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//Original:/proj/frio/dv/testcases/seq/se_misaligned_fetch/se_misaligned_fetch.dsp
// Description: attempt to fetch code from misaligned address
# mach: bfin
# sim: --environment operating
#include "test.h"
.include "testutils.inc"
start
//
// Constants and Defines
//
include(gen_int.inc)
include(selfcheck.inc)
include(std.inc)
include(symtable.inc)
#ifndef STACKSIZE
#define STACKSIZE 0x10
#endif
#ifndef EVT
#define EVT 0xFFE02000
#endif
#ifndef EVT15
#define EVT15 0xFFE0203C
#endif
#ifndef EVT_OVERRIDE
#define EVT_OVERRIDE 0xFFE02100
#endif
#ifndef ITABLE
#define ITABLE 0xF0000000
#endif
GEN_INT_INIT(ITABLE) // set location for interrupt table
//
// Reset/Bootstrap Code
// (Here we should set the processor operating modes, initialize registers,
// etc.)
//
BOOT:
INIT_R_REGS(0); // initialize general purpose regs
INIT_P_REGS(0); // initialize the pointers
INIT_I_REGS(0); // initialize the dsp address regs
INIT_M_REGS(0);
INIT_L_REGS(0);
INIT_B_REGS(0);
LD32_LABEL(sp, KSTACK); // setup the stack pointer
FP = SP; // and frame pointer
LD32(p0, EVT); // Setup Event Vectors and Handlers
CLI R0; // hold off nonmaskables while writing EVTs
LD32_LABEL(r0, EHANDLE); // Emulation Handler (Int0)
[ P0 ++ ] = R0;
LD32_LABEL(r0, RHANDLE); // Reset Handler (Int1)
[ P0 ++ ] = R0;
LD32_LABEL(r0, NHANDLE); // NMI Handler (Int2)
[ P0 ++ ] = R0;
LD32_LABEL(r0, XHANDLE); // Exception Handler (Int3)
[ P0 ++ ] = R0;
[ P0 ++ ] = R0; // IVT4 not used
LD32_LABEL(r0, HWHANDLE); // HW Error Handler (Int5)
[ P0 ++ ] = R0;
LD32_LABEL(r0, THANDLE); // Timer Handler (Int6)
[ P0 ++ ] = R0;
LD32_LABEL(r0, I7HANDLE); // IVG7 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I8HANDLE); // IVG8 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I9HANDLE); // IVG9 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I10HANDLE);// IVG10 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I11HANDLE);// IVG11 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I12HANDLE);// IVG12 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I13HANDLE);// IVG13 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I14HANDLE);// IVG14 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I15HANDLE);// IVG15 Handler
[ P0 ++ ] = R0;
LD32(p0, EVT_OVERRIDE);
R0 = 0;
[ P0 ++ ] = R0;
R0 = -1; // Change this to mask interrupts (*)
[ P0 ] = R0; // IMASK
CSYNC; // wait for MMR writes
STI R0; // reenable events
DUMMY:
R0 = 0 (Z);
LT0 = r0; // set loop counters to something deterministic
LB0 = r0;
LC0 = r0;
LT1 = r0;
LB1 = r0;
LC1 = r0;
ASTAT = r0; // reset other internal regs
// The following code sets up the test for running in USER mode
LD32_LABEL(r0, STARTUSER);// One gets to user mode by doing a
// ReturnFromInterrupt (RTI)
RETI = r0; // We need to load the return address
// Comment the following line for a USER Mode test
// JUMP STARTSUP; // jump to code start for SUPERVISOR mode
RTI;
STARTSUP:
LD32_LABEL(p1, BEGIN);
LD32(p0, EVT15);
[ P0 ] = P1; // IVG15 (General) handler (Int 15) load with start
RAISE 15; // after we RTI, INT 15 should be taken
RTI;
//
// The Main Program
//
STARTUSER:
LD32_LABEL(sp, USTACK); // setup the stack pointer
FP = SP; // set frame pointer
JUMP BEGIN;
//*********************************************************************
BEGIN:
// COMMENT the following line for USER MODE tests
// [--sp] = RETI; // enable interrupts in supervisor mode
// **** YOUR CODE GOES HERE ****
CHECK_INIT_DEF(p0); //CHECK_INIT(p0, 0xFF7FFFFC);
LD32_LABEL(p1, TARGET);
P1 += 1; // cause access to be misaligned
JUMP ( P1 ); // should cause misaligned
R1 += 1;
R1 += 1;
R1 += 1;
R1 += 1;
R1 += 1;
R1 += 1;
R1 += 1;
R1 += 1;
TARGET:
NOP;
NOP;
NOP;
// PUT YOUR TEST HERE!
END:
CHECKREG(r5, 0xFFFFFFFF); // handler sets this if reached
dbg_pass; // End the test
//*********************************************************************
//
// Handlers for Events
//
EHANDLE: // Emulation Handler 0
RTE;
RHANDLE: // Reset Handler 1
RTI;
NHANDLE: // NMI Handler 2
RTN;
XHANDLE: // Exception Handler 3
[ -- SP ] = ASTAT; // save what we damage
[ -- SP ] = ( R7:6 );
R7 = SEQSTAT;
R7 <<= 26;
R7 >>= 26; // only want EXCAUSE
R6 = 0x2A; // EXCAUSE 0x2A means I-Fetch Misaligned Access
CC = r7 == r6;
IF CC JUMP IFETCHMISALIGNED; // If EXCAUSE != 0x2A then leave
dbg_pass; // if the EXCAUSE is wrong the test will infinite loop
IFETCHMISALIGNED:
R7 = P1; // Fix up return address
BITCLR(r7, 0); // Strip off errant LSB
RETX = r7; // and put back in RETX
R5 = -1; // set flag to indicate success
OUT:
( R7:6 ) = [ SP ++ ];
ASTAT = [sp++];
RTX;
HWHANDLE: // HW Error Handler 5
RTI;
THANDLE: // Timer Handler 6
RTI;
I7HANDLE: // IVG 7 Handler
RTI;
I8HANDLE: // IVG 8 Handler
RTI;
I9HANDLE: // IVG 9 Handler
RTI;
I10HANDLE: // IVG 10 Handler
RTI;
I11HANDLE: // IVG 11 Handler
RTI;
I12HANDLE: // IVG 12 Handler
RTI;
I13HANDLE: // IVG 13 Handler
RTI;
I14HANDLE: // IVG 14 Handler
RTI;
I15HANDLE: // IVG 15 Handler
RTI;
NOP;NOP;NOP;NOP;NOP;NOP;NOP; // needed for icache bug
//
// Data Segment
//
.data
DATA:
.space (0x10);
// Stack Segments (Both Kernel and User)
.space (STACKSIZE);
KSTACK:
.space (STACKSIZE);
USTACK:
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