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[/] [ion/] [trunk/] [src/] [common/] [opcode_emu.s] - Rev 239
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#------------------------------------------------------------------------------- # opcode_emu.s -- Emulation of some mips-32 opcodes in trap handler # # Operation: # 1.- If the trapped opcode is one of the emulated opcodes, it is emulated. # 2.- Otherwise, nothing is done (as if the trapped opcode was a NOP) and a flag # is set in the emu_frame area (meant for debugging, mostly). # 3.- In either case, if the trapped opcode is in a jump delay slot, the jump # instruction is emulated. # FIXME it isn't yet # # Uses a small workspace in the BSS section. Does NOT use the regular stack # nor makes any assumptions about any registers, including the sp. # #------------------------------------------------------------------------------- # This is a trap handler meant to emulate those few MIPS32r1/r2 opcodes that # gcc commonly emits even for a -mips1 target. This happens specially when using # soft floating point. # The opcodes chosen for emulation are those actually observed in real gcc # programs. This is easier, for the time being, than replacing a whole host of # gcc support functions. # # Emulates the following opcodes: # EXT, INS, CLO, CLZ # # FIXME these opcodes will be emulated eventually: # MUL (3-reg version), LWL, LWR, SWL, SWR #------------------------------------------------------------------------------- # Size of work space .set EMU_FRAME_SIZE, 64 # Reserve work space in BSS segment .comm emu_frame, EMU_FRAME_SIZE .text .align 2 .set noreorder .global opcode_emu # $k0 = cp0.cause on entry, other registers have their original value opcode_emu: # Save the CPU state. # No nested exceptions are to be allowed, so we only save the registers # we're going to use and leave the CP0 registers unsaved. la $k1,emu_frame+EMU_FRAME_SIZE-4 sw $sp,-16($k1) sw $ra,-20($k1) sw $t0,-24($k1) sw $t1,-28($k1) sw $t2,-32($k1) move $sp,$k1 mfc0 $t0,$14 # get bad opcode (or branch opcode if in DS) lw $k0,0($t0) # Handle delay slot situation: emulate jump if necessary mfc0 $k1,$13 # Check bit 31 (BD) from C0 cause register bltzal $k1,emulate_branch nop # decode instruction: either SPECIAL3 or SPECIAL2 srl $t1,$k0,26 xori $t0,$t1,0x01f beqz $t0,mips32_special3 xori $t0,$t1,0x01c beqz $t0,mips32_special2 nop # if it was none of the above we will just ignore it # Write ignored opcode to some debug register for external reference # (this is to be used bu the SW simulator, mostly) li $t0,0x20010000 sw $k0,1024($t0) # Run into opcode_emu_return opcode_emu_return: # restore modified registers lw $t2,-32($sp) lw $t1,-28($sp) lw $t0,-24($sp) lw $ra,-20($sp) lw $sp,-16($sp) # return to interrupted code, handling trap-in-delay-slot cases properly 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,mips32_emu_return_delay_slot addi $k1,$k1,4 # skip 'victim' instruction jr $k1 nop mips32_emu_return_delay_slot: addi $k1,$k1,4 # skip jump instruction too (it's been emulated) jr $k1 # (we just added 8 to epc) rfe # SPECIAL2 opcodes # entry: k0=opcode mips32_special2: andi $k1,$k0,0x03f xori $t0,$k1,0x020 beqz $t0,mips32_CLZ xori $t0,$k1,0x021 beqz $t0,mips32_CLO nop # all other special-3 opcodes go unemulated li $t0,0x20010000 # Write ignored opcode to debug register sw $k0,1024($t0) j opcode_emu_return nop # SPECIAL3 opcodes # $k0 = opcode mips32_special3: andi $k1,$k0,0x03f xori $t0,$k1,0x0 beqz $t0,mips32_EXT xori $t0,$k1,0x04 beqz $t0,mips32_INS nop # all other special-3 opcodes go unemulated li $t0,0x20010000 # Write ignored opcode to debug register sw $k0,1024($t0) j opcode_emu_return nop # Get the branch opcode, decode it and emulate it # entry: $k0 = opcode, $t0 = address of branch # exit: $k0 = opcode that triggered exception (in branch delay) emulate_branch: # FIXME branch emulation is missing! lw $k0,4($t0) # read actual guilty opcode jr $ra nop #---- Branch emulation routines -------------------------------------------- # FIXME branch emulation missing #---- Opcode emulation routines -------------------------------------------- # CLZ: rd <- count leading zeros on rs mips32_CLZ: jal get_source_register # $k1 = source register (Rs) lui $t2,0x8000 # $t2 = bit mask move $t0,$zero # $t0 = counter mips32_clz_loop: and $t1,$k1,$t2 bnez $t1,mips32_clz_done srl $t2,$t2,1 bnez $t2,mips32_clz_loop addiu $t0,$t0,1 mips32_clz_done: j mips32_save_result # put result in dest reg and return move $k1,$t0 # CLO: rd <- count leading ones on rs mips32_CLO: jal get_source_register # $k1 = source register (Rs) lui $t2,0x8000 # $t2 = bit mask move $t0,$zero # $t0 = counter mips32_clo_loop: and $t1,$k1,$t2 beqz $t1,mips32_clo_done srl $t2,$t2,1 bnez $t2,mips32_clo_loop addiu $t0,$t0,1 mips32_clo_done: j mips32_save_result # put result in dest reg and return move $k1,$t0 # EXT: mips32_EXT: jal get_source_register # $k1 = source register (Rs) nop srl $t0,$k0,6 # $t0 = pos andi $t0,$t0,0x1f srl $t1,$k0,11 andi $t1,$t1,0x1f # $t1 = size-1 addu $t2,$t0,$t1 # ...by shifting left and then right subu $t2,$zero,$t2 addiu $t2,$t2,31 sllv $k1,$k1,$t2 srlv $k1,$k1,$t2 j mips32_save_result # put result in dest reg and return srlv $k1,$k1,$t0 # k1 = bit field, zero extended # INS: mips32_INS: jal get_source_register # $k1 = source register (Rs) nop srl $t0,$k0,6 # $t0 = pos andi $t0,$t0,0x1f srl $t1,$k0,11 andi $t1,$t1,0x1f # $t1 = pos+size-1 subu $t1,$t1,$t0 # $t1 = size-1 subu $t3,$zero,$t1 # $t1 = source bit field, shifted addiu $t3,$t3,31 sllv $t1,$k1,$t0 lui $t2,0xffff # $t2 = target mask (0 for bitfield) ori $t2,$t2,0xffff sllv $t2,$t2,$t3 srlv $t2,$t2,$t3 sllv $t2,$t2,$t0 and $t1,$t1,$t2 # $t1 = source bit field, masked not $t2,$t2 # ok, we're done with the source register, and we have the following: # $t0=pos, $t1=size-1, $t3=left shift amount, $t4=bitfield, $t2=mask # (uses $k1 and $t0) jal get_source_register # $k1 = target register sll $k0,$k0,5 srl $k0,$k0,5 # restore field Rt of opcode and $k1,$k1,$t2 # insert bit field in Rt... or $k1,$k1,$t1 j mips32_save_result # ...and put result back in register nop #---- Common utility routines ---------------------------------------------- # entry: $k0 = opcode, $k1 = result mips32_save_result: srl $t1,$k0,16 andi $t1,$t1,0x1f la $t0,set_target_table sll $t1,$t1,3 add $t0,$t1 jr $t0 nop set_target_done: j opcode_emu_return nop set_target_table: j set_target_done ori $0,$k1,0 j set_target_done ori $1,$k1,0 j set_target_done ori $2,$k1,0 j set_target_done ori $3,$k1,0 j set_target_done ori $4,$k1,0 j set_target_done ori $5,$k1,0 j set_target_done ori $6,$k1,0 j set_target_done ori $7,$k1,0 j set_target_done sw $k1,-24($sp) j set_target_done sw $k1,-28($sp) j set_target_done sw $k1,-32($sp) j set_target_done ori $11,$k1,0 j set_target_done ori $12,$k1,0 j set_target_done ori $13,$k1,0 j set_target_done ori $14,$k1,0 j set_target_done ori $15,$k1,0 j set_target_done ori $16,$k1,0 j set_target_done ori $17,$k1,0 j set_target_done ori $18,$k1,0 j set_target_done ori $19,$k1,0 j set_target_done ori $20,$k1,0 j set_target_done ori $21,$k1,0 j set_target_done ori $22,$k1,0 j set_target_done ori $23,$k1,0 j set_target_done ori $24,$k1,0 j set_target_done ori $25,$k1,0 j set_target_done ori $26,$k1,0 j set_target_done ori $27,$k1,0 j set_target_done ori $28,$k1,0 j set_target_done sw $k1,-20($sp) j set_target_done ori $30,$k1,0 j set_target_done sw $k1,-16($sp) # get value of register rs (field 25..21) # entry: $k0=opcode # exit: $k1=source get_source_register: sw $ra,0($sp) srl $k1,$k0,21 andi $k1,$k1,0x1f la $t0,get_source_table sll $k1,$k1,3 add $t0,$t0,$k1 jalr $t0 nop lw $ra,0($sp) jr $ra nop # exit: $k1=source reg get_source_table: jr $ra ori $k1,$0,0 jr $ra ori $k1,$1,0 jr $ra ori $k1,$2,0 jr $ra ori $k1,$3,0 jr $ra ori $k1,$4,0 jr $ra ori $k1,$5,0 jr $ra ori $k1,$6,0 jr $ra ori $k1,$7,0 jr $ra lw $k1,-24($sp) jr $ra lw $k1,-28($sp) jr $ra lw $k1,-32($sp) jr $ra ori $k1,$11,0 jr $ra ori $k1,$12,0 jr $ra ori $k1,$13,0 jr $ra ori $k1,$14,0 jr $ra ori $k1,$15,0 jr $ra ori $k1,$16,0 jr $ra ori $k1,$17,0 jr $ra ori $k1,$18,0 jr $ra ori $k1,$19,0 jr $ra ori $k1,$20,0 jr $ra ori $k1,$21,0 jr $ra ori $k1,$22,0 jr $ra ori $k1,$23,0 jr $ra ori $k1,$24,0 jr $ra ori $k1,$25,0 jr $ra ori $k1,$26,0 jr $ra ori $k1,$27,0 jr $ra ori $k0,$28,0 jr $ra lw $k1,-16($sp) jr $ra ori $k1,$30,0 jr $ra lw $k1,-20($sp)
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