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Message-Id: <20230621072234.9900-2-alexghiti@rivosinc.com>
Date: Wed, 21 Jun 2023 09:22:33 +0200
From: Alexandre Ghiti <alexghiti@...osinc.com>
To: Jonathan Corbet <corbet@....net>,
Paul Walmsley <paul.walmsley@...ive.com>,
Palmer Dabbelt <palmer@...belt.com>,
Albert Ou <aou@...s.berkeley.edu>,
Conor Dooley <conor.dooley@...rochip.com>,
Sunil V L <sunilvl@...tanamicro.com>,
Song Shuai <songshuaishuai@...ylab.org>,
linux-doc@...r.kernel.org, linux-riscv@...ts.infradead.org,
linux-kernel@...r.kernel.org
Cc: Alexandre Ghiti <alexghiti@...osinc.com>,
Björn Töpel <bjorn@...osinc.com>
Subject: [PATCH v2 2/3] Documentation: riscv: Add early boot document
This document describes the constraints and requirements of the early
boot process in a RISC-V kernel.
Signed-off-by: Alexandre Ghiti <alexghiti@...osinc.com>
Reviewed-by: Björn Töpel <bjorn@...osinc.com>
---
Documentation/riscv/boot-image-header.rst | 3 -
Documentation/riscv/boot.rst | 170 ++++++++++++++++++++++
Documentation/riscv/index.rst | 1 +
3 files changed, 171 insertions(+), 3 deletions(-)
create mode 100644 Documentation/riscv/boot.rst
diff --git a/Documentation/riscv/boot-image-header.rst b/Documentation/riscv/boot-image-header.rst
index d7752533865f..a4a45310c4c4 100644
--- a/Documentation/riscv/boot-image-header.rst
+++ b/Documentation/riscv/boot-image-header.rst
@@ -7,9 +7,6 @@ Boot image header in RISC-V Linux
This document only describes the boot image header details for RISC-V Linux.
-TODO:
- Write a complete booting guide.
-
The following 64-byte header is present in decompressed Linux kernel image::
u32 code0; /* Executable code */
diff --git a/Documentation/riscv/boot.rst b/Documentation/riscv/boot.rst
new file mode 100644
index 000000000000..019ee818686d
--- /dev/null
+++ b/Documentation/riscv/boot.rst
@@ -0,0 +1,170 @@
+.. SPDX-License-Identifier: GPL-2.0
+
+===============================================
+RISC-V Kernel Boot Requirements and Constraints
+===============================================
+
+:Author: Alexandre Ghiti <alexghiti@...osinc.com>
+:Date: 23 May 2023
+
+This document describes what the RISC-V kernel expects from bootloaders and
+firmware, but also the constraints that any developer must have in mind when
+touching the early boot process. For the purposes of this document, the
+'early boot process' refers to any code that runs before the final virtual
+mapping is set up.
+
+Pre-kernel Requirements and Constraints
+=======================================
+
+The RISC-V kernel expects the following of bootloaders and platform firmware:
+
+Register state
+--------------
+
+The RISC-V kernel expects:
+
+ * `$a0` to contain the hartid of the current core.
+ * `$a1` to contain the address of the devicetree in memory.
+
+CSR state
+---------
+
+The RISC-V kernel expects:
+
+ * `$satp = 0`: the MMU, if present, must be disabled.
+
+Reserved memory for resident firmware
+-------------------------------------
+
+The RISC-V kernel must not map any resident memory, or memory protected with
+PMPs, in the direct mapping, so the firmware must correctly mark those regions
+as per the devicetree specification and/or the UEFI specification.
+
+Kernel location
+---------------
+
+The RISC-V kernel expects to be placed at a PMD boundary (2MB aligned for rv64
+and 4MB aligned for rv32). Note that the EFI stub will physically relocate the
+kernel if that's not the case.
+
+Hardware description
+--------------------
+
+The firmware can pass either a devicetree or ACPI tables to the RISC-V kernel.
+
+The devicetree is either passed directly to the kernel from the previous stage
+using the `$a1` register, or when booting with UEFI, it can be passed using the
+EFI configuration table.
+
+The ACPI tables are passed to the kernel using the EFI configuration table. In
+this case, a tiny devicetree is still created by the EFI stub. Please refer to
+"EFI stub and devicetree" tree section below for details about this devicetree.
+
+Kernel entrance
+---------------
+
+On SMP systems, there are 2 methods to enter the kernel:
+
+- `RISCV_BOOT_SPINWAIT`: the firmware releases all harts in the kernel, one hart
+ wins a lottery and executes the early boot code while the other harts are
+ parked waiting for the initialization to finish. This method is mostly used to
+ support older firmwares without SBI HSM extension and M-mode RISC-V kernel.
+- `Ordered booting`: the firmware releases only one hart that will execute the
+ initialization phase and then will start all other harts using the SBI HSM
+ extension. The ordered booting method is the preferred booting method for
+ booting the RISC-V kernel because it can support cpu hotplug and kexec.
+
+UEFI
+----
+
+UEFI memory map
+~~~~~~~~~~~~~~~
+
+When booting with UEFI, the RISC-V kernel will use only the EFI memory map to
+populate the system memory.
+
+The UEFI firmware must parse the subnodes of the `/reserved-memory` devicetree
+node and abide by the devicetree specification to convert the attributes of
+those subnodes (`no-map` and `reusable`) into their correct EFI equivalent
+(refer to section "3.5.4 /reserved-memory and UEFI" of the devicetree
+specification v0.4-rc1).
+
+RISCV_EFI_BOOT_PROTOCOL
+~~~~~~~~~~~~~~~~~~~~~~~
+
+When booting with UEFI, the EFI stub requires the boot hartid in order to pass
+it to the RISC-V kernel in `$a1`. The EFI stub retrieves the boot hartid using
+one of the following methods:
+
+- `RISCV_EFI_BOOT_PROTOCOL` (**preferred**).
+- `boot-hartid` devicetree subnode (**deprecated**).
+
+Any new firmware must implement `RISCV_EFI_BOOT_PROTOCOL` as the devicetree
+based approach is deprecated now.
+
+Early Boot Requirements and Constraints
+=======================================
+
+The RISC-V kernel's early boot process operates under the following constraints:
+
+EFI stub and devicetree
+-----------------------
+
+When booting with UEFI, the devicetree is supplemented (or created) by the EFI
+stub with the same parameters as arm64 which are described at the paragraph
+"UEFI kernel support on ARM" in Documentation/arm/uefi.rst.
+
+Virtual mapping installation
+----------------------------
+
+The installation of the virtual mapping is done in 2 steps in the RISC-V kernel:
+
+1. :c:func:`setup_vm` installs a temporary kernel mapping in
+ :c:var:`early_pg_dir` which allows discovery of the system memory. Only the
+ kernel text/data are mapped at this point. When establishing this mapping, no
+ allocation can be done (since the system memory is not known yet), so
+ :c:var:`early_pg_dir` page table is statically allocated (using only one
+ table for each level).
+
+2. :c:func:`setup_vm_final` creates the final kernel mapping in
+ :c:var:`swapper_pg_dir` and takes advantage of the discovered system memory
+ to create the linear mapping. When establishing this mapping, the kernel
+ can allocate memory but cannot access it directly (since the direct mapping
+ is not present yet), so it uses temporary mappings in the fixmap region to
+ be able to access the newly allocated page table levels.
+
+For :c:func:`virt_to_phys` and :c:func:`phys_to_virt` to be able to correctly
+convert direct mapping addresses to physical addresses, they need to know the
+start of the DRAM. This happens after step 1, right before step 2 installs the
+direct mapping (see :c:func:`setup_bootmem` function in arch/riscv/mm/init.c).
+Any usage of those macros before the final virtual mapping is installed must
+be carefully examined.
+
+Device-tree mapping via fixmap
+------------------------------
+
+The RISC-V kernel uses the fixmap region to map the devicetree because the
+devicetree virtual mapping must remain the same between :c:func:`setup_vm` and
+:c:func:`setup_vm_final` calls since the :c:var:`reserved_mem` array is
+initialized with virtual addresses established by :c:func:`setup_vm` and used
+with the mapping established by :c:func:`setup_vm_final`.
+
+Pre-MMU execution
+-----------------
+
+A few pieces of code need to run before even the first virtual mapping is
+established. These are the installation of the first virtual mapping itself,
+patching of early alternatives and the early parsing of the kernel command line.
+That code must be very carefully compiled as:
+
+- `-fno-pie`: This is needed for relocatable kernels which use `-fPIE`, since
+ otherwise, any access to a global symbol would go through the GOT which is
+ only relocated virtually.
+- `-mcmodel=medany`: Any access to a global symbol must be PC-relative to avoid
+ any relocations to happen before the MMU is setup.
+- *all* instrumentation must also be disabled (that includes KASAN, ftrace and
+ others).
+
+As using a symbol from a different compilation unit requires this unit to be
+compiled with those flags, we advise, as much as possible, not to use external
+symbols.
diff --git a/Documentation/riscv/index.rst b/Documentation/riscv/index.rst
index 175a91db0200..1f66062def6d 100644
--- a/Documentation/riscv/index.rst
+++ b/Documentation/riscv/index.rst
@@ -5,6 +5,7 @@ RISC-V architecture
.. toctree::
:maxdepth: 1
+ boot
boot-image-header
vm-layout
hwprobe
--
2.39.2
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