/* * Galileo Technology chip interrupt handler * * Modified by RidgeRun, Inc. */ #include #include #include #include #include #include #include #include #include #include #include /* * These are interrupt handlers for the GT on-chip interrupts. They all come * in to the MIPS on a single interrupt line, and have to be handled and ack'ed * differently than other MIPS interrupts. */ #if CURRENTLY_UNUSED struct tq_struct irq_handlers[MAX_CAUSE_REGS][MAX_CAUSE_REG_WIDTH]; void hook_irq_handler(int int_cause, int bit_num, void *isr_ptr); /* * hook_irq_handler * * Hooks IRQ handler to the system. When the system is interrupted * the interrupt service routine is called. * * Inputs : * int_cause - The interrupt cause number. In EVB64120 two parameters * are declared, INT_CAUSE_MAIN and INT_CAUSE_HIGH. * bit_num - Indicates which bit number in the cause register * isr_ptr - Pointer to the interrupt service routine * * Outputs : */ void hook_irq_handler(int int_cause, int bit_num, void *isr_ptr) { irq_handlers[int_cause][bit_num].routine = isr_ptr; } /* * enable_galileo_irq * * Enables the IRQ on Galileo Chip * * Inputs : * int_cause - The interrupt cause number. In EVB64120 two parameters * are declared, INT_CAUSE_MAIN and INT_CAUSE_HIGH. * bit_num - Indicates which bit number in the cause register * * Outputs : * 1 if succesful, 0 if failure */ int enable_galileo_irq(int int_cause, int bit_num) { if (int_cause == INT_CAUSE_MAIN) SET_REG_BITS(CPU_INTERRUPT_MASK_REGISTER, (1 << bit_num)); else if (int_cause == INT_CAUSE_HIGH) SET_REG_BITS(CPU_HIGH_INTERRUPT_MASK_REGISTER, (1 << bit_num)); else return 0; return 1; } /* * disable_galileo_irq * * Disables the IRQ on Galileo Chip * * Inputs : * int_cause - The interrupt cause number. In EVB64120 two parameters * are declared, INT_CAUSE_MAIN and INT_CAUSE_HIGH. * bit_num - Indicates which bit number in the cause register * * Outputs : * 1 if succesful, 0 if failure */ int disable_galileo_irq(int int_cause, int bit_num) { if (int_cause == INT_CAUSE_MAIN) RESET_REG_BITS(CPU_INTERRUPT_MASK_REGISTER, (1 << bit_num)); else if (int_cause == INT_CAUSE_HIGH) RESET_REG_BITS(CPU_HIGH_INTERRUPT_MASK_REGISTER, (1 << bit_num)); else return 0; return 1; } #endif /* UNUSED */ /* * galileo_irq - * * Interrupt handler for interrupts coming from the Galileo chip. * It could be timer interrupt, built in ethernet ports etc... * * Inputs : * * Outputs : * */ static void galileo_irq(int irq, void *dev_id, struct pt_regs *regs) { unsigned int irq_src, int_high_src, irq_src_mask, int_high_src_mask; int handled; unsigned int count; static int counter = 0; GT_READ(GT_INTRCAUSE_OFS, &irq_src); GT_READ(GT_INTRMASK_OFS, &irq_src_mask); GT_READ(GT_HINTRCAUSE_OFS, &int_high_src); GT_READ(GT_HINTRMASK_OFS, &int_high_src_mask); irq_src = irq_src & irq_src_mask; int_high_src = int_high_src & int_high_src_mask; handled = 0; /* Execute all interrupt handlers */ /* Check for timer interrupt */ if (irq_src & 0x00000800) { handled = 1; irq_src &= ~0x00000800; // RESET_REG_BITS (INTERRUPT_CAUSE_REGISTER,BIT8); do_timer(regs); } if (irq_src) { printk(KERN_INFO "Other Galileo interrupt received irq_src %x\n", irq_src); #if CURRENTLY_UNUSED for (count = 0; count < MAX_CAUSE_REG_WIDTH; count++) { if (irq_src & (1 << count)) { if (irq_handlers[INT_CAUSE_MAIN][count]. routine) { queue_task(&irq_handlers [INT_CAUSE_MAIN][count], &tq_immediate); mark_bh(IMMEDIATE_BH); handled = 1; } } } #endif /* UNUSED */ } GT_WRITE(GT_INTRCAUSE_OFS, 0); GT_WRITE(GT_HINTRCAUSE_OFS, 0); #undef GALILEO_I2O #ifdef GALILEO_I2O /* Future I2O support. We currently attach I2O interrupt handlers to the Galileo interrupt (int 4) and handle them in do_IRQ. */ if (isInBoundDoorBellInterruptSet()) { printk(KERN_INFO "I2O doorbell interrupt received.\n"); handled = 1; } if (isInBoundPostQueueInterruptSet()) { printk(KERN_INFO "I2O Queue interrupt received.\n"); handled = 1; } /* This normally would be outside of the ifdef, but since we're handling I2O outside of this handler, this printk shows up every time we get a valid I2O interrupt. So turn this off for now. */ if (handled == 0) { if (counter < 50) { printk("Spurious Galileo interrupt...\n"); counter++; } } #endif } /* * galileo_time_init - * * Initializes timer using galileo's built in timer. * * * Inputs : * irq - number of irq to be used by the timer * * Outpus : * */ #ifdef CONFIG_SYSCLK_100 #define Sys_clock (100 * 1000000) // 100 MHz #endif #ifdef CONFIG_SYSCLK_83 #define Sys_clock (83.333 * 1000000) // 83.333 MHz #endif #ifdef CONFIG_SYSCLK_75 #define Sys_clock (75 * 1000000) // 75 MHz #endif /* * This will ignore the standard MIPS timer interrupt handler that is passed * in as *irq (=irq0 in ../kernel/time.c). We will do our own timer interrupt * handling. */ void galileo_time_init(struct irqaction *irq) { extern irq_desc_t irq_desc[NR_IRQS]; static struct irqaction timer; /* Disable timer first */ GT_WRITE(GT_TC_CONTROL_OFS, 0); /* Load timer value for 100 Hz */ GT_WRITE(GT_TC3_OFS, Sys_clock / 100); /* * Create the IRQ structure entry for the timer. Since we're too early * in the boot process to use the "request_irq()" call, we'll hard-code * the values to the correct interrupt line. */ timer.handler = &galileo_irq; timer.flags = SA_SHIRQ; timer.name = "timer"; timer.dev_id = NULL; timer.next = NULL; timer.mask = 0; irq_desc[TIMER].action = &timer; /* Enable timer ints */ GT_WRITE(GT_TC_CONTROL_OFS, 0xc0); /* clear Cause register first */ GT_WRITE(GT_INTRCAUSE_OFS, 0x0); /* Unmask timer int */ GT_WRITE(GT_INTRMASK_OFS, 0x800); /* Clear High int register */ GT_WRITE(GT_HINTRCAUSE_OFS, 0x0); /* Mask All interrupts at High cause interrupt */ GT_WRITE(GT_HINTRMASK_OFS, 0x0); } void galileo_irq_init(void) { int i, j; #if CURRENTLY_UNUSED /* Reset irq handlers pointers to NULL */ for (i = 0; i < MAX_CAUSE_REGS; i++) { for (j = 0; j < MAX_CAUSE_REG_WIDTH; j++) { irq_handlers[i][j].next = NULL; irq_handlers[i][j].sync = 0; irq_handlers[i][j].routine = NULL; irq_handlers[i][j].data = NULL; } } #endif }