changed the code not to use r11 (specifically) and r8,r9 for good

measure. The rest of the registers I used are touched by the tlaser
platform code so I would guess their are fair game.
Random memory troubles hopefully over.
This commit is contained in:
Ali Saidi 2004-07-01 01:28:45 -04:00
parent ad63f2e67e
commit ae3ba61665

View file

@ -756,17 +756,17 @@ sys_int_23:
ALIGN_BRANCH
sys_int_22:
or r31,1,r16 // a0 means it is a clock interrupt
lda r8,0xf01(r31) // build up an address for the MISC register
sll r8,16,r8
lda r8,0xa000(r8)
sll r8,16,r8
lda r8,0x080(r8)
lda r12,0xf01(r31) // build up an address for the MISC register
sll r12,16,r12
lda r12,0xa000(r12)
sll r12,16,r12
lda r12,0x080(r12)
ldq_p r10,0(r8) // read misc register
ldq_p r10,0(r12) // read misc register
and r10,0x3,r10 // isolate CPUID
or r31,0x10,r9 // load r9 with bit to clear
sll r9,r10,r9 // left shift by CPU ID
stq_p r9, 0(r8) // clear the rtc interrupt
or r31,0x10,r14 // load r9 with bit to clear
sll r14,r10,r14 // left shift by CPU ID
stq_p r14, 0(r12) // clear the rtc interrupt
br r31, pal_post_interrupt // Tell the OS
@ -802,56 +802,57 @@ sys_int_20:
ALIGN_BRANCH
sys_int_21:
or r31,3,r16 // a0 means it is a I/O interrupt
lda r8,0xf01(r31)
sll r8,32,r8
ldah r9,0xa0(r31)
sll r9,8,r9
bis r8,r9,r8
lda r8,0x0080(r8)
ldqp r9, 0(r8) // read the MISC register for CPUID
lda r12,0xf01(r31)
sll r12,32,r12
ldah r13,0xa0(r31)
sll r13,8,r13
bis r12,r13,r12
lda r12,0x0080(r12)
ldqp r13, 0(r12) // read the MISC register for CPUID
and r9,0x1,r10 // grab LSB and shift left 2
sll r10,2,r10
and r9,0x2,r11 // grabl LSB+1 and shift left 5
sll r11,5,r11
and r13,0x1,r14 // grab LSB and shift left 2
sll r14,2,r14
and r13,0x2,r10 // grabl LSB+1 and shift left 5
sll r10,5,r10
mskbl r8,0,r8 // calculate DIRn address
lda r9,0x280(r31)
bis r8,r9,r8
or r8,r10,r8
or r8,r11,r8
ldqp r9, 0(r8) // read DIRn
mskbl r12,0,r12 // calculate DIRn address
lda r13,0x280(r31)
bis r12,r13,r12
or r12,r14,r12
or r12,r10,r12
ldqp r13, 0(r12) // read DIRn
or r31,1,r10 // set bit 55 (ISA Interrupt)
sll r10,55,r10
or r31,1,r14 // set bit 55 (ISA Interrupt)
sll r14,55,r14
and r9, r10, r10 // check if bit 55 is set
lda r13,0x900(r31) // load offset for normal into r13
beq r10, normal_int // if not compute the vector normally
and r13, r14, r14 // check if bit 55 is set
lda r16,0x900(r31) // load offset for normal into r13
beq r14, normal_int // if not compute the vector normally
lda r13,0x800(r31) // replace with offset for pic
lda r8,0xf01(r31) // build an addr to access PIC
sll r8,32,r8 // at f01fc000000
ldah r9,0xfc(r31)
sll r9,8,r9
bis r8,r9,r8
ldqp r9,0x0020(r8) // read PIC1 ISR for interrupting dev
lda r16,0x800(r31) // replace with offset for pic
lda r12,0xf01(r31) // build an addr to access PIC
sll r12,32,r12 // at f01fc000000
ldah r13,0xfc(r31)
sll r13,8,r13
bis r12,r13,r12
ldqp r13,0x0020(r12) // read PIC1 ISR for interrupting dev
normal_int:
//ctlz r9,r10 // count the number of leading zeros
//ctlz r13,r14 // count the number of leading zeros
// EV5 doesn't have ctlz, but we do, so lets use it
.byte 0x4a
.byte 0x4e
.byte 0x06
.byte 0xe9
.byte 0xed
.byte 0x73
lda r11,63(r31)
subq r11,r10,r17 // subtract from
lda r10,63(r31)
subq r10,r14,r17 // subtract from
lda r9,0x10(r31)
mulq r17,r9,r17 // compute 0x900 + (0x10 * Highest DIRn-bit)
addq r17,r13,r17
lda r13,0x10(r31)
mulq r17,r13,r17 // compute 0x900 + (0x10 * Highest DIRn-bit)
addq r17,r16,r17
or r31,3,r16 // a0 means it is a I/O interrupt
br r31, pal_post_interrupt