#! /usr/bin/env python ############################################################################### # # simulavr - A simulator for the Atmel AVR family of microcontrollers. # Copyright (C) 2001, 2002 Theodore A. Roth # # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 2 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License along # with this program; if not, write to the Free Software Foundation, Inc., # 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. # ############################################################################### # # $Id: test_MULS.py,v 1.1 2004/07/31 00:59:11 rivetwa Exp $ # """Test the MULS opcode. """ import base_test from registers import Reg, SREG class MULS_TestFail(base_test.TestFail): pass class base_MULS(base_test.opcode_test): """Generic test case for testing MULS opcode. description: multiply two signed numbers and save the result in R1:R0 (highb:lowbyte) opcode: 0000 0010 dddd rrrr 16 <= d,r <= 31 changes: R1,R0,SREG: C set if R15 set, Z set if result 0x0000 """ def setup(self): # Set SREG to zero or only C flag set self.setup_regs[Reg.SREG] = 0x0 # Set the register values self.setup_regs[self.Rd] = self.Vd & 0xff self.setup_regs[self.Rr] = self.Vr & 0xff # Return the raw opcode return 0x0200 | (self.Rr & 0x0f) | (self.Rd & 0x0f) << 4 def analyze_results(self): self.reg_changed.extend( [Reg.R00, Reg.R01, Reg.SREG] ) if (self.Vd & 0x80): # Vd is a negative 8 bit number, so convert to 32 bit self.Vd |= -256 if (self.Vr & 0x80): # Vd is a negative 8 bit number, so convert to 32 bit self.Vr |= -256 # check that result is correct res = (self.Vd * self.Vr) expect = res & 0xffff got = self.anal_regs[Reg.R00] | self.anal_regs[Reg.R01] << 8 if expect != got: self.fail('MULS calc r%02d, r%02d: %d * %d = (expect=%04x, got=%04x)' % ( self.Rd, self.Rr, self.Vd, self.Vr, expect, got)) expect_sreg = 0 # calculate what we expect sreg to be C = (expect & 0x8000) >> 15 expect_sreg += (expect == 0) << SREG.Z expect_sreg += C << SREG.C got_sreg = self.anal_regs[Reg.SREG] if expect_sreg != got_sreg: self.fail('MULS flag setting: 0x%d * 0x%d -> SREG (expect=%02x, got=%02x)' % ( self.Vd, self.Vr, expect_sreg, got_sreg)) # # Template code for test case. # The fail method will raise a test specific exception. # template = """ class MULS_rd%02d_vd%02x_rr%02d_vr%02x_TestFail(MULS_TestFail): pass class test_MULS_rd%02d_vd%02x_rr%02d_vr%02x(base_MULS): Rd = %d Vd = %d Rr = %d Vr = %d def fail(self,s): raise MULS_rd%02d_vd%02x_rr%02d_vr%02x_TestFail(s) """ # # Define a list of test values such that we all the cases of SREG bits being set. # vals = ( ( 0x00, 0x00), ( 0xff, 0x01), ( 0x01, 0xff), ( 0xff, 0xff), ( 0xff, 0x00), ( 0x00, 0xb3), ( 0x80, 0x7f), ( 0x80, 0x80), ( 0x7f, 0x7f), ( 0x4d, 0x4d), ) # # automagically generate the test_MULS_rdNN_vdXX_rrNN_vrXX_C[01] class definitions. # For these, we don't want Rd=Rr as that is a special case handled below. # code = '' step = 3 for d in range(16,32,step): for r in range(17,32,step): for vd,vr in vals: args = (d, vd, r, vr)*4 code += template % args # # Special case when Rd==Rr, make sure Vd==Vr. # for d in range(16,32,step): for vd,vr in vals: args = (d, vd, d, vd)*4 code += template % args exec(code)