board-js2x/rtas/rtas_board.c - SLOF - Git at Google

 /******************************************************************************
  * Copyright (c) 2004, 2008 IBM Corporation
  * All rights reserved.
  * This program and the accompanying materials
  * are made available under the terms of the BSD License
  * which accompanies this distribution, and is available at
  * http://www.opensource.org/licenses/bsd-license.php
  *
  * Contributors:
  *     IBM Corporation - initial implementation
  *****************************************************************************/

 #include <stdint.h>
 #include <rtas.h>
 #include "rtas_board.h"
 #include <bmc.h>
 #include <rtas_i2c_bmc.h>
 #include <rtas_ipmi_bmc.h>
 #include "libipmi.h"
 #include <hw.h>

 void io_init(void);
 short reg_get_flashside(void);
 void rtas_init(void);

 void (*bmc_system_reboot) (void);
 void (*bmc_power_off) (void);

 short (*bmc_set_flashside) (short mode);
 short (*bmc_get_flashside) (void);
 int (*bmc_stop_bootwatchdog) (void);
 int (*bmc_set_bootwatchdog) (unsigned short);

 uint32_t(*bmc_read_vpd) (uint8_t * dst, uint32_t len, uint32_t offset);
 uint32_t(*bmc_write_vpd) (uint8_t * src, uint32_t len, uint32_t offset);

 uint32_t(*bmc_get_blade_descr) (uint8_t * dst, uint32_t maxlen, uint32_t * len);

 typedef struct {
 	uint64_t r3;
 	uint64_t addr;
 	volatile uint64_t id;
 } slave_t;

 volatile slave_t rtas_slave_interface;

 static void
 rtas_slave_loop(volatile slave_t * pIface)
 {
 	uint64_t mask = pIface->id;
 	pIface->id = 0;
 	while (pIface->id != mask) {
 		int dly = 0x1000;
 		while (dly--);
 	}
 	pIface->id = 0;
 	asm volatile ("  mr 3,%0 ; mtctr %1 ; bctr "
 			::"r"(pIface->r3), "r"(pIface->addr));
 }

 void
 rtas_fetch_slaves(rtas_args_t * pArgs)
 {
 	int retVal = 0;
 	int idx = 0;
 	uint32_t mask = pArgs->args[0] & 0xFFFFFFFE;
 	uint64_t *rtas_slave_loop_ptr = (uint64_t *)rtas_slave_loop;
 	while (mask) {
 		if (mask & 0x1) {
 			rtas_slave_interface.id = idx | 0x100;
 			*(int *) 0x3fc0 = (int)(unsigned long) &rtas_slave_interface;	// r3
 			*(int *) 0x3f80 = *rtas_slave_loop_ptr;		// addr
 			*(int *) 0x3fa0 = idx | 0x100;	// pid
 			while (rtas_slave_interface.id);
 		}
 		mask >>= 1;
 		idx++;
 	}
 	pArgs->args[pArgs->nargs] = retVal;
 }

 void
 rtas_start_cpu(rtas_args_t * pArgs)
 {
 	int retVal = 0;
 	int idx = pArgs->args[0];	// pid
 	rtas_slave_interface.r3 = pArgs->args[2];	// r3
 	rtas_slave_interface.addr = pArgs->args[1];	// addr
 	asm(" sync ");
 	rtas_slave_interface.id = idx | 0x100;	// pid
 	while (rtas_slave_interface.id);
 	pArgs->args[pArgs->nargs] = retVal;
 }

 void
 rtas_read_vpd(rtas_args_t * pArgs)
 {
 	pArgs->args[pArgs->nargs] =
 	    bmc_read_vpd((uint8_t *) (uint64_t) pArgs->args[2], pArgs->args[1],
 			 pArgs->args[0]);
 }

 void
 rtas_write_vpd(rtas_args_t * pArgs)
 {
 	pArgs->args[pArgs->nargs] =
 	    bmc_write_vpd((uint8_t *) (uint64_t) pArgs->args[2], pArgs->args[1],
 			  pArgs->args[0]);
 }

 void
 rtas_set_indicator(rtas_args_t * pArgs)
 {
 	pArgs->args[pArgs->nargs] = -1;
 }

 void
 rtas_event_scan(rtas_args_t * pArgs)
 {
 	pArgs->args[pArgs->nargs] = -1;
 }

 void
 rtas_stop_bootwatchdog(rtas_args_t * pArgs)
 {
 	pArgs->args[pArgs->nargs] = bmc_stop_bootwatchdog();
 }

 void
 rtas_set_bootwatchdog(rtas_args_t * pArgs)
 {
 	pArgs->args[pArgs->nargs] = bmc_set_bootwatchdog(pArgs->args[0]);
 }

 void
 rtas_set_flashside(rtas_args_t * pArgs)
 {
 	pArgs->args[pArgs->nargs] = bmc_set_flashside(pArgs->args[0]);
 }

 void
 rtas_get_flashside(rtas_args_t * pArgs)
 {
 	int retVal = bmc_get_flashside();
 	pArgs->args[pArgs->nargs] = retVal;
 }

 void
 rtas_flash_test(rtas_args_t * pArgs)
 {
 	pArgs->args[pArgs->nargs] = -1;
 }

 void
 rtas_system_reboot(rtas_args_t * pArgs)
 {
 	bmc_system_reboot();
 	pArgs->args[pArgs->nargs] = -1;
 }

 void
 rtas_power_off(rtas_args_t * pArgs)
 {
 	bmc_power_off();
 	pArgs->args[pArgs->nargs] = -1;
 }

 void
 rtas_get_blade_descr(rtas_args_t * pArgs)
 {
 	uint8_t *buffer = (uint8_t *) (uint64_t) pArgs->args[0];
 	uint32_t maxlen = pArgs->args[1];
 	uint32_t retlen = 0;
 	uint32_t retval = bmc_get_blade_descr(buffer, maxlen, &retlen);
 	pArgs->args[pArgs->nargs] = retlen;
 	pArgs->args[pArgs->nargs + 1] = retval;
 }

 // for JS20 cannot read blade descr
 static uint32_t
 dummy_get_blade_descr(uint8_t *dst, uint32_t maxlen, uint32_t *len)
 {
 	// to not have a warning we need to do _something_ with *dst and maxlen...
 	*dst = *dst;
 	maxlen = maxlen;
 	*len = 0;
 	return -1;
 }

 /* read flashside from register */
 short
 reg_get_flashside(void)
 {
 	short retVal;
 	uint8_t val = load8_ci(0xf4003fe3);
 	if (val & 0x80) {
 		// temp
 		retVal = 1;
 	} else {
 		// perm
 		retVal = 0;
 	}
 	return retVal;
 }

 void
 rtas_init(void)
 {
 	io_init();
 	if (u4Flag) {
 		bmc_system_reboot = ipmi_system_reboot;
 		bmc_power_off = ipmi_power_off;
 		bmc_set_flashside = ipmi_set_flashside;
 		bmc_get_flashside = reg_get_flashside;
 		bmc_stop_bootwatchdog = ipmi_oem_stop_bootwatchdog;
 		bmc_set_bootwatchdog = ipmi_oem_set_bootwatchdog;
 		bmc_read_vpd = ipmi_oem_read_vpd;
 		bmc_write_vpd = ipmi_oem_write_vpd;
 		bmc_get_blade_descr = ipmi_oem_get_blade_descr;
 	} else {
 		bmc_system_reboot = i2c_system_reboot;
 		bmc_power_off = i2c_power_off;
 		bmc_set_flashside = i2c_set_flashside;
 		bmc_get_flashside = i2c_get_flashside;
 		bmc_stop_bootwatchdog = i2c_stop_bootwatchdog;
 		bmc_set_bootwatchdog = i2c_set_bootwatchdog;
 		bmc_read_vpd = i2c_read_vpd;
 		bmc_write_vpd = i2c_write_vpd;
 		bmc_get_blade_descr = dummy_get_blade_descr;
 	}
 }
	/******************************************************************************
	* Copyright (c) 2004, 2008 IBM Corporation
	* All rights reserved.
	* This program and the accompanying materials
	* are made available under the terms of the BSD License
	* which accompanies this distribution, and is available at
	* http://www.opensource.org/licenses/bsd-license.php
	*
	* Contributors:
	* IBM Corporation - initial implementation
	*****************************************************************************/

	#include <stdint.h>
	#include <rtas.h>
	#include "rtas_board.h"
	#include <bmc.h>
	#include <rtas_i2c_bmc.h>
	#include <rtas_ipmi_bmc.h>
	#include "libipmi.h"
	#include <hw.h>

	void io_init(void);
	short reg_get_flashside(void);
	void rtas_init(void);

	void (*bmc_system_reboot) (void);
	void (*bmc_power_off) (void);

	short (*bmc_set_flashside) (short mode);
	short (*bmc_get_flashside) (void);
	int (*bmc_stop_bootwatchdog) (void);
	int (*bmc_set_bootwatchdog) (unsigned short);

	uint32_t(bmc_read_vpd) (uint8_t dst, uint32_t len, uint32_t offset);
	uint32_t(bmc_write_vpd) (uint8_t src, uint32_t len, uint32_t offset);

	uint32_t(bmc_get_blade_descr) (uint8_t dst, uint32_t maxlen, uint32_t * len);

	typedef struct {
	uint64_t r3;
	uint64_t addr;
	volatile uint64_t id;
	} slave_t;

	volatile slave_t rtas_slave_interface;

	static void
	rtas_slave_loop(volatile slave_t * pIface)
	{
	uint64_t mask = pIface->id;
	pIface->id = 0;
	while (pIface->id != mask) {
	int dly = 0x1000;
	while (dly--);
	}
	pIface->id = 0;
	asm volatile (" mr 3,%0 ; mtctr %1 ; bctr "
	::"r"(pIface->r3), "r"(pIface->addr));
	}

	void
	rtas_fetch_slaves(rtas_args_t * pArgs)
	{
	int retVal = 0;
	int idx = 0;
	uint32_t mask = pArgs->args[0] & 0xFFFFFFFE;
	uint64_t rtas_slave_loop_ptr = (uint64_t )rtas_slave_loop;
	while (mask) {
	if (mask & 0x1) {
	rtas_slave_interface.id = idx \| 0x100;
	(int ) 0x3fc0 = (int)(unsigned long) &rtas_slave_interface; // r3
	(int ) 0x3f80 = *rtas_slave_loop_ptr; // addr
	(int ) 0x3fa0 = idx \| 0x100; // pid
	while (rtas_slave_interface.id);
	}
	mask >>= 1;
	idx++;
	}
	pArgs->args[pArgs->nargs] = retVal;
	}

	void
	rtas_start_cpu(rtas_args_t * pArgs)
	{
	int retVal = 0;
	int idx = pArgs->args[0]; // pid
	rtas_slave_interface.r3 = pArgs->args[2]; // r3
	rtas_slave_interface.addr = pArgs->args[1]; // addr
	asm(" sync ");
	rtas_slave_interface.id = idx \| 0x100; // pid
	while (rtas_slave_interface.id);
	pArgs->args[pArgs->nargs] = retVal;
	}

	void
	rtas_read_vpd(rtas_args_t * pArgs)
	{
	pArgs->args[pArgs->nargs] =
	bmc_read_vpd((uint8_t *) (uint64_t) pArgs->args[2], pArgs->args[1],
	pArgs->args[0]);
	}

	void
	rtas_write_vpd(rtas_args_t * pArgs)
	{
	pArgs->args[pArgs->nargs] =
	bmc_write_vpd((uint8_t *) (uint64_t) pArgs->args[2], pArgs->args[1],
	pArgs->args[0]);
	}

	void
	rtas_set_indicator(rtas_args_t * pArgs)
	{
	pArgs->args[pArgs->nargs] = -1;
	}

	void
	rtas_event_scan(rtas_args_t * pArgs)
	{
	pArgs->args[pArgs->nargs] = -1;
	}

	void
	rtas_stop_bootwatchdog(rtas_args_t * pArgs)
	{
	pArgs->args[pArgs->nargs] = bmc_stop_bootwatchdog();
	}

	void
	rtas_set_bootwatchdog(rtas_args_t * pArgs)
	{
	pArgs->args[pArgs->nargs] = bmc_set_bootwatchdog(pArgs->args[0]);
	}

	void
	rtas_set_flashside(rtas_args_t * pArgs)
	{
	pArgs->args[pArgs->nargs] = bmc_set_flashside(pArgs->args[0]);
	}

	void
	rtas_get_flashside(rtas_args_t * pArgs)
	{
	int retVal = bmc_get_flashside();
	pArgs->args[pArgs->nargs] = retVal;
	}

	void
	rtas_flash_test(rtas_args_t * pArgs)
	{
	pArgs->args[pArgs->nargs] = -1;
	}

	void
	rtas_system_reboot(rtas_args_t * pArgs)
	{
	bmc_system_reboot();
	pArgs->args[pArgs->nargs] = -1;
	}

	void
	rtas_power_off(rtas_args_t * pArgs)
	{
	bmc_power_off();
	pArgs->args[pArgs->nargs] = -1;
	}

	void
	rtas_get_blade_descr(rtas_args_t * pArgs)
	{
	uint8_t buffer = (uint8_t ) (uint64_t) pArgs->args[0];
	uint32_t maxlen = pArgs->args[1];
	uint32_t retlen = 0;
	uint32_t retval = bmc_get_blade_descr(buffer, maxlen, &retlen);
	pArgs->args[pArgs->nargs] = retlen;
	pArgs->args[pArgs->nargs + 1] = retval;
	}

	// for JS20 cannot read blade descr
	static uint32_t
	dummy_get_blade_descr(uint8_t dst, uint32_t maxlen, uint32_t len)
	{
	// to not have a warning we need to do _something_ with *dst and maxlen...
	dst = dst;
	maxlen = maxlen;
	*len = 0;
	return -1;
	}

	/* read flashside from register */
	short
	reg_get_flashside(void)
	{
	short retVal;
	uint8_t val = load8_ci(0xf4003fe3);
	if (val & 0x80) {
	// temp
	retVal = 1;
	} else {
	// perm
	retVal = 0;
	}
	return retVal;
	}

	void
	rtas_init(void)
	{
	io_init();
	if (u4Flag) {
	bmc_system_reboot = ipmi_system_reboot;
	bmc_power_off = ipmi_power_off;
	bmc_set_flashside = ipmi_set_flashside;
	bmc_get_flashside = reg_get_flashside;
	bmc_stop_bootwatchdog = ipmi_oem_stop_bootwatchdog;
	bmc_set_bootwatchdog = ipmi_oem_set_bootwatchdog;
	bmc_read_vpd = ipmi_oem_read_vpd;
	bmc_write_vpd = ipmi_oem_write_vpd;
	bmc_get_blade_descr = ipmi_oem_get_blade_descr;
	} else {
	bmc_system_reboot = i2c_system_reboot;
	bmc_power_off = i2c_power_off;
	bmc_set_flashside = i2c_set_flashside;
	bmc_get_flashside = i2c_get_flashside;
	bmc_stop_bootwatchdog = i2c_stop_bootwatchdog;
	bmc_set_bootwatchdog = i2c_set_bootwatchdog;
	bmc_read_vpd = i2c_read_vpd;
	bmc_write_vpd = i2c_write_vpd;
	bmc_get_blade_descr = dummy_get_blade_descr;
	}
	}