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#==============================================================================
##
## vads.S
##
## MPC8260 VADS board hardware setup
##
##=============================================================================
#####ECOSGPLCOPYRIGHTBEGIN####
## -------------------------------------------
## This file is part of eCos, the Embedded Configurable Operating System.
## Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc.
## Copyright (C) 2002 Gary Thomas
##
## 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): nickg
## Contributors: wpd, gthomas
## Date: 2002-12-09
## Purpose: VADS MPC8260 board hardware setup
## Description: This file contains any code needed to initialize the
## hardware on the Motorola VADS MPC8260 board.
##
######DESCRIPTIONEND####
##
##=============================================================================
#include <pkgconf/hal.h>
#include <cyg/hal/arch.inc>
#include <cyg/hal/ppc_regs.h> /* on-chip resource layout, special */
#------------------------------------------------------------------------------
.globl hal_hardware_init
hal_hardware_init:
// It is possible that the board may experience a soft reset, which
// will cause this hal_hardware_init routine to be called. As a
// result of the soft reset, the IMMR, memory controller, system
// protection logic, interrupt controller and parallel I/O pins are
// NOT reset (MPC8260 User Manual p 5-2), and therefor we do not want to
// run the setup in this routine. Luckily, a hard reset will clear
// the NHR bit (bit 15) of the HID0 register. We will check for this bit
// to be 0 (implying a hard reset). If it is 0, we will run the
// initialization. If non-zero, we will skip the initialization.
//
// If we do the initialization, then we must set the NHR bit so that
// next time we hit this point in the routine, we can determine the type
// of reset.
//#ifdef DCSPRI_HAL_VADS_ROM_MLT_RAM
// Today, we will totally skip over all of this if we are using
// the RAM memory layout
// b hardware_init_done
//#endif
mfspr r22,CYGARC_REG_HID0 # Get contents of HID0
rlwinm r23,r22,0,15,15 #shift r0 by 0, mask HID0 with 0x10000, store in r23
cmpwi r23,0 # Compare r23 with 0
bne hardware_init_done
mfspr r31,CYGARC_REG_LR
#----------------------------------------------
# Load the IMMR register with the base address
#----------------------------------------------
addis r4,0,0x0471 # IMMR base addr = 0x04700000+10000. We add
# 0x10000 because using relative addressing
# in load and store instructions only allow a
# offset from the base of +/-32767.
addis r5,0,0x0470
addis r3,0,0x0F01
# The default IMMR base address was 0x0F0000000 as
# originally programmed into the Hard Reset
# Configuration Word.
stw r5,CYGARC_REG_IMM_IMMR(r3)
mfspr r21,CYGARC_REG_HID0 # get HID0 in R21
oris r21,r21,0x1 # Set bit 15 of HID0 (NHR)
mtspr CYGARC_REG_HID0,r21 # load HID0 with NHR set
#*******************************************
# Main System Clock Configuration Registers
#*******************************************
#-------------------------------------------------------------------------
# We only need to program the System Clock Control Register (SCCR). The
# System Clock Mode Register (SCMR) doesn t need to be programmed here
# because the MODCLK_HI bits in the Hard Reset Configuration Word and the
# MODCK pins dictate the values in the SCCR during power-on reset.
#-------------------------------------------------------------------------
#-------------------------------------------------------------------------
# Program the System Clock Control Register (SCCR).
#
# - Bits 0 - 28 Reserved. Clear to 0.
#
# - CLPD (CPM Low Power Disable) = 0 =
#
# CPM does not enter low power mode when the core enters low power
# mode.
#
# - DFBRG (Division Factor of BRGCLK) = 01 - Divide by 8.
#
#-------------------------------------------------------------------------
addis r3,0,0x0000
ori r3,r3,0x0001 # SCCR = 0x00000001
stw r3,CYGARC_REG_IMM_SCCR(r4)
#~~~~~~~~~~~~~~~~~~~~
# Initialize the SIU
#~~~~~~~~~~~~~~~~~~~~
bl init_siu
#~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
# Initialize the memory controller and SDRAM
#~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
bl init_memc
mtspr CYGARC_REG_LR,r31 # restore original Link Register value
hardware_init_done:
bclr 20,0
#########################################################################
# Function: init_siu
#
# Description: Initializes the System Interface Unit
#
# History:
#
#
#########################################################################
init_siu:
#-----------------------------------------------------------------------
# Program the System Protection Control Register with the following
# values:
#
# - SWTC (Software Watchdog Timer Count) = 0xFFFF = programmed to max
# count value.
#
# - BMT (Bus Monitor Timing) = 0xFF = Set to max timeout period.
#
# - PBME (60x Bus Monitor Enable) = 1 = enabled.
#
# - LBME (Local Bus Monitor Enable) = 1 = enabled.
#
# - Bits 26-28 Reserved. Set to 0.
#
# - SWE (Software Watchdog Enabled) = 0 = disabled for now. User will
# have to enable this in a non-debug application.
#
# - SWRI (Software Watchdog Reset/Interrupt Select) = 1 = Software
# watchdog timeout or bus monitor time-out causes a soft reset.
#
# - SWP (Software Watchdog Prescale) = 1 = clock is prescaled.
#-----------------------------------------------------------------------
addis r3,0,0xFFFF
ori r3,r3,0xFFC3 # SYPCR = 0xFFFFFFC3
stw r3,CYGARC_REG_IMM_SYPCR(r4)
#-------------------------------------------------------------------------
# Program the Bus Configuration Register. The details are as follows:
#
# - EBM (External Bus Mode) = 0 = Single MPC8260 bus mode is assumed.
#
# - APD (Address Phase delay) = 001 =
#
# One address tenure wait states for address operations initiated by
# a 60x bus master.
#
# - L2C (Secondary Cache Controller) = 0 = No secondary cache controller
# is assumed.
#
# - L2D (L2 cache hit Delay) = 000 = This is a don t care because we re
# not using the L2 cache.
#
# - PLDP (PipeLine maximum Depth) = 0 = The pipeline max depth is one.
#
# - Bits 9-11 = Reserved. Set to 0.
#
# - ETM (Compatibility Mode enable) = 1 = Extended transfer mode is
# enabled.
#
# - LETM (Local Bus Compatibility Mode Enable) = 1 =
#
# Extended transfer mode is enabled on the local bus.
#
# - EPAR (Even Parity) = 0 = This is a do not care.
#
# - LEPAR (Local Bus Even Parity) = 0 = This is a do not care.
#
# - Bits 16-20 = Reserved. Set to 0.
#
# - EXDD (External Master Delay Disable) = 0 =
#
# The memory controller inserts one wait state between the assertion
# of TS and the assertion of CS when an external master accesses an
# address space controlled by the memory controller.
#
# - Bits 22-26 = Reserved. Set to 0.
#
# - ISPS (Internal Space Port Size) = 0 =
#
# MPC8260 acts as a 64-bit slave to external master accesses to its
# internal space.
#
# - Bits 28-31 = Reserved. Set to 0.
#
#-------------------------------------------------------------------------
addis r3,0,0x100c
stw r3,CYGARC_REG_IMM_BCR(r4)
#-------------------------------------------------------------------------
# Program the 60x Bus Arbiter Configuration Register. The details are as
# follows:
#
# - Bits 0-1 = Reserved. Set to 0.
#
# - DBGD (Data Bus Grant Delay) = Minimum of zero wait states for PowerPC
# master-initiated data operations. This
# is the minimum delay between TS/ and
# DBG/.
#
# - Bits 3 = Reserved. Set to 0.
#
# - PRKM (Parking Master) = 0010 = CPM is at a low request level for the
# parked master.
#
#-------------------------------------------------------------------------
addi r3,0,0x0002
stb r3,CYGARC_REG_IMM_PPC_ACR(r4)
#-------------------------------------------------------------------------
# Program the 60x Bus Arbitration-Level[High] Register. The priority for
# potential bus masters are defined by locating the value associated with
# a particular master from the PRKM field in the PPC_ACR register and
# inserting its value in the priority field. Priority field 0 is the
# highest priority and the lowest is Priority field 15 in the PPC_ALRH
# register.
#
# - Priority Field 0 = 0000 = CPM high request level
#
# - Priority Field 1 = 0001 = CPM middle request level
#
# - Priority Field 2 = 0010 = CPM low request level
#
# - Priority Field 3 = 0110 = Internal Core
#
# - Priority Field 4 = 0111 = External Master 1
#
# - Priority Field 5 = 1000 = External Master 2
#
# - Priority Field 6 = 1001 = External Master 3
#
# - Priority Field 7 = 0011 = Reserved
#
#-------------------------------------------------------------------------
addis r3,0,0x0126
ori r3,r3,0x7893
stw r3,CYGARC_REG_IMM_PPC_ALRH(r4)
#------------------------------------------------------------------------
#
# First program the SIUMCR. The details are as follows:
#
# - BBD (Bus Busy Disable) = 0 = [ABB/]/[IRQ2] pin is ABB/ and [DBB/]/IRQ2
# pin is DBB/.
#
# - ESE (External Snoop Enable = 0 = [GPL/]/[IRQ1/] pin is IRQ1/
#
# - PBSE (Parity Byte Select Enable) = 0 = Parity byte select is disabled.
#
# - CDIS (Core DISable) = 0 = The PowerQUICCII CPU core is enabled.
#
# - DPPC (Data Parity Pins Configuration) = 10 =
#
# Gives the following pin meanings: DP(0)|RSRV/|EXT_BR2/ = RSRV/
# DP(1)|IRQ1/|EXT_BG2/ = IRQ1/
# DP(2)|TLBISYNC/|IRQ2/ = TLBISYNC/
# DP(3)|IRQ3/ = IRQ3/
# DP(4)|IRQ4/ = IRQ4/
# DP(5)|TBEN/|IRQ5 = TBEN/
# DP(6)|CSE(0)|IRQ6/ = CSE(0)
# DP(7)|CSE(1)|IRQ7/ = CSE(1)
#
# - L2CPC (L2 Cache Pins Configuration) = 00 =
#
# Gives the following pin meanings: CI/|BADDR(29)|IRQ2/ = CI/
# WT/|BADDR(30)|IRQ3/ = WT/
# L2_HIT/|IRQ4 = L2_HIT/
#
# CPU_BG/|BADDR(31)
# |IRQ5/ = CPU_BG/
#
# - LBPC (Local Bus Pins Configuration) = 00 =
#
# Local Bus pins function as local bus.
#
# - APPC (Address Parity Pins Configuration) = 10 =
#
# Gives the following pin meanings: MODCK1|AP(1)|TC(0) = BNKSEL(0)
# MODCK2|AP(2)|TC(1) = BNKSEL(1)
# MODCK3|AP(3)|TC(2) = BNKSEL(2)
# IRQ7/|APE/|INT_OUT/ = IRQ7/+INT_OUT/
# CS11/|AP(0) = CS11/
#
# - CS10PC (Chip Select 10-pin Configuration) = 00 =
#
# CS10/|BCTL1/|DBG_DIS/ = CS10/
#
# - BCTLC (Buffer Control Configuration) = 00 =
#
# BCTL0 pin is used as W|R/ control. BCTL1 is used as OE/ control if
# BCTL1 was connected to its alternate pin.
#
# - MMR (Mask Masters Requests) = 00 = No masking on bus request lines.
#
# - LPBSE (Local Bus Parity Byte Select Enable) = 0
#
# Parity byte select is disabled.
#
# Bits 19-31 are reserved and set to 0.
#
#------------------------------------------------------------------------
#--------------------------------------------------------------------------
# Program the 60x Bus Transfer Error Status and Control Register 1. The
# details are as follows:
#
# - DMD (Data Errors Disable) = 1 =
#
# Disable all data errors on the 60x bus. Also parity single and double
# ECC error.
#
# - All other bits are either status or reserved bits. All reserved bits
# should be set to 0.
#--------------------------------------------------------------------------
addis r3,0,0x0000
ori r3,r3,0x4000
stw r3,CYGARC_REG_IMM_TESCR1(r4)
#--------------------------------------------------------------------------
# Program the Local Bus Transfer Error Status and Control Register 1. The
# details are as follows:
#
# - DMD (Data Errors Disable) = 1 =
#
# Disable parity errors on the Local bus.
#
# - All other bits are either status or reserved bits. All reserved bits
# should be set to 0.
#--------------------------------------------------------------------------
addis r3,0,0x0000
ori r3,r3,0x4000
stw r3,CYGARC_REG_IMM_LTESCR1(r4)
#-------------------------------------------------------------------------
# First, program the Memory Periodic Timer Prescaler Register (MPTPR).
# Finding the value to this ties in with the desired SDRAM Refresh
# Timer (PSRT) value and the required Refresh Command interval for
# refreshing each row. The Refresh Command interval is found by
# determining the number of rows on the SDRAM device. In this case
# its 2048. The "total time between refresh" value in the AC characteristic
# section of the data sheet is 32.8 msec. This value is divided by the
# number of rows to give the number of Refresh commands that needs to be
# sent in a 32.8 msec interval. This value is 32.8 Msec/2048 = 16.02 usec.
# Due to probable contention from time to time with other memory
# controller bus requests, lets make the refresh command interval to be
# around 15.5 usec.
#
# Now let us divide the input VADs system clock by 64 (somewhat arbitrary).
# If this is our prescaler value then the input frequency to the Refresh
# timer is 1.031 Mhz. Using the formula:
#
# Timer Period = PSRT
# ----
# F(MPTC)
#
# - Where F(MPTC) is the output from the MPT Prescaler block
# or 66 Mhz/64 = 1.031 Mhz.
#
# - Timer Period = 15.5 usec
#
# The PSRT value would be approximately 16.
#
# The clock distribution block diagram looks like this:
#
# ---------- ------------- ----------- -------------
# | Clock | | MPT | | SDRAM | | Refresh |
# | Gen. |-----| Prescaler |---------| Refresh |----| Command |
# | 66 Mhz | ------------- | Timer | | Logic in |
# | on Vads | ----------- | Mem.Cont. |
# | Board | -------------
# -----------
#
#-------------------------------------------------------------------------
addi r5,0,0x4000 # load 0x40 or 64 into the PTP field of MPTPR
sth r5,CYGARC_REG_IMM_MPTPR(r4) # store half word - bits[16-31]
#-----------------------
# return from init_siu
#-----------------------
bclr 20,0 # jump unconditionally to effective address in Link
# register
#########################################################################
# Function: init_memc
#
# Description:
#
# The following registers directly control the memory controllers
# operation:
#
# BR0-BR11 - Base Register Banks 0-11
# OR0-OR11 - Option Register Banks 0-11
# PSDMR - 60x bus SDRAM machine mode register
# LSDMR - Local bus SDRAM machine mode register
# MAMR - UPMA mode register
# MBMR - UPMB mode register
# MCMR - UPMC mode register
# MDR - Memory data register
# MAR - Memory address register
# MPTPR - Memory periodic timer pre-scaler register
# PURT - 60x bus assigned UPM refresh timer
# PSRT - 60x bus assigned SDRAM refresh timer
# LURT - Local Bus assigned UPM refresh timer
# LSRT - Local Bus assigned SDRAM refresh timer
#
# This example will program the following registers. The rest will remain at
# their default values.
#
# BR0 - Base Register for Flash Memory
# OR0 - Option Register for Flash Memory
# BR1 - Base Register for BCSR (Board Control and Status Registers)
# OR1 - Option Register for BCSR
# BR2 - Base Register for 60x SDRAM
# OR2 - Option Register for 60x SDRAM
# BR3 - Base Register for 60x Local Bus SDRAM
# OR3 - Option Register for 60x Local Bus SDRAM
# PSDMR - 60x bus SDRAM machine mode register
# LSDMR - Local bus SDRAM machine mode register
# MPTPR - Memory periodic timer pre-scaler register
# PSRT - 60x bus assigned SDRAM refresh timer
# LSRT - Local Bus assigned SDRAM refresh timer
#
#
# History:
#
#########################################################################
init_memc:
mfspr r30,CYGARC_REG_LR # Save the Link Register value. The link registers
# value will be restored so that this function
# can return to the calling address.
bl init_flash # 8 Mbyte of flash memory
bl init_bcsr # Board Control and Status Registers
bl init_local_sdram # Local Bus SDRAM
bl init_60x_sdram # Main 60x Bus SDRAM
#-----------------------
# return from init_memc
#-----------------------
mtspr CYGARC_REG_LR,r30 # restore original Link Register value
bclr 20,0 # jump unconditionally to effective address in Link
# register
############################################################################
# Function: init_flash
#
# Description: This function programs Base Register 0 and Option Register 0
# designating bank 0 for the 8Mbyte flash SIMM on the VADS
# board. Programming these two registers describes how the
# MPC8260 will inter-operate with this memory space and thus
# this memory device.
#
# History:
#
############################################################################
init_flash:
#-------------------------------------------------------------------------
# Base Register 0 (BR0): Bank 0 is assigned to the 8Mbyte (2M X 32)
# flash that resides on the MPC8260 VADS board.
# The particulars are defined here.
#
# BA (Base Address) = 0xFF80+0b for a total of 17 address bits. This value
# represents the upper 17 bits of the base address.
#
# Bits 17-18 reserved. = 00
#
# PS (Port Size) = 11b = 32 bit port size
#
# DECC (Data Error Correction and Checking) = 00 = Data errors checking
# Disabled.
#
# WP (Write Protect) = 0 = both read and write accesses are allowed
#
# MS (Machine Select) = 000 = General Purpose Chip Select Machine (GPCM)
# for 60x bus Selected
#
# EMEMC (External Memory Controller Enable) = 0 = Accesses are handled by
# the memory controller
# according to MSEL.
#
# ATOM (Atomic Operation) = 00 = The address space controlled by the
# memory controller bank is not used for
# atomic operations.
#
# DR (Delayed Read) = 0 = Normal operation.
#
# V (Valid Bit) = 1 = Valid bit set
#-------------------------------------------------------------------------
#define nPFHACK
#ifdef PF_HACK // move Flash from 0xFF800000 to 0xFE000000
addis r3,0,0xFE00 # R3 holds the value temporarily
#else
addis r3,0,0xFF80 # R3 holds the value temporarily
#endif
ori r3,r3,0x1801
#-------------------------------------------------------------------------
# Option Register 0 (OR0) for GPCM use: further flash definitions
#
# AM (Address Mask) = 0xFF80+0b = We have masked the upper 9 bits which
# defines a 8 Mbyte memory block.
#
# Bits 17-19 Reserved - set to 000.
#
# CSNT (Chip Select Negation Time) = 1 = CS/|WE/ are negated a quarter
# of a clock early.
#
# ACS (Address To Chip-Select Setup) = 00 = CS/ is output the same time as
# the addr lines.
#
# Bit 23 Reserved - set to 0.
#
# SCY (Cycle Length In Clocks) = 0011 = Add a 3 clock cycle wait state
#
# SETA (External Transfer Acknowledge) = 0 = PSDVAL/ is generated
# internally by the memory
# controller unless GTA/ is
# asserted earlier externally.
#
# TRLX (Timing Relaxed) = 1 = Relaxed timing is generated by the GPCM.
#
# EHTR (Extended Hold Time On Read Accesses) = 1 =
#
# Extended hold time is generated by the memory controller. An idle
# clock cycle is inserted between a read access from the current bank
# and any write or read access to a different bank.
#
# Bit 31 Reserved - set to 0.
#-------------------------------------------------------------------------
#ifdef PF_HACK // move Flash from 0xFF800000 to 0xFE000000
addis r5,0,0xFE00 # R5 holds the value temporarily
#else
addis r5,0,0xFF80 # R5 holds the value temporarily
#endif
ori r5,r5,0x0836
#------------------------------------------------------------------------
# It is important to note the order in which OR0 and BR0 are programmed.
# When coming out of reset and CS0 is the global chip select, OR0 MUST be
# programmed AFTER BR0. In all other cases BRx would be programmed after
# ORx.
#------------------------------------------------------------------------
#------------------
# Write the values
#------------------
stw r3,CYGARC_REG_IMM_BR0(r4)
stw r5,CYGARC_REG_IMM_OR0(r4)
bclr 20,0 # jump unconditionally to effective address in Link
# register
#########################################################################
# Function: init_bcsr
#
# Description: This function programs Base Register 1 and Option Register 1
# designating bank 1 for BCSR0, BCSR1, and BCSR2 on the VADS
# board. BCSR stands for Board Control and Status Register.
# This space is treated as general I/O. Programming the
# following 2 registers describes how the MPC8260 will inter-
# operate with this memory space.
#
# History:
#
# Jan 9/99 jay
#
#########################################################################
init_bcsr:
#-------------------------------------------------------------------------
# Base Register 1 (BR1): Bank 1 is assigned to the Board Control and
# Status Registers (BCSRs). There are 3
# that resides on the MPC8260 VADS board.
# The particulars are defined here.
#
# BA (Base Address) = 0x0450+0b for a total of 17 address bits. This value
# represents the upper 17 bits of the base address.
#
# Bits 17-18 reserved. = 00
#
# PS (Port Size) = 11b = 32 bit port size
#
# DECC (Data Error Correction and Checking) = 00 = Data errors checking
# Disabled.
#
# WP (Write Protect) = 0 = both read and write accesses are allowed
#
# MS (Machine Select) = 000 = General Purpose Chip Select Machine (GPCM)
# for 60x bus Selected
#
# EMEMC (External Memory Controller Enable) = 0 = Accesses are handled by
# the memory controller
# according to MSEL.
#
# ATOM (Atomic Operation) = 00 = The address space controlled by the
# memory controller bank is not used for
# atomic operations.
#
# DR (Delayed Read) = 0 = Normal operation.
#
# V (Valid Bit) = 1 = Valid bit set
#-------------------------------------------------------------------------
addis r3,0,0x0450 # R3 holds the value temporarily
ori r3,r3,0x1801
#-------------------------------------------------------------------------
# Option Register 1 (OR1) for GPCM use: further BCSR definitions
#
# AM (Address Mask) = 0xFFFF +1b = We have masked the upper 17 bits which
# which defines a 32 Kbyte memory block.
#
# Bits 17-19 Reserved - set to 000.
#
# CSNT (Chip Select Negation Time) = 0 = CS/|WE/ are negated normally.
#
# ACS (Address To Chip-Select Setup) = 00 = CS/ is output at the same
# time as the addr lines.
#
# Bit 23 Reserved - set to 0.
#
# SCY (Cycle Length In Clocks) = 0001 = Add a 1 clock cycle wait state
#
# SETA (External Transfer Acknowledge) = 0 = PSDVAL/ is generated
# internally by the memory
# controller unless GTA/ is
# asserted earlier externally.
#
# TRLX (Timing Relaxed) = 0 = Normal timing is generated by the GPCM.
#
# EHTR (Extended Hold Time On Read Accesses) = 0 = Normal timing is
# generated by the memory
# controller
#
# Bit 31 Reserved - set to 0.
#-------------------------------------------------------------------------
addis r5,0,0xFFFF # R5 holds the value temporarily
ori r5,r5,0x8010
#------------------
# Write the values
#------------------
stw r5,CYGARC_REG_IMM_OR1(r4)
stw r3,CYGARC_REG_IMM_BR1(r4)
bclr 20,0 # jump unconditionally to effective address in Link
# register
#########################################################################
# Function: init_60x_sdram
#
# Description: This function programs the 16 Mbyte SDRAM DIMM on the VADS
# board. This memory functions as the RAM for the 603 core and
# is connected to the 60x bus. Base and Option Register 2 are
# used as well as the SDRAM Machine #1 and Chip Select #2.
#
# History:
#
# Jan /9/99 jay Initial Release
#
#########################################################################
init_60x_sdram:
##################
# Program Refresh
##################
#-------------------------------------------------------------------------
# Program the 60x Bus Assigned SDRAM Refresh Timer (PSRT).
#-------------------------------------------------------------------------
addi r5,0,0x0010 # load 0x10 or 16
stb r5,CYGARC_REG_IMM_PSRT(r4) # store byte - bits[24-31]
#########################
# Program Bank Registers
#########################
#-------------------------------------------------------------------------
# Base Register 2 (BR2): Bank 2 is assigned to the 16 Mbyte 60x SDRAM DIMM
# that resides on the MPC8260 VADS board. The
# particulars are defined here.
#
# - BA (Base Address) = 0x0000+0b for a total of 17 address bits. This
# value represents the upper 17 bits of the base
# address.
#
# - Bits 17-18 reserved. = 00 = cleared to 0.
#
# - PS (Port Size) = 00b = 64 bit port size
#
# - DECC (Data Error Correction and Checking) = 00 = Data errors checking
# Disabled.
#
# - WP (Write Protect) = 0 = both read and write accesses are allowed
#
# - MS (Machine Select) = 010 = SDRAM Machine for 60x bus Selected
#
# - EMEMC (External Memory Controller Enable) = 0 =
#
# Accesses are handled by the memory controller according to MSEL.
#
# - ATOM (Atomic Operation) = 00 = The address space controlled by the
# memory controller bank is not used for
# atomic operations.
#
# - DR (Delayed Read) = 0 = Normal operation.
#
# - V (Valid Bit) = 1 = Valid bit set
#-------------------------------------------------------------------------
addis r3,0,0x0000 # R3 holds the value temporarily
ori r3,r3,0x0041
#-------------------------------------------------------------------------
# Option Register 2 (OR2) for SDRAM Machine use: further SDRAM definitions
#
# - USDAM (Upper SDRAM Address Mask) = 11111b =
#
# We have masked all 5 bits which defines a maximum 128 Mbyte block.
# Note that since the maximum SDRAM block size is 128 Mbyte, this field
# should always be 11111b.
#
# - SDAM (SDRAM Address Mask) = 1110000b = 16 Mbyte block.
#
# - LSDAM (Lower SDRAM Address Mask) = 00000b = Minimum of 1 Mbyte size.
#
# - BPD (Banks Per Device) = 00 = 2 internal banks per device.
#
# - ROWST (Row Start Address Bit) = 011 = A9 being the row start address
# bit.
#
# - Bit 22 Reserved - set to 0.
#
# - NUMR (Number of Row Address Lines) = 010 = 11 row address lines.
#
# - PMSEL (Page Mode Select) = 1 = Reserved
#
# - IBID (Internal bank interleaving within same device disable) = 0 =
#
# Bank interleaving allowed.
#
# - AACKR (AACK/ release) = 0 = Normal operation.
#
# - Bits 29-31 Reserved - set to 0.
#-------------------------------------------------------------------------
#define nCYGHWR_HAL_POWERPC_VADS_64MB_DIMM
#ifdef CYGHWR_HAL_POWERPC_VADS_64MB_DIMM
addis r5,0,0xFC00 # R5 holds the value temporarily
ori r5,r5,0x28E0
#else
addis r5,0,0xFF00 # R5 holds the value temporarily
ori r5,r5,0x0CA0
#endif
#------------------
# Write the values
#------------------
stw r5,CYGARC_REG_IMM_OR2(r4)
stw r3,CYGARC_REG_IMM_BR2(r4)
###########################################
# Perform Initialization sequence to SDRAM
###########################################
#-------------------------------------------------------------------------
# Program the PowerPC SDRAM Mode Registr (PSDMR). This register is used
# to configure operations pertaining to SDRAM. Program the PSDMR, turning
# off refresh services and changing the SDRAM operation to "Precharge all
# banks". Then do a single write to an arbitrary location. Writing 0xFF
# to address 0 will do the trick.
#
# - Bit 0 is reserved. Set to 0.
#
# - RFEN (Refresh Enable) = 0 = Refresh services not required. This bit
# will be set later in this function as a
# last step.
#
# - OP (SDRAM Operation) = 000 = Precharge all banks.
#
# - SDAM (Address Multiplex Size = 001 =
#
# Coming up the value for this field is one of the most confusing
# and non-intuitive steps in the SDRAM programming process. This is how
# it works... The SDRAM device is a 16 Mbit DIMM that has a data width
# of 64 bits or 8 bytes. The bank size is 64 bits so the SDRAM will
# ignore the least significant 3 bits. Given this information and
# knowing that the number of row address lines is 11 and the column
# addresses is 9 and also knowing that the row addresses must be
# multiplexed, write out the following:
#
# addresses ignored by SDRAM : A29 A30 A31
#
# column addresses: A20 A21 A22 A23 A24 A25 A26 A27 A28
#
# row addresses: A9 A10 A11 A12 A13 A14 A15 A16 A17 A18 A19
#
# When the memory controller multiplexes the addresses it puts the
# column addresses out on the actual physical pins that matches its
# corresponding effective address bits.
#
# According to the SDRAM Address Multiplexing table in the memory
# controller section of the manual, SDAM selection of 001 fits the
# address layout given above. Because its the row that is multiplexed on
# designated column address pins, the row addresses are put out on the
# following column pins:
#
# column ----------------------> A20 A21 A22 A23 A24 A25 A26 A27 A28
# | | | | | | | | |
# row address -----------> A9 A10 A11 A12 A13 A14 A15 A16 A17 A18 A19
# on corresponding
# column pins.
#
# Column pins A19, A18, and A17 were not connected to the DIMM device so
# A9 and A10 as well as the bank select address which is A8 are put out
# on their respective pins because it was decided that these address
# pins would be directly connected to the DIMM. That is, A10 of the real
# address is put out on the A10 pin, A9 on the A9 pin, etc.
#
# As a final note on this subject, the row address is output on the
# address bus first on the actual column address pins according to the
# multiplexing scheme in the SDRAM address multiplexing table, then the
# column address follows which makes up the most significant part of the
# real address which is connected to the memory device.
#
# Any entries in the multiplexing table that show a "-" means nothing is
# multiplexed on the physical pins shown on the top row of the table
# and therefore any part of the row address will also show up on its
# respective physical pin if this pin is not used for multiplexing. For
# example, for a SDAM of 001, the multiplexing table shows that A13
# through A0 are not multiplexed because they have "-" in their
# respective boxes. This means that A13 through A5 of the real address
# will show up multiplexed on address pins A22 through A14 and A13
# through A0 of the real address will also show up on their actual
# respective physical pins.
#
# - BSMA (Bank Select Multiplexed Address line) = 011 = A15-A17
#
# BSMA determines how BNKSEL[0:2] will operate. This SDRAM has only 2
# banks, so only BANKSEL2 is of concern because its the least
# significant bit. BANKSEL2 should be programmed to operate as physical
# pin A17. Because we are multiplexing 9 column addresses, it will
# actually behave as A8.
#
# - SDA10 ("A10 Control") = 011 =
#
# A9 is the address pin used for the activate command. The A10/AP pin
# the SDRAM needs to act as a command line during on phase of the
# access and as an address line in the other phase. The SDA10 pin on
# MPC8260 takes care of this function. Instead of connecting the
# A10/AP pin to A9 on the address bus, connect it to SDA10 and program
# SDA10 to function as A9.
#
# - RFRC (ReFresh ReCovery) = 101 =
#
# Once a refresh request is granted, the memory controller begins
# issuing auto-refresh commands to each device associated with the
# refresh timer in one clock intervals. After the last REFRESH
# command is issued, the memory controller waits for 7 clocks before
# the ACTIVATE command and before normal read/write operations can
# resume.
#
# - PRETOACT (PREcharge TO ACTivate interval) = 011 =
#
# Wait 3 clock cycles before an activate command. This parameter is
# determined by the requirements of the SDRAM at a particular clock
# speed.
#
# - ACTTORW (ACTivate TO Read/Write interval) = 010 = 2 clock cycles.
#
# - BL (Burst Length) = 0 = SDRAM burst length is 4. This is programmed
# into the SDRAM via the MRS commmand.
#
# - LDOTOPRE (Last Data Out TO PREcharge) = 01 =
#
# The delay required from the last data out to precharge state is 1 clock
# cycle. This parameter is determined by the requirements of the SDRAM at
# a particular clock speed.
#
# - WRC (Write Recovery Time) = 01 =
#
# Time needed to elapse before another operation is 1 clock cycle. This
# parameter is determined by the requirements of the SDRAM at a
# particular clock speed.
#
# - EAMUX (External Address MUltipleXing) = 0 No external address
# multiplexing.
#
# - BUFCMD (Buffer Control Lines) = 0 = Normal timing for the control
# lines.
#
# - CL (CAS Latency) = 10 =
#
# CAS latency is 2. Two cycles after column address is registered, data
# is valid. This parameter is determined by the requirements of the
# SDRAM at a particular clock speed.
#
#-------------------------------------------------------------------------
#ifdef CYGHWR_HAL_POWERPC_VADS_64MB_DIMM
addis r3,0,0x294E
ori r3,r3,0xB452
#else
addis r3,0,0x296E
ori r3,r3,0xB452
#endif
stw r3,CYGARC_REG_IMM_PSDMR(r4)
addis r0,0,0
addi r3,0,0x00FF # Load 0x000000FF into r3
stb r3,0(r0) # Write 0xFF to address 0 - bits [24-31]
#-------------------------------------------------------------------------
# Program the PSDMR keeping refresh services off and changing the
# SDRAM operation to "CBR Refresh". This step is responsible for issuing
# a minimum of 8 auto-refresh commands. This is done by the SDRAM machine
# by issuing the CBR Refresh command by programming the OP field of the
# PSDMR register and writing 0xFF 8 times to an arbitrary address.
#-------------------------------------------------------------------------
#ifdef CYGHWR_HAL_POWERPC_VADS_64MB_DIMM
addis r3,0,0x094E
ori r3,r3,0xB452
#else
addis r3,0,0x096E
ori r3,r3,0xB452
#endif
stw r3,CYGARC_REG_IMM_PSDMR(r4)
#------------------------------------------
# Loop 8 times, writing 0xFF to address 0
#------------------------------------------
addi r6,0,0x0008
mtspr CYGARC_REG_CTR,r6 # Load CTR with 8. The CTR special purpose
# is spr 9
addi r3,0,0x00FF # Load 0x000000FF into r3
write_loop:
stb r3,0(r0) # Write 0xFF to address 0 - bits [24-31]
bc 16,0,write_loop # Decrement CTR, then branch if the decremented CTR
# is not equal to 0
#-------------------------------------------------------------------------
# Program the PSDMR again turning off refresh services and changing the
# SDRAM operation to "Mode Register Write". Then do a single write to an
# arbitrary location. The various fields that will be programmed in the
# mode register on the SDRAM were specified in fields of the PSDMR, like
# the BR (burst length) and the CL (CAS Latency) field.
#-------------------------------------------------------------------------
#ifdef CYGHWR_HAL_POWERPC_VADS_64MB_DIMM
addis r3,0,0x194E
ori r3,r3,0xB452
#else
addis r3,0,0x196E
ori r3,r3,0xB452
#endif
stw r3,CYGARC_REG_IMM_PSDMR(r4)
addi r3,0,0x00FF # Load 0x000000FF into r3
stb r3,0(r0) # Write 0xFF to address 0 - bits [24-31]
#-------------------------------------------------------------------------
# Program the PSDMR one last time turning on refresh services and changing
# the SDRAM operation to "Normal Operation".
#-------------------------------------------------------------------------
#ifdef CYGHWR_HAL_POWERPC_VADS_64MB_DIMM
addis r3,0,0x414E
ori r3,r3,0xB452
#else
addis r3,0,0x416E
ori r3,r3,0xB452
#endif
stw r3,CYGARC_REG_IMM_PSDMR(r4)
#----------------------------
# return from init_60x_sdram
#----------------------------
bclr 20,0 # jump unconditionally to effective address in Link
# register
#########################################################################
# Function: init_local_sdram
#
# Description: This function programs the 4 Mbytes of SDRAM on the Local
# Bus on the VADS board. This memory functions as storage for
# connection tables and data buffers for the CPM peripherals.
# Base and Option Register 4 are used. SDRAM Machine #2
# and Chip Select #4 is used in the memory controller.
#
# History:
#
# Jan 9/99 jay
#
#########################################################################
init_local_sdram:
##################
# Program Refresh
##################
#-------------------------------------------------------------------------
# Program the Local Bus Assigned SDRAM Refresh Timer (LSRT). Note that the
# MPTPR register was programmed in the init_siu function which also
# dictates the frequency to the LSRT block. Because the frequency rating
# for the local bus SDRAM is same as the 60x SDRAM DIMM, only the LSRT
# needs to be programmed and it is going to be the same as the PSRT
# register.
#-------------------------------------------------------------------------
addi r5,0,0x0010 # load 0x10 or 16
stb r5,CYGARC_REG_IMM_LSRT(r4) # store byte - bits[24-31]
#########################
# Program Bank Registers
#########################
#-------------------------------------------------------------------------
# Base Register 4 (BR4): Bank 4 is assigned to the 4 Mbyte Local SDRAM
# bank that resides on the MPC8260 VADS board. The
# particulars are defined here.
#
# - BA (Base Address) = 0x0400+0b for a total of 17 address bits. This
# value represents the upper 17 bits of the base
# address.
#
# - Bits 17-18 reserved. = 00 = cleared to 0.
#
# - PS (Port Size) = 11b = 32 bit port size
#
# - DECC (Data Error Correction and Checking) = 00 = Data errors checking
# Disabled.
#
# - WP (Write Protect) = 0 = both read and write accesses are allowed
#
# - MS (Machine Select) = 011 = SDRAM Machine for Local bus Selected
#
# - EMEMC (External Memory Controller Enable) = 0 =
#
# Accesses are handled by the memory controller according to MSEL.
#
# - ATOM (Atomic Operation) = 00 =
#
# The address space controlled by the memory controller bank is not
# used for atomic operations.
#
# - DR (Delayed Read) = 0 = Normal operation.
#
# - V (Valid Bit) = 1 = Valid bit set
#-------------------------------------------------------------------------
addis r3,0,0x0400 # R3 holds the value temporarily
ori r3,r3,0x1861
#-------------------------------------------------------------------------
# Option Register 4 (OR4) for SDRAM Machine use: further SDRAM definitions
#
# - USDAM (Upper SDRAM Address Mask) = 11111b =
#
# We have masked all 5 bits which defines a maximum 128 Mbyte block Note
# that since the maximum SDRAM block size is 128 Mbyte, this field
# should always be 11111b.
#
# - SDAM (SDRAM Address Mask) = 1111100b = 4 Mbyte block.
#
# - LSDAM (Lower SDRAM Address Mask) = 00000b = Minimum of 1 Mbyte size.
#
# - BPD (Banks Per Device) = 00 = 2 internal banks per device.
#
# - ROWST (Row Start Address Bit) = 101 = A11 being the row start address
# bit.
#
# - Bit 22 Reserved - set to 0.
#
# - NUMR (Number of Row Address Lines) = 010 = 11 row address lines.
#
# - PMSEL (Page Mode Select) = 0 = back-to-back page mode (normal
# operation).
#
# - IBID (Internal bank interleaving within same device disable) = 0 =
#
# Bank interleaving allowed.
#
# - AACKR (AACK/ release) = 0 = Normal operation.
#
# - Bits 29-31 Reserved - set to 0.
#-------------------------------------------------------------------------
addis r5,0,0xFFC0 # R5 holds the value temporarily
ori r5,r5,0x1480
#------------------
# Write the values
#------------------
stw r5,CYGARC_REG_IMM_OR4(r4)
stw r3,CYGARC_REG_IMM_BR4(r4)
###########################################
# Perform Initialization sequence to SDRAM
###########################################
#-------------------------------------------------------------------------
# Program the Local SDRAM Mode Registr (LSDMR). This register is used
# to configure operations pertaining to SDRAM on the Local bus. Turn off
# refresh services and change the SDRAM operation to "Precharge all banks".
# Then do a single write to an arbitrary location. Writing 0 top
# address 0 will do the trick.
#
# - Bit 0 is reserved. Set to 0.
#
# - RFEN (Refresh Enable) = 0 = Refresh services not required. This bit
# will be set later in this function as a
# last step.
#
# - OP (SDRAM Operation) = 101 = Precharge all banks.
#
# - SDAM (Address Multiplex Size = 000 =
#
# Coming up the value for this field is one of the most confusing
# and non-intuitive steps in the SDRAM programming process. This is how
# it works... The SDRAM device is a 4 Mbit chip set that has a data
# width of 32 bits or 4 bytes so the SDRAM will ignore the least
# significant 2 bits. Given this information and knowing that the
# number of row address lines is 11 and the column addresses is 8 and
# also knowing that the row addresses must be multiplexed, write out the
# following:
#
# addresses ignored by SDRAM : A30 A31
#
# column addresses: A22 A23 A24 A25 A26 A27 A28 A29
#
# row addresses: A11 A12 A13 A14 A15 A16 A17 A18 A19 A20 A21
#
# When the memory controller multiplexes the addresses it puts the
# column addresses out on the actual physical pins that matches its
# corresponding effective address bits.
#
# According to the SDRAM Address Multiplexing table in the memory
# controller section of the manual, SDAM selection of 000 fits the
# address layout given above. Because the row is what is multiplexed
# on designated column address pins, the row addresses are put out on the
# following column pins:
#
#. 8 column addresses
# |
# column ------------->A19 A20 A21|A22 A23 A24 A25 A26 A27 A28 A29
# | | | | | | | | | | |
#. 11 row addresses---->A11 A12 A13 A14 A15 A16 A17 A18 A19 A20 A21
# on corresponding
# column pins.
#
# The row address is output on the address bus first, then the column
# address.
#
# - BSMA (Bank Select Multiplexed Address line) = 100 = A16-A18
#
# For Local bus accesses, this field is a "do not care". BNKSEL[0:2]
# are associated with this field and these pins are only used for
# 60x compatible mode for 60x bus transactions.
#
# - SDA10 ("A10 Control") = 001 = A11 is the address pin used for the
# activate command.
#
# - RFRC (ReFresh ReCovery) = 101 =
#
# Once a refresh request is granted, the memory controller begins
# issuing auto-refresh commands to each device associated with the
# refresh timer in one clock intervals. After the last REFRESH
# command is issued, the memory controller waits for 7 clocks before
# the ACTIVATE command and before normal read/write operations can
# resume.
#
# - PRETOACT (PREcharge TO ACTivate interval) = 010 =
#
# Wait 2 clock cycles before an activate command.
#
# - ACTTORW (ACTivate TO Read/Write interval) = 010 = 2 clock cycles.
#
# - BL (Burst Length) = 1 = SDRAM burst length is 8. This is programmed
# into the SDRAM via the MRS commmand.
#
# - LDOTOPRE (Last Data Out TO PREcharge) = 00 =
#
# The delay required from the last data out to precharge state is 0 clock
# cycles.
#
# - WRC (Write Recovery Time) = 01 =
#
# Time needed to elapse before another operation is 1 clock cycle.
#
# - EAMUX (External Address MUltipleXing) = 0 No external address
# multiplexing.
#
# - BUFCMD (Buffer Control Lines) = 0 = Normal timing for the control
# lines.
#
# - CL (CAS Latency) = 10 = CAS latency is 2. Two cycles after column
# address is registered, data is valid.
#
#-------------------------------------------------------------------------
addis r3,0,0x2886
ori r3,r3,0xA522
stw r3,CYGARC_REG_IMM_LSDMR(r4)
addis r2,0,0x0400
addi r3,0,-1
stb r3,0(r2) # Write 0xFF to address 0x04000000
#-------------------------------------------------------------------------
# Program the LSDMR keeping refresh services off and changing the
# SDRAM operation to "CBR Refresh". This step is responsible for issuing
# a minimum of 8 auto-refresh commands. This is done by the SDRAM machine
# by issuing the CBR Refresh command by programming the OP field of the
# PSDMR register and writing 0xFF 8 times to an arbitrary address.
#-------------------------------------------------------------------------
addis r3,0,0x0886
ori r3,r3,0xA522
stw r3,CYGARC_REG_IMM_LSDMR(r4)
#--------------------------------------------------
# Loop 8 times, writing 0xFF to address 0x04000000
#--------------------------------------------------
addis r6,0,0
ori r6,r6,8
mtspr CYGARC_REG_CTR,r6 # Load CTR with 8.
addi r3,0,-1 # Load 0xFs into r3
write_loop1:
stb r3,0(r2) # Write 0 to address 0x04000000
bc 16,0,write_loop1 # Decrement CTR, then branch if the decremented CTR
# is not equal to 0
#-------------------------------------------------------------------------
# Program the LSDMR again turning off refresh services and changing the
# SDRAM operation to "Mode Register Write". Then do a single write to an
# arbitrary location. The various fields that will be programmed in the
# mode register on the SDRAM were specified in fields of the LSDMR, like
# the BR (burst length) and the CL (CAS Latency) field.
#-------------------------------------------------------------------------
addis r3,0,0x1886
ori r3,r3,0xA522
stw r3,CYGARC_REG_IMM_LSDMR(r4)
addi r3,0,-1
stb r3,0(r2) # Write 0xFF to address 0x04000000
#-------------------------------------------------------------------------
# Program the LSDMR one last time turning on refresh services and changing
# the SDRAM operation to "Normal Operation".
#-------------------------------------------------------------------------
addis r3,0,0x4086
ori r3,r3,0xA522
stw r3,CYGARC_REG_IMM_LSDMR(r4)
#------------------------------
# return from init_local_sdram
#------------------------------
bclr 20,0 # jump unconditionally to effective address in Link
# register
#------------------------------------------------------------------------------
# end of vads.S
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