123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122 |
- Kernel mode NEON
- ================
- TL;DR summary
- -------------
- * Use only NEON instructions, or VFP instructions that don't rely on support
- code
- * Isolate your NEON code in a separate compilation unit, and compile it with
- '-mfpu=neon -mfloat-abi=softfp'
- * Put kernel_neon_begin() and kernel_neon_end() calls around the calls into your
- NEON code
- * Don't sleep in your NEON code, and be aware that it will be executed with
- preemption disabled
- Introduction
- ------------
- It is possible to use NEON instructions (and in some cases, VFP instructions) in
- code that runs in kernel mode. However, for performance reasons, the NEON/VFP
- register file is not preserved and restored at every context switch or taken
- exception like the normal register file is, so some manual intervention is
- required. Furthermore, special care is required for code that may sleep [i.e.,
- may call schedule()], as NEON or VFP instructions will be executed in a
- non-preemptible section for reasons outlined below.
- Lazy preserve and restore
- -------------------------
- The NEON/VFP register file is managed using lazy preserve (on UP systems) and
- lazy restore (on both SMP and UP systems). This means that the register file is
- kept 'live', and is only preserved and restored when multiple tasks are
- contending for the NEON/VFP unit (or, in the SMP case, when a task migrates to
- another core). Lazy restore is implemented by disabling the NEON/VFP unit after
- every context switch, resulting in a trap when subsequently a NEON/VFP
- instruction is issued, allowing the kernel to step in and perform the restore if
- necessary.
- Any use of the NEON/VFP unit in kernel mode should not interfere with this, so
- it is required to do an 'eager' preserve of the NEON/VFP register file, and
- enable the NEON/VFP unit explicitly so no exceptions are generated on first
- subsequent use. This is handled by the function kernel_neon_begin(), which
- should be called before any kernel mode NEON or VFP instructions are issued.
- Likewise, the NEON/VFP unit should be disabled again after use to make sure user
- mode will hit the lazy restore trap upon next use. This is handled by the
- function kernel_neon_end().
- Interruptions in kernel mode
- ----------------------------
- For reasons of performance and simplicity, it was decided that there shall be no
- preserve/restore mechanism for the kernel mode NEON/VFP register contents. This
- implies that interruptions of a kernel mode NEON section can only be allowed if
- they are guaranteed not to touch the NEON/VFP registers. For this reason, the
- following rules and restrictions apply in the kernel:
- * NEON/VFP code is not allowed in interrupt context;
- * NEON/VFP code is not allowed to sleep;
- * NEON/VFP code is executed with preemption disabled.
- If latency is a concern, it is possible to put back to back calls to
- kernel_neon_end() and kernel_neon_begin() in places in your code where none of
- the NEON registers are live. (Additional calls to kernel_neon_begin() should be
- reasonably cheap if no context switch occurred in the meantime)
- VFP and support code
- --------------------
- Earlier versions of VFP (prior to version 3) rely on software support for things
- like IEEE-754 compliant underflow handling etc. When the VFP unit needs such
- software assistance, it signals the kernel by raising an undefined instruction
- exception. The kernel responds by inspecting the VFP control registers and the
- current instruction and arguments, and emulates the instruction in software.
- Such software assistance is currently not implemented for VFP instructions
- executed in kernel mode. If such a condition is encountered, the kernel will
- fail and generate an OOPS.
- Separating NEON code from ordinary code
- ---------------------------------------
- The compiler is not aware of the special significance of kernel_neon_begin() and
- kernel_neon_end(), i.e., that it is only allowed to issue NEON/VFP instructions
- between calls to these respective functions. Furthermore, GCC may generate NEON
- instructions of its own at -O3 level if -mfpu=neon is selected, and even if the
- kernel is currently compiled at -O2, future changes may result in NEON/VFP
- instructions appearing in unexpected places if no special care is taken.
- Therefore, the recommended and only supported way of using NEON/VFP in the
- kernel is by adhering to the following rules:
- * isolate the NEON code in a separate compilation unit and compile it with
- '-mfpu=neon -mfloat-abi=softfp';
- * issue the calls to kernel_neon_begin(), kernel_neon_end() as well as the calls
- into the unit containing the NEON code from a compilation unit which is *not*
- built with the GCC flag '-mfpu=neon' set.
- As the kernel is compiled with '-msoft-float', the above will guarantee that
- both NEON and VFP instructions will only ever appear in designated compilation
- units at any optimization level.
- NEON assembler
- --------------
- NEON assembler is supported with no additional caveats as long as the rules
- above are followed.
- NEON code generated by GCC
- --------------------------
- The GCC option -ftree-vectorize (implied by -O3) tries to exploit implicit
- parallelism, and generates NEON code from ordinary C source code. This is fully
- supported as long as the rules above are followed.
- NEON intrinsics
- ---------------
- NEON intrinsics are also supported. However, as code using NEON intrinsics
- relies on the GCC header <arm_neon.h>, (which #includes <stdint.h>), you should
- observe the following in addition to the rules above:
- * Compile the unit containing the NEON intrinsics with '-ffreestanding' so GCC
- uses its builtin version of <stdint.h> (this is a C99 header which the kernel
- does not supply);
- * Include <arm_neon.h> last, or at least after <linux/types.h>
|