android_kernel_xiaomi_sm8350/include/asm-ia64/sn/sn_sal.h
John Keller 8ea6091f50 Altix: Add initial ACPI IO support
First phase in introducing ACPI support to SN.
In this phase, when running with an ACPI capable PROM,
the DSDT will define the root busses and all SN nodes
(SGIHUB, SGITIO). An ACPI bus driver will be registered
for the node devices, with the acpi_pci_root_driver being
used for the root busses. An ACPI vendor descriptor is
now used to pass platform specific information for both
nodes and busses, eliminating the need for the current
SAL calls. Also, with ACPI support, SN fixup code is no longer
needed to initiate the PCI bus scans, as the acpi_pci_root_driver
does that.

However, to maintain backward compatibility with non-ACPI capable
PROMs, none of the current 'fixup' code can been deleted, though
much restructuring has been done. For example, the bulk of the code
in io_common.c is relocated code that is now common regardless
of what PROM is running, while io_acpi_init.c and io_init.c contain
routines specific to an ACPI or non ACPI capable PROM respectively.

A new pci bus fixup platform vector has been created to provide
a hook for invoking platform specific bus fixup from pcibios_fixup_bus().

The size of io_space[] has been increased to support systems with
large IO configurations.


Signed-off-by: John Keller <jpk@sgi.com>
Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2006-12-01 14:36:57 -08:00

1159 lines
31 KiB
C

#ifndef _ASM_IA64_SN_SN_SAL_H
#define _ASM_IA64_SN_SN_SAL_H
/*
* System Abstraction Layer definitions for IA64
*
* This file is subject to the terms and conditions of the GNU General Public
* License. See the file "COPYING" in the main directory of this archive
* for more details.
*
* Copyright (c) 2000-2006 Silicon Graphics, Inc. All rights reserved.
*/
#include <asm/sal.h>
#include <asm/sn/sn_cpuid.h>
#include <asm/sn/arch.h>
#include <asm/sn/geo.h>
#include <asm/sn/nodepda.h>
#include <asm/sn/shub_mmr.h>
// SGI Specific Calls
#define SN_SAL_POD_MODE 0x02000001
#define SN_SAL_SYSTEM_RESET 0x02000002
#define SN_SAL_PROBE 0x02000003
#define SN_SAL_GET_MASTER_NASID 0x02000004
#define SN_SAL_GET_KLCONFIG_ADDR 0x02000005
#define SN_SAL_LOG_CE 0x02000006
#define SN_SAL_REGISTER_CE 0x02000007
#define SN_SAL_GET_PARTITION_ADDR 0x02000009
#define SN_SAL_XP_ADDR_REGION 0x0200000f
#define SN_SAL_NO_FAULT_ZONE_VIRTUAL 0x02000010
#define SN_SAL_NO_FAULT_ZONE_PHYSICAL 0x02000011
#define SN_SAL_PRINT_ERROR 0x02000012
#define SN_SAL_SET_ERROR_HANDLING_FEATURES 0x0200001a // reentrant
#define SN_SAL_GET_FIT_COMPT 0x0200001b // reentrant
#define SN_SAL_GET_SAPIC_INFO 0x0200001d
#define SN_SAL_GET_SN_INFO 0x0200001e
#define SN_SAL_CONSOLE_PUTC 0x02000021
#define SN_SAL_CONSOLE_GETC 0x02000022
#define SN_SAL_CONSOLE_PUTS 0x02000023
#define SN_SAL_CONSOLE_GETS 0x02000024
#define SN_SAL_CONSOLE_GETS_TIMEOUT 0x02000025
#define SN_SAL_CONSOLE_POLL 0x02000026
#define SN_SAL_CONSOLE_INTR 0x02000027
#define SN_SAL_CONSOLE_PUTB 0x02000028
#define SN_SAL_CONSOLE_XMIT_CHARS 0x0200002a
#define SN_SAL_CONSOLE_READC 0x0200002b
#define SN_SAL_SYSCTL_OP 0x02000030
#define SN_SAL_SYSCTL_MODID_GET 0x02000031
#define SN_SAL_SYSCTL_GET 0x02000032
#define SN_SAL_SYSCTL_IOBRICK_MODULE_GET 0x02000033
#define SN_SAL_SYSCTL_IO_PORTSPEED_GET 0x02000035
#define SN_SAL_SYSCTL_SLAB_GET 0x02000036
#define SN_SAL_BUS_CONFIG 0x02000037
#define SN_SAL_SYS_SERIAL_GET 0x02000038
#define SN_SAL_PARTITION_SERIAL_GET 0x02000039
#define SN_SAL_SYSCTL_PARTITION_GET 0x0200003a
#define SN_SAL_SYSTEM_POWER_DOWN 0x0200003b
#define SN_SAL_GET_MASTER_BASEIO_NASID 0x0200003c
#define SN_SAL_COHERENCE 0x0200003d
#define SN_SAL_MEMPROTECT 0x0200003e
#define SN_SAL_SYSCTL_FRU_CAPTURE 0x0200003f
#define SN_SAL_SYSCTL_IOBRICK_PCI_OP 0x02000042 // reentrant
#define SN_SAL_IROUTER_OP 0x02000043
#define SN_SAL_SYSCTL_EVENT 0x02000044
#define SN_SAL_IOIF_INTERRUPT 0x0200004a
#define SN_SAL_HWPERF_OP 0x02000050 // lock
#define SN_SAL_IOIF_ERROR_INTERRUPT 0x02000051
#define SN_SAL_IOIF_PCI_SAFE 0x02000052
#define SN_SAL_IOIF_SLOT_ENABLE 0x02000053
#define SN_SAL_IOIF_SLOT_DISABLE 0x02000054
#define SN_SAL_IOIF_GET_HUBDEV_INFO 0x02000055
#define SN_SAL_IOIF_GET_PCIBUS_INFO 0x02000056
#define SN_SAL_IOIF_GET_PCIDEV_INFO 0x02000057
#define SN_SAL_IOIF_GET_WIDGET_DMAFLUSH_LIST 0x02000058 // deprecated
#define SN_SAL_IOIF_GET_DEVICE_DMAFLUSH_LIST 0x0200005a
#define SN_SAL_IOIF_INIT 0x0200005f
#define SN_SAL_HUB_ERROR_INTERRUPT 0x02000060
#define SN_SAL_BTE_RECOVER 0x02000061
#define SN_SAL_RESERVED_DO_NOT_USE 0x02000062
#define SN_SAL_IOIF_GET_PCI_TOPOLOGY 0x02000064
#define SN_SAL_GET_PROM_FEATURE_SET 0x02000065
#define SN_SAL_SET_OS_FEATURE_SET 0x02000066
#define SN_SAL_INJECT_ERROR 0x02000067
#define SN_SAL_SET_CPU_NUMBER 0x02000068
/*
* Service-specific constants
*/
/* Console interrupt manipulation */
/* action codes */
#define SAL_CONSOLE_INTR_OFF 0 /* turn the interrupt off */
#define SAL_CONSOLE_INTR_ON 1 /* turn the interrupt on */
#define SAL_CONSOLE_INTR_STATUS 2 /* retrieve the interrupt status */
/* interrupt specification & status return codes */
#define SAL_CONSOLE_INTR_XMIT 1 /* output interrupt */
#define SAL_CONSOLE_INTR_RECV 2 /* input interrupt */
/* interrupt handling */
#define SAL_INTR_ALLOC 1
#define SAL_INTR_FREE 2
/*
* operations available on the generic SN_SAL_SYSCTL_OP
* runtime service
*/
#define SAL_SYSCTL_OP_IOBOARD 0x0001 /* retrieve board type */
#define SAL_SYSCTL_OP_TIO_JLCK_RST 0x0002 /* issue TIO clock reset */
/*
* IRouter (i.e. generalized system controller) operations
*/
#define SAL_IROUTER_OPEN 0 /* open a subchannel */
#define SAL_IROUTER_CLOSE 1 /* close a subchannel */
#define SAL_IROUTER_SEND 2 /* send part of an IRouter packet */
#define SAL_IROUTER_RECV 3 /* receive part of an IRouter packet */
#define SAL_IROUTER_INTR_STATUS 4 /* check the interrupt status for
* an open subchannel
*/
#define SAL_IROUTER_INTR_ON 5 /* enable an interrupt */
#define SAL_IROUTER_INTR_OFF 6 /* disable an interrupt */
#define SAL_IROUTER_INIT 7 /* initialize IRouter driver */
/* IRouter interrupt mask bits */
#define SAL_IROUTER_INTR_XMIT SAL_CONSOLE_INTR_XMIT
#define SAL_IROUTER_INTR_RECV SAL_CONSOLE_INTR_RECV
/*
* Error Handling Features
*/
#define SAL_ERR_FEAT_MCA_SLV_TO_OS_INIT_SLV 0x1 // obsolete
#define SAL_ERR_FEAT_LOG_SBES 0x2 // obsolete
#define SAL_ERR_FEAT_MFR_OVERRIDE 0x4
#define SAL_ERR_FEAT_SBE_THRESHOLD 0xffff0000
/*
* SAL Error Codes
*/
#define SALRET_MORE_PASSES 1
#define SALRET_OK 0
#define SALRET_NOT_IMPLEMENTED (-1)
#define SALRET_INVALID_ARG (-2)
#define SALRET_ERROR (-3)
#define SN_SAL_FAKE_PROM 0x02009999
/**
* sn_sal_revision - get the SGI SAL revision number
*
* The SGI PROM stores its version in the sal_[ab]_rev_(major|minor).
* This routine simply extracts the major and minor values and
* presents them in a u32 format.
*
* For example, version 4.05 would be represented at 0x0405.
*/
static inline u32
sn_sal_rev(void)
{
struct ia64_sal_systab *systab = __va(efi.sal_systab);
return (u32)(systab->sal_b_rev_major << 8 | systab->sal_b_rev_minor);
}
/*
* Returns the master console nasid, if the call fails, return an illegal
* value.
*/
static inline u64
ia64_sn_get_console_nasid(void)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL(ret_stuff, SN_SAL_GET_MASTER_NASID, 0, 0, 0, 0, 0, 0, 0);
if (ret_stuff.status < 0)
return ret_stuff.status;
/* Master console nasid is in 'v0' */
return ret_stuff.v0;
}
/*
* Returns the master baseio nasid, if the call fails, return an illegal
* value.
*/
static inline u64
ia64_sn_get_master_baseio_nasid(void)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL(ret_stuff, SN_SAL_GET_MASTER_BASEIO_NASID, 0, 0, 0, 0, 0, 0, 0);
if (ret_stuff.status < 0)
return ret_stuff.status;
/* Master baseio nasid is in 'v0' */
return ret_stuff.v0;
}
static inline void *
ia64_sn_get_klconfig_addr(nasid_t nasid)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL(ret_stuff, SN_SAL_GET_KLCONFIG_ADDR, (u64)nasid, 0, 0, 0, 0, 0, 0);
return ret_stuff.v0 ? __va(ret_stuff.v0) : NULL;
}
/*
* Returns the next console character.
*/
static inline u64
ia64_sn_console_getc(int *ch)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_CONSOLE_GETC, 0, 0, 0, 0, 0, 0, 0);
/* character is in 'v0' */
*ch = (int)ret_stuff.v0;
return ret_stuff.status;
}
/*
* Read a character from the SAL console device, after a previous interrupt
* or poll operation has given us to know that a character is available
* to be read.
*/
static inline u64
ia64_sn_console_readc(void)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_CONSOLE_READC, 0, 0, 0, 0, 0, 0, 0);
/* character is in 'v0' */
return ret_stuff.v0;
}
/*
* Sends the given character to the console.
*/
static inline u64
ia64_sn_console_putc(char ch)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_CONSOLE_PUTC, (u64)ch, 0, 0, 0, 0, 0, 0);
return ret_stuff.status;
}
/*
* Sends the given buffer to the console.
*/
static inline u64
ia64_sn_console_putb(const char *buf, int len)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_CONSOLE_PUTB, (u64)buf, (u64)len, 0, 0, 0, 0, 0);
if ( ret_stuff.status == 0 ) {
return ret_stuff.v0;
}
return (u64)0;
}
/*
* Print a platform error record
*/
static inline u64
ia64_sn_plat_specific_err_print(int (*hook)(const char*, ...), char *rec)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_REENTRANT(ret_stuff, SN_SAL_PRINT_ERROR, (u64)hook, (u64)rec, 0, 0, 0, 0, 0);
return ret_stuff.status;
}
/*
* Check for Platform errors
*/
static inline u64
ia64_sn_plat_cpei_handler(void)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_LOG_CE, 0, 0, 0, 0, 0, 0, 0);
return ret_stuff.status;
}
/*
* Set Error Handling Features (Obsolete)
*/
static inline u64
ia64_sn_plat_set_error_handling_features(void)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_REENTRANT(ret_stuff, SN_SAL_SET_ERROR_HANDLING_FEATURES,
SAL_ERR_FEAT_LOG_SBES,
0, 0, 0, 0, 0, 0);
return ret_stuff.status;
}
/*
* Checks for console input.
*/
static inline u64
ia64_sn_console_check(int *result)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_CONSOLE_POLL, 0, 0, 0, 0, 0, 0, 0);
/* result is in 'v0' */
*result = (int)ret_stuff.v0;
return ret_stuff.status;
}
/*
* Checks console interrupt status
*/
static inline u64
ia64_sn_console_intr_status(void)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_CONSOLE_INTR,
0, SAL_CONSOLE_INTR_STATUS,
0, 0, 0, 0, 0);
if (ret_stuff.status == 0) {
return ret_stuff.v0;
}
return 0;
}
/*
* Enable an interrupt on the SAL console device.
*/
static inline void
ia64_sn_console_intr_enable(u64 intr)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_CONSOLE_INTR,
intr, SAL_CONSOLE_INTR_ON,
0, 0, 0, 0, 0);
}
/*
* Disable an interrupt on the SAL console device.
*/
static inline void
ia64_sn_console_intr_disable(u64 intr)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_CONSOLE_INTR,
intr, SAL_CONSOLE_INTR_OFF,
0, 0, 0, 0, 0);
}
/*
* Sends a character buffer to the console asynchronously.
*/
static inline u64
ia64_sn_console_xmit_chars(char *buf, int len)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_CONSOLE_XMIT_CHARS,
(u64)buf, (u64)len,
0, 0, 0, 0, 0);
if (ret_stuff.status == 0) {
return ret_stuff.v0;
}
return 0;
}
/*
* Returns the iobrick module Id
*/
static inline u64
ia64_sn_sysctl_iobrick_module_get(nasid_t nasid, int *result)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_SYSCTL_IOBRICK_MODULE_GET, nasid, 0, 0, 0, 0, 0, 0);
/* result is in 'v0' */
*result = (int)ret_stuff.v0;
return ret_stuff.status;
}
/**
* ia64_sn_pod_mode - call the SN_SAL_POD_MODE function
*
* SN_SAL_POD_MODE actually takes an argument, but it's always
* 0 when we call it from the kernel, so we don't have to expose
* it to the caller.
*/
static inline u64
ia64_sn_pod_mode(void)
{
struct ia64_sal_retval isrv;
SAL_CALL_REENTRANT(isrv, SN_SAL_POD_MODE, 0, 0, 0, 0, 0, 0, 0);
if (isrv.status)
return 0;
return isrv.v0;
}
/**
* ia64_sn_probe_mem - read from memory safely
* @addr: address to probe
* @size: number bytes to read (1,2,4,8)
* @data_ptr: address to store value read by probe (-1 returned if probe fails)
*
* Call into the SAL to do a memory read. If the read generates a machine
* check, this routine will recover gracefully and return -1 to the caller.
* @addr is usually a kernel virtual address in uncached space (i.e. the
* address starts with 0xc), but if called in physical mode, @addr should
* be a physical address.
*
* Return values:
* 0 - probe successful
* 1 - probe failed (generated MCA)
* 2 - Bad arg
* <0 - PAL error
*/
static inline u64
ia64_sn_probe_mem(long addr, long size, void *data_ptr)
{
struct ia64_sal_retval isrv;
SAL_CALL(isrv, SN_SAL_PROBE, addr, size, 0, 0, 0, 0, 0);
if (data_ptr) {
switch (size) {
case 1:
*((u8*)data_ptr) = (u8)isrv.v0;
break;
case 2:
*((u16*)data_ptr) = (u16)isrv.v0;
break;
case 4:
*((u32*)data_ptr) = (u32)isrv.v0;
break;
case 8:
*((u64*)data_ptr) = (u64)isrv.v0;
break;
default:
isrv.status = 2;
}
}
return isrv.status;
}
/*
* Retrieve the system serial number as an ASCII string.
*/
static inline u64
ia64_sn_sys_serial_get(char *buf)
{
struct ia64_sal_retval ret_stuff;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_SYS_SERIAL_GET, buf, 0, 0, 0, 0, 0, 0);
return ret_stuff.status;
}
extern char sn_system_serial_number_string[];
extern u64 sn_partition_serial_number;
static inline char *
sn_system_serial_number(void) {
if (sn_system_serial_number_string[0]) {
return(sn_system_serial_number_string);
} else {
ia64_sn_sys_serial_get(sn_system_serial_number_string);
return(sn_system_serial_number_string);
}
}
/*
* Returns a unique id number for this system and partition (suitable for
* use with license managers), based in part on the system serial number.
*/
static inline u64
ia64_sn_partition_serial_get(void)
{
struct ia64_sal_retval ret_stuff;
ia64_sal_oemcall_reentrant(&ret_stuff, SN_SAL_PARTITION_SERIAL_GET, 0,
0, 0, 0, 0, 0, 0);
if (ret_stuff.status != 0)
return 0;
return ret_stuff.v0;
}
static inline u64
sn_partition_serial_number_val(void) {
if (unlikely(sn_partition_serial_number == 0)) {
sn_partition_serial_number = ia64_sn_partition_serial_get();
}
return sn_partition_serial_number;
}
/*
* Returns the partition id of the nasid passed in as an argument,
* or INVALID_PARTID if the partition id cannot be retrieved.
*/
static inline partid_t
ia64_sn_sysctl_partition_get(nasid_t nasid)
{
struct ia64_sal_retval ret_stuff;
SAL_CALL(ret_stuff, SN_SAL_SYSCTL_PARTITION_GET, nasid,
0, 0, 0, 0, 0, 0);
if (ret_stuff.status != 0)
return -1;
return ((partid_t)ret_stuff.v0);
}
/*
* Returns the physical address of the partition's reserved page through
* an iterative number of calls.
*
* On first call, 'cookie' and 'len' should be set to 0, and 'addr'
* set to the nasid of the partition whose reserved page's address is
* being sought.
* On subsequent calls, pass the values, that were passed back on the
* previous call.
*
* While the return status equals SALRET_MORE_PASSES, keep calling
* this function after first copying 'len' bytes starting at 'addr'
* into 'buf'. Once the return status equals SALRET_OK, 'addr' will
* be the physical address of the partition's reserved page. If the
* return status equals neither of these, an error as occurred.
*/
static inline s64
sn_partition_reserved_page_pa(u64 buf, u64 *cookie, u64 *addr, u64 *len)
{
struct ia64_sal_retval rv;
ia64_sal_oemcall_reentrant(&rv, SN_SAL_GET_PARTITION_ADDR, *cookie,
*addr, buf, *len, 0, 0, 0);
*cookie = rv.v0;
*addr = rv.v1;
*len = rv.v2;
return rv.status;
}
/*
* Register or unregister a physical address range being referenced across
* a partition boundary for which certain SAL errors should be scanned for,
* cleaned up and ignored. This is of value for kernel partitioning code only.
* Values for the operation argument:
* 1 = register this address range with SAL
* 0 = unregister this address range with SAL
*
* SAL maintains a reference count on an address range in case it is registered
* multiple times.
*
* On success, returns the reference count of the address range after the SAL
* call has performed the current registration/unregistration. Returns a
* negative value if an error occurred.
*/
static inline int
sn_register_xp_addr_region(u64 paddr, u64 len, int operation)
{
struct ia64_sal_retval ret_stuff;
ia64_sal_oemcall(&ret_stuff, SN_SAL_XP_ADDR_REGION, paddr, len,
(u64)operation, 0, 0, 0, 0);
return ret_stuff.status;
}
/*
* Register or unregister an instruction range for which SAL errors should
* be ignored. If an error occurs while in the registered range, SAL jumps
* to return_addr after ignoring the error. Values for the operation argument:
* 1 = register this instruction range with SAL
* 0 = unregister this instruction range with SAL
*
* Returns 0 on success, or a negative value if an error occurred.
*/
static inline int
sn_register_nofault_code(u64 start_addr, u64 end_addr, u64 return_addr,
int virtual, int operation)
{
struct ia64_sal_retval ret_stuff;
u64 call;
if (virtual) {
call = SN_SAL_NO_FAULT_ZONE_VIRTUAL;
} else {
call = SN_SAL_NO_FAULT_ZONE_PHYSICAL;
}
ia64_sal_oemcall(&ret_stuff, call, start_addr, end_addr, return_addr,
(u64)1, 0, 0, 0);
return ret_stuff.status;
}
/*
* Change or query the coherence domain for this partition. Each cpu-based
* nasid is represented by a bit in an array of 64-bit words:
* 0 = not in this partition's coherency domain
* 1 = in this partition's coherency domain
*
* It is not possible for the local system's nasids to be removed from
* the coherency domain. Purpose of the domain arguments:
* new_domain = set the coherence domain to the given nasids
* old_domain = return the current coherence domain
*
* Returns 0 on success, or a negative value if an error occurred.
*/
static inline int
sn_change_coherence(u64 *new_domain, u64 *old_domain)
{
struct ia64_sal_retval ret_stuff;
ia64_sal_oemcall(&ret_stuff, SN_SAL_COHERENCE, (u64)new_domain,
(u64)old_domain, 0, 0, 0, 0, 0);
return ret_stuff.status;
}
/*
* Change memory access protections for a physical address range.
* nasid_array is not used on Altix, but may be in future architectures.
* Available memory protection access classes are defined after the function.
*/
static inline int
sn_change_memprotect(u64 paddr, u64 len, u64 perms, u64 *nasid_array)
{
struct ia64_sal_retval ret_stuff;
ia64_sal_oemcall_nolock(&ret_stuff, SN_SAL_MEMPROTECT, paddr, len,
(u64)nasid_array, perms, 0, 0, 0);
return ret_stuff.status;
}
#define SN_MEMPROT_ACCESS_CLASS_0 0x14a080
#define SN_MEMPROT_ACCESS_CLASS_1 0x2520c2
#define SN_MEMPROT_ACCESS_CLASS_2 0x14a1ca
#define SN_MEMPROT_ACCESS_CLASS_3 0x14a290
#define SN_MEMPROT_ACCESS_CLASS_6 0x084080
#define SN_MEMPROT_ACCESS_CLASS_7 0x021080
/*
* Turns off system power.
*/
static inline void
ia64_sn_power_down(void)
{
struct ia64_sal_retval ret_stuff;
SAL_CALL(ret_stuff, SN_SAL_SYSTEM_POWER_DOWN, 0, 0, 0, 0, 0, 0, 0);
while(1)
cpu_relax();
/* never returns */
}
/**
* ia64_sn_fru_capture - tell the system controller to capture hw state
*
* This routine will call the SAL which will tell the system controller(s)
* to capture hw mmr information from each SHub in the system.
*/
static inline u64
ia64_sn_fru_capture(void)
{
struct ia64_sal_retval isrv;
SAL_CALL(isrv, SN_SAL_SYSCTL_FRU_CAPTURE, 0, 0, 0, 0, 0, 0, 0);
if (isrv.status)
return 0;
return isrv.v0;
}
/*
* Performs an operation on a PCI bus or slot -- power up, power down
* or reset.
*/
static inline u64
ia64_sn_sysctl_iobrick_pci_op(nasid_t n, u64 connection_type,
u64 bus, char slot,
u64 action)
{
struct ia64_sal_retval rv = {0, 0, 0, 0};
SAL_CALL_NOLOCK(rv, SN_SAL_SYSCTL_IOBRICK_PCI_OP, connection_type, n, action,
bus, (u64) slot, 0, 0);
if (rv.status)
return rv.v0;
return 0;
}
/*
* Open a subchannel for sending arbitrary data to the system
* controller network via the system controller device associated with
* 'nasid'. Return the subchannel number or a negative error code.
*/
static inline int
ia64_sn_irtr_open(nasid_t nasid)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_IROUTER_OP, SAL_IROUTER_OPEN, nasid,
0, 0, 0, 0, 0);
return (int) rv.v0;
}
/*
* Close system controller subchannel 'subch' previously opened on 'nasid'.
*/
static inline int
ia64_sn_irtr_close(nasid_t nasid, int subch)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_IROUTER_OP, SAL_IROUTER_CLOSE,
(u64) nasid, (u64) subch, 0, 0, 0, 0);
return (int) rv.status;
}
/*
* Read data from system controller associated with 'nasid' on
* subchannel 'subch'. The buffer to be filled is pointed to by
* 'buf', and its capacity is in the integer pointed to by 'len'. The
* referent of 'len' is set to the number of bytes read by the SAL
* call. The return value is either SALRET_OK (for bytes read) or
* SALRET_ERROR (for error or "no data available").
*/
static inline int
ia64_sn_irtr_recv(nasid_t nasid, int subch, char *buf, int *len)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_IROUTER_OP, SAL_IROUTER_RECV,
(u64) nasid, (u64) subch, (u64) buf, (u64) len,
0, 0);
return (int) rv.status;
}
/*
* Write data to the system controller network via the system
* controller associated with 'nasid' on suchannel 'subch'. The
* buffer to be written out is pointed to by 'buf', and 'len' is the
* number of bytes to be written. The return value is either the
* number of bytes written (which could be zero) or a negative error
* code.
*/
static inline int
ia64_sn_irtr_send(nasid_t nasid, int subch, char *buf, int len)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_IROUTER_OP, SAL_IROUTER_SEND,
(u64) nasid, (u64) subch, (u64) buf, (u64) len,
0, 0);
return (int) rv.v0;
}
/*
* Check whether any interrupts are pending for the system controller
* associated with 'nasid' and its subchannel 'subch'. The return
* value is a mask of pending interrupts (SAL_IROUTER_INTR_XMIT and/or
* SAL_IROUTER_INTR_RECV).
*/
static inline int
ia64_sn_irtr_intr(nasid_t nasid, int subch)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_IROUTER_OP, SAL_IROUTER_INTR_STATUS,
(u64) nasid, (u64) subch, 0, 0, 0, 0);
return (int) rv.v0;
}
/*
* Enable the interrupt indicated by the intr parameter (either
* SAL_IROUTER_INTR_XMIT or SAL_IROUTER_INTR_RECV).
*/
static inline int
ia64_sn_irtr_intr_enable(nasid_t nasid, int subch, u64 intr)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_IROUTER_OP, SAL_IROUTER_INTR_ON,
(u64) nasid, (u64) subch, intr, 0, 0, 0);
return (int) rv.v0;
}
/*
* Disable the interrupt indicated by the intr parameter (either
* SAL_IROUTER_INTR_XMIT or SAL_IROUTER_INTR_RECV).
*/
static inline int
ia64_sn_irtr_intr_disable(nasid_t nasid, int subch, u64 intr)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_IROUTER_OP, SAL_IROUTER_INTR_OFF,
(u64) nasid, (u64) subch, intr, 0, 0, 0);
return (int) rv.v0;
}
/*
* Set up a node as the point of contact for system controller
* environmental event delivery.
*/
static inline int
ia64_sn_sysctl_event_init(nasid_t nasid)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_SYSCTL_EVENT, (u64) nasid,
0, 0, 0, 0, 0, 0);
return (int) rv.v0;
}
/*
* Ask the system controller on the specified nasid to reset
* the CX corelet clock. Only valid on TIO nodes.
*/
static inline int
ia64_sn_sysctl_tio_clock_reset(nasid_t nasid)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_SYSCTL_OP, SAL_SYSCTL_OP_TIO_JLCK_RST,
nasid, 0, 0, 0, 0, 0);
if (rv.status != 0)
return (int)rv.status;
if (rv.v0 != 0)
return (int)rv.v0;
return 0;
}
/*
* Get the associated ioboard type for a given nasid.
*/
static inline s64
ia64_sn_sysctl_ioboard_get(nasid_t nasid, u16 *ioboard)
{
struct ia64_sal_retval isrv;
SAL_CALL_REENTRANT(isrv, SN_SAL_SYSCTL_OP, SAL_SYSCTL_OP_IOBOARD,
nasid, 0, 0, 0, 0, 0);
if (isrv.v0 != 0) {
*ioboard = isrv.v0;
return isrv.status;
}
if (isrv.v1 != 0) {
*ioboard = isrv.v1;
return isrv.status;
}
return isrv.status;
}
/**
* ia64_sn_get_fit_compt - read a FIT entry from the PROM header
* @nasid: NASID of node to read
* @index: FIT entry index to be retrieved (0..n)
* @fitentry: 16 byte buffer where FIT entry will be stored.
* @banbuf: optional buffer for retrieving banner
* @banlen: length of banner buffer
*
* Access to the physical PROM chips needs to be serialized since reads and
* writes can't occur at the same time, so we need to call into the SAL when
* we want to look at the FIT entries on the chips.
*
* Returns:
* %SALRET_OK if ok
* %SALRET_INVALID_ARG if index too big
* %SALRET_NOT_IMPLEMENTED if running on older PROM
* ??? if nasid invalid OR banner buffer not large enough
*/
static inline int
ia64_sn_get_fit_compt(u64 nasid, u64 index, void *fitentry, void *banbuf,
u64 banlen)
{
struct ia64_sal_retval rv;
SAL_CALL_NOLOCK(rv, SN_SAL_GET_FIT_COMPT, nasid, index, fitentry,
banbuf, banlen, 0, 0);
return (int) rv.status;
}
/*
* Initialize the SAL components of the system controller
* communication driver; specifically pass in a sizable buffer that
* can be used for allocation of subchannel queues as new subchannels
* are opened. "buf" points to the buffer, and "len" specifies its
* length.
*/
static inline int
ia64_sn_irtr_init(nasid_t nasid, void *buf, int len)
{
struct ia64_sal_retval rv;
SAL_CALL_REENTRANT(rv, SN_SAL_IROUTER_OP, SAL_IROUTER_INIT,
(u64) nasid, (u64) buf, (u64) len, 0, 0, 0);
return (int) rv.status;
}
/*
* Returns the nasid, subnode & slice corresponding to a SAPIC ID
*
* In:
* arg0 - SN_SAL_GET_SAPIC_INFO
* arg1 - sapicid (lid >> 16)
* Out:
* v0 - nasid
* v1 - subnode
* v2 - slice
*/
static inline u64
ia64_sn_get_sapic_info(int sapicid, int *nasid, int *subnode, int *slice)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_GET_SAPIC_INFO, sapicid, 0, 0, 0, 0, 0, 0);
/***** BEGIN HACK - temp til old proms no longer supported ********/
if (ret_stuff.status == SALRET_NOT_IMPLEMENTED) {
if (nasid) *nasid = sapicid & 0xfff;
if (subnode) *subnode = (sapicid >> 13) & 1;
if (slice) *slice = (sapicid >> 12) & 3;
return 0;
}
/***** END HACK *******/
if (ret_stuff.status < 0)
return ret_stuff.status;
if (nasid) *nasid = (int) ret_stuff.v0;
if (subnode) *subnode = (int) ret_stuff.v1;
if (slice) *slice = (int) ret_stuff.v2;
return 0;
}
/*
* Returns information about the HUB/SHUB.
* In:
* arg0 - SN_SAL_GET_SN_INFO
* arg1 - 0 (other values reserved for future use)
* Out:
* v0
* [7:0] - shub type (0=shub1, 1=shub2)
* [15:8] - Log2 max number of nodes in entire system (includes
* C-bricks, I-bricks, etc)
* [23:16] - Log2 of nodes per sharing domain
* [31:24] - partition ID
* [39:32] - coherency_id
* [47:40] - regionsize
* v1
* [15:0] - nasid mask (ex., 0x7ff for 11 bit nasid)
* [23:15] - bit position of low nasid bit
*/
static inline u64
ia64_sn_get_sn_info(int fc, u8 *shubtype, u16 *nasid_bitmask, u8 *nasid_shift,
u8 *systemsize, u8 *sharing_domain_size, u8 *partid, u8 *coher, u8 *reg)
{
struct ia64_sal_retval ret_stuff;
ret_stuff.status = 0;
ret_stuff.v0 = 0;
ret_stuff.v1 = 0;
ret_stuff.v2 = 0;
SAL_CALL_NOLOCK(ret_stuff, SN_SAL_GET_SN_INFO, fc, 0, 0, 0, 0, 0, 0);
/***** BEGIN HACK - temp til old proms no longer supported ********/
if (ret_stuff.status == SALRET_NOT_IMPLEMENTED) {
int nasid = get_sapicid() & 0xfff;
#define SH_SHUB_ID_NODES_PER_BIT_MASK 0x001f000000000000UL
#define SH_SHUB_ID_NODES_PER_BIT_SHFT 48
if (shubtype) *shubtype = 0;
if (nasid_bitmask) *nasid_bitmask = 0x7ff;
if (nasid_shift) *nasid_shift = 38;
if (systemsize) *systemsize = 10;
if (sharing_domain_size) *sharing_domain_size = 8;
if (partid) *partid = ia64_sn_sysctl_partition_get(nasid);
if (coher) *coher = nasid >> 9;
if (reg) *reg = (HUB_L((u64 *) LOCAL_MMR_ADDR(SH1_SHUB_ID)) & SH_SHUB_ID_NODES_PER_BIT_MASK) >>
SH_SHUB_ID_NODES_PER_BIT_SHFT;
return 0;
}
/***** END HACK *******/
if (ret_stuff.status < 0)
return ret_stuff.status;
if (shubtype) *shubtype = ret_stuff.v0 & 0xff;
if (systemsize) *systemsize = (ret_stuff.v0 >> 8) & 0xff;
if (sharing_domain_size) *sharing_domain_size = (ret_stuff.v0 >> 16) & 0xff;
if (partid) *partid = (ret_stuff.v0 >> 24) & 0xff;
if (coher) *coher = (ret_stuff.v0 >> 32) & 0xff;
if (reg) *reg = (ret_stuff.v0 >> 40) & 0xff;
if (nasid_bitmask) *nasid_bitmask = (ret_stuff.v1 & 0xffff);
if (nasid_shift) *nasid_shift = (ret_stuff.v1 >> 16) & 0xff;
return 0;
}
/*
* This is the access point to the Altix PROM hardware performance
* and status monitoring interface. For info on using this, see
* include/asm-ia64/sn/sn2/sn_hwperf.h
*/
static inline int
ia64_sn_hwperf_op(nasid_t nasid, u64 opcode, u64 a0, u64 a1, u64 a2,
u64 a3, u64 a4, int *v0)
{
struct ia64_sal_retval rv;
SAL_CALL_NOLOCK(rv, SN_SAL_HWPERF_OP, (u64)nasid,
opcode, a0, a1, a2, a3, a4);
if (v0)
*v0 = (int) rv.v0;
return (int) rv.status;
}
static inline int
ia64_sn_ioif_get_pci_topology(u64 buf, u64 len)
{
struct ia64_sal_retval rv;
SAL_CALL_NOLOCK(rv, SN_SAL_IOIF_GET_PCI_TOPOLOGY, buf, len, 0, 0, 0, 0, 0);
return (int) rv.status;
}
/*
* BTE error recovery is implemented in SAL
*/
static inline int
ia64_sn_bte_recovery(nasid_t nasid)
{
struct ia64_sal_retval rv;
rv.status = 0;
SAL_CALL_NOLOCK(rv, SN_SAL_BTE_RECOVER, (u64)nasid, 0, 0, 0, 0, 0, 0);
if (rv.status == SALRET_NOT_IMPLEMENTED)
return 0;
return (int) rv.status;
}
static inline int
ia64_sn_is_fake_prom(void)
{
struct ia64_sal_retval rv;
SAL_CALL_NOLOCK(rv, SN_SAL_FAKE_PROM, 0, 0, 0, 0, 0, 0, 0);
return (rv.status == 0);
}
static inline int
ia64_sn_get_prom_feature_set(int set, unsigned long *feature_set)
{
struct ia64_sal_retval rv;
SAL_CALL_NOLOCK(rv, SN_SAL_GET_PROM_FEATURE_SET, set, 0, 0, 0, 0, 0, 0);
if (rv.status != 0)
return rv.status;
*feature_set = rv.v0;
return 0;
}
static inline int
ia64_sn_set_os_feature(int feature)
{
struct ia64_sal_retval rv;
SAL_CALL_NOLOCK(rv, SN_SAL_SET_OS_FEATURE_SET, feature, 0, 0, 0, 0, 0, 0);
return rv.status;
}
static inline int
sn_inject_error(u64 paddr, u64 *data, u64 *ecc)
{
struct ia64_sal_retval ret_stuff;
ia64_sal_oemcall_nolock(&ret_stuff, SN_SAL_INJECT_ERROR, paddr, (u64)data,
(u64)ecc, 0, 0, 0, 0);
return ret_stuff.status;
}
static inline int
ia64_sn_set_cpu_number(int cpu)
{
struct ia64_sal_retval rv;
SAL_CALL_NOLOCK(rv, SN_SAL_SET_CPU_NUMBER, cpu, 0, 0, 0, 0, 0, 0);
return rv.status;
}
#endif /* _ASM_IA64_SN_SN_SAL_H */