/* * arch/mips/ddb5476/nile4.c -- * low-level PIC code for NEC Vrc-5476 (Nile 4) * * Copyright (C) 2000 Geert Uytterhoeven * Sony Software Development Center Europe (SDCE), Brussels * * Copyright 2001 MontaVista Software Inc. * Author: jsun@mvista.com or jsun@junsun.net * */ #include #include #include #include #include #include static int irq_base; /* * Interrupt Programming */ void nile4_map_irq(int nile4_irq, int cpu_irq) { u32 offset, t; offset = DDB_INTCTRL; if (nile4_irq >= 8) { offset += 4; nile4_irq -= 8; } t = ddb_in32(offset); t &= ~(7 << (nile4_irq * 4)); t |= cpu_irq << (nile4_irq * 4); ddb_out32(offset, t); } void nile4_map_irq_all(int cpu_irq) { u32 all, t; all = cpu_irq; all |= all << 4; all |= all << 8; all |= all << 16; t = ddb_in32(DDB_INTCTRL); t &= 0x88888888; t |= all; ddb_out32(DDB_INTCTRL, t); t = ddb_in32(DDB_INTCTRL + 4); t &= 0x88888888; t |= all; ddb_out32(DDB_INTCTRL + 4, t); } void nile4_enable_irq(unsigned int nile4_irq) { u32 offset, t; nile4_irq-=irq_base; ddb5074_led_hex(8); offset = DDB_INTCTRL; if (nile4_irq >= 8) { offset += 4; nile4_irq -= 8; } ddb5074_led_hex(9); t = ddb_in32(offset); ddb5074_led_hex(0xa); t |= 8 << (nile4_irq * 4); ddb_out32(offset, t); ddb5074_led_hex(0xb); } void nile4_disable_irq(unsigned int nile4_irq) { u32 offset, t; nile4_irq-=irq_base; offset = DDB_INTCTRL; if (nile4_irq >= 8) { offset += 4; nile4_irq -= 8; } t = ddb_in32(offset); t &= ~(8 << (nile4_irq * 4)); ddb_out32(offset, t); } void nile4_disable_irq_all(void) { ddb_out32(DDB_INTCTRL, 0); ddb_out32(DDB_INTCTRL + 4, 0); } u16 nile4_get_irq_stat(int cpu_irq) { return ddb_in16(DDB_INTSTAT0 + cpu_irq * 2); } void nile4_enable_irq_output(int cpu_irq) { u32 t; t = ddb_in32(DDB_INTSTAT1 + 4); t |= 1 << (16 + cpu_irq); ddb_out32(DDB_INTSTAT1, t); } void nile4_disable_irq_output(int cpu_irq) { u32 t; t = ddb_in32(DDB_INTSTAT1 + 4); t &= ~(1 << (16 + cpu_irq)); ddb_out32(DDB_INTSTAT1, t); } void nile4_set_pci_irq_polarity(int pci_irq, int high) { u32 t; t = ddb_in32(DDB_INTPPES); if (high) t &= ~(1 << (pci_irq * 2)); else t |= 1 << (pci_irq * 2); ddb_out32(DDB_INTPPES, t); } void nile4_set_pci_irq_level_or_edge(int pci_irq, int level) { u32 t; t = ddb_in32(DDB_INTPPES); if (level) t |= 2 << (pci_irq * 2); else t &= ~(2 << (pci_irq * 2)); ddb_out32(DDB_INTPPES, t); } void nile4_clear_irq(int nile4_irq) { nile4_irq-=irq_base; ddb_out32(DDB_INTCLR, 1 << nile4_irq); } void nile4_clear_irq_mask(u32 mask) { ddb_out32(DDB_INTCLR, mask); } u8 nile4_i8259_iack(void) { u8 irq; u32 reg; /* Set window 0 for interrupt acknowledge */ reg = ddb_in32(DDB_PCIINIT0); ddb_set_pmr(DDB_PCIINIT0, DDB_PCICMD_IACK, 0, DDB_PCI_ACCESS_32); irq = *(volatile u8 *) KSEG1ADDR(DDB_PCI_IACK_BASE); /* restore window 0 for PCI I/O space */ // ddb_set_pmr(DDB_PCIINIT0, DDB_PCICMD_IO, 0, DDB_PCI_ACCESS_32); ddb_out32(DDB_PCIINIT0, reg); /* i8269.c set the base vector to be 0x0 */ return irq ; } static unsigned int nile4_irq_startup(unsigned int irq) { nile4_enable_irq(irq); return 0; } static void nile4_ack_irq(unsigned int irq) { ddb5074_led_hex(4); nile4_clear_irq(irq); ddb5074_led_hex(2); nile4_disable_irq(irq); ddb5074_led_hex(0); } static void nile4_irq_end(unsigned int irq) { ddb5074_led_hex(3); if(!(irq_desc[irq].status & (IRQ_DISABLED | IRQ_INPROGRESS))) { ddb5074_led_hex(5); nile4_enable_irq(irq); ddb5074_led_hex(7); } ddb5074_led_hex(1); } #define nile4_irq_shutdown nile4_disable_irq static hw_irq_controller nile4_irq_controller = { "nile4", nile4_irq_startup, nile4_irq_shutdown, nile4_enable_irq, nile4_disable_irq, nile4_ack_irq, nile4_irq_end, NULL }; void nile4_irq_setup(u32 base) { int i; extern irq_desc_t irq_desc[]; irq_base=base; /* Map all interrupts to CPU int #0 */ nile4_map_irq_all(0); /* PCI INTA#-E# must be level triggered */ nile4_set_pci_irq_level_or_edge(0, 1); nile4_set_pci_irq_level_or_edge(1, 1); nile4_set_pci_irq_level_or_edge(2, 1); nile4_set_pci_irq_level_or_edge(3, 1); nile4_set_pci_irq_level_or_edge(4, 1); /* PCI INTA#-D# must be active low, INTE# must be active high */ nile4_set_pci_irq_polarity(0, 0); nile4_set_pci_irq_polarity(1, 0); nile4_set_pci_irq_polarity(2, 0); nile4_set_pci_irq_polarity(3, 0); nile4_set_pci_irq_polarity(4, 1); for (i = 0; i < 16; i++) { nile4_clear_irq(i); nile4_disable_irq(i); } /* Enable CPU int #0 */ nile4_enable_irq_output(0); for (i= base; i< base + NUM_NILE4_INTERRUPTS; i++) { irq_desc[i].status = IRQ_DISABLED; irq_desc[i].action = NULL; irq_desc[i].depth = 1; irq_desc[i].handler = &nile4_irq_controller; } } #if defined(CONFIG_RUNTIME_DEBUG) void nile4_dump_irq_status(void) { printk(KERN_DEBUG " CPUSTAT = %p:%p\n", (void *) ddb_in32(DDB_CPUSTAT + 4), (void *) ddb_in32(DDB_CPUSTAT)); printk(KERN_DEBUG " INTCTRL = %p:%p\n", (void *) ddb_in32(DDB_INTCTRL + 4), (void *) ddb_in32(DDB_INTCTRL)); printk(KERN_DEBUG "INTSTAT0 = %p:%p\n", (void *) ddb_in32(DDB_INTSTAT0 + 4), (void *) ddb_in32(DDB_INTSTAT0)); printk(KERN_DEBUG "INTSTAT1 = %p:%p\n", (void *) ddb_in32(DDB_INTSTAT1 + 4), (void *) ddb_in32(DDB_INTSTAT1)); printk(KERN_DEBUG "INTCLR = %p:%p\n", (void *) ddb_in32(DDB_INTCLR + 4), (void *) ddb_in32(DDB_INTCLR)); printk(KERN_DEBUG "INTPPES = %p:%p\n", (void *) ddb_in32(DDB_INTPPES + 4), (void *) ddb_in32(DDB_INTPPES)); } #endif