @@ Currently, the memory mapping is the following for 4KB page:
Enable the MMU
--------------
-All kernel functions and symbols are in virtual memory except for kvx_start()
-function which is loaded at 0x0 in physical memory.
-To be able to switch from physical addresses to virtual addresses we choose to
+All kernel functions and symbols are in virtual memory except for
+``kvx_start()`` function which is loaded at 0x0 in physical memory. To be able
+to switch from physical addresses to virtual addresses, the decision is to
setup the TLB at the very beginning of the boot process to be able to map both
-pieces of code. For this we added two entries in the LTLB. The first one,
-LTLB[0], contains the mapping between virtual memory and DDR. Its size is 512MB.
-The second entry, LTLB[1], contains a flat mapping of the first 2MB of the SMEM.
-Once those two entries are present we can enable the MMU. LTLB[1] will be
-removed during paging_init() because once we are really running in virtual space
-it will not be used anymore.
-In order to access more than 512MB DDR memory, the remaining memory (> 512MB) is
-refill using a comparison in kernel_perf_refill that does not walk the kernel
-page table, thus having a faster refill time for kernel. These entries are
-inserted into the LTLB for easier computation (4 LTLB entries). The drawback of
-this approach is that mapped entries are using RWX protection attributes,
-leading to no protection at all.
+pieces of code. For this purpose, two LTLB entries are added. The first one,
+LTLB[0], contains the mapping between virtual and physical memory. Its size is
+512MB. The second pme, LTLB[1], contains a flat mapping of the first 2MB of
+the SMEM. Once those two entries are present the MMU can be enabled. LTLB[1]
+will be removed during ``paging_init()`` because once the kernel is running in
+virtual memory space it will not be used anymore. In order to access more than
+512MB of physical memory, the remaining memory (> 512MB) is refilled using a
+comparison in ``kernel_perf_refill`` that does not walk the kernel page table,
+thus having a faster kernel refill time. These entries are inserted into the
+LTLB for easier computation (4 LTLB entries). The drawback of this approach is
+that mapped entries are using RWX protection attributes, leading to no
+protection at all and anything can happen.
Kernel strict RWX
-----------------
-``CONFIG_STRICT_KERNEL_RWX`` is enabled by default in defconfig.
-Once booted, if ``CONFIG_STRICT_KERNEL_RWX`` is enable, the kernel text and memory
-will be mapped in the init_mm page table. Once mapped, the refill routine for
-the kernel is patched to always do a page table walk, bypassing the faster
-comparison but enforcing page protection attributes when refilling.
-Finally, the LTLB[0] entry is replaced by a 4K one, mapping only exceptions with
-RX protection. It allows us to never trigger nomapping on nomapping refill
-routine which would (obviously) not work... Once this is done, we can flush the
-4 LTLB entries for kernel refill in order to be sure there is no stalled
+``CONFIG_STRICT_KERNEL_RWX`` is enabled by default in defconfig. Once the
+kernel is booted, if the aforementioned configuration is enabled, the kernel
+text and memory will be mapped in the ``init_mm`` page table. Once mapped, the
+refill routine for the kernel is patched to always walk the page table,
+bypassing the faster comparison but enforcing page protection attributes when
+refilling. Finally, the LTLB[0] entry is replaced by a 4K one, mapping only
+read-only (RX) exceptions. It allows us to never trigger nomapping on nomapping
+refill routine which would (obviously) not work. Once this is done, 4 LTLB
+entries can be flused for kernel refill in order to be sure there is no stalled
entries and that new entries inserted in JTLB will apply.
By default, the following policy is applied on vmlinux sections:
- init_data: RW
- - init_text: RX (or RWX if parameter rodata=off)
- - text: RX (or RWX if parameter rodata=off)
+ - init_text: RX (or RWX if ``rodata=off`` parameter is specified)
+ - text: RX (or RWX if ``rodata=off`` is specified)
- rodata: RW before init, RO after init
- sdata: RW
-Kernel RWX mode can then be switched on/off using /sys/kvx/kernel_rwx file.
+Kernel RWX mode can then be switched on/off with ``/sys/kvx/kernel_rwx``.
Privilege Level
---------------
-Since we are using privilege levels on kvx, we make use of the virtual
-spaces to be in the same space as the user. The kernel will have the
+Since kvx uses privilege levels, the virtual memory space is leveraged so that
+the kernel memory space is same as userspace. The kernel will have the
$ps.mmup set in kernel (PL1) and unset for user (PL2).
-As said in kvx documentation, we have two cases when the kernel is
-booted:
+As mentioned in :doc:`kvx`, there are two cases when the kernel is booted:
- - Either we have been booted by someone (bootloader, hypervisor, etc)
- - Or we are alone (boot from flash)
+ - Boot via intermediaries (bootloader, hypervisor, etc)
+ - Direct boot from flash.
-In both cases, we will use the virtual space 0. Indeed, if we are alone
-on the core, then it means nobody is using the MMU and we can take the
-first virtual space. If not alone, then when writing an entry to the tlb
-using writetlb instruction, the hypervisor will catch it and change the
+In both cases, the virtual space 0 is used. Indeed, if there is only the kernel
+running on the core, nothing else is using the MMU and the first virtual space
+can be used directly by the kernel. Otherwise, when writing an entry to the tlb
+using ``writetlb`` instruction, the hypervisor will catch it and change the
virtual space accordingly.
Memblock
========
When the kernel starts there is no memory allocator available. One of the first
-step in the kernel is to detect the amount of DDR available by getting this
-information in the device tree and initialize the low-level "memblock" allocator.
+step in the kernel is to detect the amount of available memory by gathering
+this information from the device tree and initialize the low-level "memblock"
+allocator.
-We start by reserving memory for the whole kernel. For instance with a device
-tree containing 512MB of DDR you could see the following boot messages::
+memblock initialization starts by reserving memory for the whole kernel. For
+instance, with a device tree containing 512MB RAM device dmseg will print::
setup_bootmem: Memory : 0x100000000 - 0x120000000
setup_bootmem: Reserved: 0x10001f000 - 0x1002d1bc0
-During the paging init we need to set:
+During the paging init three settings need to be set:
- - min_low_pfn that is the lowest PFN available in the system
- - max_low_pfn that indicates the end if NORMAL zone
- - max_pfn that is the number of pages in the system
+ - ``min_low_pfn`` - the lowest PFN available in the system
+ - ``max_low_pfn`` - the end if NORMAL zone
+ - ``max_pfn`` - the number of pages in the system
-This setting is used for dividing memory into pages and for configuring the
-zone. See the memory map section for more information about ZONE.
+This setting is used for dividing memory into pages and for configuring zones.
+See the memory map section for more details.
-Zones are configured in free_area_init_core(). During start_kernel() other
-allocations are done for command line, cpu areas, PID hash table, different
-caches for VFS. This allocator is used until mem_init() is called.
+Zones are configured in ``free_area_init_core()``. During ``start_kernel()``
+other allocations are done for command line, cpu areas, PID hash table, and
+different caches for VFS. The memblock allocator is used until ``mem_init()``
+is called.
-mem_init() is provided by the architecture. For MPPA we just call
-free_all_bootmem() that will go through all pages that are not used by the
-low level allocator and mark them as not used. So physical pages that are
-reserved for the kernel are still used and remain in physical memory. All pages
-released will now be used by the buddy allocator.
+``mem_init()`` is provided by the architecture. For MPPA ``free_all_bootmem()``
+is called, which goes through all pages that are not used by the low level
+allocator and mark them as not used. Thus, physical pages that are reserved for
+the kernel are still used and remain in physical memory. All pages released
+will now be used by the buddy allocator.
Peripherals
-----------
@@ -143,20 +144,20 @@ LTLB Usage
----------
LTLB is used to add resident mapping which allows for faster MMU lookup.
-Currently, the LTLB is used to map some mandatory kernel pages and to allow fast
-accesses to l2 cache (mailbox and registers).
-When CONFIG_STRICT_KERNEL_RWX is disabled, 4 entries are reserved for kernel
-TLB refill using 512MB pages. When CONFIG_STRICT_KERNEL_RWX is enabled, these
-entries are unused since kernel is paginated using the same mecanism than for
-user (page walking and entries in JTLB)
+Currently, the LTLB is used to map some mandatory kernel pages and to allow
+fast accesses to l2 cache (mailbox and registers). When
+``CONFIG_STRICT_KERNEL_RWX`` is disabled, 4 entries are reserved for kernel TLB
+refill using 512MB pages. When ``CONFIG_STRICT_KERNEL_RWX`` is enabled, these
+entries are unused since kernel is paginated using the same mecanism as in the
+userspace (page walking and entries in JTLB)
Page Table
==========
-We only support three levels for the page table and 4KB for page size.
+Only three-level page table and 4KB page size are supported.
-3 levels page table
--------------------
+3-level page table
+------------------
::
@@ -169,16 +170,16 @@ We only support three levels for the page table and 4KB for page size.
| +-----------------------> [29:21] PMD offset (9 bits)
+----------------------------------> [39:30] PGD offset (10 bits)
-Bits 40 to 64 are signed extended according to bit 39. If bit 39 is equal to 1
-we are in kernel space.
+Bits 40 to 64 are signed extended according to bit 39. If this bit is equal to
+1 the process is in kernel space.
-As 10 bits are used for PGD we need to allocate 2 pages.
+As 10 bits are used for PGD 2 pages need to be allocated.
PTE format
==========
-About the format of the PTE entry, as we are not forced by hardware for choices,
-we choose to follow the format described in the RiscV implementation as a
+For PTE entry format, instead of being forced by hardware constraints,
+the decision is to follow the format described in the RISC-V port as a
starting point::
+---------+--------+----+--------+---+---+---+---+---+---+------+---+---+
@@ -202,43 +203,35 @@ starting point::
Huge bit must be somewhere in the first 12 bits to be able to detect it
when reading the PMD entry.
-PageSZ must be on bit 10 and 11 because it matches the TEL.PS bits. And
-by doing that it is easier in assembly to set the TEL.PS to PageSZ.
+PageSZ must be on bit 10 and 11 because it matches the TEL.PS bits. As such,
+it is easier in assembly to set the TEL.PS to PageSZ.
Fast TLB refill
===============
-kvx core does not feature a hardware page walker. This work must be done
-by the core in software. In order to optimize TLB refill, a special fast
-path is taken when entering in kernel space.
-In order to speed up the process, the following actions are taken:
+kvx core does not feature a hardware page walker. Instead, page walking must
+be done by the core in software. In order to optimize TLB refill, a special
+fast path is utilizedwhen entering in kernel space. In order to speed up the
+process, the TLB refill process is:
- 1. Save some registers in a per process scratchpad
- 2. If the trap is a nomapping then try the fastpath
- 3. Save some more registers for this fastpath
- 4. Check if faulting address is a memory direct mapping one.
-
- * If entry is a direct mapping one and RWX is not enabled, add an entry into LTLB
- * If not, continue
-
- 5. Try to walk the page table
-
- * If entry is not present, take the slowpath (do_page_fault)
-
- 6. Refill the tlb properly
- 7. Exit by restoring only a few registers
+ 1. Save some registers in a per process scratchpad.
+ 2. If the trap is a nomapping then try the fastpath, then save more registers
+ for that path.
+ 3. Check if faulting address is a memory direct mapping one. If it is the case
+ and RWX is not enabled, add an entry into LTLB. Otherwise, continue.
+ 4. Try to walk the page table If entry is not present, take the slowpath
+ (``do_page_fault``)
+ 5. Refill the tlb.
+ 6. Exit by restoring only a few registers
ASN Handling
============
-Disclaimer: Some part of this are taken from ARC architecture.
-
kvx MMU provides 9-bit ASN (Address Space Number) in order to tag TLB entries.
It allows for multiple process with the same virtual space to cohabit without
-the need to flush TLB everytime we context switch.
-kvx implementation to use them is based on other architectures (such as arc
-or xtensa) and uses a wrapping ASN counter containing both cycle/generation and
-asn.
+the need to flush TLB every time context switch is done. The kvx implementation
+is based on other architectures (such as arc or xtensa) and uses a wrapping ASN
+counter containing both cycle/generation and asn.
::
@@ -250,27 +243,26 @@ asn.
This ASN counter is incremented monotonously to allocate new ASNs. When the
counter reaches 511 (9 bit), TLB is completely flushed and a new cycle is
started. A new allocation cycle, post rollover, could potentially reassign an
-ASN to a different task. Thus the rule is to reassign an ASN when the current
-context cycles does not match the allocation cycle.
-The 64 bit @cpu_asn_cache (and mm->asn) have 9 bits MMU ASN and rest 55 bits
-serve as cycle/generation indicator and natural 64 bit unsigned math
-automagically increments the generation when lower 9 bits rollover.
-When the counter completely wraps, we reset the counter to first cycle value
-(ie cycle = 1). This allows to distinguish context without any ASN and old cycle
-generated value with the same operation (XOR on cycle).
+ASN to a different task, hence the rule is to reassign an ASN when the current
+context cycles does not match the allocation cycle. The 64-bit
+``@cpu_asn_cache`` (and ``mm->asn``) have 9 bits of MMU ASN and the rest 55
+bits serve as cycle/generation indicator and natural 64 bit unsigned math
+automagically increments the generation when lower 9 bits rolls over. When the
+counter completely wraps, the counter is reset to first cycle value (ie cycle =
+1). This allows to distinguish context without any ASN and old cycle generated
+value with the same operation (XOR on cycle).
Huge page
=========
-Currently only 3 level page table has been implemented for 4KB base page size.
-So the page shift is 12 bits, the pmd shift is 21 and the pgdir shift is 30 bits.
-This choice implies that for 4KB base page size if we use a PMD as a huge
-page the size will be 2MB and if we use a PUD as a huge page it will be 1GB.
+Currently only 3-level page table is implemented for 4KB base page size. As
+such, the page shift is 12-bit, the pmd shift is 21 and the pgdir shift is
+30-bit. This also implies that for 4KB base page size, if PMD is used as a huge
+page the size will be 2MB and if PUD is used, it will be 1GB.
-To support other huge page sizes (64KB and 512MB) we need to use several
-contiguous entries in the page table. For huge page of 64KB we will need to
-use 16 entries in the PTE and for a huge page of 512MB it means that 256
-entries in PMD will be used.
+To support other huge page sizes (64KB and 512MB) it is necessary to use
+several contiguous entries in the page table. For 64KB page size 16 entries in
+the PTE are needed whereas for 512MB page size it requires 256 entries in PMD.
Debug
=====
@@ -278,10 +270,10 @@ Debug
In order to debug the page table and tlb entries, gdb scripts contains commands
which allows to dump the page table:
-:``lx-kvx-page-table-walk``: Display the current process page table by default
-:``lx-kvx-tlb-decode``: Display the content of $tel and $teh into something readable
+ * ``lx-kvx-page-table-walk``: Display the current process page table by default
+ * ``lx-kvx-tlb-decode``: Display human-readable content of $tel and $teh
-Other commands available in kvx-gdb are the following:
+Other commands available in kvx-gdb are:
-:``mppa-dump-tlb``: Display the content of TLBs (JTLB and LTLB)
-:``mppa-lookup-addr``: Find physical address matching a virtual one
+ * ``mppa-dump-tlb``: Display the content of TLBs (JTLB and LTLB)
+ * ``mppa-lookup-addr``: Find physical address matching a virtual address
diff --git a/Documentation/kvx/kvx-smp.rst b/Documentation/kvx/kvx-smp.rst
index 12efddbfd1e04d..69cec021bc2acd 100644
--- a/Documentation/kvx/kvx-smp.rst
+++ b/Documentation/kvx/kvx-smp.rst
@@ -1,34 +1,33 @@
-===
-SMP
-===
+=============================
+kvx Symmetric Multiprocessing
+=============================
-The Coolidge SoC is comprised of 5 clusters, each organized as a group
-of 17 cores: 16 application core (PE) and 1 secure core (RM).
-These 17 cores have their L1 cache coherent with the local Tightly
-Coupled Memory (TCM or SMEM). The L2 cache is necessary for SMP support
-is and implemented with a mix of HW support and SW firmware. The L2 cache
-data and meta-data are stored in the TCM.
-The RM core is not meant to run Linux and is reserved for implementing
-hypervisor services, thus only 16 processors are available for SMP.
+The Coolidge SoC is comprised of 5 clusters, each organized as a group of 17
+cores: 16 application core (PE) and 1 secure core (RM). These cores have their
+L1 cache coherent with the local Tightly Coupled Memory (TCM or SMEM). The L2
+cache is necessary for SMP support is and implemented with a mix of HW support
+and SW firmware. The L2 cache data and meta-data are stored in the TCM. As the
+RM core is not meant to run Linux and is reserved for implementing hypervisor
+services, only 16 processors are available for SMP.
Booting
-------
-When booting the kvx processor, only the RM is woken up. This RM will
-execute a portion of code located in the section named ``.rm_firmware``.
-By default, a simple power off code is embedded in this section.
-To avoid embedding the firmware in kernel sources, the section is patched
-using external tools to add the L2 firmware (and replace the default firmware).
-Before executing this firmware, the RM boots the PE0. PE0 will then enable L2
-coherency and request will be stalled until RM boots the L2 firmware.
+When booting the kvx processor, only the RM core is woken up. This core will
+execute a portion of code located in the section named ``.rm_firmware``. By
+default, a simple power off code is embedded in this section. To avoid embedding
+the firmware in kernel sources, the section is patched using external tools to
+add the L2 firmware (and replace the default firmware). Before executing this
+firmware, the core boots the PE0, which the latter will then enable L2 coherency
+and request will be stalled until the core boots the L2 firmware.
Locking primitives
------------------
-spinlock/rwlock are using the kernel standard queued spinlock/rwlocks.
-These primitives are based on cmpxch and xchg. More particularly, it uses xchg16
-which is implemented as a read modify write with acswap on 32bit word since
-kvx does not have atomic cmpxchg instructions for less than 32 bits.
+spinlocks/rwlocks are implemented using the kernel standard queued
+spinlock/rwlocks. These primitives are based on cmpxch and xchg. Specifically,
+it uses xchg16 which is implemented as a read-modify-write with acswap on 32-bit
+word since kvx does not have atomic cmpxchg instructions for less than 32 bits.
IPI
---
diff --git a/Documentation/kvx/kvx.rst b/Documentation/kvx/kvx.rst
index 9407b7d4fdf169..a172bab58dcafc 100644
--- a/Documentation/kvx/kvx.rst
+++ b/Documentation/kvx/kvx.rst
@@ -1,8 +1,8 @@
.. SPDX-License-Identifier: GPL-2.0
-=========
-kvx Linux
-=========
+==================
+The kvx Linux port
+==================
This documents will try to explain any architecture choice for the kvx
Linux port.
@@ -154,54 +154,53 @@ and ``r21`` are set up to special values containing the function to call.
The normal path for a kernel thread is:
1. Enter copy_thread_tls and setup callee saved registers which will
- be restored in __switch_to.
-2. set r20 and r21 (in thread_struct) to function and argument and
- ra to ret_from_kernel_thread.
- These callee saved will be restored in switch_to.
-3. Call _switch_to at some point.
-4. Save all callee saved register since switch_to is seen as a
+ be restored in ``__switch_to``.
+2. set ``r20`` and ``r21`` (in ``thread_struct``) to function and argument and
+ ra to ``ret_from_kernel_thread``. These callee-saved registers will be
+ restored in ``__switch_to``.
+3. Call ``_switch_to`` at some point.
+4. Save all callee-saved registers since ``__switch_to`` is seen as a
standard function call by the caller.
-5. Change stack pointer to the new stack
-6. At the end of switch to, set sr0 to the new task and use ret to
- jump to ret_from_kernel_thread (address restored from ra).
-7. In ret_from_kernel_thread, execute the function with arguments by
- using r20, r21 and we are done
+5. Change stack pointer to the new stack.
+6. At the end of ``__switch_to``, set sr0 to the new task and use ret to
+ jump to ``ret_from_kernel_thread`` (address restored from ra).
+7. In ret_from_kernel_thread, execute the function with arguments from
+ ``r20`` and ``r21``
For more explanations, you can refer to https://lwn.net/Articles/520227/
User thread creation
--------------------
-We are using almost the same path as copy_thread to create it.
-The detailed path is the following:
+The similar path as ``copy_thread`` is used to create threads. It consists
+of:
- 1. Call start_thread which will setup user pc and stack pointer in
- task regs. We also set sps and clear privilege mode bit.
+ 1. Call ``start_thread`` which will setup user pc and stack pointer in
+ task regs. sps and clear privilege mode bit are also set.
When returning from exception, it will "flip" to user mode.
- 2. Enter copy_thread_tls and setup callee saved registers which will
- be restored in __switch_to. Also, set the "return" function to be
- ret_from_fork which will be called at end of switch_to
- 3. set r20 (in thread_struct) with tracing information.
- (simply by lazyness to avoid computing it in assembly...)
- 4. Call _switch_to at some point.
- 5. The current pc will then be restored to be ret_from fork.
- 6. Ret from fork calls schedule_tail and then check if tracing is
- enabled. If so call syscall_trace_exit
- 7. finally, instead of returning to kernel, we restore all registers
- that have been setup by start_thread by restoring regs stored on
- stack
+ 2. Enter ``copy_thread_tls`` and setup callee-saved registers which will
+ be restored in ``__switch_to``. Also, set the "return" function to be
+ ret_from_fork which will be called at end of ``__switch_to``.
+ 3. Set ``r20`` (in ``thread_struct``) with tracing information.
+ (This is done to avoid computing it in assembly.)
+ 4. Call ``__switch_to`` at some point.
+ 5. The current pc will then be restored to be ``ret_from`` fork.
+ 6. ``ret_from`` fork calls ``schedule_tail`` and then check if tracing is
+ enabled. If so call ``syscall_trace_exit``.
+ 7. Finally, instead of returning to kernel, all registers that have been
+ setup by ``start_thread`` is restored by restoring regs stored on stack.
L2 handling
-----------
On kvx, the L2 is handled by a firmware running on the RM. This firmware
needs various information to be aware of its configuration and communicate
-with the kernel. In order to do that, when firmware is starting, the device
+with the kernel. In order to do that, when the firmware is starting, the device
tree is given as parameter along with the "registers" zone. This zone is
-simply a memory area where data are exchanged between kernel <-> L2. When
+simply a memory area where data are exchanged between kernel and L2. When
some commands are written to it, the kernel sends an interrupt using a mailbox.
-If the L2 node is not present in the device tree, then, the RM will directly go
-into sleeping.
+If the L2 node is not present in the device tree, the RM will directly go into
+sleeping.
Boot diagram::
@@ -244,26 +243,29 @@ Boot diagram::
+------------+ + v
-Since this driver is started early (before SMP boot), A lot of drivers
+Since this driver is started early (before initializing SMP), a lot of drivers
are not yet probed (mailboxes, IOMMU, etc) and thus can not be used.
Building
--------
-In order to build the kernel, you will need a complete kvx toolchain.
-First, setup the config using the following command line::
+In order to build the kernel, you will need kvx cross toolchain and have it
+somewhere in the ``PATH``.
+
+First, prepare the default configuration by::
$ make ARCH=kvx O=your_directory defconfig
-Adjust any configuration option you may need and then, build the kernel::
+Launch your desired configuration frontend (like ``menuconfig``) and then,
+build the kernel::
$ make ARCH=kvx O=your_directory -j12
-You will finally have a vmlinux image ready to be run::
+You will finally have ``vmlinux`` kernel image, which can be run by::
$ kvx-mppa -- vmlinux
-Additionally, you may want to debug it. To do so, use kvx-gdb::
+In case you need to debug the kernel, you can simply launch::
$ kvx-gdb vmlinux
Thanks.
--
An old man doll... just what I always wanted! - Clara
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