/* $Id$ */
/* remap the zero-based PCI IO spaces of both hoses to a single
* address space
*
* This must be called AFTER to BSP_pci_initialize()
*/
/*
* Authorship
* ----------
* This software ('beatnik' RTEMS BSP for MVME6100 and MVME5500) was
* created by Till Straumann <strauman@slac.stanford.edu>, 2005-2007,
* Stanford Linear Accelerator Center, Stanford University.
*
* Acknowledgement of sponsorship
* ------------------------------
* The 'beatnik' BSP was produced by
* the Stanford Linear Accelerator Center, Stanford University,
* under Contract DE-AC03-76SFO0515 with the Department of Energy.
*
* Government disclaimer of liability
* ----------------------------------
* Neither the United States nor the United States Department of Energy,
* nor any of their employees, makes any warranty, express or implied, or
* assumes any legal liability or responsibility for the accuracy,
* completeness, or usefulness of any data, apparatus, product, or process
* disclosed, or represents that its use would not infringe privately owned
* rights.
*
* Stanford disclaimer of liability
* --------------------------------
* Stanford University makes no representations or warranties, express or
* implied, nor assumes any liability for the use of this software.
*
* Stanford disclaimer of copyright
* --------------------------------
* Stanford University, owner of the copyright, hereby disclaims its
* copyright and all other rights in this software. Hence, anyone may
* freely use it for any purpose without restriction.
*
* Maintenance of notices
* ----------------------
* In the interest of clarity regarding the origin and status of this
* SLAC software, this and all the preceding Stanford University notices
* are to remain affixed to any copy or derivative of this software made
* or distributed by the recipient and are to be affixed to any copy of
* software made or distributed by the recipient that contains a copy or
* derivative of this software.
*
* ------------------ SLAC Software Notices, Set 4 OTT.002a, 2004 FEB 03
*/
#include <rtems.h>
#include <bsp.h>
#include <libcpu/io.h>
#include <bsp/pci.h>
#include <bsp/irq.h>
#include <rtems/bspIo.h>
#include <bsp/gtreg.h>
#include "pci_io_remap.h"
static int
fixup_irq_line(int bus, int slot, int fun, void *uarg)
{
unsigned char line;
pci_read_config_byte( bus, slot, fun, PCI_INTERRUPT_LINE, &line);
if ( line < BSP_IRQ_GPP_0 ) {
pci_write_config_byte( bus, slot, fun, PCI_INTERRUPT_LINE, line + BSP_IRQ_GPP_0 );
}
return 0;
}
void BSP_motload_pci_fixup(void)
{
uint32_t b0,b1,r0,r1,lim,dis;
/* MotLoad on the mvme5500 and mvme6100 configures the PCI
* busses nicely, i.e., the values read from the memory address
* space BARs by means of PCI config cycles directly reflect the
* CPU memory map. Thus, the presence of two hoses is already hidden.
*
* Unfortunately, all PCI I/O addresses are 'zero-based' i.e.,
* a hose-specific base address would have to be added to
* the values read from config space.
*
* We fix this here so I/O BARs also reflect the CPU memory map.
*
* Furthermore, the mvme5500 uses
* f000.0000
* ..f07f.ffff for PCI-0 / hose0
*
* and
*
* f080.0000
* ..f0ff.0000 for PCI-1 / hose 0
*
* whereas the mvme6100 does it the other way round...
*/
b0 = in_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI0_IO_Low_Decode) );
b1 = in_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI1_IO_Low_Decode) );
r0 = in_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI0_IO_Remap) );
r1 = in_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI1_IO_Remap) );
switch ( BSP_getDiscoveryVersion(0) ) {
case MV_64360:
/* In case of the MV64360 the 'limit' is actually a 'size'!
* Disable by setting special bits in the 'BAR disable reg'.
*/
dis = in_le32( (volatile unsigned*)(BSP_MV64x60_BASE + MV_64360_BASE_ADDR_DISBL) );
/* disable PCI0 I/O and PCI1 I/O */
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + MV_64360_BASE_ADDR_DISBL), dis | (1<<9) | (1<<14) );
/* remap busses on hose 0; if the remap register was already set, assume
* that someone else [such as the bootloader] already performed the fixup
*/
if ( (b0 & 0xffff) && 0 == (r0 & 0xffff) ) {
rtems_pci_io_remap( 0, BSP_pci_hose1_bus_base, (b0 & 0xffff)<<16 );
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI0_IO_Remap), (b0 & 0xffff) );
}
/* remap busses on hose 1 */
if ( (b1 & 0xffff) && 0 == (r1 & 0xffff) ) {
rtems_pci_io_remap( BSP_pci_hose1_bus_base, pci_bus_count(), (b1 & 0xffff)<<16 );
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI1_IO_Remap), (b1 & 0xffff) );
}
/* re-enable */
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + MV_64360_BASE_ADDR_DISBL), dis );
break;
case GT_64260_A:
case GT_64260_B:
if ( (b0 & 0xfff) && 0 == (r0 & 0xfff) ) { /* base are only 12 bits */
/* switch window off by setting the limit < base */
lim = in_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI0_IO_High_Decode) );
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI0_IO_High_Decode), 0 );
/* remap busses on hose 0 */
rtems_pci_io_remap( 0, BSP_pci_hose1_bus_base, (b0 & 0xfff)<<20 );
/* BTW: it seems that writing the base register also copies the
* value into the 'remap' register automatically (??)
*/
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI0_IO_Remap), (b0 & 0xfff) );
/* re-enable */
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI0_IO_High_Decode), lim );
}
if ( (b1 & 0xfff) && 0 == (r1 & 0xfff) ) { /* base are only 12 bits */
/* switch window off by setting the limit < base */
lim = in_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI1_IO_High_Decode) );
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI1_IO_High_Decode), 0 );
/* remap busses on hose 1 */
rtems_pci_io_remap( BSP_pci_hose1_bus_base, pci_bus_count(), (b1 & 0xfff)<<20 );
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI1_IO_Remap), (b1 & 0xfff) );
/* re-enable */
out_le32( (volatile unsigned*)(BSP_MV64x60_BASE + GT_PCI1_IO_High_Decode), lim );
}
break;
default:
BSP_panic("Unknown discovery version; switch in file: "__FILE__" not implemented (yet)");
break; /* never get here */
}
/* Fixup the IRQ lines; the mvme6100 maps them nicely into our scheme, i.e., GPP
* interrupts start at 64 upwards
*
* The mvme5500 is apparently initialized differently :-(. GPP interrupts start at 0
* Since all PCI interrupts are wired to GPP we simply check for a value < 64 and
* reprogram the interrupt line register.
*/
BSP_pciScan(0, fixup_irq_line, 0);
}