linux/Documentation/arm64/memory.rst
Steve Capper d2c68de192 docs: arm64: Add layout and 52-bit info to memory document
As the kernel no longer prints out the memory layout on boot, this patch
adds this information back to the memory document.

Also, as the 52-bit support introduces some subtle changes to the arm64
memory, the rationale behind these changes are also added to the memory
document.

Signed-off-by: Steve Capper <steve.capper@arm.com>
Reviewed-by: Catalin Marinas <catalin.marinas@arm.com>
Signed-off-by: Will Deacon <will@kernel.org>
2019-08-09 11:17:32 +01:00

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==============================
Memory Layout on AArch64 Linux
==============================
Author: Catalin Marinas <catalin.marinas@arm.com>
This document describes the virtual memory layout used by the AArch64
Linux kernel. The architecture allows up to 4 levels of translation
tables with a 4KB page size and up to 3 levels with a 64KB page size.
AArch64 Linux uses either 3 levels or 4 levels of translation tables
with the 4KB page configuration, allowing 39-bit (512GB) or 48-bit
(256TB) virtual addresses, respectively, for both user and kernel. With
64KB pages, only 2 levels of translation tables, allowing 42-bit (4TB)
virtual address, are used but the memory layout is the same.
ARMv8.2 adds optional support for Large Virtual Address space. This is
only available when running with a 64KB page size and expands the
number of descriptors in the first level of translation.
User addresses have bits 63:48 set to 0 while the kernel addresses have
the same bits set to 1. TTBRx selection is given by bit 63 of the
virtual address. The swapper_pg_dir contains only kernel (global)
mappings while the user pgd contains only user (non-global) mappings.
The swapper_pg_dir address is written to TTBR1 and never written to
TTBR0.
AArch64 Linux memory layout with 4KB pages + 4 levels (48-bit)::
Start End Size Use
-----------------------------------------------------------------------
0000000000000000 0000ffffffffffff 256TB user
ffff000000000000 ffff7fffffffffff 128TB kernel logical memory map
ffff800000000000 ffff9fffffffffff 32TB kasan shadow region
ffffa00000000000 ffffa00007ffffff 128MB bpf jit region
ffffa00008000000 ffffa0000fffffff 128MB modules
ffffa00010000000 fffffdffbffeffff ~93TB vmalloc
fffffdffbfff0000 fffffdfffe5f8fff ~998MB [guard region]
fffffdfffe5f9000 fffffdfffe9fffff 4124KB fixed mappings
fffffdfffea00000 fffffdfffebfffff 2MB [guard region]
fffffdfffec00000 fffffdffffbfffff 16MB PCI I/O space
fffffdffffc00000 fffffdffffdfffff 2MB [guard region]
fffffdffffe00000 ffffffffffdfffff 2TB vmemmap
ffffffffffe00000 ffffffffffffffff 2MB [guard region]
AArch64 Linux memory layout with 64KB pages + 3 levels (52-bit with HW support)::
Start End Size Use
-----------------------------------------------------------------------
0000000000000000 000fffffffffffff 4PB user
fff0000000000000 fff7ffffffffffff 2PB kernel logical memory map
fff8000000000000 fffd9fffffffffff 1440TB [gap]
fffda00000000000 ffff9fffffffffff 512TB kasan shadow region
ffffa00000000000 ffffa00007ffffff 128MB bpf jit region
ffffa00008000000 ffffa0000fffffff 128MB modules
ffffa00010000000 fffff81ffffeffff ~88TB vmalloc
fffff81fffff0000 fffffc1ffe58ffff ~3TB [guard region]
fffffc1ffe590000 fffffc1ffe9fffff 4544KB fixed mappings
fffffc1ffea00000 fffffc1ffebfffff 2MB [guard region]
fffffc1ffec00000 fffffc1fffbfffff 16MB PCI I/O space
fffffc1fffc00000 fffffc1fffdfffff 2MB [guard region]
fffffc1fffe00000 ffffffffffdfffff 3968GB vmemmap
ffffffffffe00000 ffffffffffffffff 2MB [guard region]
Translation table lookup with 4KB pages::
+--------+--------+--------+--------+--------+--------+--------+--------+
|63 56|55 48|47 40|39 32|31 24|23 16|15 8|7 0|
+--------+--------+--------+--------+--------+--------+--------+--------+
| | | | | |
| | | | | v
| | | | | [11:0] in-page offset
| | | | +-> [20:12] L3 index
| | | +-----------> [29:21] L2 index
| | +---------------------> [38:30] L1 index
| +-------------------------------> [47:39] L0 index
+-------------------------------------------------> [63] TTBR0/1
Translation table lookup with 64KB pages::
+--------+--------+--------+--------+--------+--------+--------+--------+
|63 56|55 48|47 40|39 32|31 24|23 16|15 8|7 0|
+--------+--------+--------+--------+--------+--------+--------+--------+
| | | | |
| | | | v
| | | | [15:0] in-page offset
| | | +----------> [28:16] L3 index
| | +--------------------------> [41:29] L2 index
| +-------------------------------> [47:42] L1 index (48-bit)
| [51:42] L1 index (52-bit)
+-------------------------------------------------> [63] TTBR0/1
When using KVM without the Virtualization Host Extensions, the
hypervisor maps kernel pages in EL2 at a fixed (and potentially
random) offset from the linear mapping. See the kern_hyp_va macro and
kvm_update_va_mask function for more details. MMIO devices such as
GICv2 gets mapped next to the HYP idmap page, as do vectors when
ARM64_HARDEN_EL2_VECTORS is selected for particular CPUs.
When using KVM with the Virtualization Host Extensions, no additional
mappings are created, since the host kernel runs directly in EL2.
52-bit VA support in the kernel
-------------------------------
If the ARMv8.2-LVA optional feature is present, and we are running
with a 64KB page size; then it is possible to use 52-bits of address
space for both userspace and kernel addresses. However, any kernel
binary that supports 52-bit must also be able to fall back to 48-bit
at early boot time if the hardware feature is not present.
This fallback mechanism necessitates the kernel .text to be in the
higher addresses such that they are invariant to 48/52-bit VAs. Due
to the kasan shadow being a fraction of the entire kernel VA space,
the end of the kasan shadow must also be in the higher half of the
kernel VA space for both 48/52-bit. (Switching from 48-bit to 52-bit,
the end of the kasan shadow is invariant and dependent on ~0UL,
whilst the start address will "grow" towards the lower addresses).
In order to optimise phys_to_virt and virt_to_phys, the PAGE_OFFSET
is kept constant at 0xFFF0000000000000 (corresponding to 52-bit),
this obviates the need for an extra variable read. The physvirt
offset and vmemmap offsets are computed at early boot to enable
this logic.
As a single binary will need to support both 48-bit and 52-bit VA
spaces, the VMEMMAP must be sized large enough for 52-bit VAs and
also must be sized large enought to accommodate a fixed PAGE_OFFSET.
Most code in the kernel should not need to consider the VA_BITS, for
code that does need to know the VA size the variables are
defined as follows:
VA_BITS constant the *maximum* VA space size
VA_BITS_MIN constant the *minimum* VA space size
vabits_actual variable the *actual* VA space size
Maximum and minimum sizes can be useful to ensure that buffers are
sized large enough or that addresses are positioned close enough for
the "worst" case.
52-bit userspace VAs
--------------------
To maintain compatibility with software that relies on the ARMv8.0
VA space maximum size of 48-bits, the kernel will, by default,
return virtual addresses to userspace from a 48-bit range.
Software can "opt-in" to receiving VAs from a 52-bit space by
specifying an mmap hint parameter that is larger than 48-bit.
For example:
maybe_high_address = mmap(~0UL, size, prot, flags,...);
It is also possible to build a debug kernel that returns addresses
from a 52-bit space by enabling the following kernel config options:
CONFIG_EXPERT=y && CONFIG_ARM64_FORCE_52BIT=y
Note that this option is only intended for debugging applications
and should not be used in production.