xref: /linux/Documentation/arch/riscv/boot.rst (revision 3d0fe49454652117522f60bfbefb978ba0e5300b)
1.. SPDX-License-Identifier: GPL-2.0
2
3===============================================
4RISC-V Kernel Boot Requirements and Constraints
5===============================================
6
7:Author: Alexandre Ghiti <alexghiti@rivosinc.com>
8:Date: 23 May 2023
9
10This document describes what the RISC-V kernel expects from bootloaders and
11firmware, and also the constraints that any developer must have in mind when
12touching the early boot process. For the purposes of this document, the
13``early boot process`` refers to any code that runs before the final virtual
14mapping is set up.
15
16Pre-kernel Requirements and Constraints
17=======================================
18
19The RISC-V kernel expects the following of bootloaders and platform firmware:
20
21Register state
22--------------
23
24The RISC-V kernel expects:
25
26  * ``$a0`` to contain the hartid of the current core.
27  * ``$a1`` to contain the address of the devicetree in memory.
28
29CSR state
30---------
31
32The RISC-V kernel expects:
33
34  * ``$satp = 0``: the MMU, if present, must be disabled.
35
36Reserved memory for resident firmware
37-------------------------------------
38
39The RISC-V kernel must not map any resident memory, or memory protected with
40PMPs, in the direct mapping, so the firmware must correctly mark those regions
41as per the devicetree specification and/or the UEFI specification.
42
43Kernel location
44---------------
45
46The RISC-V kernel expects to be placed at a PMD boundary (2MB aligned for rv64
47and 4MB aligned for rv32). Note that the EFI stub will physically relocate the
48kernel if that's not the case.
49
50Hardware description
51--------------------
52
53The firmware can pass either a devicetree or ACPI tables to the RISC-V kernel.
54
55The devicetree is either passed directly to the kernel from the previous stage
56using the ``$a1`` register, or when booting with UEFI, it can be passed using the
57EFI configuration table.
58
59The ACPI tables are passed to the kernel using the EFI configuration table. In
60this case, a tiny devicetree is still created by the EFI stub. Please refer to
61"EFI stub and devicetree" section below for details about this devicetree.
62
63Kernel entry
64------------
65
66On SMP systems, there are 2 methods to enter the kernel:
67
68- ``RISCV_BOOT_SPINWAIT``: the firmware releases all harts in the kernel, one hart
69  wins a lottery and executes the early boot code while the other harts are
70  parked waiting for the initialization to finish. This method is mostly used to
71  support older firmwares without SBI HSM extension and M-mode RISC-V kernel.
72- ``Ordered booting``: the firmware releases only one hart that will execute the
73  initialization phase and then will start all other harts using the SBI HSM
74  extension. The ordered booting method is the preferred booting method for
75  booting the RISC-V kernel because it can support CPU hotplug and kexec.
76
77UEFI
78----
79
80UEFI memory map
81~~~~~~~~~~~~~~~
82
83When booting with UEFI, the RISC-V kernel will use only the EFI memory map to
84populate the system memory.
85
86The UEFI firmware must parse the subnodes of the ``/reserved-memory`` devicetree
87node and abide by the devicetree specification to convert the attributes of
88those subnodes (``no-map`` and ``reusable``) into their correct EFI equivalent
89(refer to section "3.5.4 /reserved-memory and UEFI" of the devicetree
90specification v0.4-rc1).
91
92RISCV_EFI_BOOT_PROTOCOL
93~~~~~~~~~~~~~~~~~~~~~~~
94
95When booting with UEFI, the EFI stub requires the boot hartid in order to pass
96it to the RISC-V kernel in ``$a1``. The EFI stub retrieves the boot hartid using
97one of the following methods:
98
99- ``RISCV_EFI_BOOT_PROTOCOL`` (**preferred**).
100- ``boot-hartid`` devicetree subnode (**deprecated**).
101
102Any new firmware must implement ``RISCV_EFI_BOOT_PROTOCOL`` as the devicetree
103based approach is deprecated now.
104
105Early Boot Requirements and Constraints
106=======================================
107
108The RISC-V kernel's early boot process operates under the following constraints:
109
110EFI stub and devicetree
111-----------------------
112
113When booting with UEFI, the devicetree is supplemented (or created) by the EFI
114stub with the same parameters as arm64 which are described at the paragraph
115"UEFI kernel support on ARM" in Documentation/arch/arm/uefi.rst.
116
117Virtual mapping installation
118----------------------------
119
120The installation of the virtual mapping is done in 2 steps in the RISC-V kernel:
121
1221. ``setup_vm()`` installs a temporary kernel mapping in ``early_pg_dir`` which
123   allows discovery of the system memory. Only the kernel text/data are mapped
124   at this point. When establishing this mapping, no allocation can be done
125   (since the system memory is not known yet), so ``early_pg_dir`` page table is
126   statically allocated (using only one table for each level).
127
1282. ``setup_vm_final()`` creates the final kernel mapping in ``swapper_pg_dir``
129   and takes advantage of the discovered system memory to create the linear
130   mapping. When establishing this mapping, the kernel can allocate memory but
131   cannot access it directly (since the direct mapping is not present yet), so
132   it uses temporary mappings in the fixmap region to be able to access the
133   newly allocated page table levels.
134
135For ``virt_to_phys()`` and ``phys_to_virt()`` to be able to correctly convert
136direct mapping addresses to physical addresses, they need to know the start of
137the DRAM. This happens after step 1, right before step 2 installs the direct
138mapping (see ``setup_bootmem()`` function in arch/riscv/mm/init.c). Any usage of
139those macros before the final virtual mapping is installed must be carefully
140examined.
141
142Devicetree mapping via fixmap
143-----------------------------
144
145As the ``reserved_mem`` array is initialized with virtual addresses established
146by ``setup_vm()``, and used with the mapping established by
147``setup_vm_final()``, the RISC-V kernel uses the fixmap region to map the
148devicetree. This ensures that the devicetree remains accessible by both virtual
149mappings.
150
151Pre-MMU execution
152-----------------
153
154A few pieces of code need to run before even the first virtual mapping is
155established. These are the installation of the first virtual mapping itself,
156patching of early alternatives and the early parsing of the kernel command line.
157That code must be very carefully compiled as:
158
159- ``-fno-pie``: This is needed for relocatable kernels which use ``-fPIE``,
160  since otherwise, any access to a global symbol would go through the GOT which
161  is only relocated virtually.
162- ``-mcmodel=medany``: Any access to a global symbol must be PC-relative to
163  avoid any relocations to happen before the MMU is setup.
164- *all* instrumentation must also be disabled (that includes KASAN, ftrace and
165  others).
166
167As using a symbol from a different compilation unit requires this unit to be
168compiled with those flags, we advise, as much as possible, not to use external
169symbols.
170