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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [hal/] [arm/] [xscale/] [iop310/] [v2_0/] [src/] [iop310_pci.c] - Rev 379
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//========================================================================== // // iop310_pci.c // // HAL board support code for XScale IOP310 PCI // //========================================================================== //####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): msalter // Contributors: msalter // Date: 2000-10-10 // Purpose: PCI support // Description: Implementations of HAL PCI interfaces // //####DESCRIPTIONEND#### // //========================================================================*/ #include <pkgconf/hal.h> #include <pkgconf/system.h> #include CYGBLD_HAL_PLATFORM_H #include CYGHWR_MEMORY_LAYOUT_H #include <cyg/infra/cyg_type.h> // base types #include <cyg/infra/cyg_trac.h> // tracing macros #include <cyg/infra/cyg_ass.h> // assertion macros #include <cyg/hal/hal_io.h> // IO macros #include <cyg/hal/hal_if.h> // calling interface API #include <cyg/hal/hal_arch.h> // Register state info #include <cyg/hal/hal_diag.h> #include <cyg/hal/hal_intr.h> // Interrupt names #include <cyg/hal/hal_cache.h> #include <cyg/hal/hal_iop310.h> // Hardware definitions #include <cyg/io/pci_hw.h> #include <cyg/io/pci.h> static cyg_uint8 pbus_nr; static cyg_uint8 sbus_nr; static cyg_uint8 subbus_nr; void cyg_hal_plf_pci_init(void) { cyg_uint32 limit_reg; cyg_uint8 next_bus; // ************ bridge registers ******************* if (iop310_is_host()) { // set the primary inbound ATU base address to the start of DRAM *PIABAR_REG = MEMBASE_DRAM & 0xFFFFF000; // ********* Set Primary Outbound Windows ********* // Note: The primary outbound ATU memory window value register // and i/o window value registers are defaulted to 0 // set the primary outbound windows to directly map Local - PCI // requests // outbound memory window *POMWVR_REG = PRIMARY_MEM_BASE; // outbound DAC Window *PODWVR_REG = PRIMARY_DAC_BASE; // outbound I/O window *POIOWVR_REG = PRIMARY_IO_BASE; // set the bridge command register *PCR_REG = (CYG_PCI_CFG_COMMAND_SERR | \ CYG_PCI_CFG_COMMAND_PARITY | \ CYG_PCI_CFG_COMMAND_MASTER | \ CYG_PCI_CFG_COMMAND_MEMORY); // set the subordinate bus number to 0xFF *SUBBNR_REG = 0xFF; // set the secondary bus number to 1 *SBNR_REG = SECONDARY_BUS_NUM; *BCR_REG = 0x0823; // set the primary bus number to 0 *PBNR_REG = PRIMARY_BUS_NUM; // allow primary ATU to act as a bus master, respond to PCI // memory accesses, assert P_SERR#, and enable parity checking *PATUCMD_REG = (CYG_PCI_CFG_COMMAND_SERR | \ CYG_PCI_CFG_COMMAND_PARITY | \ CYG_PCI_CFG_COMMAND_MASTER | \ CYG_PCI_CFG_COMMAND_MEMORY); } else { #ifdef CYGSEM_HAL_ARM_IOP310_CLEAR_PCI_RETRY // Wait for PC BIOS to initialize bus number int i; for (i = 0; i < 15000; i++) { if (*PCR_REG & CYG_PCI_CFG_COMMAND_MEMORY) break; hal_delay_us(1000); // 1msec } for (i = 0; i < 15000; i++) { if (*SBNR_REG != 0) break; hal_delay_us(1000); // 1msec } #endif if (*SBNR_REG == 0) *SBNR_REG = SECONDARY_BUS_NUM; if (*SUBBNR_REG == 0) *SUBBNR_REG = 0xFF; if (*BCR_REG == 0) *BCR_REG = 0x0823; if (*PCR_REG == 0) *PCR_REG = (CYG_PCI_CFG_COMMAND_SERR | \ CYG_PCI_CFG_COMMAND_PARITY | \ CYG_PCI_CFG_COMMAND_MASTER | \ CYG_PCI_CFG_COMMAND_MEMORY); if (*PATUCMD_REG == 0) *PATUCMD_REG = (CYG_PCI_CFG_COMMAND_SERR | \ CYG_PCI_CFG_COMMAND_PARITY | \ CYG_PCI_CFG_COMMAND_MASTER | \ CYG_PCI_CFG_COMMAND_MEMORY); } // Initialize Secondary PCI bus (bus 1) *BCR_REG |= 0x40; // reset secondary bus hal_delay_us(10 * 1000); // 10ms enough?? *BCR_REG &= ~0x40; // release reset // ******** Secondary Inbound ATU *********** // set secondary inbound ATU translate value register to point to base // of local DRAM *SIATVR_REG = MEMBASE_DRAM & 0xFFFFFFFC; // set secondary inbound ATU base address to start of DRAM *SIABAR_REG = MEMBASE_DRAM & 0xFFFFF000; // always allow secondary pci access to all memory (even with A0 step) limit_reg = (0xFFFFFFFF - (hal_dram_size - 1)) & 0xFFFFFFF0; *SIALR_REG = limit_reg; // ********** Set Secondary Outbound Windows *********** // Note: The secondary outbound ATU memory window value register // and i/o window value registers are defaulted to 0 // set the secondary outbound window to directly map Local - PCI requests // outbound memory window *SOMWVR_REG = SECONDARY_MEM_BASE; // outbound DAC Window *SODWVR_REG = SECONDARY_DAC_BASE; // outbound I/O window *SOIOWVR_REG = SECONDARY_IO_BASE; // allow secondary ATU to act as a bus master, respond to PCI memory // accesses, and assert S_SERR# *SATUCMD_REG = (CYG_PCI_CFG_COMMAND_SERR | \ CYG_PCI_CFG_COMMAND_PARITY | \ CYG_PCI_CFG_COMMAND_MASTER | \ CYG_PCI_CFG_COMMAND_MEMORY); // enable primary and secondary outbound ATUs, BIST, and primary bus // direct addressing *ATUCR_REG = 0x00000006; pbus_nr = *PBNR_REG; sbus_nr = *SBNR_REG; // Now initialize the PCI busses. // Next assignable bus number. Yavapai primary bus is fixed as // bus zero and yavapai secondary is fixed as bus 1. next_bus = sbus_nr + 1; // If we are the host on the Primary bus, then configure it. if (iop310_is_host()) { // Initialize these so all config cycles first go out over // the Primary side pbus_nr = 0; sbus_nr = 0xff; // set the primary bus number to 0 *PBNR_REG = 0; next_bus = 1; // Initialize Primary PCI bus (bus 0) cyg_pci_set_memory_base(PRIMARY_MEM_BASE); cyg_pci_set_io_base(PRIMARY_IO_BASE); cyg_pci_configure_bus(0, &next_bus); // set the secondary bus number to next available number *SBNR_REG = sbus_nr = next_bus; pbus_nr = *PBNR_REG; next_bus = sbus_nr + 1; } // Initialize Secondary PCI bus (bus 1) cyg_pci_set_memory_base(SECONDARY_MEM_BASE); cyg_pci_set_io_base(SECONDARY_IO_BASE); subbus_nr = 0xFF; cyg_pci_configure_bus(sbus_nr, &next_bus); *SUBBNR_REG = subbus_nr = next_bus - 1; if (0){ cyg_uint8 devfn; cyg_pci_device_id devid; cyg_pci_device dev_info; diag_printf("pbus[%d] sbus[%d] subbus[%d]\n", pbus_nr, sbus_nr, subbus_nr); devid = CYG_PCI_DEV_MAKE_ID(sbus_nr, 0) | CYG_PCI_NULL_DEVFN; while (cyg_pci_find_next(devid, &devid)) { devfn = CYG_PCI_DEV_GET_DEVFN(devid); cyg_pci_get_device_info(devid, &dev_info); diag_printf("\n"); diag_printf(" Bus: %d\n", CYG_PCI_DEV_GET_BUS(devid)); diag_printf(" PCI Device: %d\n", CYG_PCI_DEV_GET_DEV(devfn)); diag_printf(" PCI Func : %d\n", CYG_PCI_DEV_GET_FN(devfn)); diag_printf(" Vendor Id : 0x%08X\n", dev_info.vendor); diag_printf(" Device Id : 0x%08X\n", dev_info.device); } } } // Use "naked" attribute to suppress C prologue/epilogue static void __attribute__ ((naked)) __pci_abort_handler(void) { asm ( "subs pc, lr, #4\n" ); } static cyg_uint32 orig_abort_vec; static inline cyg_uint32 *pci_config_setup(cyg_uint32 bus, cyg_uint32 devfn, cyg_uint32 offset) { volatile cyg_uint32 *pdata, *paddr; cyg_uint32 dev = CYG_PCI_DEV_GET_DEV(devfn); cyg_uint32 fn = CYG_PCI_DEV_GET_FN(devfn); if (bus < sbus_nr || bus > subbus_nr) { paddr = (volatile cyg_uint32 *)POCCAR_ADDR; pdata = (volatile cyg_uint32 *)POCCDR_ADDR; } else { paddr = (volatile cyg_uint32 *)SOCCAR_ADDR; pdata = (volatile cyg_uint32 *)SOCCDR_ADDR; } /* Offsets must be dword-aligned */ offset &= ~3; /* Primary or secondary bus use type 0 config */ /* all others use type 1 config */ if (bus == pbus_nr || bus == sbus_nr) *paddr = ( (1 << (dev + 16)) | (fn << 8) | offset | 0 ); else *paddr = ( (bus << 16) | (dev << 11) | (fn << 8) | offset | 1 ); orig_abort_vec = ((volatile cyg_uint32 *)0x20)[4]; ((volatile unsigned *)0x20)[4] = (unsigned)__pci_abort_handler; HAL_ICACHE_SYNC(); return pdata; } static inline int pci_config_cleanup(cyg_uint32 bus) { cyg_uint32 status = 0, err = 0; if (bus < sbus_nr || bus > subbus_nr) { status = *PATUSR_REG; if ((status & 0xF900) != 0) { err = 1; *PATUSR_REG = status & 0xF980; } status = *PSR_REG; if ((status & 0xF900) != 0) { err = 1; *PSR_REG = status & 0xF980; } status = *PATUISR_REG; if ((status & 0x79F) != 0) { err = 1; *PATUISR_REG = status & 0x79f; } status = *PBISR_REG; if ((status & 0x3F) != 0) { err = 1; *PBISR_REG = status & 0x3F; } } else { status = *SATUSR_REG; if ((status & 0xF900) != 0) { err = 1; *SATUSR_REG = status & 0xF900; } status = *SSR_REG; if ((status & 0xF900) != 0) { err = 1; *SSR_REG = status & 0xF980; } status = *SATUISR_REG; if ((status & 0x69F) != 0) { err = 1; *SATUISR_REG = status & 0x69F; } } ((volatile unsigned *)0x20)[4] = orig_abort_vec; HAL_ICACHE_SYNC(); return err; } cyg_uint32 cyg_hal_plf_pci_cfg_read_dword (cyg_uint32 bus, cyg_uint32 devfn, cyg_uint32 offset) { cyg_uint32 *pdata, config_data; pdata = pci_config_setup(bus, devfn, offset); config_data = *pdata; if (pci_config_cleanup(bus)) return 0xffffffff; else return config_data; } void cyg_hal_plf_pci_cfg_write_dword (cyg_uint32 bus, cyg_uint32 devfn, cyg_uint32 offset, cyg_uint32 data) { cyg_uint32 *pdata; pdata = pci_config_setup(bus, devfn, offset); *pdata = data; pci_config_cleanup(bus); } cyg_uint16 cyg_hal_plf_pci_cfg_read_word (cyg_uint32 bus, cyg_uint32 devfn, cyg_uint32 offset) { cyg_uint32 *pdata; cyg_uint16 config_data; pdata = pci_config_setup(bus, devfn, offset); config_data = (cyg_uint16)(((*pdata) >> ((offset % 0x4) * 8)) & 0xffff); if (pci_config_cleanup(bus)) return 0xffff; else return config_data; } void cyg_hal_plf_pci_cfg_write_word (cyg_uint32 bus, cyg_uint32 devfn, cyg_uint32 offset, cyg_uint16 data) { cyg_uint32 *pdata, mask, temp; pdata = pci_config_setup(bus, devfn, offset); mask = ~(0x0000ffff << ((offset % 0x4) * 8)); temp = (cyg_uint32)(((cyg_uint32)data) << ((offset % 0x4) * 8)); *pdata = (*pdata & mask) | temp; pci_config_cleanup(bus); } cyg_uint8 cyg_hal_plf_pci_cfg_read_byte (cyg_uint32 bus, cyg_uint32 devfn, cyg_uint32 offset) { cyg_uint32 *pdata; cyg_uint8 config_data; pdata = pci_config_setup(bus, devfn, offset); config_data = (cyg_uint8)(((*pdata) >> ((offset % 0x4) * 8)) & 0xff); if (pci_config_cleanup(bus)) return 0xff; else return config_data; } void cyg_hal_plf_pci_cfg_write_byte (cyg_uint32 bus, cyg_uint32 devfn, cyg_uint32 offset, cyg_uint8 data) { cyg_uint32 *pdata, mask, temp; pdata = pci_config_setup(bus, devfn, offset); mask = ~(0x000000ff << ((offset % 0x4) * 8)); temp = (cyg_uint32)(((cyg_uint32)data) << ((offset % 0x4) * 8)); *pdata = (*pdata & mask) | temp; pci_config_cleanup(bus); }
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