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################################################################################ # opcode.s -- MIPS opcode tester for Ion project #------------------------------------------------------------------------------- # ORIGINAL AUTHOR: Steve Rhoads (rhoadss@yahoo.com) -- 1/10/01 # # This file is an edited version of 'opcodes.asm', which is part of the Plasma # project (http://opencores.org/project,plasma). # COPYRIGHT: Software placed into the public domain by the original author. # Software 'as is' without warranty. Author liable for nothing. # #------------------------------------------------------------------------------- # This assembly file tests all of the opcodes supported by the Ion core. # This test assumes that address 0x20000000 is the UART write register. # Successful tests will print out "A" or "AB" or "ABC" or .... # Missing letters or letters out of order indicate a failure. # #------------------------------------------------------------------------------- # NOTE: This test bench relies on the simulation logs to catch errors. That is, # unlike the original Plasma code, this one does not check the test success # conditions. Instead, it performs the operations to be tested and relies on you # to compare the logs from the logic simulation and the software simulation. # Test that work this way have been commented with this tag: "@log" # #------------------------------------------------------------------------------- # @note1: Hardware interrupt simulation # # Hardware interrupts can be triggered by writing to a bank of debug # registers; you can trigger any or all of the 6 hardware interrupts of the # R3000 architecture (i.e. excluding the 2 SW interrupts), with any delay you # want, measured in instruction cycles, NOT clock cycles. You can make two or # more IRQs assert at the same time for test purposes. # Both the software simulator and the VHDL simulation test bench implement # these debug registers. # Note again that the delay is given in instruction cycles. ################################################################################ #-- Set flags below to >0 to enable/disable test assembly ------------------ .set TEST_UNALIGNED_LOADS, 0 # unaligned loads .set TEST_UNALIGNED_STORES, 0 # unaligned stores .set TEST_BREAK, 1 # BREAK instruction # WARNING: the assembler expands div instructions, see 'as' manual .set TEST_DIV, 1 # DIV* instructions .set TEST_MUL, 1 # MUL* instructions .set TEST_BAD_OPCODES, 1 # Test opcode emulation trap .set TEST_TRAP_DELAY_EMU, 0 # Test emu of bad opcodes in delay slots .set TEST_HW_INTS, 1 # Test HW interrupts (@note1) .set USE_CACHE, 1 # Initialize and enable cache .set ICACHE_NUM_LINES, 256 # no. of lines in the I-Cache .set DCACHE_NUM_LINES, 256 # no. of lines in the D-Cache .set DCACHE_LINE_SIZE, 4 # D-Cache line size in words #--------------------------------------------------------------------------- .text .align 2 .globl entry .ent entry entry: .set noreorder la $gp, _gp #initialize stack pointer la $4, __bss_start #$4 = .sbss_start la $5, _end #$5 = .bss_end nop #no stack needed nop b StartTest nop # Trap handler address #.org 0x3c .org 0x0180 # We have three trap sources: syscall, break and unimplemented opcode # Plus we have to account for a faulty cause code; that's 4 causes # Besides, we have to look out for the branch delay flag (BD) # We'll just increment $4 by a fixed constant depending on the cause # so we will not save any registers (there's no stack anyway) InterruptVector: mfc0 $k0,$13 # Get trap cause code srl $k0,$k0,2 andi $k0,$k0,0x01f ori $k1,$zero,0x8 # was it a syscall? beq $k0,$k1,trap_syscall addi $k1,$k1,0x1 # was it a break? beq $k0,$k1,trap_break addi $k1,$k1,0x1 # was it a bad opcode? bne $k0,$k1,trap_invalid nop # Unimplemented instruction trap_unimplemented: .ifgt TEST_BAD_OPCODES # jump to mips32 opcode emulator with c0_cause in $k0 j opcode_emu nop .else # just do some simple arith so the opcode tester knows we were here j trap_return add $4,$4,4 .endif # Break instruction trap_break: j trap_return add $4,$4,5 # Syscall instruction trap_syscall: mfc0 $k0,$12 # test behavior of rfe: invert bit IE of SR... xori $k0,0x01 mtc0 $k0,$12 # ...and see (in the @log) if rfe recovers it j trap_return add $4,$4,6 # Invalid trap cause code, most likely hardware bug trap_invalid: j trap_return add $4,$4,0xf trap_return: mfc0 $k1,$14 # C0_EPC=14 (Exception PC) mfc0 $k0,$13 # Get bit 31 (BD) from C0 cause register srl $k0,31 andi $k0,$k0,1 bnez $k0,trap_return_delay_slot addi $k1,$k1,4 # skip trap instruction jr $k1 nop trap_return_delay_slot: addi $k1,$k1,4 # skip jump instruction too jr $k1 # (we just added 8 to epc) rfe StartTest: .ifgt USE_CACHE jal setup_cache nop .else ori $k0,$zero,0x1 mtc0 $k0,$12 # disable interrupts and cache, stay in kernel .endif li $k0,0x00020000 # enter user mode... mtc0 $k0,$12 # ...NOW mfc0 $k0,$12 # verify COP* in user mode triggers trap (@log) ori $k0,0x01 mtc0 $k0,$12 # verify COP* in user mode triggers trap (@log) # The two above COP0s should trigger a trap. The 1st one tests the delay in # entering user mode. # The rest of the tests proceed in user mode (not that there's much # difference...) lui $20,0x2000 # serial port write address ori $21,$0,'\n' # <CR> character ori $22,$0,'X' # 'X' letter ori $23,$0,'\r' ori $24,$0,0x0f80 # temp memory sb $23,0($20) # Write a message to console sb $21,0($20) sb $23,0($20) sb $21,0($20) sb $23,0($20) sb $21,0($20) sb $23,0($20) sb $21,0($20) ###################################### #Arithmetic Instructions ###################################### ArthmeticTest: ori $2,$0,'A' sb $2,0($20) ori $2,$0,'r' sb $2,0($20) ori $2,$0,'i' sb $2,0($20) ori $2,$0,'t' sb $2,0($20) ori $2,$0,'h' sb $2,0($20) sb $23,0($20) sb $21,0($20) #a: ADD ori $2,$0,'a' sb $2,0($20) ori $3,$0,5 ori $4,$0,60 add $2,$3,$4 sb $2,0($20) #A sb $23,0($20) sb $21,0($20) #b: ADDI ori $2,$0,'b' sb $2,0($20) ori $4,$0,60 addi $2,$4,5 sb $2,0($20) #A sb $23,0($20) sb $21,0($20) #c: ADDIU ori $2,$0,'c' sb $2,0($20) ori $4,$0,50 addiu $5,$4,15 sb $5,0($20) #A sb $23,0($20) sb $21,0($20) #d: ADDU ori $2,$0,'d' sb $2,0($20) ori $3,$0,5 ori $4,$0,60 add $2,$3,$4 sb $2,0($20) #A sb $23,0($20) sb $21,0($20) # DIV tests, skip conditionally .ifgt TEST_DIV #e: DIV ori $2,$0,'e' sb $2,0($20) ori $2,$0,65*117+41 ori $3,$0,117 div $2,$3 nop mflo $4 sb $4,0($20) #A mfhi $4 addi $4,$4,66-41 sb $4,0($20) #B li $2,-67*19 ori $3,$0,19 div $2,$3 nop mflo $4 sub $4,$0,$4 sb $4,0($20) #C ori $2,$0,68*23 li $3,-23 div $2,$3 nop mflo $4 sub $4,$0,$4 sb $4,0($20) #D li $2,-69*13 li $3,-13 div $2,$3 mflo $4 sb $4,0($20) #E sb $23,0($20) sb $21,0($20) #f: DIVU ori $2,$0,'f' sb $2,0($20) ori $2,$0,65*13 ori $3,$0,13 divu $2,$3 nop mflo $4 sb $4,0($20) #A sb $23,0($20) sb $21,0($20) .endif # MUL tests, skip conditionally .ifgt TEST_MUL #g: MULT ori $2,$0,'g' sb $2,0($20) ori $2,$0,5 ori $3,$0,13 mult $2,$3 nop mflo $4 sb $4,0($20) #A li $2,-5 ori $3,$0,13 mult $2,$3 mfhi $5 mflo $4 sub $4,$0,$4 addu $4,$4,$5 addi $4,$4,2 sb $4,0($20) #B ori $2,$0,5 li $3,-13 mult $2,$3 mfhi $5 mflo $4 sub $4,$0,$4 addu $4,$4,$5 addi $4,$4,3 sb $4,0($20) #C li $2,-5 li $3,-13 mult $2,$3 mfhi $5 mflo $4 addu $4,$4,$5 addi $4,$4,3 sb $4,0($20) #D lui $4,0xfe98 ori $4,$4,0x62e5 lui $5,0x6 ori $5,0x8db8 mult $4,$5 mfhi $6 addiu $7,$6,2356+1+'E' #E sb $7,0($20) sb $23,0($20) sb $21,0($20) #h: MULTU ori $2,$0,'h' sb $2,0($20) ori $2,$0,5 ori $3,$0,13 multu $2,$3 nop mflo $4 sb $4,0($20) #A sb $23,0($20) sb $21,0($20) .endif #i: SLT ori $2,$0,'i' sb $2,0($20) ori $2,$0,10 ori $3,$0,12 slt $4,$2,$3 addi $5,$4,64 sb $5,0($20) #A slt $4,$3,$2 addi $5,$4,66 sb $5,0($20) #B li $2,0xfffffff0 slt $4,$2,$3 addi $5,$4,66 sb $5,0($20) #C slt $4,$3,$2 addi $5,$4,68 sb $5,0($20) #D li $3,0xffffffff slt $4,$2,$3 addi $5,$4,68 sb $5,0($20) #E slt $4,$3,$2 addi $5,$4,70 sb $5,0($20) #F sb $23,0($20) sb $21,0($20) #j: SLTI ori $2,$0,'j' sb $2,0($20) ori $2,$0,10 slti $4,$2,12 addi $5,$4,64 sb $5,0($20) #A slti $4,$2,8 addi $5,$4,66 sb $5,0($20) #B sb $23,0($20) sb $21,0($20) #k: SLTIU ori $2,$0,'k' sb $2,0($20) ori $2,$0,10 sltiu $4,$2,12 addi $5,$4,64 sb $5,0($20) #A sltiu $4,$2,8 addi $5,$4,66 sb $5,0($20) #B sb $23,0($20) sb $21,0($20) #l: SLTU ori $2,$0,'l' sb $2,0($20) ori $2,$0,10 ori $3,$0,12 slt $4,$2,$3 addi $5,$4,64 sb $5,0($20) #A slt $4,$3,$2 addi $5,$4,66 sb $5,0($20) #B sb $23,0($20) sb $21,0($20) #m: SUB ori $2,$0,'m' sb $2,0($20) ori $3,$0,70 ori $4,$0,5 sub $2,$3,$4 sb $2,0($20) #A sb $23,0($20) sb $21,0($20) #n: SUBU ori $2,$0,'n' sb $2,0($20) ori $3,$0,70 ori $4,$0,5 sub $2,$3,$4 sb $2,0($20) #A sb $23,0($20) sb $21,0($20) ###################################### #Branch and Jump Instructions ###################################### BranchTest: ori $2,$0,'B' sb $2,0($20) ori $2,$0,'r' sb $2,0($20) ori $2,$0,'a' sb $2,0($20) ori $2,$0,'n' sb $2,0($20) ori $2,$0,'c' sb $2,0($20) ori $2,$0,'h' sb $2,0($20) sb $23,0($20) sb $21,0($20) #a: B ori $2,$0,'a' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' b $B1 sb $10,0($20) sb $22,0($20) $B1: sb $11,0($20) sb $23,0($20) sb $21,0($20) #b: BAL ori $2,$0,'b' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $14,$0,'E' ori $15,$0,'X' bal $BAL1 sb $10,0($20) sb $13,0($20) b $BAL2 sb $14,0($20) sb $15,0($20) $BAL1: sb $11,0($20) jr $31 sb $12,0($20) sb $22,0($20) $BAL2: sb $23,0($20) sb $21,0($20) #c: BEQ ori $2,$0,'c' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $2,$0,100 ori $3,$0,123 ori $4,$0,123 beq $2,$3,$BEQ1 sb $10,0($20) sb $11,0($20) beq $3,$4,$BEQ1 sb $12,0($20) sb $22,0($20) $BEQ1: sb $13,0($20) sb $23,0($20) sb $21,0($20) #d: BGEZ ori $2,$0,'d' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' or $15,$0,'X' ori $2,$0,100 li $3,0xffff1234 ori $4,$0,123 bgez $3,$BGEZ1 sb $10,0($20) sb $11,0($20) bgez $2,$BGEZ1 sb $12,0($20) sb $22,0($20) $BGEZ1: bgez $0,$BGEZ2 nop sb $15,0($20) $BGEZ2: sb $13,0($20) sb $23,0($20) sb $21,0($20) #e: BGEZAL ori $2,$0,'e' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $14,$0,'E' ori $15,$0,'X' li $3,0xffff1234 bgezal $3,$BGEZAL1 nop sb $10,0($20) bgezal $0,$BGEZAL1 nop sb $13,0($20) b $BGEZAL2 sb $14,0($20) sb $15,0($20) $BGEZAL1: sb $11,0($20) jr $31 sb $12,0($20) sb $22,0($20) $BGEZAL2: sb $23,0($20) sb $21,0($20) #f: BGTZ ori $2,$0,'f' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $2,$0,100 li $3,0xffff1234 bgtz $3,$BGTZ1 sb $10,0($20) sb $11,0($20) bgtz $2,$BGTZ1 sb $12,0($20) sb $22,0($20) $BGTZ1: sb $13,0($20) sb $23,0($20) sb $21,0($20) #g: BLEZ ori $2,$0,'g' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $2,$0,100 li $3,0xffff1234 blez $2,$BLEZ1 sb $10,0($20) sb $11,0($20) blez $3,$BLEZ1 sb $12,0($20) sb $22,0($20) $BLEZ1: blez $0,$BLEZ2 nop sb $22,0($20) $BLEZ2: sb $13,0($20) sb $23,0($20) sb $21,0($20) #h: BLTZ ori $2,$0,'h' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $14,$0,'E' ori $2,$0,100 li $3,0xffff1234 ori $4,$0,0 bltz $2,$BLTZ1 sb $10,0($20) sb $11,0($20) bltz $3,$BLTZ1 sb $12,0($20) sb $22,0($20) $BLTZ1: bltz $4,$BLTZ2 nop sb $13,0($20) $BLTZ2: sb $14,0($20) sb $23,0($20) sb $21,0($20) #i: BLTZAL ori $2,$0,'i' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $14,$0,'E' ori $15,$0,'X' li $3,0xffff1234 bltzal $0,$BLTZAL1 nop sb $10,0($20) bltzal $3,$BLTZAL1 nop sb $13,0($20) b $BLTZAL2 sb $14,0($20) sb $15,0($20) $BLTZAL1: sb $11,0($20) jr $31 sb $12,0($20) sb $22,0($20) $BLTZAL2: sb $23,0($20) sb $21,0($20) #j: BNE ori $2,$0,'j' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $2,$0,100 ori $3,$0,123 ori $4,$0,123 bne $3,$4,$BNE1 sb $10,0($20) sb $11,0($20) bne $2,$3,$BNE1 sb $12,0($20) sb $22,0($20) $BNE1: sb $13,0($20) sb $23,0($20) sb $21,0($20) #k: J ori $2,$0,'k' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $15,$0,'X' j $J1 sb $10,0($20) sb $15,0($20) $J1: sb $11,0($20) sb $23,0($20) sb $21,0($20) #l: JAL ori $2,$0,'l' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $14,$0,'E' ori $15,$0,'X' jal $JAL1 sb $10,0($20) sb $13,0($20) b $JAL2 sb $14,0($20) sb $15,0($20) $JAL1: sb $11,0($20) jr $31 sb $12,0($20) sb $22,0($20) $JAL2: sb $23,0($20) sb $21,0($20) #m: JALR ori $2,$0,'m' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $12,$0,'C' ori $13,$0,'D' ori $14,$0,'E' ori $15,$0,'X' la $3,$JALR1 jalr $3 sb $10,0($20) sb $13,0($20) b $JALR2 sb $14,0($20) sb $15,0($20) $JALR1: sb $11,0($20) jr $31 sb $12,0($20) sb $22,0($20) $JALR2: sb $23,0($20) sb $21,0($20) #n: JR ori $2,$0,'n' sb $2,0($20) ori $10,$0,'A' ori $11,$0,'B' ori $15,$0,'X' la $3,$JR1 jr $3 sb $10,0($20) sb $15,0($20) $JR1: sb $11,0($20) sb $23,0($20) sb $21,0($20) #o: NOP ori $2,$0,'o' sb $2,0($20) ori $2,$0,65 nop sb $2,0($20) sb $23,0($20) sb $21,0($20) # b LoadTest BreakTest: .ifgt TEST_BREAK #p: BREAK ori $2,$0,'p' # check if it jumps to break address and comes back sb $2,0($20) ori $2,$0,'z' ori $4,$0,59 break 0 addi $4,$4,1 sb $4,0($20) break 0 # check if load instruction is aborted (@log) lb $2,16($2) break 0 # check if jump instruction is aborted (@log) j break_jump_test1 add $4,$4,5 break_jump_test1: add $4,$4,1 # make sure the jump shows in the log (@log) break 0 # check if store instruction is aborted sb $4,0($20) j break_jump_test2 # check if break works in delay slot of jump break 0 nop j break_continue nop break_jump_test2: add $4,$4,1 break_continue: sb $23,0($20) sb $21,0($20) .endif #q: SYSCALL ori $2,$0,'q' # check if it jumpts to trap vector and comes back sb $2,0($20) ori $4,$0,61 syscall 0 addi $4,$4,-1 sb $4,0($20) syscall 0 # check if load instruction is aborted (@log) lb $2,16($2) syscall 0 # check if jump instruction is aborted (@log) j syscall_jump_test1 add $4,$4,5 syscall_jump_test1: add $4,$4,1 # make sure the jump shows in the log (@log) j syscall_jump_test2 # check if syscall works in delay slot of jump syscall 0 nop j syscall_continue nop syscall_jump_test2: add $4,$4,1 syscall_continue: sb $23,0($20) sb $21,0($20) ###################################### #Load, Store, and Memory Control Instructions ###################################### LoadTest: ori $2,$0,'L' sb $2,0($20) ori $2,$0,'o' sb $2,0($20) ori $2,$0,'a' sb $2,0($20) ori $2,$0,'d' sb $2,0($20) sb $23,0($20) sb $21,0($20) #a: LB ori $2,$0,'a' sb $2,0($20) or $2,$0,$24 li $3,0x414243fc sw $3,16($2) # 16($2) = 0x414243fc lb $4,16($2) # $4 = 0x41 sb $4,0($20) # UART = 0x41 lb $4,17($2) # $4 = 0x42 nop sb $4,0($20) # UART = 0x42 lb $4,18($2) # $4 = 0x43 nop sb $4,0($20) # UART = 0x43 lb $2,19($2) # $2 = 0xffff.fffc nop sra $3,$2,8 # $3 = 0xffff.ffff addi $3,$3,0x45 # $3 = 0x44 sb $3,0($20) # UART = 0x44 addi $2,$2,0x49 # $4 = 0x45, overflow sb $2,0($20) # UART = 0x45 sb $23,0($20) # UART = CR sb $21,0($20) # UART = LF #b: LBU ori $2,$0,'b' sb $2,0($20) or $2,$0,$24 li $3,0x41424344 sw $3,16($2) lb $4,16($2) sb $4,0($20) lb $4,17($2) sb $4,0($20) lb $4,18($2) sb $4,0($20) lb $2,19($2) sb $2,0($20) sb $23,0($20) sb $21,0($20) #c: LH ori $2,$0,'c' sb $2,0($20) or $2,$0,$24 li $3,0x00410042 sw $3,16($2) lh $4,16($2) sb $4,0($20) lh $2,18($2) sb $2,0($20) sb $23,0($20) sb $21,0($20) #d: LHU ori $2,$0,'d' sb $2,0($20) or $2,$0,$24 li $3,0x00410042 sw $3,16($2) lh $4,16($2) sb $4,0($20) lh $2,18($2) sb $2,0($20) sb $23,0($20) sb $21,0($20) #e: LW ori $2,$0,'e' sb $2,0($20) or $2,$0,$24 li $3,'A' sw $3,16($2) ori $3,$0,0 lw $2,16($2) sb $2,0($20) sb $23,0($20) sb $21,0($20) .ifgt TEST_UNALIGNED_LOADS #f: LWL & LWR ori $2,$0,'f' sb $2,0($20) or $2,$0,$24 li $3,'A' sw $3,16($2) ori $3,$0,0 lwl $2,16($2) lwr $2,16($2) sb $2,0($20) sb $23,0($20) sb $21,0($20) .endif #g: SB ori $2,$0,'g' sb $2,0($20) ori $2,$0,'A' sb $2,0($20) sb $23,0($20) sb $21,0($20) #h: SH ori $2,$0,'h' sb $2,0($20) or $4,$0,$24 ori $2,$0,0x4142 sh $2,16($4) lb $3,16($4) sb $3,0($20) lb $2,17($4) sb $2,0($20) sb $23,0($20) sb $21,0($20) #i: SW ori $2,$0,'i' sb $2,0($20) or $2,$0,$24 li $3,0x41424344 sw $3,16($2) lb $4,16($2) sb $4,0($20) lb $4,17($2) sb $4,0($20) lb $4,18($2) sb $4,0($20) lb $2,19($2) sb $2,0($20) sb $23,0($20) sb $21,0($20) .ifgt TEST_UNALIGNED_STORES #j: SWL & SWR ori $2,$0,'j' sb $2,0($20) or $2,$0,$24 li $3,0x41424344 swl $3,16($2) swr $3,16($2) lb $4,16($2) sb $4,0($20) lb $4,17($2) sb $4,0($20) lb $4,18($2) sb $4,0($20) lb $2,19($2) sb $2,0($20) sb $23,0($20) sb $21,0($20) .endif ###################################### #Logical Instructions ###################################### LogicalTest: ori $2,$0,'L' sb $2,0($20) ori $2,$0,'o' sb $2,0($20) ori $2,$0,'g' sb $2,0($20) ori $2,$0,'i' sb $2,0($20) ori $2,$0,'c' sb $2,0($20) sb $23,0($20) sb $21,0($20) #a: AND ori $2,$0,'a' sb $2,0($20) ori $2,$0,0x0741 ori $3,$0,0x60f3 and $4,$2,$3 sb $4,0($20) sb $23,0($20) sb $21,0($20) #b: ANDI ori $2,$0,'b' sb $2,0($20) ori $2,$0,0x0741 andi $4,$2,0x60f3 sb $4,0($20) sb $23,0($20) sb $21,0($20) #c: LUI ori $2,$0,'c' sb $2,0($20) lui $2,0x41 srl $3,$2,16 sb $3,0($20) sb $23,0($20) sb $21,0($20) #d: NOR ori $2,$0,'d' sb $2,0($20) li $2,0xf0fff08e li $3,0x0f0f0f30 nor $4,$2,$3 sb $4,0($20) sb $23,0($20) sb $21,0($20) #e: OR ori $2,$0,'e' sb $2,0($20) ori $2,$0,0x40 ori $3,$0,0x01 or $4,$2,$3 sb $4,0($20) sb $23,0($20) sb $21,0($20) #f: ORI ori $2,$0,'f' sb $2,0($20) ori $2,$0,0x40 ori $4,$2,0x01 sb $4,0($20) sb $23,0($20) sb $21,0($20) #g: XOR ori $2,$0,'g' sb $2,0($20) ori $2,$0,0xf043 ori $3,$0,0xf002 xor $4,$2,$3 sb $4,0($20) sb $23,0($20) sb $21,0($20) #h: XORI ori $2,$0,'h' sb $2,0($20) ori $2,$0,0xf043 xor $4,$2,0xf002 sb $4,0($20) sb $23,0($20) sb $21,0($20) ###################################### #Move Instructions ###################################### MoveTest: ori $2,$0,'M' sb $2,0($20) ori $2,$0,'o' sb $2,0($20) ori $2,$0,'v' sb $2,0($20) ori $2,$0,'e' sb $2,0($20) sb $23,0($20) sb $21,0($20) # HI and LO are only implemented if the mul/div block is .ifgt (TEST_DIV + TEST_MUL) #a: MFHI ori $2,$0,'a' sb $2,0($20) ori $2,$0,65 mthi $2 mfhi $3 sb $3,0($20) sb $23,0($20) sb $21,0($20) #b: MFLO ori $2,$0,'b' sb $2,0($20) ori $2,$0,65 mtlo $2 mflo $3 sb $3,0($20) sb $23,0($20) sb $21,0($20) #c: MTHI ori $2,$0,'c' sb $2,0($20) ori $2,$0,65 mthi $2 mfhi $3 sb $3,0($20) sb $23,0($20) sb $21,0($20) #d: MTLO ori $2,$0,'d' sb $2,0($20) ori $2,$0,66 # use 'B' instead of 'A' to cach change in HI and LO mtlo $2 mflo $3 sb $3,0($20) sb $23,0($20) sb $21,0($20) .endif ###################################### #Shift Instructions ###################################### ShiftTest: ori $2,$0,'S' sb $2,0($20) ori $2,$0,'h' sb $2,0($20) ori $2,$0,'i' sb $2,0($20) ori $2,$0,'f' sb $2,0($20) ori $2,$0,'t' sb $2,0($20) sb $23,0($20) sb $21,0($20) #a: SLL ori $2,$0,'a' sb $2,0($20) li $2,0x40414243 sll $3,$2,8 srl $3,$3,24 sb $3,0($20) sb $23,0($20) sb $21,0($20) #b: SLLV ori $2,$0,'b' sb $2,0($20) li $2,0x40414243 ori $3,$0,8 sllv $3,$2,$3 srl $3,$3,24 sb $3,0($20) sb $23,0($20) sb $21,0($20) #c: SRA ori $2,$0,'c' sb $2,0($20) li $2,0x40414243 sra $3,$2,16 sb $3,0($20) li $2,0x84000000 sra $3,$2,25 sub $3,$3,0x80 sb $3,0($20) sb $23,0($20) sb $21,0($20) #d: SRAV ori $2,$0,'d' sb $2,0($20) li $2,0x40414243 ori $3,$0,16 srav $3,$2,$3 sb $3,0($20) ori $3,$0,25 li $2,0x84000000 srav $3,$2,$3 sub $3,$3,0x80 sb $3,0($20) sb $23,0($20) sb $21,0($20) #e: SRL ori $2,$0,'e' sb $2,0($20) li $2,0x40414243 srl $3,$2,16 sb $3,0($20) li $2,0x84000000 srl $3,$2,25 sb $3,0($20) sb $23,0($20) sb $21,0($20) #f: SRLV ori $2,$0,'f' sb $2,0($20) li $2,0x40414243 ori $3,$0,16 srlv $4,$2,$3 sb $4,0($20) ori $3,$0,25 li $2,0x84000000 srlv $3,$2,$3 sb $3,0($20) sb $23,0($20) sb $21,0($20) ###################################### #Emulated MIPS32r2 Instructions ###################################### .ifgt TEST_BAD_OPCODES ori $2,$0,'M' sb $2,0($20) ori $2,$0,'i' sb $2,0($20) ori $2,$0,'p' sb $2,0($20) ori $2,$0,'s' sb $2,0($20) ori $2,$0,'3' sb $2,0($20) ori $2,$0,'2' sb $2,0($20) ori $2,$0,'r' sb $2,0($20) ori $2,$0,'2' sb $2,0($20) sb $23,0($20) sb $21,0($20) #-- EXT --------------------------- ori $a1,$zero,'a' sb $a1,0($20) li $a0,0x01234567 ext $a1,$a0,12,8 addi $a1,$a1,'A' - 0x34 sb $a1,0($20) ext $a1,$a0,0,8 addi $a1,$a1,'B' - 0x67 sb $a1,0($20) ext $a1,$a0,0,4 addi $a1,$a1,'C' - 0x7 sb $a1,0($20) ext $a2,$a0,20,12 addi $a2,$a2,'D' - 0x012 sb $a2,0($20) sb $23,0($20) sb $21,0($20) #-- INS --------------------------- ori $a1,$zero,'b' sb $a1,0($20) li $a0,0x01234567 ori $a2,$zero,0xc35a test_ins_1: move $a1,$a0 ins $a1,$a2,0,8 li $a3,0x0123455a bne $a3,$a1,test_ins_2 ori $a1,$zero,'A' sb $a1,0($20) test_ins_2: move $a1,$a0 ins $a1,$a2,4,8 li $a3,0x012345a7 bne $a3,$a1,test_ins_3 ori $a1,$zero,'B' sb $a1,0($20) test_ins_3: move $a1,$a0 ins $a1,$a2,24,8 li $a3,0x5a234567 bne $a3,$a1,test_ins_4 ori $a1,$zero,'C' sb $a1,0($20) test_ins_4: move $a1,$a0 ins $a1,$a2,30,2 li $a3,0x81234567 bne $a3,$a1,test_ins_5 ori $a1,$zero,'D' sb $a1,0($20) test_ins_5: sb $23,0($20) sb $21,0($20) #-- CLZ --------------------------- ori $a1,$zero,'c' sb $a1,0($20) li $a1,0x00080000 clz $a1,$a1 addiu $a1,$a1,'A'-12 sb $a1,0($20) li $a1,0x40000000 clz $a1,$a1 addiu $a1,$a1,'B'-1 sb $a1,0($20) clz $a1,$zero addiu $a1,$a1,'C'-32 sb $a1,0($20) li $k1,0x80000000 clz $k0,$k1 addiu $a1,$k0,'D'-0 sb $a1,0($20) sb $23,0($20) sb $21,0($20) #-- CLO --------------------------- ori $a1,$zero,'d' sb $a1,0($20) li $a1,0xfff7ffff clo $a1,$a1 addiu $a1,$a1,'A'-12 sb $a1,0($20) li $a1,0xbfffffff clo $a1,$a1 addiu $a1,$a1,'B'-1 sb $a1,0($20) li $a1,0xffffffff clo $a1,$a1 addiu $a1,$a1,'C'-32 sb $a1,0($20) li $k1,0x7fffffff clo $k0,$k1 addiu $a1,$k0,'D'-0 sb $a1,0($20) sb $23,0($20) sb $21,0($20) # FIXME should test the bad opcode emulation in delay slots .endif # Print 'Done'; the rest of the tests are for log matching only ori $2,$0,'D' sb $2,0($20) ori $2,$0,'o' sb $2,0($20) ori $2,$0,'n' sb $2,0($20) ori $2,$0,'e' sb $2,0($20) sb $23,0($20) sb $21,0($20) # These tests are to be evaluated by matching logs with the software # simulator. There is no need to perform any actual tests here, if there is # any error it will show up as a mismatch in the logs. #-- Arithmetic -------------------------------------------------- ori $s0,$zero,0xa5a5 ori $s1,$zero,15 ori $s2,$zero,1 li $s3,-1 li $s4,-1000 li $s5,0x80000000 li $s6,0x7fffffff #-- ADD --------------------------- move $t0,$s0 # P + P = P move $t1,$s1 add $t0,$t1,$s1 move $t0,$s0 # P + N = P move $t1,$s1 add $t0,$t1,$s3 move $t0,$s0 # P + N = N move $t1,$s1 add $t0,$t1,$s4 move $t0,$s0 # P + P = N (overflow) move $t1,$s6 add $t0,$t1,$s6 move $t0,$s0 # N + N = P (overflow) move $t1,$s5 add $t0,$t1,$s5 #-- ADDI -------------------------- move $t0,$s0 # N + N = P (overflow) move $t1,$s5 addi $t0,$t1,-1 move $t0,$s0 # N + P = N move $t1,$s5 addi $t0,$t1,15 move $t0,$s0 # N + P = P move $t1,$s3 addi $t0,$t1,2 move $t0,$s0 # P + P = P move $t1,$s1 addi $t0,$t1,2 move $t0,$s0 # P + P = N (overflow) move $t1,$s6 addi $t0,$t1,2 #-- ADDIU ------------------------- move $t0,$s0 # N + N = P (overflow) move $t1,$s5 addiu $t0,$t1,-1 move $t0,$s0 # N + P = N move $t1,$s5 addiu $t0,$t1,15 move $t0,$s0 # N + P = P move $t1,$s3 addiu $t0,$t1,2 move $t0,$s0 # P + P = P move $t1,$s1 addiu $t0,$t1,2 move $t0,$s0 # P + P = N (overflow) move $t1,$s6 addiu $t0,$t1,2 #-- ADDU -------------------------- move $t0,$s0 # P + P = P move $t1,$s1 addu $t0,$t1,$s1 move $t0,$s0 # P + N = P move $t1,$s1 addu $t0,$t1,$s3 move $t0,$s0 # P + N = N move $t1,$s1 addu $t0,$t1,$s4 move $t0,$s0 # P + P = N (overflow) move $t1,$s6 addu $t0,$t1,$s6 move $t0,$s0 # N + N = P (overflow) move $t1,$s5 addu $t0,$t1,$s5 #-- SUB --------------------------- move $t0,$s0 # P - P = P move $t1,$s2 sub $t0,$t1,$s1 move $t0,$s0 # P - N = P move $t1,$s1 add $t0,$t1,$s3 move $t0,$s0 # P + N = N move $t1,$s1 add $t0,$t1,$s4 move $t0,$s0 # P + P = N (overflow) move $t1,$s6 add $t0,$t1,$s6 move $t0,$s0 # N + N = P (overflow) move $t1,$s5 add $t0,$t1,$s5 # SLT, SLTI, SLTIU ori $a2,$zero,0xa5a5 ori $a0,$zero,15 ori $a1,$zero,1 move $v0,$a3 slt $v0,$a0,$a1 move $v0,$a3 slt $v0,$a1,$a0 move $v0,$a3 slti $v0,$a0,1 move $v0,$a3 slti $v0,$a1,15 move $v0,$a3 sltiu $v0,$a0,1 move $v0,$a3 sltiu $v0,$a1,15 li $a1,0xa5a5 li $a0,1029 addiu $a0,$a0,-2000 sltu $a1,$a0,1000 #-- Relative jumps ---------------------------------------------- li $s0,0x7fffffff ori $s1,1000 ori $s1,15 ori $s1,2 li $s4,0x80000000 li $s5,-1001 li $s6,-16 li $s7,-3 bgtz $s1,test_b0 nop ori $v0,0x5500 test_b0: bgtz $s7,test_b1 nop ori $v0,0x5501 test_b1: bgtz $s0,test_b2 nop ori $v0,0x5502 test_b2: bgtz $s4,test_b3 nop ori $v0,0x5503 test_b3: bgez $s1,test_b4 nop ori $v0,0x5500 test_b4: bgez $s7,test_b5 nop ori $v0,0x5501 test_b5: bgez $s0,test_b6 nop ori $v0,0x5502 test_b6: bgez $s4,test_b7 nop ori $v0,0x5503 test_b7: bltz $s1,test_b8 nop ori $v0,0x5500 test_b8: bltz $s7,test_b9 nop ori $v0,0x5501 test_b9: bltz $s0,test_b10 nop ori $v0,0x5502 test_b10: bltz $s4,test_b11 nop ori $v0,0x5503 test_b11: #-- Hardware interrupts ----------------------------------------- test_hw_irq: .ifgt TEST_HW_INTS li $a0,0x20010000 # base address of debug reg block # Trigger IRQ_0 in 10 instruction cycles (@note1) #lhu $a1,10 # load irq count down register... li $a1,10 sw $a1,0($a0) lhu $a2,20 test_hw_irq_0: bnez $a2,test_hw_irq_0 # ...and wait for irq to trigger addiu $a2,$a2,-1 # When we arrive here, we should have executed the irq handler if # the irq worked properly, so check it. # FIXME incomplete code, stopped work here .endif $DONE: j $DONE # End in an infinite loop nop # void setup_cache(void) -- invalidates all I- and D-Cache lines (uses no RAM) setup_cache: li $a0,0x00010002 # Enable I-cache line invalidation mtc0 $a0,$12 # In order to invalidate a I-Cache line we have to write its tag number to # any address while bits CP0[12].17:16=01. The write will be executed as a # regular write too, as a side effect, so we need to choose a harmless # target address. The BSS will do -- it will be cleared later. # We'll cover all ICACHE_NUM_LINES lines no matter what the starting # address is, anyway. la $a0,__bss_start li $a2,0 li $a1,ICACHE_NUM_LINES-1 inv_i_cache_loop: sw $a2,0($a0) blt $a2,$a1,inv_i_cache_loop addi $a2,1 # Now, the D-Cache is different. To invalidate a D-Cache line you just # read from it (by proper selection of a dummy target address) while bits # CP0[12].17:16=01. The data read is undefined and should be discarded. li $a0,0 # Use any base address that is mapped li $a2,0 li $a1,DCACHE_NUM_LINES-1 inv_d_cache_loop: lw $zero,0($a0) addi $a0,DCACHE_LINE_SIZE*4 blt $a2,$a1,inv_d_cache_loop addi $a2,1 li $a1,0x00020002 # Leave with cache enabled jr $ra mtc0 $a1,$12 .set reorder .end entry
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