1445 lines
68 KiB
JavaScript
1445 lines
68 KiB
JavaScript
/*
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* Copyright (c) 2011-2012, Preston Skupinski <preston.skupinski@gmail.com>
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*
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* Permission to use, copy, modify, and/or distribute this software for any
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* purpose with or without fee is hereby granted, provided that the above
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* copyright notice and this permission notice appear in all copies.
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*
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* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
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* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
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* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
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* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
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* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
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* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
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* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
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*/
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function run_tests() {
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test_cpu_load_binary();
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test_lda();
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test_inc();
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test_inx();
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test_iny();
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test_dec();
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test_stz();
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test_rep();
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test_sep();
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test_branching();
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test_adc();
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test_sbc();
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test_cmp();
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test_subroutines();
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test_mvn_and_mvp();
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test_emulation_mode();
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test_cpu_memory_mapped_io_devices();
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}
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function test_lda() {
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module("LDA");
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test("Make sure LDA with a constant properly loads an 8-bit value in "+
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"8-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba9ff", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xff, "The accumulator should be 0xff when 0xff is "+
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"given as its argument in 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
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"for 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode");
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});
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test("Make sure LDA with a constant properly loads a 16-bit value in "+
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"16-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a9ffff", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xffff, "The accumulator should be 0xffff when "+
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"0xffff is given as its argument in 16-bit "+
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"memory/accumulator mode.");
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strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
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"for 16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode");
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});
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test("Make sure LDA with a direct page address loads an 8-bit value in "+
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"8-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba90185fea5fe", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 1, "The accumulator should be 1 when 1 is "+
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"loaded from $fe(direct page) in 8-bit memory/accumulator "+
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"mode.");
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strictEqual(cpu.p.m, 1, "m flag of the p status register should be 1 for "+
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"8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The Hidden e flag of the p status register "+
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"should be 0 for native mode");
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});
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test("Make sure LDA with a direct page address loads a 16-bit value in "+
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"16-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a901ff85fea5fe", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xff01, "The accumulator should be 0xff01 when "+
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"0xff01 is loaded from $fe(direct page) in 16-bit "+
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"memory/accumulator mode.");
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strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
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"for 16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Make sure LDA with an absolute address loads an 8-bit value in "+
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"8-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba9fe8dff0aa900adff0a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfe, "The accumulator should be 0xfe when 0xfe is "+
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"loaded from $0aff(absolute) in 8-bit memory/accumulator "+
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"mode.");
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strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
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"for 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Make sure LDA with an absolute address loads a 16-bit value in "+
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"16-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a9ffff8dff0aa90000adff0a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xffff, "The accumulator should be 0xffff when "+
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"0xffff is loaded from $0aff and $0b00(absolute) in 16-bit "+
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"memory/accumulator mode.");
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strictEqual(cpu.p.m, 0, "m flag of the p status register should be 0 for "+
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"16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "Hidden e flag of the p status register should "+
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"be 0 for native mode.");
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});
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test("Make sure LDA with a direct page address indexed with the x "+
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"register loads an 8-bit value in 8-bit memory/accumulator mode.",
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function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba201a9ff85ffa900b5fe", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xff, "The accumulator should be 0xff when 0xff "+
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"is loaded from direct page address $fe indexed "+
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"with x(which is 1) and thus loaded from $ff in "+
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"8-bit memory/accumulator mode.");
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strictEqual(cpu.r.x, 1, "The x register should be 1 in order to be used "+
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"as an index with the base address to get to the desired "+
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"address.");
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strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
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"for 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Make sure LDA with a direct page address indexed with the x "+
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"register loads a 16-bit value in 16-bit memory/accumulator mode.",
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function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a201a9ffff85fea90000bdfd", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xffff, "The accumulator should be 0xffff when "+
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"0xffff is loaded from direct page addresses $fe and $ff "+
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"after $fd is indexed with the x register(which is 1) in "+
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"16-bit memory/accumulator mode.");
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strictEqual(cpu.r.x, 1, "The x register should be 1 in order to be used "+
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"as an index with the base address to get to the desired "+
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"address.");
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strictEqual(cpu.p.m, 0, "m flag of the p status register should be 0 for "+
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"16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Make sure LDA indirect given a direct page address loads an 8-bit "+
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"value in 8-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba9ff85fea90a85ffa9068dff0aa900b2fe", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 6, "The accumulator should be 6 when LDA loads an "+
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"8-bit value using an indirect address in 8-bit mode "+
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"memory/accumulator mode.");
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strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
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"for 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Make sure LDA indirect given a direct page address loads a 16-bit "+
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"value in 16-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a9ff0a85fea9ffff8dff0aa90000b2fe", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xffff, "The accumulator should be 0xffff when "+
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"LDA loads a 16-bit value using an indirect address loaded "+
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"from a direct page address.");
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strictEqual(cpu.p.m, 0, "The m flag of the p status register should be "+
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"0 for 16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA absolute indexed by the x register works for 8-bit "+
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"memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba9fa8dff0aa201a900bdfe0a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfa, "The accumulator should be 0xfa when LDA loads "+
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"an 8-bit value using absolute indexed x mode from $0aff");
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strictEqual(cpu.r.x, 1, "The x register should be 1 to properly load "+
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"the value added to the base address.");
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strictEqual(cpu.p.m, 1, "The m flag of the p status register should be "+
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"1 for 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA absolute indexed by the x register works for 16-bit "+
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"memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a9fefa8dff0aa203bdfc0a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfafe, "The accumulator should be 0xfafe when LDA "+
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"loads a 16-bit value from $0aff using absolute indexed x "+
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"addressing mode.");
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strictEqual(cpu.r.x, 3, "The x register should be 3 to properly load "+
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"the value added to the base address.");
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strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
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"for 16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA absolute indexed by the y register works for 8-bit "+
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"memory/acccumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba9fe8dff0aa002a900b9fd0a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfe, "The accumulator should be 0xfe when LDA "+
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"loads an 8-bit value from $0aff using absolute indexed y "+
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"addressing mode.");
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strictEqual(cpu.r.y, 2, "The y register should be 2 to properly load the "+
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"value added to the base address.");
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strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+ "for 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA absolute indexed by the y register works for 16-bit "+
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"memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a9fefa8dff0aa003a90000b9fc0a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfafe, "The accumulator should be 0xfafe when LDA "+
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"loads a 16-bit value from $0aff using absolute indexed y "+
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"addressing mode.");
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strictEqual(cpu.r.y, 3, "The y register should be 3 to properly load the "+
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"value added to the base address.");
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strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
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"for 16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA stack relative works for 8-bit memory/accumulator "+
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"mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba9fe48a90148a900a302", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfe, "The accumulator should be 0xfe when LDA loads "+
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"an 8-bit value from the stack using LDA stack relative "+
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"addressing mode.");
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strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
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"for 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA stack relative works for 16-bit memory/accumulator "+
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"mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a9fefa48a9010048a90000a303", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfafe, "The accumulator should be 0xfafe when LDA "+
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"loads a 16-bit value from the stack using LDA stack "+
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"relative addressing mode.");
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strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
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"for 16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA absolute long works for 8-bit memory/accumulator "+
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"mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba9fa8fffeeaaa900afffeeaa", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfa, "The accumulator should be 0xfa when LDA "+
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"loads an 8-bit value from $aaeeff using absolute long "+
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"addressing mode.");
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strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
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"for 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA absolute long works for 16-bit memory/accumulator "+
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"mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a9fefa8fffeeaaa90000afffeeaa", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfafe, "The accumulator should be 0xfafe when LDA "+
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"loads a 16-bit value from $aaeeff using absolute long "+
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"addressing mode.");
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strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
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"for 16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA absolute long indexed by the x register works for "+
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"8-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba9fe8fffeeaaa202a900bffdeeaa", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfe, "The accumulator should be 0xfe when LDA "+
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"loads an 8-bit value from $aaeeff using absolute long "+
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"indexed x addressing mode.");
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strictEqual(cpu.r.x, 2, "The x register should be 2 in order to be used "+
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"as an index to reach the correct address.");
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strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
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"for 8-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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test("Ensure that LDA absolute long indexed by the x register works for "+
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"16-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a9fefa8fffeeaaa203a90000bffceeaa", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xfafe, "The accumulator should be 0xfafe when LDA "+
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"loads a 16-bit value from $aaeeff using absolute long "+
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"indexed x addressing mode.");
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strictEqual(cpu.r.x, 3, "The x register should be 3 in order to be used "+
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"as an index to reach the correct address.");
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strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
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"for 16-bit memory/accumulator mode.");
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strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
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"should be 0 for native mode.");
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});
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}
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function test_inc() {
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module("INC");
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test("Test INC accumulator for 8-bit memory/accumulator mode.", function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fba9fe1a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xff, "The accumulator should be 0xff after "+
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"incrementing 0xfe by one.");
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strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
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"mode.");
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strictEqual(cpu.p.m, 1, "The m flag should be one for 8-bit "+
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"memory/accumulator mode.");
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strictEqual(cpu.p.n, 1, "The n flag should be one to represent a negative "+
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"number.");
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strictEqual(cpu.p.z, 0, "The z flag should be zero to represent a non-zero"+
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"number.");
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cpu.reset();
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cpu.load_binary("18fba9ff1a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0, "The accumulator should be zero after "+
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"incrementing 0xff by one.");
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strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
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"mode.");
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strictEqual(cpu.p.m, 1, "The m flag should be one for 8-bit "+
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"memory/accumulator mode.");
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strictEqual(cpu.p.n, 0, "The n flag should be zero to represent a "+
|
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"non-negative number.");
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strictEqual(cpu.p.z, 1, "The z flag should be one to represent zero.");
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});
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test("Test INC accumulator for 16-bit memory/accumulator mode.",
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function() {
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var cpu = new CPU_65816();
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cpu.load_binary("18fbc220a9feff1a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0xffff, "The accumulator should be 0xffff after "+
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"incrementing 0xfffe by one.");
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strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
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"mode.");
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strictEqual(cpu.p.m, 0, "The m flag should be zero for 16-bit "+
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"memory/accumulator mode.");
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strictEqual(cpu.p.z, 0, "The z flag should be zero to represent a "+
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"non-zero number.");
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strictEqual(cpu.p.n, 1, "The n flag should be one to represent a negative "+
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"number.");
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cpu.reset();
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cpu.load_binary("18fbc220a9ffff1a", 0x8000);
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cpu.execute(0x8000);
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strictEqual(cpu.r.a, 0, "The accumulator should be zero after "+
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"incrementing 0xffff by one.");
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strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
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"mode.");
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strictEqual(cpu.p.m, 0, "The m flag should be zero for 16-bit "+
|
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"memory/accumulator mode.");
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strictEqual(cpu.p.z, 1, "The z flag should be one to represent zero.");
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strictEqual(cpu.p.n, 0, "The n flag should be zero to represent a "+
|
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"non-negative number.");
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});
|
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test("Test INC absolute for 8-bit memory/accumulator mode", function() {
|
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var cpu = new CPU_65816();
|
|
cpu.load_binary("18fba9fe8d0070ee0070af0070", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0xff, "The accumulator should be 0xff after loading "+
|
|
"from memory a value that was originally 0xfe "+
|
|
"and incremented by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 1, "The m flag should be one for 8-bit "+
|
|
"memory/accumulator mode.");
|
|
strictEqual(cpu.p.z, 0, "The z flag should be zero for a non-zero number.");
|
|
strictEqual(cpu.p.n, 1, "The n flag should be one for a negative number.");
|
|
});
|
|
test("Test INC absolute for 16-bit memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220a9feff8d0070ee0070af0070", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0xffff, "The accumulator should be 0xffff after "+
|
|
"loading from memory a value that was originally 0xfffe "+
|
|
"and incremented by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 0, "The m flag should be zero for 16-bit "+
|
|
"memory/accumulator mode.");
|
|
strictEqual(cpu.p.z, 0, "The z flag should be zero for a non-zero number.");
|
|
strictEqual(cpu.p.n, 1, "The n flag should be one for a negative number.");
|
|
});
|
|
}
|
|
|
|
function test_inx() {
|
|
module("INX");
|
|
test("Test INX for 8-bit index register mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fba2fee8", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.x, 0xff, "The x register should be 0xff after "+
|
|
"incrementing 0xfe by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.x, 1, "The x flag should be one for 8-bit "+
|
|
"index register mode.");
|
|
strictEqual(cpu.p.n, 1, "The n flag should be one to represent a negative "+
|
|
"number.");
|
|
strictEqual(cpu.p.z, 0, "The z flag should be zero to represent a "+
|
|
"non-zero number.");
|
|
cpu.reset();
|
|
cpu.load_binary("18fba2ffe8", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.x, 0, "The x register should be zero after incrementing "+
|
|
"0xff by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.x, 1, "The x flag should be one for 8-bit "+
|
|
"index register mode.");
|
|
strictEqual(cpu.p.z, 1, "The z flag should be one for zero.");
|
|
strictEqual(cpu.p.n, 0, "The n flag should be zero to represent a "+
|
|
"non-negative number.");
|
|
});
|
|
test("Test INX for 16-bit index register mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc210a2feffe8", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.x, 0xffff, "The x register should be 0xffff after "+
|
|
"incrementing 0xfffe by one.");
|
|
strictEqual(cpu.p.x, 0, "The x flag of the p status register should be "+
|
|
"zero for 16-bit index register mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.z, 0, "The z flag should be zero for a non-zero number.");
|
|
strictEqual(cpu.p.n, 1, "The n flag should be one for a negative number.");
|
|
cpu.reset();
|
|
cpu.load_binary("18fbc210a2ffffe8", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.x, 0, "The x register should be zero after incrementing "+
|
|
"0xffff by one.");
|
|
strictEqual(cpu.p.x, 0, "The x flag of the p status register should be "+
|
|
"zero for 16-bit index register mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.n, 0, "The n flag should be zero for a non-negative "+
|
|
"number.");
|
|
strictEqual(cpu.p.z, 1, "The z flag should be one for zero.");
|
|
});
|
|
}
|
|
|
|
function test_iny() {
|
|
module("INY");
|
|
test("Test INY for 8-bit index register mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fba0fec8", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.y, 0xff, "The y register should be 0xff after "+
|
|
"incrementing 0xfe by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.x, 1, "The x flag should be one for 8-bit index "+
|
|
"register mode.");
|
|
cpu.reset();
|
|
cpu.load_binary("18fba0ffc8", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.y, 0, "The y register should be zero after incrementing "+
|
|
"0xff by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.x, 1, "The x flag should be one for 8-bit index "+
|
|
"register mode.");
|
|
});
|
|
test("Test INY for 16-bit index register mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc210a0feffc8", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.y, 0xffff, "The y register should be 0xffff after "+
|
|
"incrementing 0xfffe by one.");
|
|
strictEqual(cpu.p.x, 0, "The x flag of the p status register should be "+
|
|
"zero for 16-bit index register mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
cpu.reset();
|
|
cpu.load_binary("18fbc210a0ffffc8", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.y, 0, "The y register should be zero after incrementing "+
|
|
"0xffff by one.");
|
|
strictEqual(cpu.p.x, 0, "The x flag of the p status register should be "+
|
|
"zero for 16-bit index register mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
});
|
|
}
|
|
|
|
function test_dec() {
|
|
module("DEC");
|
|
test("Test DEC accumulator for 8-bit memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fba9013a", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after "+
|
|
"decrementing one by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 1, "The m flag should be one for 8-bit "+
|
|
"memory/accumulator mode.");
|
|
strictEqual(cpu.p.z, 1, "The z flag should be one for zero.");
|
|
strictEqual(cpu.p.n, 0, "The n flag should be zero for a non-negative "+
|
|
"number.");
|
|
});
|
|
test("Test DEC accumulator decrementing zero by one behavior for 8-bit "+
|
|
"memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fba9003a", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0xff, "The accumulator should be 0xff after "+
|
|
"decrementing zero by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 1, "The m flag should be one for 8-bit "+
|
|
"memory/accumulator mode.");
|
|
strictEqual(cpu.p.z, 0, "The z flag should be zero for a non-zero number.");
|
|
strictEqual(cpu.p.n, 1, "The n flag should be one for a negative number.");
|
|
});
|
|
test("Test DEC accumulator for 16-bit memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220a901003a", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after "+
|
|
"decrementing one by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 0, "The m flag should be zero for 16-bit "+
|
|
"memory/accumulator mode.");
|
|
strictEqual(cpu.p.z, 1, "The z flag should be one for zero.");
|
|
strictEqual(cpu.p.n, 0, "The n flag should be zero for a non-negative "+
|
|
"number.");
|
|
});
|
|
test("Test DEC accumulator decrementing zero by one behavior for 16-bit "+
|
|
"memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220a900003a", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0xffff, "The accumulator should be 0xffff after "+
|
|
"decrementing zero by one.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 0, "The m flag sholud be zero for 16-bit "+
|
|
"memory/accumulator mode.");
|
|
strictEqual(cpu.p.z, 0, "The z flag should be zero for a non-zero number.");
|
|
strictEqual(cpu.p.n, 1, "The n flag should be one for a negative number.");
|
|
});
|
|
}
|
|
|
|
function test_stz() {
|
|
module("STZ");
|
|
test("Test STZ direct page for 8-bit memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fba9ff85fa64faa5fa", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after loading "+
|
|
"from a direct page addresss that has had zero stored to it.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 1, "The m flag should be one for 8-bit "+
|
|
"memory/accumulator mode.");
|
|
});
|
|
test("Test STZ direct page for 16-bit memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220a9ffff85fa64faa5fa", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after loading "+
|
|
"from a direct page address that had zero stored to it.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 0, "The m flag should be zero for 16-bit "+
|
|
"memory/accumulator mode.");
|
|
});
|
|
test("Test STZ absolute for 8-bit memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fba9ff8d34129c3412ad3412", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after loading "+
|
|
"from an absolute address that had zero stored to it.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 1, "The m flag should be one for 8-bit "+
|
|
"memory/accumulator mode.");
|
|
});
|
|
test("Test STZ absolute for 16-bit memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220a9ffff8d34129c3412ad3412", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after loading "+
|
|
"from an absolute page address that had zero stored to it.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 0, "The m flag should be zero for 16-bit "+
|
|
"memory/accumulator mode.");
|
|
});
|
|
test("Test STZ direct page indexed by the x register for 8-bit "+
|
|
"memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fba9ff85fb85faa20174faa5fb", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after loading "+
|
|
"from a direct page addresss that has had zero stored to it.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 1, "The m flag should be one for 8-bit "+
|
|
"memory/accumulator mode.");
|
|
});
|
|
test("Test STZ direct page indexed by the x register for 16-bit "+
|
|
"memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220a9ffff85faa20274f8a5fa", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after loading "+
|
|
"from a direct page address that had zero stored to it.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 0, "The m flag should be zero for 16-bit "+
|
|
"memory/accumulator mode.");
|
|
});
|
|
test("Test STZ absolute indexed by the x register for 8-bit "+
|
|
"memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fba9ff8dbbaa8dbaaaa2019ebaaaadbbaa", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after loading "+
|
|
"from an absolute address that had zero stored to it.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 1, "The m flag should be one for 8-bit "+
|
|
"memory/accumulator mode.");
|
|
});
|
|
test("Test STZ absolute indexed by the x register for 16-bit "+
|
|
"memory/accumulator mode.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220a9ffff8dbbaaa2029eb9aaadbbaa", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "The accumulator should be zero after loading "+
|
|
"from an absolute page address that had zero stored to it.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag should be zero for native "+
|
|
"mode.");
|
|
strictEqual(cpu.p.m, 0, "The m flag should be zero for 16-bit "+
|
|
"memory/accumulator mode.");
|
|
});
|
|
}
|
|
|
|
function test_emulation_mode() {
|
|
module("Emulation Mode");
|
|
test("Make sure pulling from the stack when the stack register is at 0x1ff"+
|
|
"causes the stack register to pull from 0x100.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("a9fe8d0001a90068", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.s, 0, "The stack register should be 0 after the pull "+
|
|
"operation.");
|
|
strictEqual(cpu.r.a, 0xfe, "The accumulator should be 0xfe after the pull "+
|
|
"operation.");
|
|
});
|
|
}
|
|
|
|
function test_mvn_and_mvp() {
|
|
module("MVN and MVP");
|
|
test("Test a short example program for MVP", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbe230a9ab8dff0fa9cd8d0010c230a90100a20010a00020440000",
|
|
0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0xffff, "After executing the example program the "+
|
|
"accumulator should've underflowed and resulted in 0xffff.");
|
|
strictEqual(cpu.r.x, 0x0ffe, "After executing the example program the x "+
|
|
"register should be 0x0ffe.");
|
|
strictEqual(cpu.r.y, 0x1ffe, "After executing the example program the y "+
|
|
"register should be 0x1ffe.");
|
|
var byte_one = cpu.mmu.read_byte(0x1fff);
|
|
var byte_two = cpu.mmu.read_byte(0x2000);
|
|
strictEqual(byte_one, 0xab, "After executing the example program 0x001fff "+ "in memory should contain 0xab.");
|
|
strictEqual(byte_two, 0xcd, "After executing the example program 0x002000 "+
|
|
"in memory should contain 0xcd.");
|
|
});
|
|
}
|
|
|
|
function test_subroutines() {
|
|
module("Subroutines");
|
|
test("Short program to check that JSR and RTS work", function() {
|
|
var cpu = new CPU_65816();
|
|
// It jumps to 0xffff so it doesn't execute the subroutine again and
|
|
// effectively halts the program.
|
|
cpu.load_binary("18fbc23018a9ffff200e804cffff3a60", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0xfffe, "The subroutine should execute exactly once, "+
|
|
"decrementing 0xffff to 0xfffe.");
|
|
});
|
|
}
|
|
|
|
function test_cmp() {
|
|
module("CMP");
|
|
test("Compare two 8-bit numbers, 0x01 and 0xff", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbe23018a901c9ff", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x01, "CMP should not change the value of the "+
|
|
"accumulator");
|
|
strictEqual(cpu.p.z, 0, "When comparing 0x01 and 0xff the zero(z) bit "+
|
|
"should not be set (0x01 != 0xff)");
|
|
strictEqual(cpu.p.n, 0, "When comparing 0x01 and 0xff the negative(n) bit "+
|
|
"should not be set");
|
|
strictEqual(cpu.p.c, 0, "When comparing 0x01 and 0xff the carry(c) bit "+
|
|
"should not be set (0x01 < 0xff)");
|
|
});
|
|
test("Compare two 16-bit numbers, 0xff01 and 0xfeff", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc23018a901ffc9fffe", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0xff01, "CMP should not change the value of the "+
|
|
"accumulator");
|
|
strictEqual(cpu.p.n, 0, "When comparing 0xff01 and 0xfeff the negative(n) "+
|
|
"bit should not be set");
|
|
strictEqual(cpu.p.z, 0, "When comparing 0xff01 and 0xfeff the zero(z) bit "+
|
|
"should not be set (0xff01 != 0xfeff)");
|
|
strictEqual(cpu.p.c, 1, "When comparing 0xff01 and 0xfeff the carry(c) "+
|
|
"bit should be set (0xff01 >= 0xfeff)");
|
|
});
|
|
}
|
|
|
|
function test_sbc() {
|
|
module("SBC");
|
|
test("Test normal subtraction of two 8-bit numbers that don't cause a "+
|
|
"borrow.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbe230a90138e901", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "0x01 - 0x01 should result in zero when using "+
|
|
"SBC");
|
|
strictEqual(cpu.p.z, 1, "0x01 - 0x01 should set the zero(z) bit when "+
|
|
"using SBC");
|
|
strictEqual(cpu.p.n, 0, "0x01 - 0x01 should not set the negative(n) bit "+
|
|
"when using SBC");
|
|
strictEqual(cpu.p.v, 0, "0x01 - 0x01 should not set the overflow(v) bit "+
|
|
"when using SBC");
|
|
strictEqual(cpu.p.c, 1, "0x01 - 0x01 should set the carry(c) bit when "+
|
|
"using SBC");
|
|
});
|
|
|
|
test("Test normal subtraction of two 16-bit numbers that don't cause a "+
|
|
"borrow.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc230a9010038e90100", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0, "0x0001 - 0x0001 should result in zero when using "+
|
|
"SBC");
|
|
strictEqual(cpu.p.z, 1, "0x0001 - 0x0001 should set the zero(z) bit when "+
|
|
"using SBC");
|
|
strictEqual(cpu.p.n, 0, "0x0001 - 0x0001 should not set the negative(n) "+
|
|
"bit when using SBC");
|
|
strictEqual(cpu.p.v, 0, "0x0001 - 0x0001 should not set the overflow(v) "+
|
|
"bit when using SBC");
|
|
strictEqual(cpu.p.c, 1, "0x0001 - 0x0001 should set the carry(c) bit when "+
|
|
"using SBC");
|
|
});
|
|
test("Test subtraction that triggers a borrow with 8-bit numbers",
|
|
function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbe230a9d038e9ef", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0xe1, "0xd0 - 0xef should set the accumulator to "+
|
|
"0xe1 when using SBC");
|
|
strictEqual(cpu.p.n, 1, "0xd0 - 0xef should set the negative(n) bit when "+
|
|
"using SBC");
|
|
strictEqual(cpu.p.v, 0, "0xd0 - 0xef should not set the overflow(v) bit "+
|
|
"when using SBC");
|
|
strictEqual(cpu.p.z, 0, "0xd0 - 0xef should not set the zero(z) bit when "+
|
|
"using SBC");
|
|
strictEqual(cpu.p.c, 0, "0xd0 - 0xef should not set the carry(c) bit when "+
|
|
"using SBC");
|
|
});
|
|
test("Test subtraction that triggers a borrow with 16-bit numbers",
|
|
function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc230a900d038e900ef", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0xe100, "0xd000 - 0xef00 should set the accumulator "+
|
|
"to 0xe0ff when using SBC");
|
|
strictEqual(cpu.p.n, 1, "0xd000 - 0xef00 should set the negative(n) bit "+
|
|
"when using SBC");
|
|
strictEqual(cpu.p.v, 0, "0xd000 - 0xef00 should not set the overflow(v) "+
|
|
"bit when using SBC");
|
|
strictEqual(cpu.p.z, 0, "0xd000 - 0xef00 should not set the zero(z) bit "+
|
|
"when using SBC");
|
|
strictEqual(cpu.p.c, 0, "0xd000 - 0xef00 should not set the carry(c) bit "+
|
|
"when using SBC");
|
|
});
|
|
test("Test subtraction with decimal mode on with two single digit 8-bit "+
|
|
"numbers.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbf8a90938e905", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 4, "The accumulator should be 4 after subtracting "+
|
|
"0x5 0x9 with decimal mode on with 8-bit memory/accumulator "+
|
|
"mode.");
|
|
strictEqual(cpu.p.c, 1, "The carry bit should be set after no borrow is "+
|
|
"triggered.");
|
|
strictEqual(cpu.p.m, 1, "The m flag of the p status register should be "+
|
|
"one for 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be zero for native mode.");
|
|
});
|
|
test("Test subtraction with decimal mode on with two double digit 8-bit "+
|
|
"numbers.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbf8a99038e949", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x41, "The accumulator should be 0x41 after "+
|
|
"subtracting 0x49 from 0x90 with decimal mode on with 8-bit "+
|
|
"memory/accumulator mode.");
|
|
strictEqual(cpu.p.c, 1, "The carry bit should be set after no borrow is "+
|
|
"triggered.");
|
|
strictEqual(cpu.p.m, 1, "The m flag of the p status register should be "+
|
|
"one for 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be zero for native mode.");
|
|
});
|
|
test("Test subtraction with decimal mode on with 8-bit numbers that causes "+
|
|
"a borrow.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbf8a91038e920", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x90, "The accumulator should be 0x90 after "+
|
|
"subtracting 0x20 from 0x10 with decimal and 8-bit "+
|
|
"memory/accumulator modes.");
|
|
strictEqual(cpu.p.c, 0, "The carry bit should be clear after a borrow is "+
|
|
"triggered.");
|
|
strictEqual(cpu.p.m, 1, "The m flag of the p status register should be "+
|
|
"one for 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be zero for native mode.");
|
|
});
|
|
test("Test subtraction of two single digit 16-bit numbers with decimal "+
|
|
"mode set.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220f8a9050038e90200", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x03, "The accumulator should be 0x03 after "+
|
|
"subtracting 0x02 from 0x05 with decimal and 16-bit "+
|
|
"memory/accumulator modes.");
|
|
strictEqual(cpu.p.c, 1, "The carry bit should be set after no borrow is "+
|
|
"triggered.");
|
|
strictEqual(cpu.p.m, 0, "The m flag of the p status register should be "+
|
|
"zero for 16-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be zero for native mode.");
|
|
});
|
|
test("Test subtraction of two four digit 16-bit numbers with decimal "+
|
|
"mode set.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220f8a9999938e91111", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x8888, "The accumulator should be 0x8888 after "+
|
|
"subtracting 0x1111 from 0x9999 with decimal "+
|
|
"and 16-bit memory/accumulator modes.");
|
|
strictEqual(cpu.p.c, 1, "The carry bit should be set after no borrow is "+
|
|
"triggered.");
|
|
strictEqual(cpu.p.m, 0, "The m flag of the p status register should be "+
|
|
"zero for 16-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be zero for native mode.");
|
|
});
|
|
test("Test subtraction of two four digit 16-bit numbers with decimal "+
|
|
"mode set that causes a borrow.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc220f8a9111138e99999", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x1112, "The accumulator should be 0x1112 after "+
|
|
"subtracting 0x9999 from 0x1111 with decimal and 16-bit "+
|
|
"memory/accumulator modes.");
|
|
strictEqual(cpu.p.c, 0, "The carry bit should be clear after a borrow is "+
|
|
"triggered.");
|
|
strictEqual(cpu.p.m, 0, "The m flag of the p status register should be "+
|
|
"zero for 16-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be zero for native mode.");
|
|
});
|
|
}
|
|
|
|
function test_adc() {
|
|
module("ADC");
|
|
test("Test normal addition of two 16-bit numbers that don't cause an "+
|
|
"overflow (m bit is 0)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18c230a90100690100", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 2, "0x0001 + 0x0001 should result in 0x0002 when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.n, 0, "0x0001 + 0x0001 does not result in a negative "+
|
|
"two's complement number when adding with ADC.");
|
|
strictEqual(cpu.p.c, 0, "0x0001 + 0x0001 should not set the carry(c) "+
|
|
"bit when adding with ADC");
|
|
strictEqual(cpu.p.z, 0, "0x0001 + 0x0001 should not set the zero(z) bit "+
|
|
"when adding with ADC");
|
|
strictEqual(cpu.p.v, 0, "0x0001 + 0x0001 should not set the overflow(v) "+
|
|
"bit when adding with ADC");
|
|
});
|
|
test("Test normal addition of two 8-bit numbers that don't cause an "+
|
|
"overflow (m bit is 1)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18e230a9016901", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 2, "0x01 + 0x01 should result in 0x02 when using "+
|
|
"ADC");
|
|
strictEqual(cpu.p.n, 0, "0x01 + 0x01 does not result in a negative "+
|
|
"two's complement number when adding with ADC.");
|
|
strictEqual(cpu.p.c, 0, "0x01 + 0x01 should not set the carry(c) bit "+
|
|
"when adding with ADC");
|
|
strictEqual(cpu.p.z, 0, "0x01 + 0x01 should not set the zero(z) bit when "+
|
|
"adding with ADC");
|
|
strictEqual(cpu.p.v, 0, "0x01 + 0x01 should not set the overflow(v) bit "+
|
|
"when adding with ADC");
|
|
});
|
|
|
|
test("Test that overflow sets the carry flag and works in general with two"+
|
|
"16-bit numbers (m bit is 0)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18c230a9ffff690100", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.p.c, 1, "0xffff + 0x0001 should set the carry bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.r.a, 0, "0xffff + 0x0001 should result in the accumulator "+
|
|
"being 0 when using ADC");
|
|
strictEqual(cpu.p.n, 0, "0xffff + 0x0001 should not set the negative(n) "+
|
|
"bit when using ADC");
|
|
strictEqual(cpu.p.z, 1, "0xffff + 0x0001 should set the zero(z) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.v, 0, "0xffff + 0x0001 should not set the overflow(v) "+
|
|
"bit when using ADC");
|
|
});
|
|
|
|
test("Test that overflow sets the carry flag and works in general with two"+
|
|
"8-bit numbers (m bit is 1)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18e230a9ff6901", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.p.c, 1, "0xff + 0x01 should set the carry bit when using "+
|
|
"ADC");
|
|
strictEqual(cpu.r.a, 0, "0xff + 0x01 should result in the accumulator "+
|
|
"being 0 when using ADC");
|
|
strictEqual(cpu.p.n, 0, "0xff + 0x01 should not set the negative(n) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.z, 1, "0xff + 0x01 should set the zero(z) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.v, 0, "0xff + 0x01 should not set the overflow(v) bit "+
|
|
"when using ADC");
|
|
});
|
|
|
|
test("Test signed overflow with two 8-bit numbers (m bit is 1)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18e230a97f6901", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x80, "0x7f + 0x01 should result in 0x80 when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.v, 1, "0x7f + 0x01 should set the overflow(v) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.c, 0, "0x7f + 0x01 should not set the carry(c) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.z, 0, "0x7f + 0x01 should not set the zero(z) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.n, 1, "0x7f + 0x01 should set the negative(n) bit when "+
|
|
"using ADC");
|
|
});
|
|
test("Test signed overflow with two 16-bit numbers (m bit is 0)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18c230a9ff7f690100", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x8000, "0x7fff + 0x0001 should result in 0x8000 "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.v, 1, "0x7fff + 0x0001 should set the overflow(v) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.c, 0, "0x7fff + 0x0001 should not set the carry(c) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.z, 0, "0x7fff + 0x0001 should not set the zero(z) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.n, 1, "0x7fff + 0x0001 should set the negative(n) bit "+
|
|
"when using ADC");
|
|
});
|
|
|
|
test("Test ADC direct page with 8-bit numbers (m bit is 1)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18e230a90185ffa97f65ff", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x80, "0x7f + 0x01 should result in 0x80 when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.v, 1, "0x7f + 0x01 should set the overflow(v) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.c, 0, "0x7f + 0x01 should not set the carry(c) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.z, 0, "0x7f + 0x01 should not set the zero(z) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.n, 1, "0x7f + 0x01 should set the negative(n) bit when "+
|
|
"using ADC");
|
|
});
|
|
|
|
test("Test ADC direct page with 16-bit numbers (m bit is 0)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18c230a9010085fea9ff7f65fe", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x8000, "0x7fff + 0x0001 should result in 0x8000 "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.v, 1, "0x7fff + 0x0001 should set the overflow(v) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.c, 0, "0x7fff + 0x0001 should not set the carry(c) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.z, 0, "0x7fff + 0x0001 should not set the zero(z) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.n, 1, "0x7fff + 0x0001 should set the negative(n) bit "+
|
|
"when using ADC");
|
|
});
|
|
|
|
test("Test ADC absolute with 8-bit numbers (m bit is 1)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18e230a9018dffffa97f6dffff", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x80, "0x7f + 0x01 should result in 0x80 when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.v, 1, "0x7f + 0x01 should set the overflow(v) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.c, 0, "0x7f + 0x01 should not set the carry(c) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.z, 0, "0x7f + 0x01 should not set the zero(z) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.n, 1, "0x7f + 0x01 should set the negative(n) bit when "+
|
|
"using ADC");
|
|
});
|
|
|
|
test("Test ADC absolute with 16-bit numbers (m bit is 0)", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18c230a901008dffffa9ff7f6dffff", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x8000, "0x7fff + 0x0001 should result in 0x8000 "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.v, 1, "0x7fff + 0x0001 should set the overflow(v) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.c, 0, "0x7fff + 0x0001 should not set the carry(c) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.z, 0, "0x7fff + 0x0001 should not set the zero(z) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.n, 1, "0x7fff + 0x0001 should set the negative(n) bit "+
|
|
" when using ADC");
|
|
});
|
|
|
|
test("Test ADC direct page indirect with 8-bit numbers (m bit is 1)",
|
|
function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18e230a90185ffa9ff85fd64fea97f72fd", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x80, "0x7f + 0x01 should result in 0x80 when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.v, 1, "0x7f + 0x01 should set the overflow(v) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.c, 0, "0x7f + 0x01 should not set the carry(c) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.z, 0, "0x7f + 0x01 should not set the zero(z) bit when "+
|
|
"using ADC");
|
|
strictEqual(cpu.p.n, 1, "0x7f + 0x01 should set the negative(n) bit when "+
|
|
"using ADC");
|
|
});
|
|
test("Test ADC direct page indirect with 16-bit numbers (m bit is 0)",
|
|
function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18c230a901008500a9000085bba9ff7f72bb", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x8000, "0x7fff + 0x0001 should result in 0x8000 "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.v, 1, "0x7fff + 0x0001 should set the overflow(v) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.c, 0, "0x7fff + 0x0001 should not set the carry(c) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.z, 0, "0x7fff + 0x0001 should not set the zero(z) bit "+
|
|
"when using ADC");
|
|
strictEqual(cpu.p.n, 1, "0x7fff + 0x0001 should set the negative(n) bit "+
|
|
"when using ADC");
|
|
|
|
});
|
|
test("Test that ADC handles decimal mode with legal BCD numbers in 8-bit "+
|
|
"memory/accumulator mode with single digit numbers.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18f8a9056905", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x10, "0x05 + 0x05 should result in 0x10 with "+
|
|
"decimal mode on and with 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.c, 0, "The carry flag of the p status register should "+
|
|
"be clear after no decimal overflow.");
|
|
strictEqual(cpu.p.d, 1, "Decimal mode should be set to 1 in the p status "+
|
|
"register.");
|
|
strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
|
|
"for 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be 0 for native mode.");
|
|
});
|
|
test("Test that ADC handles decimal mode with legal BCD numbers in 8-bit "+
|
|
"memory/accumulator mode with double digit numbers.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18f8a9156926", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x41, "0x15 + 0x26 should result in 0x41 with "+
|
|
"decimal mode on and with 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.c, 0, "The carry flag of the p status register should "+
|
|
"be clear after no decimal overflow.");
|
|
strictEqual(cpu.p.d, 1, "Decimal mode should be set to 1 in the p status "+
|
|
"register.");
|
|
strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
|
|
"for 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be 0 for native mode.");
|
|
});
|
|
test("Test that ADC handles decimal mode with legal BCD numbers in 8-bit "+
|
|
"memory/accumulator mode with double digit numbers with the carry "+
|
|
"bit set", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb38f8a9156926", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x42, "0x15 + 0x26 should result in 0x42 with "+
|
|
"decimal mode on and with 8-bit memory/accumulator mode and "+
|
|
"the carry bit set.");
|
|
strictEqual(cpu.p.c, 0, "The carry flag of the p status register should "+
|
|
"be clear after no decimal overflow.");
|
|
strictEqual(cpu.p.d, 1, "Decimal mode should be set to 1 in the p status "+
|
|
"register.");
|
|
strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
|
|
"for 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be 0 for native mode.");
|
|
});
|
|
test("Test that ADC handles decimal mode with legal BCD numbers in 8-bit "+
|
|
"memory/accumulator mode when adding two numbers that cause an "+
|
|
"overflow.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18f8a9556960", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x16, "0x55 + 0x60 should result in 0x16 with "+
|
|
"decimal mode on and with 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.c, 1, "The carry flag of the p status register should "+
|
|
"be set after the decimal overflow.");
|
|
strictEqual(cpu.p.d, 1, "Decimal mode should be set to 1 in the p status "+
|
|
"register.");
|
|
strictEqual(cpu.p.m, 1, "The m flag of the p status register should be 1 "+
|
|
"for 8-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be 0 for native mode.");
|
|
});
|
|
test("Test that ADC handles decimal mode with legal BCD numbers in 16-bit "+
|
|
"memory/accumulator mode when adding two single digit numbers.",
|
|
function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18f8c220a90100690900", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x10, "0x0001 + 0x0009 should result in 0x0010 with "+
|
|
"decimal mode on and with 16-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.c, 0, "The carry flag of the p status register should "+
|
|
"be clear after no decimal overflow.");
|
|
strictEqual(cpu.p.d, 1, "Decimal mode should be set to 1 in the p status "+
|
|
"register.");
|
|
strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
|
|
"for 16-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be 0 for native mode.");
|
|
});
|
|
test("Test that ADC handles decimal mode with legal BCD numbers in 16-bit "+
|
|
"memory/accumulator mode when adding two four digit numbers.",
|
|
function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18f8c220a90110699939", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x5000, "0x1001 + 0x3999 should result in 0x5000 "+
|
|
"with decimal mode on and with 16-bit "+
|
|
"memory/accumulator mode.");
|
|
strictEqual(cpu.p.c, 0, "The carry flag of the p status register should "+
|
|
"be clear after no decimal overflow.");
|
|
strictEqual(cpu.p.d, 1, "Decimal mode should be set to 1 in the p status "+
|
|
"register.");
|
|
strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
|
|
"for 16-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be 0 for native mode.");
|
|
});
|
|
test("Test that ADC handles decimal mode with legal BCD numbers in 16-bit "+
|
|
"memory/accumulator mode when adding two numbers that cause an "+
|
|
"overflow.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb18f8c220a99756699999", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x5697, "0x5697 + 0x9999 should result in 0x5697 "+
|
|
"with decimal mode on and with 16-bit memory/accumulator "+
|
|
"mode.");
|
|
strictEqual(cpu.p.c, 1, "The carry flag of the p status register should "+
|
|
"be set after decimal overflow.");
|
|
strictEqual(cpu.p.d, 1, "Decimal mode should be set to 1 in the p status "+
|
|
"register.");
|
|
strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
|
|
"for 16-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be 0 for native mode.");
|
|
});
|
|
test("Test that ADC handles decimal mode with legal BCD numbers in 16-bit "+
|
|
"memory/accumulator mode when adding two four digit numbers with the "+
|
|
"carry bit set.", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb38f8c220a90110699939", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x5001, "0x1001 + 0x3999 should result in 0x5001 "+
|
|
"with decimal mode on, with 16-bit "+
|
|
"memory/accumulator mode and the carry flag set.");
|
|
strictEqual(cpu.p.c, 0, "The carry flag of the p status register should "+
|
|
"be clear after no decimal overflow.");
|
|
strictEqual(cpu.p.d, 1, "Decimal mode should be set to 1 in the p status "+
|
|
"register.");
|
|
strictEqual(cpu.p.m, 0, "The m flag of the p status register should be 0 "+
|
|
"for 16-bit memory/accumulator mode.");
|
|
strictEqual(cpu.p.e, 0, "The hidden e flag of the p status register "+
|
|
"should be 0 for native mode.");
|
|
});
|
|
}
|
|
|
|
function test_branching() {
|
|
module("Branching");
|
|
test("Test that BRA with 0x00 as its argument doesn't increment or "+
|
|
"decrement the program counter", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("8000", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.pc, 0x8003, "Make sure that the program counter isn't "+
|
|
"incremented or decremented if BRA is given "+
|
|
"0x00 as its argument.");
|
|
});
|
|
|
|
test("Check that the branching operations properly treat the argument as "+
|
|
"a two's complement number", function() {
|
|
var cpu = new CPU_65816();
|
|
// negative two's complement number 0xf0 = -16
|
|
cpu.load_binary("80f0", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.pc, (0x8003-16), "A branching operation when given a "+
|
|
"negative two's complement number should decrement the "+
|
|
"program counter by the proper amount.");
|
|
cpu.reset();
|
|
cpu.load_binary("8020", 0x8000); // positive two's complement number.
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.pc, (0x8003+0x20), "A branching operation when given a "+
|
|
"positive two's complement number should increment the "+
|
|
"program counter by the proper amount.");
|
|
});
|
|
|
|
test("Check that BPL works as expected", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc230a9fe7f1a10fd", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x8000, "Check that branching only occurs while the "+
|
|
"number is a two's complement positive number.");
|
|
});
|
|
|
|
test("Check that BMI works as expected", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fbc230a901803a30fd", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, 0x7fff, "Check that branching only occurs while the "+
|
|
"number is a two's complement negative number.");
|
|
});
|
|
}
|
|
|
|
function test_sep() {
|
|
module("SEP");
|
|
test("Test 'SEP #$30' not in emulation mode", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.p.e = 0;
|
|
cpu.load_binary("e230", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.p.m, 1, "'SEP #$30' should set the m status bit of the p "+
|
|
"register to 1");
|
|
strictEqual(cpu.p.x, 1, "'SEP #$30' should set the x status bit of the p "+
|
|
"register to 1");
|
|
strictEqual(cpu.p.n, 0, "'SEP #$30' should not set the n status bit of "+
|
|
"the p register to 1.");
|
|
strictEqual(cpu.p.c, 0, "'SEP #$30' should not set the c status bit of "+
|
|
"the p register to 1.");
|
|
strictEqual(cpu.p.z, 0, "'SEP #$30' should not set the z status bit of "+
|
|
"the p register to 1.");
|
|
strictEqual(cpu.p.d, 0, "'SEP #$30' should not set the d status bit of "+
|
|
"the p register to 1.");
|
|
strictEqual(cpu.p.v, 0, "'SEP #$30' should not set the v status bit of "+
|
|
"the p register to 1.");
|
|
strictEqual(cpu.p.i, 0, "'SEP #$30' should not set the i status bit of "+
|
|
"the p register to 1.");
|
|
});
|
|
test("Test 'SEP #$cf' not in emulation mode", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.p.e = 0;
|
|
cpu.load_binary("e2cf", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.p.m, 0, "'SEP #$cf' should not set the m status bit of "+
|
|
"the p register to 1");
|
|
strictEqual(cpu.p.x, 0, "'SEP #$cf' should not set the x status bit of "+
|
|
"the p register to 1");
|
|
strictEqual(cpu.p.n, 1, "'SEP #$cf' should set the n status bit of the p "+
|
|
"register to 1.");
|
|
strictEqual(cpu.p.c, 1, "'SEP #$cf' should set the c status bit of the p "+
|
|
"register to 1.");
|
|
strictEqual(cpu.p.z, 1, "'SEP #$cf' should set the z status bit of the p "+
|
|
"register to 1.");
|
|
strictEqual(cpu.p.d, 1, "'SEP #$cf' should set the d status bit of the p "+
|
|
"register to 1.");
|
|
strictEqual(cpu.p.v, 1, "'SEP #$cf' should set the v status bit of the p "+
|
|
"register to 1.");
|
|
strictEqual(cpu.p.i, 1, "'SEP #$cf' should set the i status bit of the p "+
|
|
"register to 1.");
|
|
});
|
|
}
|
|
|
|
function test_rep() {
|
|
module("REP");
|
|
test("Test 'REP #$30' not in emulation mode", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.p.e = 0;
|
|
// Make sure stuff is cleared by setting all of the bits to 1 initially.
|
|
cpu.p.n = 1;
|
|
cpu.p.c = 1;
|
|
cpu.p.v = 1;
|
|
cpu.p.i = 1;
|
|
cpu.p.d = 1;
|
|
cpu.p.x = 1;
|
|
cpu.p.m = 1;
|
|
cpu.p.z = 1;
|
|
cpu.load_binary("c230", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.p.m, 0, "'REP #$30' should clear the m bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.x, 0, "'REP #$30' should clear the x bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.d, 1, "'REP #$30' should not clear the d bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.i, 1, "'REP #$30' should not clear the i bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.c, 1, "'REP #$30' should not clear the c bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.z, 1, "'REP #$30' should not clear the z bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.v, 1, "'REP #$30' should not clear the v bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.n, 1, "'REP #$30' should not clear the n bit of the p "+
|
|
"status register");
|
|
});
|
|
|
|
test("Test 'REP #$cf' not in emulation mode", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.p.e = 0;
|
|
// Make sure stuff is cleared by setting all of the bits to 1 initially.
|
|
cpu.p.n = 1;
|
|
cpu.p.c = 1;
|
|
cpu.p.v = 1;
|
|
cpu.p.i = 1;
|
|
cpu.p.d = 1;
|
|
cpu.p.x = 1;
|
|
cpu.p.m = 1;
|
|
cpu.p.z = 1;
|
|
cpu.load_binary("c2cf", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.p.m, 1, "'REP #$cf' should not clear the m bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.x, 1, "'REP #$cf' should not clear the x bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.z, 0, "'REP #$cf' should clear the z bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.n, 0, "'REP #$cf' should clear the n bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.d, 0, "'REP #$cf' should clear the d bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.v, 0, "'REP #$cf' should clear the v bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.i, 0, "'REP #$cf' should clear the i bit of the p "+
|
|
"status register");
|
|
strictEqual(cpu.p.c, 0, "'REP #$cf' should clear the c bit of the p "+
|
|
"status register");
|
|
});
|
|
}
|
|
|
|
function test_cpu_load_binary() {
|
|
module("cpu.load_binary");
|
|
test("Make sure that load binary can work with hex strings", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary("18fb", 0x8000);
|
|
strictEqual(cpu.mmu.read_byte_long(0x8000, cpu.r.k), 0x18);
|
|
strictEqual(cpu.mmu.read_byte_long(0x8001, cpu.r.k), 0xfb);
|
|
});
|
|
|
|
test("Make sure that load_binary can work with arrays", function() {
|
|
var cpu = new CPU_65816();
|
|
cpu.load_binary([0x18, 0xfb], 0x8000);
|
|
strictEqual(cpu.mmu.read_byte_long(0x8000, cpu.r.k), 0x18);
|
|
strictEqual(cpu.mmu.read_byte_long(0x8001, cpu.r.k), 0xfb);
|
|
});
|
|
}
|
|
|
|
function test_cpu_memory_mapped_io_devices() {
|
|
module("memory mapped io devices");
|
|
test("Make sure that memory mapped io devices properly receive input",
|
|
function() {
|
|
var cpu = new CPU_65816(),
|
|
written_value,
|
|
write_callback = function(cpu, b) {
|
|
written_value = b;
|
|
};
|
|
cpu.mmu.add_memory_mapped_io_device(write_callback, null, 0, 1);
|
|
cpu.load_binary("a9ff8501", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(written_value, 0xff);
|
|
});
|
|
|
|
test("Make sure that memory mapped io devices can be read from properly",
|
|
function() {
|
|
var cpu = new CPU_65816(),
|
|
read_value = 0xee,
|
|
read_callback = function(cpu) {
|
|
return read_value;
|
|
};
|
|
cpu.mmu.add_memory_mapped_io_device(null, read_callback, 0, 1);
|
|
cpu.load_binary("a501", 0x8000);
|
|
cpu.execute(0x8000);
|
|
strictEqual(cpu.r.a, read_value, "The accumulator should equal the value "+
|
|
"read from the memory mapped io device, 0xee");
|
|
});
|
|
}
|