nuttx/syscall
2015-03-31 11:59:16 -06:00
..
proxies
stubs
.gitignore
Kconfig Rename CONFIG_NUTTX_KERNEL to CONFIG_BUILD_PROTECTED; Partially integrate new CONFIG_BUILD_KERNEL 2014-08-29 14:47:22 -06:00
Makefile
README.txt Fix some cloned errors in SAM GPIO interrupt setup 2014-07-07 15:54:37 -06:00
syscall_clock_systimer.c Remove CONFIG_DISABLE_CLOCK 2014-08-07 12:35:24 -06:00
syscall_funclookup.c boardctl(): Add a new non-standard OS interface. This is similar to a driver IOCTL call. But this is an IOCTL call directly on the board logic. This function will eventually replace all of the ad hoc OS interfaces that are current used to perform application specific intialiation and application driver test confifuration. It essentially formalizes and institutionalizes these rogue interface in to at least a single crazy call. 2015-03-31 11:25:52 -06:00
syscall_lookup.h boardctl(): Add a new non-standard OS interface. This is similar to a driver IOCTL call. But this is an IOCTL call directly on the board logic. This function will eventually replace all of the ad hoc OS interfaces that are current used to perform application specific intialiation and application driver test confifuration. It essentially formalizes and institutionalizes these rogue interface in to at least a single crazy call. 2015-03-31 11:25:52 -06:00
syscall_nparms.c ARMv7-A: Add SYSCALL handling logic 2014-08-28 14:52:14 -06:00
syscall_stublookup.c Fix some problems with a preceding commit 2015-03-31 11:59:16 -06:00
syscall.csv boardctl(): Add a new non-standard OS interface. This is similar to a driver IOCTL call. But this is an IOCTL call directly on the board logic. This function will eventually replace all of the ad hoc OS interfaces that are current used to perform application specific intialiation and application driver test confifuration. It essentially formalizes and institutionalizes these rogue interface in to at least a single crazy call. 2015-03-31 11:25:52 -06:00

syscall/README.txt
==================

This directory supports a syscall layer from communication between a
monolithic, kernel-mode NuttX kernel and a separately built, user-mode
application set.

With most MCUs, NuttX is built as a flat, single executable image
containing the NuttX RTOS along with all application code.  The RTOS code
and the application run in the same address space and at the same kernel-
mode privileges.  In order to exploit security features of certain
processors, an alternative build model is also supported:  NuttX can
be built separately as a monolithic, kernel-mode module and the applications
can be added as a separately built, user-mode module.

The syscall layer provided in this directory serves as the communication
layer from the user-mode application into the kernel-mode RTOS.  The
switch from user-mode to kernel-mode is accomplished using software
interrupts (SWIs).  SWIs are implemented differently and named differently
by different manufacturers but all work essentially the same:  A special
instruction is executed in user-mode that causes a software generated
interrupt.  The software generated interrupt is caught within the kernel
and handle in kernel-mode.

Header Files
============

include/syscall.h

  This header file supports general access to SWI facilities.  It is simply
  a wrapper file that includes include/sys/syscall.h and
  include/arch/syscall.h.

include/sys/syscall.h

  The SWIs received by the kernel are distinguish by a code that identifies
  how to process the SWI.  This header file defines all such codes understood
  by the NuttX kernel.

include/arch/syscall.h (or arch/<cpu>/include/syscall.h)

  This header file is provided by the platform-specific logic and declares
  (or defines) the mechanism for providing software interrupts on this
  platform.  The following functions must be declared (or defined) in this
  header file:

  - SWI with SYS_ call number and one parameter

    uintptr_t sys_call0(unsigned int nbr);

  - SWI with SYS_ call number and one parameter

    uintptr_t sys_call1(unsigned int nbr, uintptr_t parm1);

  - SWI with SYS_ call number and two parameters

    uintptr_t sys_call2(unsigned int nbr, uintptr_t parm1, uintptr_t parm2);

  - SWI with SYS_ call number and three parameters

    uintptr_t sys_call3(unsigned int nbr, uintptr_t parm1,
                        uintptr_t parm2, uintptr_t parm3);

  - SWI with SYS_ call number and four parameters

    uintptr_t sys_call4(unsigned int nbr, uintptr_t parm1, uintptr_t parm2,
                        uintptr_t parm3, uintptr_t parm4);

  - SWI with SYS_ call number and five parameters

    uintptr_t sys_call5(unsigned int nbr, uintptr_t parm1, uintptr_t parm2,
                        uintptr_t parm3, uintptr_t parm4, uintptr_t parm5);

  - SWI with SYS_ call number and six parameters

    uintptr_t sys_call6(unsigned int nbr, uintptr_t parm1, uintptr_t parm2,
                        uintptr_t parm3, uintptr_t parm4, uintptr_t parm5,
                        uintptr_t parm6);
Syscall Database
================

Sycall information is maintained in a database.  That "database" is
implemented as a simple comma-separated-value file, syscall.csv.  Most
spreadsheets programs will accept this format and can be used to maintain
the syscall database.

The format of the CSV file for each line is:

  Field 1: Function name
  Field 2: The header file that contains the function prototype
  Field 3: Condition for compilation
  Field 4: The type of function return value.
  Field 5 - N+5: The type of each of the N formal parameters of the function

Each type field has a format as follows:

  type name:
        For all simpler types
  formal type | actual type:
        For array types where the form of the formal (eg. int parm[2])
        differs from the type of actual passed parameter (eg. int*).  This
        is necessary because you cannot do simple casts to array types.
  formal type | union member actual type | union member fieldname:
        A similar situation exists for unions.  For example, the formal
        parameter type union sigval -- You cannot cast a uintptr_t to
        a union sigval, but you can cast to the type of one of the union
        member types when passing the actual parameter.  Similarly, we
        cannot cast a union sigval to a uinptr_t either.  Rather, we need
        to cast a specific union member fieldname to uintptr_t.

NOTE: This CSV file is used both to support the generate of trap information,
but also for the generation of symbol tables.  See nuttx/tools/README.txt
and nuttx/lib/README.txt for further information.

Auto-Generated Files
====================

Stubs and proxies for the sycalls are automatically generated from this CSV
database.  Here the following definition is used:

  Proxy - A tiny bit of code that executes in the user space. A proxy
          has exactly the same function prototype as does the "real" function
          for which it proxies.  However, it only serves to map the function
          call into a syscall, marshaling all of the system call parameters
          as necessary.

  Stub  - Another tiny bit of code that executes within the NuttX kernel
          that is used to map a software interrupt received by the kernel to
          a kernel function call. The stubs receive the marshaled system
          call data, and perform the actually kernel function call (in
          kernel-mode) on behalf of the proxy function.

Sub-Directories
===============

  stubs - Autogenerated stub files are placed in this directory.
  proxies - Autogenerated proxy files are placed in this directory.

mksyscall
=========

  mksyscall is C program that is used used during the initial NuttX build
  by the logic in the top-level syscall/ directory. Information about the
  stubs and proxies is maintained in a comma separated value (CSV) file
  in the syscall/ directory.  The mksyscall program will accept this CVS
  file as input and generate all of the required proxy or stub files as
  output.  See tools/README.txt for additional information.