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[/] [or1k/] [trunk/] [ecos-2.0/] [packages/] [kernel/] [v2_0/] [include/] [intr.hxx] - Rev 1254
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#ifndef CYGONCE_KERNEL_INTR_HXX
#define CYGONCE_KERNEL_INTR_HXX
//==========================================================================
//
// intr.hxx
//
// Interrupt class declaration(s)
//
//==========================================================================
//####ECOSGPLCOPYRIGHTBEGIN####
// -------------------------------------------
// This file is part of eCos, the Embedded Configurable Operating System.
// Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc.
//
// eCos is free software; you can redistribute it and/or modify it under
// the terms of the GNU General Public License as published by the Free
// Software Foundation; either version 2 or (at your option) any later version.
//
// eCos is distributed in the hope that it will be useful, but WITHOUT ANY
// WARRANTY; without even the implied warranty of MERCHANTABILITY or
// FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
// for more details.
//
// You should have received a copy of the GNU General Public License along
// with eCos; if not, write to the Free Software Foundation, Inc.,
// 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.
//
// As a special exception, if other files instantiate templates or use macros
// or inline functions from this file, or you compile this file and link it
// with other works to produce a work based on this file, this file does not
// by itself cause the resulting work to be covered by the GNU General Public
// License. However the source code for this file must still be made available
// in accordance with section (3) of the GNU General Public License.
//
// This exception does not invalidate any other reasons why a work based on
// this file might be covered by the GNU General Public License.
//
// Alternative licenses for eCos may be arranged by contacting Red Hat, Inc.
// at http://sources.redhat.com/ecos/ecos-license/
// -------------------------------------------
//####ECOSGPLCOPYRIGHTEND####
//==========================================================================
//#####DESCRIPTIONBEGIN####
//
// Author(s): nickg
// Contributors: nickg
// Date: 1997-09-09
// Purpose: Define Interrupt class interfaces
// Description: The classes defined here provide the APIs for handling
// interrupts.
// Usage: #include "intr.hxx"
//
//
//####DESCRIPTIONEND####
//
//==========================================================================
#include <cyg/kernel/ktypes.h>
#include <cyg/kernel/smp.hxx>
// -------------------------------------------------------------------------
// Default definitions
// Some HALs define the ISR table to be a different size to the number
// of ISR vectors. These HALs will define CYGNUM_HAL_ISR_TABLE_SIZE. All
// other HALs will have the table size equal to the number of vectors.
#ifndef CYGNUM_HAL_ISR_TABLE_SIZE
# define CYGNUM_HAL_ISR_TABLE_SIZE CYGNUM_HAL_ISR_COUNT
#endif
// -------------------------------------------------------------------------
// Function prototype typedefs
// VSR = Vector Service Routine. This is the code attached directly to an
// interrupt vector. It is very architecture/platform specific and usually
// must be written in assembler.
typedef void cyg_VSR();
// ISR = Interrupt Service Routine. This is called from the default
// VSR in response to an interrupt. It may access shared data but may
// not call kernel routines. The return value may be
// Cyg_Interrupt::HANDLED and/or Cyg_Interrupt::CALL_DSR.
typedef cyg_uint32 cyg_ISR(cyg_vector vector, CYG_ADDRWORD data);
// DSR = Deferred Service Routine. This is called if the ISR returns
// the Cyg_Interrupt::CALL_DSR bit. It is called at a "safe" point in
// the kernel where it may make calls on kernel routines. The count
// argument indicates how many times the ISR has asked for the DSR to
// be posted since the last time the DSR ran.
typedef void cyg_DSR(cyg_vector vector, cyg_ucount32 count, CYG_ADDRWORD data);
// -------------------------------------------------------------------------
// Include HAL definitions
class Cyg_Interrupt;
#include <cyg/hal/hal_arch.h>
#include <cyg/hal/hal_intr.h>
#ifndef HAL_INTERRUPT_STACK_CALL_PENDING_DSRS
#define HAL_INTERRUPT_STACK_CALL_PENDING_DSRS() \
Cyg_Interrupt::call_pending_DSRs_inner()
#endif
externC void interrupt_end(
cyg_uint32 isr_ret,
Cyg_Interrupt *intr,
HAL_SavedRegisters *ctx
);
externC void cyg_interrupt_post_dsr( CYG_ADDRWORD intr_obj );
externC void cyg_interrupt_call_pending_DSRs( void );
// -------------------------------------------------------------------------
// Interrupt class. This both represents each interrupt and provides a static
// interface for controlling the interrupt hardware.
class Cyg_Interrupt
{
friend class Cyg_Scheduler;
friend void interrupt_end( cyg_uint32,
Cyg_Interrupt *,
HAL_SavedRegisters *);
friend void cyg_interrupt_post_dsr( CYG_ADDRWORD intr_obj );
friend void cyg_interrupt_call_pending_DSRs( void );
cyg_vector vector; // Interrupt vector
cyg_priority priority; // Queuing priority
cyg_ISR *isr; // Pointer to ISR
cyg_DSR *dsr; // Pointer to DSR
CYG_ADDRWORD data; // Data pointer
// DSR handling interface called by the scheduler
// Check for pending DSRs
static cyg_bool DSRs_pending();
// Call any pending DSRs
static void call_pending_DSRs();
static void call_pending_DSRs_inner();
// DSR handling interface called by the scheduler and HAL
// interrupt arbiters.
void post_dsr(); // Post the DSR for this interrupt
// Data structures for handling DSR calls. We implement two DSR
// handling mechanisms, a list based one and a table based
// one. The list based mechanism is safe with respect to temporary
// overloads and will not run out of resource. However it requires
// extra data per interrupt object, and interrupts must be turned
// off briefly when delivering the DSR. The table based mechanism
// does not need unnecessary interrupt switching, but may be prone
// to overflow on overload. However, since a correctly programmed
// real time application should not experience such a condition,
// the table based mechanism is more efficient for real use. The
// list based mechainsm is enabled by default since it is safer to
// use during development.
#ifdef CYGIMP_KERNEL_INTERRUPTS_DSRS_TABLE
static Cyg_Interrupt *dsr_table[CYGNUM_KERNEL_CPU_MAX]
[CYGNUM_KERNEL_INTERRUPTS_DSRS_TABLE_SIZE]
CYGBLD_ANNOTATE_VARIABLE_INTR;
static cyg_ucount32 dsr_table_head[CYGNUM_KERNEL_CPU_MAX]
CYGBLD_ANNOTATE_VARIABLE_INTR;
static volatile cyg_ucount32 dsr_table_tail[CYGNUM_KERNEL_CPU_MAX]
CYGBLD_ANNOTATE_VARIABLE_INTR;
#endif
#ifdef CYGIMP_KERNEL_INTERRUPTS_DSRS_LIST
// Number of DSR posts made
volatile cyg_ucount32 dsr_count CYGBLD_ANNOTATE_VARIABLE_INTR;
// next DSR in list
Cyg_Interrupt* volatile next_dsr CYGBLD_ANNOTATE_VARIABLE_INTR;
// static list of pending DSRs
static Cyg_Interrupt* volatile dsr_list[CYGNUM_KERNEL_CPU_MAX]
CYGBLD_ANNOTATE_VARIABLE_INTR;
#endif
#ifdef CYGIMP_KERNEL_INTERRUPTS_CHAIN
// The default mechanism for handling interrupts is to attach just
// one Interrupt object to each vector. In some cases, and on some
// hardware, this is not possible, and each vector must carry a chain
// of interrupts.
Cyg_Interrupt *next; // Next Interrupt in list
// Chaining ISR inserted in HAL vector
static cyg_uint32 chain_isr(cyg_vector vector, CYG_ADDRWORD data);
// Table of interrupt chains
static Cyg_Interrupt *chain_list[CYGNUM_HAL_ISR_TABLE_SIZE];
#endif
// Interrupt disable data. Interrupt disable can be nested. On
// each CPU this is controlled by disable_counter[cpu]. When the
// counter is first incremented from zero to one, the
// interrupt_disable_spinlock is claimed using spin_intsave(), the
// original interrupt enable state being saved in
// interrupt_disable_state[cpu]. When the counter is decremented
// back to zero the spinlock is cleared using clear_intsave().
// The spinlock is necessary in SMP systems since a thread
// accessing data shared with an ISR may be scheduled on a
// different CPU to the one that handles the interrupt. So, merely
// blocking local interrupts would be ineffective. SMP aware
// device drivers should either use their own spinlocks to protect
// data, or use the API supported by this class, via
// cyg_drv_isr_lock()/_unlock(). Note that it now becomes
// essential that ISRs do this if they are to be SMP-compatible.
// In a single CPU system, this mechanism reduces to just
// disabling/enabling interrupts.
// Disable level counter. This counts the number of times
// interrupts have been disabled.
static volatile cyg_int32 disable_counter[CYGNUM_KERNEL_CPU_MAX]
CYGBLD_ANNOTATE_VARIABLE_INTR;
// Interrupt disable spinlock. This is claimed by any CPU that has
// disabled interrupts via the Cyg_Interrupt API.
static Cyg_SpinLock interrupt_disable_spinlock CYGBLD_ANNOTATE_VARIABLE_INTR;
// Saved interrupt state. When each CPU first disables interrupts
// the original state of the interrupts are saved here to be
// restored later.
static CYG_INTERRUPT_STATE interrupt_disable_state[CYGNUM_KERNEL_CPU_MAX]
CYGBLD_ANNOTATE_VARIABLE_INTR;
public:
Cyg_Interrupt // Initialize interrupt
(
cyg_vector vector, // Vector to attach to
cyg_priority priority, // Queue priority
CYG_ADDRWORD data, // Data pointer
cyg_ISR *isr, // Interrupt Service Routine
cyg_DSR *dsr // Deferred Service Routine
);
~Cyg_Interrupt();
// ISR return values
enum {
HANDLED = 1, // Interrupt was handled
CALL_DSR = 2 // Schedule DSR
};
// Interrupt management
void attach(); // Attach to vector
void detach(); // Detach from vector
// Static Interrupt management functions
// Get the current service routine
static void get_vsr(cyg_vector vector, cyg_VSR **vsr);
// Install a vector service routine
static void set_vsr(
cyg_vector vector, // hardware vector to replace
cyg_VSR *vsr, // my new service routine
cyg_VSR **old = NULL // pointer to old vsr, if required
);
// Static interrupt masking functions
// Disable interrupts at the CPU
static void disable_interrupts();
// Re-enable CPU interrupts
static void enable_interrupts();
// Are interrupts enabled at the CPU?
static inline cyg_bool interrupts_enabled()
{
return (0 == disable_counter[CYG_KERNEL_CPU_THIS()]);
}
// Get the vector for the following calls
inline cyg_vector get_vector()
{
return vector;
}
// Static PIC control functions
// Mask a specific interrupt in a PIC
static void mask_interrupt(cyg_vector vector);
// The same but not interrupt safe
static void mask_interrupt_intunsafe(cyg_vector vector);
// Clear PIC mask
static void unmask_interrupt(cyg_vector vector);
// The same but not interrupt safe
static void unmask_interrupt_intunsafe(cyg_vector vector);
// Acknowledge interrupt at PIC
static void acknowledge_interrupt(cyg_vector vector);
// Change interrupt detection at PIC
static void configure_interrupt(
cyg_vector vector, // vector to control
cyg_bool level, // level or edge triggered
cyg_bool up // hi/lo level, rising/falling edge
);
#ifdef CYGPKG_KERNEL_SMP_SUPPORT
// SMP support for associating an interrupt with a specific CPU.
static void set_cpu( cyg_vector, HAL_SMP_CPU_TYPE cpu );
static HAL_SMP_CPU_TYPE get_cpu( cyg_vector );
#endif
};
#ifdef CYGIMP_KERNEL_INTERRUPTS_DSRS
// -------------------------------------------------------------------------
// Check for pending DSRs
inline cyg_bool Cyg_Interrupt::DSRs_pending()
{
HAL_SMP_CPU_TYPE cpu = CYG_KERNEL_CPU_THIS();
#ifdef CYGIMP_KERNEL_INTERRUPTS_DSRS_TABLE
return dsr_table_head[cpu] != dsr_table_tail[cpu];
#endif
#ifdef CYGIMP_KERNEL_INTERRUPTS_DSRS_LIST
return dsr_list[cpu] != NULL;
#endif
};
#endif // CYGIMP_KERNEL_INTERRUPTS_DSRS
// -------------------------------------------------------------------------
#endif // ifndef CYGONCE_KERNEL_INTR_HXX
// EOF intr.hxx
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