gem5/system/alpha/palcode/platform_srcmax.s
Ali Saidi d7fba9784e The palcode will now build by simply typing make in this directory.
Most of the changes were to fix broken macros in platfrom_tlaser.s

palcode/Makefile:
    Completly new makefile to build palcode
palcode/ev5_alpha_defs.h:
    fixed a broken define
palcode/ev5_impure.h:
    macro fixes
palcode/platform_srcmax.s:
    manual macro expansion of broken macros... this file isn't needed to
    build tlaser palcode
palcode/platform_tlaser.s:
    lots of fixups to make the code assemble
2003-12-19 14:24:01 -05:00

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// build_fixed_image: not sure what means
// real_mm to be replaced during rewrite
// remove_save_state remove_restore_state can be remooved to save space ??
#define egore 0
#define acore 0
#define beh_model 0
#define ev5_p2 1
#define ev5_p1 0
#define ldvpte_bug_fix 1
#define spe_fix 0
#define osf_chm_fix 0
#define build_fixed_image 0
#define enable_p4_fixups 0
#define osf_svmin 1
#define enable_physical_console 0
#define fill_err_hack 0
#define icflush_on_tbix 0
#define max_cpuid 1
#define perfmon_debug 0
#define rax_mode 0
#define hw_rei_spe hw_rei
#include "ev5_defs.h"
#include "ev5_impure.h"
#include "ev5_alpha_defs.h"
#include "ev5_paldef.h"
#include "ev5_osfalpha_defs.h"
#include "fromHudsonMacros.h"
#include "fromHudsonOsf.h"
#include "dc21164FromGasSources.h"
#include "cserve.h"
#define ldlp ldl_p
#define ldqp ldq_p
#define stqp stq_p
#define stqpc stqp
#define pt_entInt pt_entint
#define pt_entArith pt_entarith
#define mchk_size ((mchk_cpu_base + 7 + 8) &0xfff8)
#define mchk_flag CNS_Q_FLAG
#define mchk_sys_base 56
#define mchk_cpu_base (CNS_Q_LD_LOCK + 8)
#define mchk_offsets CNS_Q_EXC_ADDR
#define mchk_mchk_code 8
#define mchk_ic_perr_stat CNS_Q_ICPERR_STAT
#define mchk_dc_perr_stat CNS_Q_DCPERR_STAT
#define mchk_sc_addr CNS_Q_SC_ADDR
#define mchk_sc_stat CNS_Q_SC_STAT
#define mchk_ei_addr CNS_Q_EI_ADDR
#define mchk_bc_tag_addr CNS_Q_BC_TAG_ADDR
#define mchk_fill_syn CNS_Q_FILL_SYN
#define mchk_ei_stat CNS_Q_EI_STAT
#define mchk_exc_addr CNS_Q_EXC_ADDR
#define mchk_ld_lock CNS_Q_LD_LOCK
#define osfpcb_q_Ksp pcb_q_ksp
#define pal_impure_common_size ((0x200 + 7) & 0xfff8)
#define RTCADD 0x160000
#define RTCDAT 0x170000
/* Serial Port (COM) Definitions: */
#define DLA_K_BRG 12 /* Baud Rate Divisor = 9600 */
#define LSR_V_THRE 5 /* Xmit Holding Register Empty Bit */
#define LCR_M_WLS 3 /* Word Length Select Mask */
#define LCR_M_STB 4 /* Number Of Stop Bits Mask */
#define LCR_M_PEN 8 /* Parity Enable Mask */
#define LCR_M_DLAB 128 /* Divisor Latch Access Bit Mask */
#define LCR_K_INIT (LCR_M_WLS | LCR_M_STB)
#define MCR_M_DTR 1 /* Data Terminal Ready Mask */
#define MCR_M_RTS 2 /* Request To Send Mask */
#define MCR_M_OUT1 4 /* Output 1 Control Mask */
#define MCR_M_OUT2 8 /* UART Interrupt Mask Enable */
#define MCR_K_INIT (MCR_M_DTR | \
MCR_M_RTS | \
MCR_M_OUT1 | \
MCR_M_OUT2)
#define SLOT_D_COM1 (0x140000)
#define COM1_RBR (SLOT_D_COM1 | (0x0 << 1)) /* Receive Buffer Register Offset */
#define COM1_THR (SLOT_D_COM1 | (0x0 << 1)) /* Xmit Holding Register Offset */
#define COM1_IER (SLOT_D_COM1 | (0x1 << 1)) /* Interrupt Enable Register Offset
*/
#define COM1_IIR (SLOT_D_COM1 | (0x2 << 1)) /* Interrupt ID Register Offset */
#define COM1_LCR (SLOT_D_COM1 | (0x3 << 1)) /* Line Control Register Offset */
#define COM1_MCR (SLOT_D_COM1 | (0x4 << 1)) /* Modem Control Register Offset */
#define COM1_LSR (SLOT_D_COM1 | (0x5 << 1)) /* Line Status Register Offset */
#define COM1_MSR (SLOT_D_COM1 | (0x6 << 1)) /* Modem Status Register Offset */
#define COM1_SCR (SLOT_D_COM1 | (0x7 << 1)) /* Scratch Register Offset */
#define COM1_DLL (SLOT_D_COM1 | (0x8 << 1)) /* Divisor Latch (LS) Offset */
#define COM1_DLH (SLOT_D_COM1 | (0x9 << 1)) /* Divisor Latch (MS) Offset */
#define BYTE_ENABLE_SHIFT 5
#define PCI_MEM 0x400
#ifdef SIMOS
#define OutPortByte(port,val,a,b)
#define InPortByte(port,val,a)
#else
#define OutPortByte(port,val,tmp0,tmp1) \
LDLI (tmp0, port); \
sll tmp0, BYTE_ENABLE_SHIFT, tmp0; \
lda tmp1, PCI_MEM(zero); \
sll tmp1, 29, tmp1; \
bis tmp0, tmp1, tmp0; \
lda tmp1, (val)(zero); \
sll tmp1, 8*(port & 3), tmp1; \
stl_p tmp1, 0x00(tmp0); \
mb
#define InPortByte(port,tmp0,tmp1) \
LDLI (tmp0, port); \
sll tmp0, BYTE_ENABLE_SHIFT, tmp0; \
lda tmp1, PCI_MEM(zero); \
sll tmp1, 29, tmp1; \
bis tmp0, tmp1, tmp0; \
ldl_p tmp0, 0x00(tmp0); \
srl tmp0, (8 * (port & 3)), tmp0; \
zap tmp0, 0xfe, tmp0
#endif
#define r0 $0
#define r1 $1
#define r2 $2
#define r3 $3
#define r4 $4
#define r5 $5
#define r6 $6
#define r7 $7
#define r8 $8
#define r9 $9
#define r10 $10
#define r11 $11
#define r12 $12
#define r13 $13
#define r14 $14
#define r15 $15
#define r16 $16
#define r17 $17
#define r18 $18
#define r19 $19
#define r20 $20
#define r21 $21
#define r22 $22
#define r23 $23
#define r24 $24
#define r25 $25
#define r26 $26
#define r27 $27
#define r28 $28
#define r29 $29
#define r30 $30
#define r31 $31
#ifdef SIMOS
#define DEBUGSTORE(c)
#define DEBUG_EXC_ADDR()
#else
#define DEBUGSTORE(c) \
lda r13, c(zero) ; \
bsr r25, debugstore
#define DEBUG_EXC_ADDR() \
bsr r25, put_exc_addr; \
DEBUGSTORE(13) ; \
DEBUGSTORE(10)
#endif /* SIMOS */
#define ALIGN_BLOCK \
.align 5
#define ALIGN_BRANCH \
.align 3
// This module is for all the OSF system specific code.
// This version is for the EV5 behavioral model.
// .sbttl "Edit History"
//+
// Who Rev When What
// ------------ --- ----------- --------------------------------
//
// [ deleted several pages of checking comments to make the file smaller - lance ]
//
// PALcode merge done here .... JRH ....8/30/94
// JM 1.00 1-aug-1994 Add support for pass2 to sys_perfmon code
// JM 1.01 2-aug-1994 Initialize cns_bc_config in reset
// JM 1.02 5-aug-1994 Add ARITH_AND_MCHK routine.
// Fix typo in bc_config init in rax reset flow.
// JM 1.03 19-aug-1994 BUG: sys_perfmon not generating mux control mask properly, overwriting counters 0 & 1;
// mode select masks messed up too.
//
// JH 1.03A 26-Oct-1994 Log PCI error2 register ...needed for CIA Pass 2 support
//
// JM 1.04 16-sep-1994 Moved perfmon code to ev5_osf_pal.m64
// JM 1.05 9-jan-1995 Fix to EI_STAT entry in MCHK logout frame -- OR in lower 28 bits (previously wiped out)
// JM 1.06 2-feb-1995 Change "HW_REI" to "HW_REI_SPE" everywhere that we may be changing to kernel mode from user
// (part of super-page bug fix).
// Initialize DC_TEST_CTL in reset flow.
//
// PALcode merge done here .... TLC ....02/06/95
//
// JM 1.07 3-mar-1995 Add init of dc_test_ctl; fix pvc_jsr statement in ret from set_sc_bc_ctl
// ES 1.08 17-mar-1995 Add osf_chm_fix to disable dcache in reset
//
// PALcode merge done here .... TLC ....03/21/95
//
//
// Entry points
// SYS_CFLUSH - Cache flush
// SYS_CSERVE - Console service
// SYS_WRIPIR - interprocessor interrupts
// SYS_HALT_INTERRUPT - Halt interrupt
// SYS_PASSIVE_RELEASE - Interrupt, passive release
// SYS_INTERRUPT - Interrupt
// SYS_RESET - Reset
// SYS_ENTER_CONSOLE
// SYS_PERFMON - Performance monitoring setup
//
//------------------------------------------------------------------------------
//
// EB164 specific library files ....
//
//------------------------------------------------------------------------------
#if eb164 != 0
// .sbttl "EB164 firmware required definition files"
_pal_def // console definition file
_cserve_def // cserve definition file
#define hlt_c_callback 33
//
// rtc based constants
//
#define rtc_base 0xe00 // RTC device is at offset 70 << 5
#define rtc_ptr 0x0 // RTC index register (offset 0 from rtc base)
#define rtc_data 0x20 // RTC data register (offset 1 from rtc base)
#define rtc_idx_csrc 0x0c // point to CSR C in the TOY chip
//
// interrupt vectors
//
#define vec_eisa_base 0x800 // base for pci vectors
#endif
ALIGN_BLOCK
.globl sys_wripir
sys_wripir: // R16 has the processor number.
// The XXM has no interprocessor interrupts
hw_rei
// .sbttl "CFLUSH- PALcode for CFLUSH instruction"
//+
// SYS_CFLUSH
// Entry:
//
// R16 - contains the PFN of the page to be flushed
//
// Function:
// Flush all Dstream caches of 1 entire page
//
//-
ALIGN_BLOCK
.globl sys_cflush
sys_cflush:
// convert pfn to addr, and clean off <63:20>
sll r16, ((page_offset_size_bits)+(63-20)), r12
lda r13, 0x10(r31) // assume 16Mbytes of cache
sll r13, 20, r13 // convert to bytes
srl r12, 63-20, r12 // shift back to normal position
xor r12, r13, r12 // xor addr bit that aligns with cache size
or r31, 8192/(32*8), r13 // get count of loads
nop
CFLUSH_LOOP:
subq r13, 1, r13 // decr counter
mfpr r25, ev5__intid // Fetch level of interruptor
ldqp r31, 32*0(r12) // do a load
ldqp r31, 32*1(r12) // do next load
ldqp r31, 32*2(r12) // do next load
ldqp r31, 32*3(r12) // do next load
ldqp r31, 32*4(r12) // do next load
ldqp r31, 32*5(r12) // do next load
ldqp r31, 32*6(r12) // do next load
ldqp r31, 32*7(r12) // do next load
mfpr r14, ev5__ipl // Fetch current level
lda r12, (32*8)(r12) // skip to next cache block addr
cmple r25, r14, r25 // R25 = 1 if intid .less than or eql ipl
beq r25, CFLUSH_LOOP_10_ // if any int's pending, re-queue CFLUSH
bne r13, CFLUSH_LOOP // loop till done
hw_rei // back to user
ALIGN_BRANCH
CFLUSH_LOOP_10_: // Here if interrupted
mfpr r12, exc_addr
subq r12, 4, r12 // Backup PC to point to CFLUSH
mtpr r12, exc_addr
nop
mfpr r31, pt0 // Pad exc_addr write
hw_rei
// .sbttl "CSERVE- PALcode for CSERVE instruction"
//+
// SYS_CSERVE
//
// Function:
// Various functions for private use of console software
//
// option selector in r0
// arguments in r16....
//
//
// r0 = 0 unknown
//
// r0 = 1 ldqp
// r0 = 2 stqp
// args, are as for normal STQP/LDQP in VMS PAL
//
// r0 = 3 dump_tb's
// r16 = detination PA to dump tb's to.
//
// r0<0> = 1, success
// r0<0> = 0, failure, or option not supported
// r0<63:1> = (generally 0, but may be function dependent)
// r0 - load data on ldqp
//
//-
ALIGN_BLOCK
.globl sys_cserve
sys_cserve:
cmpeq r18, CSERVE_K_RD_IMPURE, r0
bne r0, Sys_Cserve_Rd_Impure
cmpeq r18, CSERVE_K_JTOPAL, r0
bne r0, Sys_Cserve_Jtopal
// For now the XXM doesn't support any console callbacks
DEBUGSTORE(0x40)
bis r18, zero, r0
bsr r25, put_hex
DEBUGSTORE(13)
DEBUGSTORE(10)
or r31, r31, r0
hw_rei // and back we go
Sys_Cserve_Rd_Impure:
mfpr r0, pt_impure // Get base of impure scratch area.
hw_rei
// .sbttl "SYS_INTERRUPT - Interrupt processing code"
//+
// SYS_INTERRUPT
//
// Current state:
// Stack is pushed
// ps, sp and gp are updated
// r12, r14 - available
// r13 - INTID (new EV5 IPL)
// r14 - exc_addr
// r25 - ISR
// r16, r17, r18 - available
//
//-
ALIGN_BLOCK
.globl sys_interrupt
sys_interrupt:
extbl r12, r14, r14 // Translate new OSFIPL->EV5IPL
mfpr r29, pt_kgp // update gp
mtpr r14, ev5__ipl // load the new IPL into Ibox
cmpeq r13, 31, r12
bne r12, sys_int_mchk_or_crd // Check for level 31 interrupt (machine check or crd)
cmpeq r13, 30, r12
bne r12, sys_int_powerfail // Check for level 30 interrupt (powerfail)
cmpeq r13, 29, r12
bne r12, sys_int_perf_cnt // Check for level 29 interrupt (performance counters)
cmpeq r13, 23, r12
bne r12, sys_int_23 // Check for level 23 interrupt
cmpeq r13, 22, r12
bne r12, sys_int_22 // Check for level 22 interrupt (clock)
cmpeq r13, 21, r12
bne r12, sys_int_21 // Check for level 21 interrupt
cmpeq r13, 20, r12
bne r12, sys_int_20 // Check for level 20 interrupt (I/O)
mfpr r14, exc_addr // ooops, something is wrong
br r31, pal_pal_bug_check_from_int
//+
//sys_int_2*
// Routines to handle device interrupts at IPL 23-20.
// System specific method to ack/clear the interrupt, detect passive release,
// detect interprocessor (22), interval clock (22), corrected
// system error (20)
//
// Current state:
// Stack is pushed
// ps, sp and gp are updated
// r12, r14 - available
// r13 - INTID (new EV5 IPL)
// r25 - ISR
//
// On exit:
// Interrupt has been ack'd/cleared
// a0/r16 - signals IO device interrupt
// a1/r17 - contains interrupt vector
// exit to ent_int address
//
//-
ALIGN_BLOCK
sys_int_23:
// INT23 is unused on the XXM
nop
DEBUGSTORE(0x21)
DEBUGSTORE(0x32)
DEBUGSTORE(0x33)
DEBUGSTORE(13)
DEBUGSTORE(10)
lda r14, 0xffff(zero)
br r31, sys_int_mchk // log as a machine check
// INT22 is the Real Time Clock
//
// Dismiss the interrupt in the TOY
// Dispatch to kernel
//
ALIGN_BLOCK
sys_int_22:
OutPortByte(RTCADD,0x0C,r12,r14)// Set up RTCADD to index register C.
InPortByte(RTCDAT,r12,r14) // Read to clear interrupt.
mfpr r12, pt_entInt
lda r17, 0x600(r31) // r17 = interrupt vector for interval timer
mtpr r12, exc_addr
// DEBUGSTORE(0x2a)
// DEBUG_EXC_ADDR()
lda r16, 0x1(r31) // r16 = interrupt type for interval timer
STALL
hw_rei
ALIGN_BLOCK
sys_int_21:
// Not connected on the XXM
nop
DEBUGSTORE(0x21)
DEBUGSTORE(0x32)
DEBUGSTORE(0x31)
DEBUGSTORE(13)
DEBUGSTORE(10)
lda r14, 0xffff(zero)
br r31, sys_int_mchk // go log the interrupt as a machine check
// INT20 are device interrupts
// Dispatch to kernel
//
ALIGN_BLOCK
sys_int_20:
mfpr r12, pt_entInt // Get pointer to kernel handler.
lda r17, 0x800(zero) // Hardcode device interrupt for now
mtpr r12, exc_addr // Load kernel entry address
bis zero, 0x3, r16 // Signal I/O device interrupt
STALL
hw_rei
//+
// sys_passive_release
// Just pretend the interrupt never occurred.
//
// make sure we restore the old PS before calling this ....
//-
ALIGN_BRANCH
.globl sys_passive_release
sys_passive_release:
mtpr r11, ev5__dtb_cm // Restore Mbox current mode for ps
nop
mfpr r31, pt0 // Pad write to dtb_cm
hw_rei_spe
//+
//sys_int_powerfail
// The XXM doesn't generate these, right?
ALIGN_BLOCK
sys_int_powerfail:
nop
lda r14, 0xffff(zero)
br r31, sys_int_mchk // go log the interrupt as a machine check
//+
// sys_halt_interrupt
// A halt interrupt has been detected. Pass control to the console.
//
//
//-
ALIGN_BLOCK
.globl sys_halt_interrupt
sys_halt_interrupt:
// wait for halt to go away
SYS_HALT_PIN: // REPEAT
mfpr r25, ev5__isr // : Fetch interrupt summary register
srl r25, isr_v_hlt, r25 // : Get HLT bit
blbs r25, SYS_HALT_PIN // UNTIL interrupt goes away
LDLI (r25, 25000000) // Loop 100msec on an XXM
SYS_HALT_KEY_DEBOUNCE:
subq r25, 1, r25
bne r25, SYS_HALT_KEY_DEBOUNCE
mfpr r25, ev5__isr
srl r25, isr_v_hlt, r25
blbs r25, SYS_HALT_PIN
mtpr r11, dtb_cm // Restore Mbox current mode
mtpr r0, pt0
// pvc_jsr updpcb, bsr=1
// bsr r0, pal_update_pcb // update the pcb
// lda r0, hlt_c_hw_halt(r31) // set halt code to hw halt
br r31, sys_enter_console // enter the console
//+
// sys_int_mchk_or_crd
//
// Current state:
// Stack is pushed
// ps, sp and gp are updated
// r12
// r13 - INTID (new EV5 IPL)
// r14 - exc_addr
// r25 - ISR
// r16, r17, r18 - available
//
//-
ALIGN_BLOCK
sys_int_mchk_or_crd:
srl r25, isr_v_mck, r12
lda r14, 7(zero)
blbs r12, sys_int_mchk
bsr r12, sys_int_mchk // on the XXM it's always a mchk
// .sbttl "SYS_INT_MCHK - MCHK Interrupt code"
//+
// Machine check interrupt from the system. Setup and join the
// regular machine check flow.
// On exit:
// pt0 - saved r0
// pt1 - saved r1
// pt4 - saved r4
// pt5 - saved r5
// pt6 - saved r6
// pt10 - saved exc_addr
// pt_misc<47:32> - mchk code
// pt_misc<31:16> - scb vector
// r14 - base of Cbox IPRs in IO space
// MCES<mchk> is set
//-
ALIGN_BLOCK
sys_int_mchk:
//
// Common code to setup machine so we can join with
// the code to log processor detected machine checks
//
// Input Registers:
//
// r14 - machine check code
//
mfpr r12, exc_addr
mtpr r6, pt6
mtpr r12, pt10 // Stash exc_addr
bis r14, r31, r6 // save machine check code
sll r14, 32, r14 // Move mchk code to position
mfpr r12, pt_misc // Get MCES and scratch
mtpr r0, pt0 // Stash for scratch
zap r12, 0x3c, r12 // Clear scratch
blbs r12, sys_double_machine_check // MCHK halt if double machine check
or r12, r14, r12 // Combine mchk code
lda r14, scb_v_sysmchk(r31) // Get SCB vector
sll r14, 16, r14 // Move SCBv to position
or r12, r14, r14 // Combine SCBv
bis r14, 1<<mces_v_mchk, r14 // Set MCES<MCHK> bit
mtpr r14, pt_misc // Save mchk code!scbv!whami!mces
ldah r14, 0xfff0(r31)
mtpr r1, pt1 // Stash for scratch
zap r14, 0xE0, r14 // Get Cbox IPR base
mtpr r4, pt4
mtpr r5, pt5
// Start to collect the IPRs. Common entry point for mchk flows.
//
// Current state:
// pt0 - saved r0
// pt1 - saved r1
// pt4 - saved r4
// pt5 - saved r5
// pt6 - saved r6
// pt10 - saved exc_addr
// pt_misc<47:32> - mchk code
// pt_misc<31:16> - scb vector
// r6 - saved machine check code
// r0, r1, r4, r5, r12, r13, r25 - available
// r8, r9, r10 - available as all loads are physical
// MCES<mchk> is set and machine check code is saved
ldah r14, 0xfff0(r31)
mtpr r1, pt1 // Stash for scratch - 30 instructions
zap r14, 0xE0, r14 // Get Cbox IPR base
mb // MB before reading Scache IPRs
mfpr r1, icperr_stat
mfpr r8, dcperr_stat
mtpr r31, dc_flush // Flush the Dcache
mfpr r31, pt0 // Pad Mbox instructions from dc_flush
mfpr r31, pt0
nop
nop
ldqp r9, sc_addr(r14)// SC_ADDR IPR
bis r9, r31, r31 // Touch ld to make sure it completes before
// read of SC_STAT
ldqp r10, sc_stat(r14) // SC_STAT, also unlocks SC_ADDR
ldqp r12, ei_addr(r14)// EI_ADDR IPR
ldqp r13, bc_tag_addr(r14) // BC_TAG_ADDR IPR
ldqp r0, fill_syn(r14) // FILL_SYN IPR
// Touch lds to make sure they complete before reading EI_STAT
bis r12, r13, r31
bis r0, r0, r31
ldqp r25, ei_stat(r14) // EI_STAT, unlock EI_ADDR, BC_TAG_ADDR, FILL_SYN
ldqp r31, ei_stat(r14) // Read again to insure it is unlocked
br r31, sys_mchk_write_logout_frame // Join common machine check flow
// .sbttl "SYS_INT_PERF_CNT - Performance counter interrupt code"
//+
//sys_int_perf_cnt
//
// A performance counter interrupt has been detected. The stack has been pushed.
// IPL and PS are updated as well.
//
// on exit to interrupt entry point ENTINT::
// a0 = osfint_c_perf
// a1 = scb_v_perfmon (650)
// a2 = 0 if performance counter 0 fired
// a2 = 1 if performance counter 1 fired
// a2 = 2 if performance counter 2 fired
// (if more than one counter overflowed, an interrupt will be
// generated for each counter that overflows)
//
//
//-
ALIGN_BLOCK
sys_int_perf_cnt: // Performance counter interrupt
lda r17, scb_v_perfmon(r31) // a1 to interrupt vector
mfpr r25, pt_entInt
lda r16, osfint_c_perf(r31) // a0 to perf counter code
mtpr r25, exc_addr
//isolate which perf ctr fired, load code in a2, and ack
mfpr r25, isr
or r31, r31, r18 // assume interrupt was pc0
srl r25, isr_v_pc1, r25 // isolate
cmovlbs r25, 1, r18 // if pc1 set, load 1 into r14
srl r25, 1, r25 // get pc2
cmovlbs r25, 2, r18 // if pc2 set, load 2 into r14
lda r25, 1(r31) // get a one
sll r25, r18, r25
sll r25, hwint_clr_v_pc0c, r25 // ack only the perf counter that generated the interrupt
mtpr r25, hwint_clr
hw_rei_spe
// .sbttl "System specific RESET code"
//+
// RESET code
// On entry:
// r1 = pal_base +8
//
// Entry state on trap:
// r0 = whami
// r2 = base of scratch area
// r3 = halt code
// and the following 3 if init_cbox is enabled:
// r5 = sc_ctl
// r6 = bc_ctl
// r7 = bc_cnfg
//
// Entry state on switch:
// r17 - new PC
// r18 - new PCBB
// r19 - new VPTB
//
//-
ALIGN_BLOCK
.globl sys_reset
sys_reset:
bis r1, r31, r22
bis r2, r31, r23
bis r3, r31, r24
lda r0, 0(zero) // The XXM has only one CPU
lda r2, 0x2000(zero) // KLUDGE the impure area address
lda r3, 0(zero) // Machine restart
mtpr r31, pt_misc // Zero out whami & swppal flag
mtpr r31, pt0 // halt code of "reset"
mtpr r31, pt1 // whami is always 0 on XXM
/* Check to see if the transfer from the POST (Power-on-Self Test) code
** is following a standard protocol and that the other input parameter
** values may be trusted. Register a3 (r19) will contain a signature if so.
**
** Register values:
**
** t0 (r1) bcCtl value, saved into pt4
** t1 (r2) bcCfg value
** t2 (r3) bcCfgOff value (values for bcache off)
**
** s6 (r15) encoded srom.s RCS revision
** a0 (r16) processor identification (a la SRM)
** a1 (r17) size of contiguous, good memory in bytes
** a2 (r18) cycle count in picoseconds
** a3 (r19) signature (0xDECB) in <31:16> and system revision ID in <15:0>
** a4 (r20) active processor mask
** a5 (r21) system context value
*/
lda r4, CNS_Q_IPR(r2) // Point to base of IPR area.
lda r4, pal_impure_common_size(r4) // Bias by PAL common size
SAVE_SHADOW(r22,CNS_Q_BC_CTL,r4) // Save shadow of bcCtl.
SAVE_SHADOW(r23,CNS_Q_BC_CFG,r4) // Save shadow of bcCfg.
#ifdef undef
SAVE_SHADOW(r24,CNS_Q_BC_CFG_OFF,r4) // Save shadow of bcCfg.
#endif
SAVE_SHADOW(r15,CNS_Q_SROM_REV,r4) // Save srom revision.
SAVE_SHADOW(r16,CNS_Q_PROC_ID,r4) // Save processor id.
SAVE_SHADOW(r17,CNS_Q_MEM_SIZE,r4) // Save memory size.
SAVE_SHADOW(r18,CNS_Q_CYCLE_CNT,r4) // Save cycle count.
SAVE_SHADOW(r19,CNS_Q_SIGNATURE,r4) // Save signature and sys rev.
SAVE_SHADOW(r20,CNS_Q_PROC_MASK,r4) // Save processor mask.
SAVE_SHADOW(r21,CNS_Q_SYSCTX,r4) // Save system context.
//;;;;;; mtpr r31, ic_flush_ctl; do not flush the icache - done by hardware before SROM load
/*
* Initialize the serial ports
*
* Baud rate: 9600 baud
* Word length: 8 bit characters
* Stop bits: 1 stop bit
* Parity: No parity
* Modem control: DTR, RTS active, OUT1 lov, UART interrupts enabled
*/
/* Initialize COM1*/
OutPortByte(COM1_LCR,LCR_M_DLAB,r12,r14)// Access clock divisor latch.
OutPortByte(COM1_DLL,DLA_K_BRG,r12,r14) // Set the baud rate.
OutPortByte(COM1_DLH,0,r12,r14)
OutPortByte(COM1_LCR,LCR_K_INIT,r12,r14)// Set line control register.
OutPortByte(COM1_MCR,MCR_K_INIT,r12,r14)// Set modem control register.
OutPortByte(COM1_IER,0x0f,r12,r14) // Turn on interrupts.
/* Flush COM1's receive buffer*/
#ifndef SIMOS
Sys_ResetFlushCom1:
InPortByte(COM1_LSR,r12,r14) // Read the line status.
blbc t0, Sys_ResetCom1Done // Are we done yet?
InPortByte(COM1_RBR,r12,r14) // Read receive buffer reg.
br zero, Sys_ResetFlushCom1 // Loop till done.
Sys_ResetCom1Done:
#endif
mb
mtpr r31, itb_ia // clear the ITB
mtpr r31, dtb_ia // clear the DTB
//;;;;;; lda r1, 0x1FFF(R31)
//;;;;;; mtpr r1, dc_test_ctl ; initialize tag index to all 1's.
/* Hardwire the base address of the PALcode */
lda r1, 0x4000(r31) // point to start of code
mtpr r1, pal_base // initialize PAL_BASE
// Interrupts
mtpr r31, astrr // stop ASTs
mtpr r31, aster // stop ASTs
mtpr r31, sirr // clear software interrupts
// enable shadow registers, floating point, kseg addressing
ldah r1, ((1<<(icsr_v_sde-16)) | (1<<(icsr_v_fpe-16)) | (2<<(icsr_v_spe-16)))(r31)
mtpr r1, icsr
// Mbox/Dcache init
lda r1, (1<<(mcsr_v_sp1))(r31)
mtpr r1, mcsr // MCSR - Super page enabled
lda r1, 1<<dc_mode_v_dc_ena(r31)
bsr r31, 1f
ALIGN_BRANCH
1: mtpr r1, dc_mode // turn Dcache on
nop
STALL // No Mbox instr in 1,2,3,4
STALL
STALL
STALL
mtpr r31, dc_flush // flush Dcache
// build PS (IPL=7,CM=K,VMM=0,SW=0)
lda r11, 0x7(r31) // Shadow copy of PS - kern mode, IPL=7
lda r1, 0x1e(r31)
mtpr r1, ev5__ipl // set internal <ipl>
mtpr r31, ips // set new ps<cm>=0, Ibox copy
mtpr r31, dtb_cm // set new ps<cm>=0, Mbox copy
// Create the PALtemp pt_intmask -
// MAP:
// OSF IPL EV5 internal IPL(hex) note
// 0 0
// 1 1
// 2 2
// 3 14 device
// 4 15 device
// 5 16 device
// 6 1e device
// 7 1e make sure we can take mchks at ipl 31
ldah r1, 0x1e1e(r31) // Create upper lw of int_mask
lda r1, 0x1615(r1)
sll r1, 32, r1
ldah r1, 0x1402(r1) // Create lower lw of int_mask
lda r1, 0x0100(r1)
mtpr r1, pt_intmask // Stash in PALtemp
// Unlock a bunch of chip internal IPRs
mtpr r31, exc_sum // clear exeception summary and exc_mask
mfpr r31, va // unlock va, mmstat
lda r8, ((1<<icperr_stat_v_dpe) | (1<<icperr_stat_v_tpe) | (1<<icperr_stat_v_tmr))(r31)
mtpr r8, icperr_stat // Clear Icache parity error & timeout
lda r8, ((1<<dcperr_stat_v_lock) | (1<<dcperr_stat_v_seo))(r31)
mtpr r8, dcperr_stat // Clear Dcache parity error status
rc r0 // clear intr_flag
mtpr r31, pt_trap
mfpr r0, pt_misc
srl r0, pt_misc_v_switch, r1
blbs r1, sys_reset_switch // see if we got here from swppal
// Rest of the "real" reset flow
// ASN
mtpr r31, dtb_asn
mtpr r31, itb_asn
lda r1, 0x1FFF(r31)
mtpr r1, dc_test_ctl // initialize tag index to all 1's.
lda r1, 0x67(r31)
sll r1, hwint_clr_v_pc0c, r1
mtpr r1, hwint_clr // Clear hardware interrupt requests
lda r1, 1<<mces_v_dpc(r31) // 1 in disable processor correctable error
mfpr r0, pt1 // get whami
insbl r0, 1, r0 // isolate whami in correct pt_misc position
or r0, r1, r1 // combine whami and mces
mtpr r1, pt_misc // store whami and mces, swap bit clear
// CPU specific impure pointer
extbl r0, 1, r0 //get whami again
#if eb164 != 0
// compile error .....
//
// mulq r0, ((pal_impure_specific_size+mchk_size+mchk_crd_size)/8), r0 ; whami * per_node size/8
lda r1, ((pal_impure_specific_size+mchk_size+mchk_crd_size)/8)(r31)
mulq r0, r1, r0 //
#endif
addq r0, pal_impure_common_size/8, r0// add common area
sll r0, 3, r0 // * 8
addq r2, r0, r2 // addr our impure area offset
mtpr r2, pt_impure
zapnot r3, 1, r0 // isolate halt code
mtpr r0, pt0 // save entry type
// Cycle counter
or r31, 1, r9 // get a one
sll r9, 32, r9 // shift to <32>
mtpr r31, cc // clear Cycle Counter
mtpr r9, cc_ctl // clear and enable the Cycle Counter
mtpr r31, pt_scc // clear System Cycle Counter
// Misc PALtemps
mtpr r31, maf_mode // no mbox instructions for 3 cycles
or r31, 1, r1 // get bogus scbb value
mtpr r1, pt_scbb // load scbb
mtpr r31, pt_prbr // clear out prbr
mfpr r1, pal_base
lda r1, (kludge_initial_pcbb-0x4000)(r1) // get address for temp pcbb
mtpr r1, pt_pcbb // load pcbb
lda r1, 2(r31) // get a two
sll r1, 32, r1 // gen up upper bits
mtpr r1, mvptbr
mtpr r1, ivptbr
mtpr r31, pt_ptbr
// Performance counters
mtpr r31, pmctr
// Clear pmctr_ctl in impure area
mfpr r1, pt_impure
stqp r31, CNS_Q_PM_CTL(r1)
ldah r14, 0xfff0(r31)
zap r14, 0xE0, r14 // Get Cbox IPR base
#ifndef SIMOS
ldqp r31, sc_stat(r14) // Clear sc_stat and sc_addr
ldqp r31, ei_stat(r14)
ldqp r31, ei_stat(r14) // Clear ei_stat, ei_addr, bc_tag_addr, fill_syn
#endif
mfpr r13, pt_impure
stqpc r31, 0(r13) // Clear lock_flag
lda r0, 0(zero)
mfpr r1, pt_impure
bsr r3, pal_save_state
mfpr r0, pt0 // get entry type
br r31, sys_enter_console // enter the cosole
// swppal entry
// r0 - pt_misc
// r17 - new PC
// r18 - new PCBB
// r19 - new VPTB
sys_reset_switch:
or r31, 1, r9
sll r9, pt_misc_v_switch, r9
bic r0, r9, r0 // clear switch bit
mtpr r0, pt_misc
rpcc r1 // get cyccounter
ldqp r22, osfpcb_q_fen(r18) // get new fen/pme
ldlp r23, osfpcb_l_cc(r18) // get cycle counter
ldlp r24, osfpcb_l_asn(r18) // get new asn
ldqp r25, osfpcb_q_Mmptr(r18)// get new mmptr
sll r25, page_offset_size_bits, r25 // convert pfn to pa
mtpr r25, pt_ptbr // load the new mmptr
mtpr r18, pt_pcbb // set new pcbb
bic r17, 3, r17 // clean use pc
mtpr r17, exc_addr // set new pc
mtpr r19, mvptbr
mtpr r19, ivptbr
ldqp r30, osfpcb_q_Usp(r18) // get new usp
mtpr r30, pt_usp // save usp
sll r24, dtb_asn_v_asn, r8
mtpr r8, dtb_asn
sll r24, itb_asn_v_asn, r24
mtpr r24, itb_asn
mfpr r25, icsr // get current icsr
lda r24, 1(r31)
sll r24, icsr_v_fpe, r24 // 1 in icsr<fpe> position
bic r25, r24, r25 // clean out old fpe
and r22, 1, r22 // isolate new fen bit
sll r22, icsr_v_fpe, r22
or r22, r25, r25 // or in new fpe
mtpr r25, icsr // update ibox ipr
subl r23, r1, r1 // gen new cc offset
insll r1, 4, r1 // << 32
mtpr r1, cc // set new offset
or r31, r31, r0 // set success
ldqp r30, osfpcb_q_Ksp(r18) // get new ksp
mfpr r31, pt0 // stall
hw_rei_stall
// .sbttl "SYS_MACHINE_CHECK - Machine check PAL"
ALIGN_BLOCK
//+
//sys_machine_check
// A machine_check trap has occurred. The Icache has been flushed.
//
//-
.globl sys_machine_check
sys_machine_check:
DEBUGSTORE(052)
DEBUGSTORE(052)
DEBUGSTORE(052)
// Need to fill up the refill buffer (32 instructions) and
// then flush the Icache again.
// Also, due to possible 2nd Cbox register file write for
// uncorrectable errors, no register file read or write for 7 cycles.
nop
mtpr r0, pt0 // Stash for scratch -- OK if Cbox overwrites r0 later
nop
nop
nop
nop
nop
nop
nop
nop
// 10 instructions; 5 cycles
nop
nop
nop
nop
// Register file can now be written
lda r0, scb_v_procmchk(r31) // SCB vector
mfpr r13, pt_mces // Get MCES
sll r0, 16, r0 // Move SCBv to correct position
bis r13, 1<<mces_v_mchk, r14 // Set MCES<MCHK> bit
zap r14, 0x3C, r14 // Clear mchk_code word and SCBv word
mtpr r14, pt_mces // 20 instructions
nop
or r14, r0, r14 // Insert new SCB vector
lda r0, mchk_c_proc_hrd_error(r31) // MCHK code
mfpr r12, exc_addr
sll r0, 32, r0 // Move MCHK code to correct position
mtpr r4, pt4
or r14, r0, r14 // Insert new MCHK code
mtpr r14, pt_misc // Store updated MCES, MCHK code, and SCBv
ldah r14, 0xfff0(r31)
mtpr r1, pt1 // Stash for scratch - 30 instructions
zap r14, 0xE0, r14 // Get Cbox IPR base
mtpr r12, pt10 // Stash exc_addr
mtpr r31, ic_flush_ctl // Second Icache flush, now it is really flushed.
// blbs r13, sys_double_machine_check ; MCHK halt if double machine check
blbs r12, sys_machine_check_while_in_pal // MCHK halt if machine check in pal
mtpr r6, pt6
mtpr r5, pt5
//+
// Start to collect the IPRs. Common entry point for mchk flows.
//
// Current state:
// pt0 - saved r0
// pt1 - saved r1
// pt4 - saved r4
// pt5 - saved r5
// pt6 - saved r6
// pt10 - saved exc_addr
// pt_misc<47:32> - mchk code
// pt_misc<31:16> - scb vector
// r14 - base of Cbox IPRs in IO space
// r0, r1, r4, r5, r6, r12, r13, r25 - available
// r8, r9, r10 - available as all loads are physical
// MCES<mchk> is set and machine check code is saved
//
//-
ALIGN_BRANCH
.globl sys_mchk_collect_iprs
sys_mchk_collect_iprs:
mb // MB before reading Scache IPRs
mfpr r1, icperr_stat
mfpr r8, dcperr_stat
mtpr r31, dc_flush // Flush the Dcache
mfpr r31, pt0 // Pad Mbox instructions from dc_flush
mfpr r31, pt0
nop
nop
ldqp r9, sc_addr(r14) // SC_ADDR IPR
bis r9, r31, r31 // Touch ld to make sure it completes before
// read of SC_STAT
ldqp r10, sc_stat(r14) // SC_STAT, also unlocks SC_ADDR
ldqp r12, ei_addr(r14) // EI_ADDR IPR
ldqp r13, bc_tag_addr(r14) // BC_TAG_ADDR IPR
ldqp r0, fill_syn(r14) // FILL_SYN IPR
// Touch lds to make sure they complete before reading EI_STAT
bis r12, r13, r31
// wait for r0 ldqp to complete
bis r0, r0, r31
ldqp r25, ei_stat(r14) // EI_STAT, unlock EI_ADDR, BC_TAG_ADDR, FILL_SYN
ldqp r31, ei_stat(r14) // Read again to insure it is unlocked
mfpr r6, pt_misc
extwl r6, 4, r6 // Fetch mchk code
br r31, sys_mchk_write_logout_frame //
//+
// Write the logout frame
//
// Current state:
// r0 - fill_syn
// r1 - icperr_stat
// r4 - available
// r5<0> - retry flag
// r6 - mchk code
// r8 - dcperr_stat
// r9 - sc_addr
// r10 - sc_stat
// r12 - ei_addr
// r13 - bc_tag_addr
// r14 - available
// r25 - ei_stat (shifted)
// pt0 - saved r0
// pt1 - saved r1
// pt4 - saved r4
// pt5 - saved r5
// pt6 - saved r6
// pt10 - saved exc_addr
//
//-
ALIGN_BRANCH
sys_mchk_write_logout_frame:
//------------------------------------------------------------------------------------
// EB164 specific code ....
//
// R14 - uncorrectable error logout frame address = 6000h + size of CRD frame
//
//------------------------------------------------------------------------------------
#if eb164 != 0
lda r14,PAL_LOGOUT_BASE(r31) // get the start of logout frame location
lda r14,mchk_mchk_base(r14) // add in the size of the CRD frame
#endif
// Write the first 2 quadwords of the logout area:
sll r5, 63, r5 // Move retry flag to bit 63
lda r4, mchk_size(r5) // Combine retry flag and frame size
stqp r4, mchk_flag(r14) // store flag/frame size
lda r4, mchk_sys_base(r31) // sys offset
sll r4, 32, r4
lda r4, mchk_cpu_base(r4) // cpu offset
stqp r4, mchk_offsets(r14) // store sys offset/cpu offset into logout frame
//+
// Write the mchk code to the logout area
// Write error IPRs already fetched to the logout area
// Restore some GPRs from PALtemps
//-
mfpr r5, pt5
stqp r6, mchk_mchk_code(r14)
mfpr r4, pt4
stqp r1, mchk_ic_perr_stat(r14)
mfpr r6, pt6
stqp r8, mchk_dc_perr_stat(r14)
mfpr r1, pt1
stqp r9, mchk_sc_addr(r14)
stqp r10, mchk_sc_stat(r14)
stqp r12, mchk_ei_addr(r14)
stqp r13, mchk_bc_tag_addr(r14)
stqp r0, mchk_fill_syn(r14)
mfpr r0, pt0
#define ei_stat_v_bc_tperr 28
sll r25, ei_stat_v_bc_tperr, r25 // Move EI_STAT status bits back to expected position
//
// Steve Shirron ei_stat.chip_id bits fix
//
// r25 has the ei_stat<35:28> bits aligned to bit 0.
// Because this alignment trashed the ei_stat.chip_id<27:24> bits,
// Steve's fix re-reads the ei_stat to recover the chip_id bits before
// writing the ei_stat to the log.
//
ldah r13, 0xfff0(r31) // r13 <- pointer to cbox
zapnot r13, 0x1f, r13 // :
ldqp r13, ei_stat(r13) // r13 <- contents of ei_stat register
sll r13, 64-ei_stat_v_bc_tperr, r13 // clear bits <63:36>
srl r13, 64-ei_stat_v_bc_tperr, r13 // put ei_stat bits back
or r25, r13, r25 // or-in the stat bits from the original read
stqp r25, mchk_ei_stat(r14) // write to the log
mfpr r25, pt10
stqp r25, mchk_exc_addr(r14)
// complete the CPU-specific part of the logout frame
#define mchk_logout(regName, regOff) \
mfpr r25, regName ; \
stqp r25, CNS_Q_/**/regOff(r14)
// mchk_logout(mm_stat, MM_STAT)
// mchk_logout(va, VA) // Unlocks VA and MM_STAT
// mchk_logout(isr, ISR)
// mchk_logout(icsr, ICSR)
// mchk_logout(pal_base, PAL_BASE)
// mchk_logout(exc_mask, EXC_MASK)
// mchk_logout(exc_sum, EXC_SUM)
mfpr r25, mm_stat
stqp r25, CNS_Q_MM_STAT(r14)
mfpr r25, va
stqp r25, CNS_Q_VA(r14)
mfpr r25, isr
stqp r25, CNS_Q_ISR(r14)
mfpr r25, icsr
stqp r25, CNS_Q_ICSR(r14)
mfpr r25, pal_base
stqp r25, CNS_Q_PAL_BASE(r14)
mfpr r25, exc_mask
stqp r25, CNS_Q_EXC_MASK(r14)
mfpr r25, exc_sum
stqp r25, CNS_Q_EXC_SUM(r14)
ldah r13, 0xfff0(r31)
zap r13, 0xE0, r13 // Get Cbox IPR base
ldqp r13, ld_lock(r13) // Get ld_lock IPR
stqp r13, mchk_ld_lock(r14) // and stash it in the frame
//+
// complete the PAL-specific part of the logout frame
//-
#define svpt(n)\
mfpr r25, pt/**/n ;\
stqp r25, CNS_Q_PT+(8*n)(r14)
mfpr r25, pt0
stqp r25, CNS_Q_PT+(8*0)(r14)
mfpr r25, pt1
stqp r25, CNS_Q_PT+(8*1)(r14)
mfpr r25, pt2
stqp r25, CNS_Q_PT+(8*2)(r14)
mfpr r25, pt3
stqp r25, CNS_Q_PT+(8*3)(r14)
mfpr r25, pt4
stqp r25, CNS_Q_PT+(8*4)(r14)
mfpr r25, pt5
stqp r25, CNS_Q_PT+(8*5)(r14)
mfpr r25, pt6
stqp r25, CNS_Q_PT+(8*6)(r14)
mfpr r25, pt7
stqp r25, CNS_Q_PT+(8*7)(r14)
mfpr r25, pt8
stqp r25, CNS_Q_PT+(8*8)(r14)
mfpr r25, pt9
stqp r25, CNS_Q_PT+(8*9)(r14)
mfpr r25, pt10
stqp r25, CNS_Q_PT+(8*10)(r14)
mfpr r25, pt11
stqp r25, CNS_Q_PT+(8*11)(r14)
mfpr r25, pt12
stqp r25, CNS_Q_PT+(8*12)(r14)
mfpr r25, pt13
stqp r25, CNS_Q_PT+(8*13)(r14)
mfpr r25, pt14
stqp r25, CNS_Q_PT+(8*14)(r14)
mfpr r25, pt15
stqp r25, CNS_Q_PT+(8*15)(r14)
mfpr r25, pt16
stqp r25, CNS_Q_PT+(8*16)(r14)
mfpr r25, pt17
stqp r25, CNS_Q_PT+(8*17)(r14)
mfpr r25, pt18
stqp r25, CNS_Q_PT+(8*18)(r14)
mfpr r25, pt19
stqp r25, CNS_Q_PT+(8*19)(r14)
mfpr r25, pt20
stqp r25, CNS_Q_PT+(8*20)(r14)
mfpr r25, pt21
stqp r25, CNS_Q_PT+(8*21)(r14)
mfpr r25, pt22
stqp r25, CNS_Q_PT+(8*22)(r14)
mfpr r25, pt23
stqp r25, CNS_Q_PT+(8*23)(r14)
// svpt(0)
// svpt(1)
// svpt(2)
// svpt(3)
// svpt(4)
// svpt(5)
// svpt(6)
// svpt(7)
// svpt(8)
// svpt(9)
// svpt(10)
// svpt(11)
// svpt(12)
// svpt(13)
// svpt(14)
// svpt(15)
// svpt(16)
// svpt(17)
// svpt(18)
// svpt(19)
// svpt(20)
// svpt(21)
// svpt(22)
// svpt(23)
//
//+
// Log system specific info here
//-
// Unlock IPRs
lda r8, ((1<<dcperr_stat_v_lock) | (1<<dcperr_stat_v_seo))(r31)
mtpr r8, dcperr_stat // Clear Dcache parity error status
lda r8, ((1<<icperr_stat_v_dpe) | (1<<icperr_stat_v_tpe) | (1<<icperr_stat_v_tmr))(r31)
mtpr r8, icperr_stat // Clear Icache parity error & timeout status
// pvc_jsr armc, bsr=1
bsr r12, sys_arith_and_mchk // go check for and deal with arith trap
mtpr r31, exc_sum // Clear Exception Summary
mfpr r25, pt10 // write exc_addr after arith_and_mchk to pickup new pc
stqp r25, mchk_exc_addr(r14)
//+
// Set up the km trap
//-
sys_post_mchk_trap:
mfpr r25, pt_misc // Check for flag from mchk interrupt
extwl r25, 4, r25
blbs r25, sys_mchk_stack_done // Stack from already pushed if from interrupt flow
bis r14, r31, r12 // stash pointer to logout area
mfpr r14, pt10 // get exc_addr
sll r11, 63-3, r25 // get mode to msb
bge r25, sys_post_mchk_trap_30_
mtpr r31, dtb_cm
mtpr r31, ips
mtpr r30, pt_usp // save user stack
mfpr r30, pt_ksp
sys_post_mchk_trap_30_:
lda sp, 0-osfsf_c_size(sp) // allocate stack space
nop
stq r18, osfsf_a2(sp) // a2
stq r11, osfsf_ps(sp) // save ps
stq r14, osfsf_pc(sp) // save pc
mfpr r25, pt_entInt // get the VA of the interrupt routine
stq r16, osfsf_a0(sp) // a0
lda r16, osfint_c_mchk(r31) // flag as mchk in a0
stq r17, osfsf_a1(sp) // a1
mfpr r17, pt_misc // get vector
stq r29, osfsf_gp(sp) // old gp
mtpr r25, exc_addr //
or r31, 7, r11 // get new ps (km, high ipl)
subq r31, 1, r18 // get a -1
extwl r17, 2, r17 // a1 <- interrupt vector
bis r31, ipl_machine_check, r25
mtpr r25, ev5__ipl // Set internal ipl
srl r18, 42, r18 // shift off low bits of kseg addr
sll r18, 42, r18 // shift back into position
mfpr r29, pt_kgp // get the kern r29
or r12, r18, r18 // EV4 algorithm - pass pointer to mchk frame as kseg address
hw_rei_spe // out to interrupt dispatch routine
//+
// The stack is pushed. Load up a0,a1,a2 and vector via entInt
//
//-
ALIGN_BRANCH
sys_mchk_stack_done:
lda r16, osfint_c_mchk(r31) // flag as mchk/crd in a0
lda r17, scb_v_sysmchk(r31) // a1 <- interrupt vector
subq r31, 1, r18 // get a -1
mfpr r25, pt_entInt
srl r18, 42, r18 // shift off low bits of kseg addr
mtpr r25, exc_addr // load interrupt vector
sll r18, 42, r18 // shift back into position
or r14, r18, r18 // EV4 algorithm - pass pointer to mchk frame as kseg address
hw_rei_spe // done
//sys_double_machine_check - a machine check was started, but MCES<MCHK> was
// already set. We will now double machine check halt.
//
// pt0 - old R0
//
ALIGN_BLOCK
.globl sys_double_machine_check
sys_double_machine_check:
// pvc_jsr updpcb, bsr=1
// bsr r0, pal_update_pcb // update the pcb
lda r0, hlt_c_dbl_mchk(r31)
br r31, sys_enter_console
//sys_machine_check_while_in_pal - a machine check was started, exc_addr points to
// a PAL PC. We will now machine check halt.
//
// pt0 - old R0
//
sys_machine_check_while_in_pal:
// pvc_jsr updpcb, bsr=1
// bsr r0, pal_update_pcb // update the pcb
lda r0, hlt_c_mchk_from_pal(r31)
br r31, sys_enter_console
//ARITH and MCHK
// Check for arithmetic errors and build trap frame,
// but don't post the trap.
// on entry:
// pt10 - exc_addr
// r12 - return address
// r14 - logout frame pointer
// r13 - available
// r8,r9,r10 - available except across stq's
// pt0,1,6 - available
//
// on exit:
// pt10 - new exc_addr
// r17 = exc_mask
// r16 = exc_sum
// r14 - logout frame pointer
//
ALIGN_BRANCH
sys_arith_and_mchk:
mfpr r13, ev5__exc_sum
srl r13, exc_sum_v_swc, r13
bne r13, handle_arith_and_mchk
// pvc_jsr armc, bsr=1, dest=1
ret r31, (r12) // return if no outstanding arithmetic error
handle_arith_and_mchk:
mtpr r31, ev5__dtb_cm // Set Mbox current mode to kernel -
// no virt ref for next 2 cycles
mtpr r14, pt0
mtpr r1, pt1 // get a scratch reg
and r11, osfps_m_mode, r1 // get mode bit
bis r11, r31, r25 // save ps
beq r1, handle_arith_and_mchk_10_ // if zero we are in kern now
bis r31, r31, r25 // set the new ps
mtpr r30, pt_usp // save user stack
mfpr r30, pt_ksp // get kern stack
handle_arith_and_mchk_10_:
mfpr r14, exc_addr // get pc into r14 in case stack writes fault
lda sp, 0-osfsf_c_size(sp) // allocate stack space
mtpr r31, ev5__ps // Set Ibox current mode to kernel
mfpr r1, pt_entArith
stq r14, osfsf_pc(sp) // save pc
stq r17, osfsf_a1(sp)
mfpr r17, ev5__exc_mask // Get exception register mask IPR - no mtpr exc_sum in next cycle
stq r29, osfsf_gp(sp)
stq r16, osfsf_a0(sp) // save regs
bis r13, r31, r16 // move exc_sum to r16
stq r18, osfsf_a2(sp)
stq r11, osfsf_ps(sp) // save ps
mfpr r29, pt_kgp // get the kern gp
mfpr r14, pt0 // restore logout frame pointer from pt0
bis r25, r31, r11 // set new ps
mtpr r1, pt10 // Set new PC
mfpr r1, pt1
// pvc_jsr armc, bsr=1, dest=1
ret r31, (r12) // return if no outstanding arithmetic error
// .sbttl "SYS_ENTER_CONSOLE - Common PALcode for ENTERING console"
// SYS_enter_console
//
// Entry:
// Entered when PAL wants to enter the console.
// usually as the result of a HALT instruction or button,
// or catastrophic error.
//
// Regs on entry...
//
// R0 = halt code
// pt0 <- r0
//
// Function:
//
// Save all readable machine state, and "call" the console
//
// Returns:
//
//
// Notes:
//
// In these routines, once the save state routine has been executed,
// the remainder of the registers become scratchable, as the only
// "valid" copy of them is the "saved" copy.
//
// Any registers or PTs that are modified before calling the save
// routine will have there data lost. The code below will save all
// state, but will loose pt 0,4,5.
//
//-
#define KSEG 0xfffffc0000000000
ALIGN_BLOCK
.globl sys_enter_console
sys_enter_console:
DEBUGSTORE(0x7a)
DEBUG_EXC_ADDR()
DEBUGSTORE(13)
DEBUGSTORE(10)
mtpr r1, pt4
mtpr r3, pt5
STALL
STALL
mfpr r1, pt_impure
bsr r3, pal_save_state
// build PS (IPL=7,CM=K,VMM=0,SW=0)
lda r11, 0x7(r31) // Shadow copy of PS - kern mode, IPL=7
lda r1, 0x1e(r31)
mtpr r1, ev5__ipl // set internal <ipl>
/* kernel sp: KSEG + 0xffe000 */
subq r31, 1, sp
sll sp, 42, sp
lda r3, 0xffe(zero)
sll r3, 12, r3
addq r3, sp, sp
mtpr sp, ptKsp // Update the saved KSP value.
mtpr zero, ips // Set mode to kernel, IPL = 0.
mtpr zero, dtb_ia // Flush the DTB
mtpr zero, itb_ia // Flush the ITB
mtpr zero, astrr // Clear all ASTs ...
mtpr zero, aster
mtpr zero, sirr // Clear all software interrupts.
// lda r3, pal_enter_console_ptr(r31) //find stored vector
// ldqp r1, 0(r3)
/* put the KSEG address in the top, then add 0x10000 to it */
subq r31, 1, r1
sll r1, 42, r1
ldah r1, 1(r1)
mtpr r1, exc_addr
mfpr r1, pt4
mfpr r3, pt5
STALL
STALL
hw_rei_stall
.align 7
kludge_initial_pcbb: // PCB is 128 bytes long
.quad 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0
.globl debugstore
debugstore:
stq_p r16,0(zero)
stq_p r17,8(zero)
lda r16, 0x400(zero)
sll r16, 29, r16
ldah r16, 0x280(r16)
9: lda r17, 0x140(r16)
ldl_p r17, 0(r17)
srl r17, 16, r17
and r17, 0x20, r17
beq r17, 9b
stl_p r13, 0(r16)
mb
ldq_p r17, 8(zero)
ldq_p r16, 0(zero)
jmp r31, (r25)
//
.globl put_exc_addr
put_exc_addr:
stq_p r16,0(zero)
stq_p r17,8(zero)
stq_p r18,16(zero)
stq_p r19,24(zero)
mfpr r16, exc_addr
bis r31, 64-4, r17 // shift count for quadword
1: lda r18, 0x400(zero) // Wait for UART ready
sll r18, 29, r18
ldah r18, 0x280(r18)
9: lda r19, 0x140(r18)
ldl_p r19, 0(r19)
srl r19, 16, r19
and r19, 0x20, r19
beq r19, 9b
srl r16, r17, r19 // grab a nibble
and r19, 0x0f, r19
addq r19, 0x30, r19 // make ascii
cmple r19, 0x39, r18
bne r18, 0f
addq r19, 0x27, r19 // 0x07 gets A-F
0: lda r18, 0x400(zero) // Wait for UART ready
sll r18, 29, r18
ldah r18, 0x280(r18)
stl_p r19, 0(r18)
mb
subq r17, 4, r17 // do all nibbles
bge r17, 1b
ldq_p r16,0(zero)
ldq_p r17,8(zero)
ldq_p r18,16(zero)
ldq_p r19,24(zero)
ret r31, (r25)
// print out r13
.globl put_hex
put_hex:
stq_p r16,0(zero)
stq_p r17,8(zero)
stq_p r18,16(zero)
stq_p r19,24(zero)
bis r13, zero, r16
bis r31, 64-4, r17 // shift count for quadword
1: lda r18, 0x400(zero) // Wait for UART ready
sll r18, 29, r18
ldah r18, 0x280(r18)
9: lda r19, 0x140(r18)
ldl_p r19, 0(r19)
srl r19, 16, r19
and r19, 0x20, r19
beq r19, 9b
srl r16, r17, r19 // grab a nibble
and r19, 0x0f, r19
addq r19, 0x30, r19 // make ascii
cmple r19, 0x39, r18
bne r18, 0f
addq r19, 0x27, r19 // 0x07 gets A-F
0: lda r18, 0x400(zero) // Wait for UART ready
sll r18, 29, r18
ldah r18, 0x280(r18)
stl_p r19, 0(r18)
mb
subq r17, 4, r17 // do all nibbles
bge r17, 1b
ldq_p r16,0(zero)
ldq_p r17,8(zero)
ldq_p r18,16(zero)
ldq_p r19,24(zero)
ret r31, (r25)
/*
**
** FUNCTIONAL DESCRIPTION:
**
** Transfer control to the specified address, passed in
** register a0, in PAL mode.
**
** INPUT PARAMETERS:
**
** a0 (r16) - Transfer address
**
** OUTPUT PARAMETERS:
**
** DECchip 21064 specific parameters:
**
** t0 (r1) - bcCtl
** t1 (r2) - bcCfg
**
** Firmware specific parameters:
**
** s6 (r15) - Encoded srom.s RCS revision
** a0 (r16) - Processor identification (a la SRM)
** a1 (r17) - Size of good memory in bytes
** a2 (r18) - Cycle count in picoseconds
** a3 (r19) - Protocol signature and system revision
** a4 (r20) - Active processor mask
** a5 (r21) - System Context value
**
** SIDE EFFECTS:
**
*/
ALIGN_BRANCH
Sys_Cserve_Jtopal:
bic a0, 3, t8 // Clear out low 2 bits of address
bis t8, 1, t8 // Or in PAL mode bit
mfpr t9, ptImpure // Get base of impure scratch area.
lda t9, CNS_Q_IPR(t9) // Point to start of IPR area.
RESTORE_SHADOW(a3,CNS_Q_SIGNATURE,t9) // Get signature.
srl a3, 16, t0 // Shift signature into lower word.
LDLI(t10,0xDECB) // Load the expected valid signature.
cmpeq t0, t10, t0 // Check if saved signature was valid.
blbc t0, 1f // If invalid, pass nothing.
/*
** Load the processor specific parameters ...
*/
RESTORE_SHADOW(t0,CNS_Q_BC_CTL,t9) // Get bcCtl.
RESTORE_SHADOW(t1,CNS_Q_BC_CFG,t9) // Get bcCfg.
/* RESTORE_SHADOW(t2,CNS_Q_BC_CFG_OFF,t9) // Get bcCfg.*/
/*
** Load the firmware specific parameters ...
*/
RESTORE_SHADOW(s6,CNS_Q_SROM_REV,t9) // Get srom revision.
RESTORE_SHADOW(a0,CNS_Q_PROC_ID,t9) // Get processor id.
RESTORE_SHADOW(a1,CNS_Q_MEM_SIZE,t9) // Get memory size.
RESTORE_SHADOW(a2,CNS_Q_CYCLE_CNT,t9) // Get cycle count.
RESTORE_SHADOW(a4,CNS_Q_PROC_MASK,t9) // Get processor mask.
RESTORE_SHADOW(a5,CNS_Q_SYSCTX,t9) // Get system context.
STALL
STALL
1: mtpr zero, ptWhami // Clear WHAMI and swap flag.
mtpr t8, excAddr // Load the dispatch address.
br zero, 2f
ALIGN_BLOCK
2: NOP
mtpr zero, icFlush // Flush the icache.
NOP
NOP
NOP // Required NOPs ... 1-10
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP // Required NOPs ... 11-20
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP // Required NOPs ... 21-30
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP // Required NOPs ... 31-40
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP
NOP // Required NOPs ... 41-44
NOP
NOP
NOP
hw_rei // Dispatch in PAL mode ...