incubator-nuttx/arch/arm/include/armv7-a/irq.h

/****************************************************************************
 * arch/arm/include/armv7-a/irq.h
 *
 *   Copyright (C) 2013-2014 Gregory Nutt. All rights reserved.
 *   Author: Gregory Nutt <gnutt@nuttx.org>
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 *
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in
 *    the documentation and/or other materials provided with the
 *    distribution.
 * 3. Neither the name NuttX nor the names of its contributors may be
 *    used to endorse or promote products derived from this software
 *    without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
 * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
 * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
 * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 * POSSIBILITY OF SUCH DAMAGE.
 *
 ****************************************************************************/

/* This file should never be included directed but, rather, only indirectly
 * through nuttx/irq.h
 */

#ifndef __ARCH_ARM_INCLUDE_ARMV7_A_IRQ_H
#define __ARCH_ARM_INCLUDE_ARMV7_A_IRQ_H

/****************************************************************************
 * Included Files
 ****************************************************************************/

#include <nuttx/config.h>
#include <nuttx/irq.h>

#ifndef __ASSEMBLY__
#  include <stdint.h>
#  include <arch/arch.h>
#endif

/****************************************************************************
 * Pre-processor Definitions
 ****************************************************************************/

/* IRQ Stack Frame Format:
 *
 * Context is always saved/restored in the same way:
 *
 *   (1) stmia rx, {r0-r14}
 *   (2) then the PC and CPSR
 *
 * This results in the following set of indices that can be used to access
 * individual registers in the xcp.regs array:
 */

#define REG_R0              (0)
#define REG_R1              (1)
#define REG_R2              (2)
#define REG_R3              (3)
#define REG_R4              (4)
#define REG_R5              (5)
#define REG_R6              (6)
#define REG_R7              (7)
#define REG_R8              (8)
#define REG_R9              (9)
#define REG_R10             (10)
#define REG_R11             (11)
#define REG_R12             (12)
#define REG_R13             (13)
#define REG_R14             (14)
#define REG_R15             (15)
#define REG_CPSR            (16)

#define ARM_CONTEXT_REGS    (17)

/* If the MCU supports a floating point unit, then it will be necessary
 * to save the state of the FPU status register and data registers on
 * each context switch.  These registers are not saved during interrupt
 * level processing, however. So, as a consequence, floating point
 * operations may NOT be performed in interrupt handlers.
 *
 * The FPU provides an extension register file containing 32 single-
 * precision registers. These can be viewed as:
 *
 * - Sixteen 64-bit double word registers, D0-D15
 * - Thirty-two 32-bit single-word registers, S0-S31
 *   S<2n> maps to the least significant half of D<n>
 *   S<2n+1> maps to the most significant half of D<n>.
 */

#ifdef CONFIG_ARCH_FPU
#  define REG_D0            (ARM_CONTEXT_REGS+0)  /* D0 */
#  define REG_S0            (ARM_CONTEXT_REGS+0)  /* S0 */
#  define REG_S1            (ARM_CONTEXT_REGS+1)  /* S1 */
#  define REG_D1            (ARM_CONTEXT_REGS+2)  /* D1 */
#  define REG_S2            (ARM_CONTEXT_REGS+2)  /* S2 */
#  define REG_S3            (ARM_CONTEXT_REGS+3)  /* S3 */
#  define REG_D2            (ARM_CONTEXT_REGS+4)  /* D2 */
#  define REG_S4            (ARM_CONTEXT_REGS+4)  /* S4 */
#  define REG_S5            (ARM_CONTEXT_REGS+5)  /* S5 */
#  define REG_D3            (ARM_CONTEXT_REGS+6)  /* D3 */
#  define REG_S6            (ARM_CONTEXT_REGS+6)  /* S6 */
#  define REG_S7            (ARM_CONTEXT_REGS+7)  /* S7 */
#  define REG_D4            (ARM_CONTEXT_REGS+8)  /* D4 */
#  define REG_S8            (ARM_CONTEXT_REGS+8)  /* S8 */
#  define REG_S9            (ARM_CONTEXT_REGS+9)  /* S9 */
#  define REG_D5            (ARM_CONTEXT_REGS+10) /* D5 */
#  define REG_S10           (ARM_CONTEXT_REGS+10) /* S10 */
#  define REG_S11           (ARM_CONTEXT_REGS+11) /* S11 */
#  define REG_D6            (ARM_CONTEXT_REGS+12) /* D6 */
#  define REG_S12           (ARM_CONTEXT_REGS+12) /* S12 */
#  define REG_S13           (ARM_CONTEXT_REGS+13) /* S13 */
#  define REG_D7            (ARM_CONTEXT_REGS+14) /* D7 */
#  define REG_S14           (ARM_CONTEXT_REGS+14) /* S14 */
#  define REG_S15           (ARM_CONTEXT_REGS+15) /* S15 */
#  define REG_D8            (ARM_CONTEXT_REGS+16) /* D8 */
#  define REG_S16           (ARM_CONTEXT_REGS+16) /* S16 */
#  define REG_S17           (ARM_CONTEXT_REGS+17) /* S17 */
#  define REG_D9            (ARM_CONTEXT_REGS+18) /* D9 */
#  define REG_S18           (ARM_CONTEXT_REGS+18) /* S18 */
#  define REG_S19           (ARM_CONTEXT_REGS+19) /* S19 */
#  define REG_D10           (ARM_CONTEXT_REGS+20) /* D10 */
#  define REG_S20           (ARM_CONTEXT_REGS+20) /* S20 */
#  define REG_S21           (ARM_CONTEXT_REGS+21) /* S21 */
#  define REG_D11           (ARM_CONTEXT_REGS+22) /* D11 */
#  define REG_S22           (ARM_CONTEXT_REGS+22) /* S22 */
#  define REG_S23           (ARM_CONTEXT_REGS+23) /* S23 */
#  define REG_D12           (ARM_CONTEXT_REGS+24) /* D12 */
#  define REG_S24           (ARM_CONTEXT_REGS+24) /* S24 */
#  define REG_S25           (ARM_CONTEXT_REGS+25) /* S25 */
#  define REG_D13           (ARM_CONTEXT_REGS+26) /* D13 */
#  define REG_S26           (ARM_CONTEXT_REGS+26) /* S26 */
#  define REG_S27           (ARM_CONTEXT_REGS+27) /* S27 */
#  define REG_D14           (ARM_CONTEXT_REGS+28) /* D14 */
#  define REG_S28           (ARM_CONTEXT_REGS+28) /* S28 */
#  define REG_S29           (ARM_CONTEXT_REGS+29) /* S29 */
#  define REG_D15           (ARM_CONTEXT_REGS+30) /* D15 */
#  define REG_S30           (ARM_CONTEXT_REGS+30) /* S30 */
#  define REG_S31           (ARM_CONTEXT_REGS+31) /* S31 */
#  define REG_FPSCR         (ARM_CONTEXT_REGS+32) /* Floating point status and control */
#  define FPU_CONTEXT_REGS  (33)
#else
#  define FPU_CONTEXT_REGS  (0)
#endif

/* The total number of registers saved by software */

#define XCPTCONTEXT_REGS    (ARM_CONTEXT_REGS + FPU_CONTEXT_REGS)
#define XCPTCONTEXT_SIZE    (4 * XCPTCONTEXT_REGS)

/* Friendly register names */

#define REG_A1              REG_R0
#define REG_A2              REG_R1
#define REG_A3              REG_R2
#define REG_A4              REG_R3
#define REG_V1              REG_R4
#define REG_V2              REG_R5
#define REG_V3              REG_R6
#define REG_V4              REG_R7
#define REG_V5              REG_R8
#define REG_V6              REG_R9
#define REG_V7              REG_R10
#define REG_SB              REG_R9
#define REG_SL              REG_R10
#define REG_FP              REG_R11
#define REG_IP              REG_R12
#define REG_SP              REG_R13
#define REG_LR              REG_R14
#define REG_PC              REG_R15

/* The PIC register is usually R10. It can be R9 is stack checking is enabled
 * or if the user changes it with -mpic-register on the GCC command line.
 */

#define REG_PIC             REG_R10

/****************************************************************************
 * Public Types
 ****************************************************************************/

#ifndef __ASSEMBLY__

/* This structure represents the return state from a system call */

#ifdef CONFIG_LIB_SYSCALL
struct xcpt_syscall_s
{
#ifdef CONFIG_BUILD_KERNEL
  uint32_t cpsr;        /* The CPSR value */
#endif
  uint32_t sysreturn;   /* The return PC */
};
#endif

/* This struct defines the way the registers are stored.  We need to save:
 *
 *  1  CPSR
 *  7  Static registers, v1-v7 (aka r4-r10)
 *  1  Frame pointer, fp (aka r11)
 *  1  Stack pointer, sp (aka r13)
 *  1  Return address, lr (aka r14)
 * ---
 * 11  (XCPTCONTEXT_USER_REG)
 *
 * On interrupts, we also need to save:
 *  4  Volatile registers, a1-a4 (aka r0-r3)
 *  1  Scratch Register, ip (aka r12)
 *---
 *  5  (XCPTCONTEXT_IRQ_REGS)
 *
 * For a total of 17 (XCPTCONTEXT_REGS)
 */

#ifndef __ASSEMBLY__
struct xcptcontext
{
  /* The following function pointer is non-zero if there are pending signals
   * to be processed.
   */

#ifndef CONFIG_DISABLE_SIGNALS
  void *sigdeliver; /* Actual type is sig_deliver_t */

  /* These are saved copies of LR and CPSR used during signal processing. */

  uint32_t saved_pc;
  uint32_t saved_cpsr;

# ifdef CONFIG_BUILD_KERNEL
  /* This is the saved address to use when returning from a user-space
   * signal handler.
   */

  uint32_t sigreturn;

# endif
#endif

  /* Register save area */

  uint32_t regs[XCPTCONTEXT_REGS];

  /* Extra fault address register saved for common paging logic.  In the
   * case of the pre-fetch abort, this value is the same as regs[REG_R15];
   * For the case of the data abort, this value is the value of the fault
   * address register (FAR) at the time of data abort exception.
   */

#ifdef CONFIG_PAGING
  uintptr_t far;
#endif

#ifdef CONFIG_LIB_SYSCALL
  /* The following array holds the return address and the exc_return value
   * needed to return from each nested system call.
   */

  uint8_t nsyscalls;
  struct xcpt_syscall_s syscall[CONFIG_SYS_NNEST];
#endif

#ifdef CONFIG_ARCH_ADDRENV
#ifdef CONFIG_ARCH_STACK_DYNAMIC
  /* This array holds the physical address of the level 2 page table used
   * to map the thread's stack memory.  This array will be initially of
   * zeroed and would be back-up up with pages during page fault exception
   * handling to support dynamically sized stacks for each thread.
   */

  FAR uintptr_t *ustack[ARCH_STACK_NSECTS];
#endif

#ifdef CONFIG_ARCH_KERNEL_STACK
  /* In this configuration, all syscalls execute from an internal kernel
   * stack.  Why?  Because when we instantiate and initialize the address
   * environment of the new user process, we will temporarily lose the
   * address environment of the old user process, including its stack
   * contents.  The kernel C logic will crash immediately with no valid
   * stack in place.
   */

  FAR uint32_t *ustkptr;  /* Saved user stack pointer */
  FAR uint32_t *kstack;   /* Allocate base of the (aligned) kernel stack */
#ifndef CONFIG_DISABLE_SIGNALS
  FAR uint32_t *kstkptr;  /* Saved kernel stack pointer */
#endif
#endif
#endif
};
#endif

#endif /* __ASSEMBLY__ */

/****************************************************************************
 * Inline functions
 ****************************************************************************/

#ifndef __ASSEMBLY__

/* Return the current IRQ state */

static inline irqstate_t irqstate(void)
{
  unsigned int cpsr;

  __asm__ __volatile__
    (
      "\tmrs    %0, cpsr\n"
      : "=r" (cpsr)
      :
      : "memory"
    );

  return cpsr;
}

/* Disable IRQs and return the previous IRQ state */

static inline irqstate_t irqsave(void)
{
  unsigned int cpsr;

  __asm__ __volatile__
    (
      "\tmrs    %0, cpsr\n"
      "\tcpsid  i\n"
#if defined(CONFIG_ARMV7A_DECODEFIQ)
      "\tcpsid  f\n"
#endif
      : "=r" (cpsr)
      :
      : "memory"
    );

  return cpsr;
}

/* Enable IRQs and return the previous IRQ state */

static inline irqstate_t irqenable(void)
{
  unsigned int cpsr;

  __asm__ __volatile__
    (
      "\tmrs    %0, cpsr\n"
      "\tcpsie  i\n"
#if defined(CONFIG_ARMV7A_DECODEFIQ)
      "\tcpsie  f\n"
#endif
      : "=r" (cpsr)
      :
      : "memory"
    );

  return cpsr;
}

/* Restore saved IRQ & FIQ state */

static inline void irqrestore(irqstate_t flags)
{
  __asm__ __volatile__
    (
      "msr    cpsr_c, %0"
      :
      : "r" (flags)
      : "memory"
    );
}

#endif /* __ASSEMBLY__ */

/****************************************************************************
 * Public Variables
 ****************************************************************************/

#ifndef __ASSEMBLY__
#ifdef __cplusplus
#define EXTERN extern "C"
extern "C"
{
#else
#define EXTERN extern
#endif

/****************************************************************************
 * Public Function Prototypes
 ****************************************************************************/

#undef EXTERN
#ifdef __cplusplus
}
#endif
#endif

#endif /* __ARCH_ARM_INCLUDE_ARMV7_A_IRQ_H */