package prog8tests.ast import io.kotest.core.spec.style.FunSpec import io.kotest.matchers.shouldBe import io.kotest.matchers.shouldNotBe import io.kotest.matchers.string.shouldContain import io.kotest.matchers.types.instanceOf import prog8.ast.expressions.AddressOf import prog8.ast.expressions.BinaryExpression import prog8.ast.expressions.IdentifierReference import prog8.ast.expressions.NumericLiteral import prog8.ast.statements.Assignment import prog8.ast.statements.Return import prog8.ast.statements.VarDecl import prog8.ast.statements.VarDeclType import prog8.code.core.DataType import prog8.code.core.Position import prog8.code.target.C64Target import prog8.code.target.Cx16Target import prog8tests.helpers.ErrorReporterForTests import prog8tests.helpers.compileText class TestConst: FunSpec({ test("const folding multiple scenarios +/-") { val source = """ main { const ubyte boardHeightC = 20 const ubyte boardOffsetC = 3 sub start() { uword @shared load_location = 12345 word @shared llw = 12345 cx16.r0 = load_location + 8000 + 1000 + 1000 cx16.r2 = 8000 + 1000 + 1000 + load_location cx16.r4 = load_location + boardOffsetC + boardHeightC - 1 cx16.r5s = llw - 900 - 999 cx16.r7s = llw - 900 + 999 } }""" val result = compileText(C64Target(), true, source, writeAssembly = false)!! // expected: // uword load_location // load_location = 12345 // word llw // llw = 12345 // cx16.r0 = load_location + 10000 // cx16.r2 = load_location + 10000 // cx16.r4 = load_location + 22 // cx16.r5s = llw - 1899 // cx16.r7s = llw + 99 val stmts = result.compilerAst.entrypoint.statements stmts.size shouldBe 9 val addR0value = (stmts[4] as Assignment).value val binexpr0 = addR0value as BinaryExpression binexpr0.operator shouldBe "+" binexpr0.right shouldBe NumericLiteral(DataType.UWORD, 10000.0, Position.DUMMY) val addR2value = (stmts[5] as Assignment).value val binexpr2 = addR2value as BinaryExpression binexpr2.operator shouldBe "+" binexpr2.right shouldBe NumericLiteral(DataType.UWORD, 10000.0, Position.DUMMY) val addR4value = (stmts[6] as Assignment).value val binexpr4 = addR4value as BinaryExpression binexpr4.operator shouldBe "+" binexpr4.right shouldBe NumericLiteral(DataType.UWORD, 22.0, Position.DUMMY) val subR5value = (stmts[7] as Assignment).value val binexpr5 = subR5value as BinaryExpression binexpr5.operator shouldBe "-" binexpr5.right shouldBe NumericLiteral(DataType.WORD, 1899.0, Position.DUMMY) val subR7value = (stmts[8] as Assignment).value val binexpr7 = subR7value as BinaryExpression binexpr7.operator shouldBe "+" binexpr7.right shouldBe NumericLiteral(DataType.WORD, 99.0, Position.DUMMY) } test("const folding multiple scenarios * and / (floats)") { val source = """ %option enable_floats main { sub start() { float @shared llw = 300.0 float @shared result result = 9 * 2 * 10 * llw result++ result = llw * 9 * 2 * 10 result++ result = llw / 30 / 3 result++ result = llw / 2 * 10 result++ result = llw * 90 / 5 } }""" val result = compileText(C64Target(), true, source, writeAssembly = false)!! // expected: // float llw // llw = 300.0 // float result // result = llw * 180.0 // result++ // result = llw * 180.0 // result++ // result = llw / 90.0 // result++ // result = llw * 5.0 // result++ // result = llw * 18.0 val stmts = result.compilerAst.entrypoint.statements stmts.size shouldBe 12 val mulR0Value = (stmts[3] as Assignment).value val binexpr0 = mulR0Value as BinaryExpression binexpr0.operator shouldBe "*" binexpr0.right shouldBe NumericLiteral(DataType.FLOAT, 180.0, Position.DUMMY) val mulR1Value = (stmts[5] as Assignment).value val binexpr1 = mulR1Value as BinaryExpression binexpr1.operator shouldBe "*" binexpr1.right shouldBe NumericLiteral(DataType.FLOAT, 180.0, Position.DUMMY) val divR2Value = (stmts[7] as Assignment).value val binexpr2 = divR2Value as BinaryExpression binexpr2.operator shouldBe "/" binexpr2.right shouldBe NumericLiteral(DataType.FLOAT, 90.0, Position.DUMMY) val mulR3Value = (stmts[9] as Assignment).value val binexpr3 = mulR3Value as BinaryExpression binexpr3.operator shouldBe "*" binexpr3.right shouldBe NumericLiteral(DataType.FLOAT, 5.0, Position.DUMMY) binexpr3.left shouldBe instanceOf() val mulR4Value = (stmts[11] as Assignment).value val binexpr4 = mulR4Value as BinaryExpression binexpr4.operator shouldBe "*" binexpr4.right shouldBe NumericLiteral(DataType.FLOAT, 18.0, Position.DUMMY) binexpr4.left shouldBe instanceOf() } test("const folding multiple scenarios * and / (integers)") { val source = """ main { sub start() { word @shared llw = 300 cx16.r0s = 9 * 2 * 10 * llw cx16.r1s = llw * 9 * 2 * 10 cx16.r2s = llw / 30 / 3 cx16.r3s = llw / 2 * 10 cx16.r4s = llw * 90 / 5 ; not optimized because of loss of integer division precision } }""" val result = compileText(C64Target(), true, source, writeAssembly = false)!! // expected: // word llw // llw = 300 // cx16.r0s = llw * 180 // cx16.r1s = llw * 180 // cx16.r2s = llw / 90 // cx16.r3s = llw /2 *10 // cx16.r4s = llw *90 /5 val stmts = result.compilerAst.entrypoint.statements stmts.size shouldBe 7 val mulR0Value = (stmts[2] as Assignment).value val binexpr0 = mulR0Value as BinaryExpression binexpr0.operator shouldBe "*" binexpr0.right shouldBe NumericLiteral(DataType.WORD, 180.0, Position.DUMMY) val mulR1Value = (stmts[3] as Assignment).value val binexpr1 = mulR1Value as BinaryExpression binexpr1.operator shouldBe "*" binexpr1.right shouldBe NumericLiteral(DataType.WORD, 180.0, Position.DUMMY) val divR2Value = (stmts[4] as Assignment).value val binexpr2 = divR2Value as BinaryExpression binexpr2.operator shouldBe "/" binexpr2.right shouldBe NumericLiteral(DataType.WORD, 90.0, Position.DUMMY) val mulR3Value = (stmts[5] as Assignment).value val binexpr3 = mulR3Value as BinaryExpression binexpr3.operator shouldBe "*" binexpr3.right shouldBe NumericLiteral(DataType.WORD, 10.0, Position.DUMMY) binexpr3.left shouldBe instanceOf() val mulR4Value = (stmts[6] as Assignment).value val binexpr4 = mulR4Value as BinaryExpression binexpr4.operator shouldBe "/" binexpr4.right shouldBe NumericLiteral(DataType.WORD, 5.0, Position.DUMMY) binexpr4.left shouldBe instanceOf() } test("const folding and silently typecasted for initializervalues") { val sourcecode = """ main { sub start() { const ubyte TEST = 10 byte @shared x1 = TEST as byte + 1 byte @shared x2 = 1 + TEST as byte ubyte @shared y1 = TEST + 1 as byte ubyte @shared y2 = 1 as byte + TEST } } """ val result = compileText(C64Target(), false, sourcecode)!! val mainsub = result.compilerAst.entrypoint mainsub.statements.size shouldBe 10 val declTest = mainsub.statements[0] as VarDecl val declX1 = mainsub.statements[1] as VarDecl val initX1 = mainsub.statements[2] as Assignment val declX2 = mainsub.statements[3] as VarDecl val initX2 = mainsub.statements[4] as Assignment val declY1 = mainsub.statements[5] as VarDecl val initY1 = mainsub.statements[6] as Assignment val declY2 = mainsub.statements[7] as VarDecl val initY2 = mainsub.statements[8] as Assignment mainsub.statements[9] shouldBe instanceOf() (declTest.value as NumericLiteral).number shouldBe 10.0 declX1.value shouldBe null declX2.value shouldBe null declY1.value shouldBe null declY2.value shouldBe null (initX1.value as NumericLiteral).type shouldBe DataType.BYTE (initX1.value as NumericLiteral).number shouldBe 11.0 (initX2.value as NumericLiteral).type shouldBe DataType.BYTE (initX2.value as NumericLiteral).number shouldBe 11.0 (initY1.value as NumericLiteral).type shouldBe DataType.UBYTE (initY1.value as NumericLiteral).number shouldBe 11.0 (initY2.value as NumericLiteral).type shouldBe DataType.UBYTE (initY2.value as NumericLiteral).number shouldBe 11.0 } test("const pointer variable indexing works") { val src=""" main { sub start() { const uword pointer=$1000 cx16.r0L = pointer[2] pointer[2] = cx16.r0L } } """ compileText(C64Target(), optimize=false, src, writeAssembly=false) shouldNotBe null } test("advanced const folding of known library functions") { val src=""" %import floats %import math %import string main { sub start() { float fl = 1.2 ; no other assignments bool @shared result1 = string.isdigit(math.diff(119, floats.floor(floats.deg(fl)) as ubyte)) bool @shared result2 = string.isletter(math.diff(119, floats.floor(floats.deg(1.2)) as ubyte)) } }""" val result = compileText(Cx16Target(), true, src, writeAssembly = false)!! val st = result.compilerAst.entrypoint.statements st.size shouldBe 5 (st[0] as VarDecl).type shouldBe VarDeclType.CONST val assignv1 = (st[2] as Assignment).value val assignv2 = (st[4] as Assignment).value (assignv1 as NumericLiteral).number shouldBe 1.0 (assignv2 as NumericLiteral).number shouldBe 0.0 } test("const address-of memory mapped arrays") { val src=""" main { sub start() { &uword[30] wb = ${'$'}2000 &uword[100] array1 = ${'$'}9e00 &uword[30] array2 = &array1[len(wb)] cx16.r0 = &array1 ; ${'$'}9e00 cx16.r1 = &array1[len(wb)] ; ${'$'}9e3c cx16.r2 = &array2 ; ${'$'}9e3c } }""" val result = compileText(Cx16Target(), false, src, writeAssembly = false)!! val st = result.compilerAst.entrypoint.statements st.size shouldBe 6 ((st[0] as VarDecl).value as NumericLiteral).number shouldBe 0x2000 ((st[1] as VarDecl).value as NumericLiteral).number shouldBe 0x9e00 ((st[2] as VarDecl).value as NumericLiteral).number shouldBe 0x9e00+2*30 ((st[3] as Assignment).value as NumericLiteral).number shouldBe 0x9e00 ((st[4] as Assignment).value as NumericLiteral).number shouldBe 0x9e00+2*30 ((st[5] as Assignment).value as NumericLiteral).number shouldBe 0x9e00+2*30 } test("address of a memory mapped variable") { val src = """ main { sub start() { &ubyte mappedvar = 1000 cx16.r0 = &mappedvar &ubyte[8] array = &mappedvar cx16.r0 = &array const uword HIGH_MEMORY_START = 40960 &uword[20] @shared wa = HIGH_MEMORY_START } }""" val result = compileText(Cx16Target(), optimize=false, src, writeAssembly=true)!! val st = result.compilerAst.entrypoint.statements st.size shouldBe 7 val arrayDeclV = (st[2] as VarDecl).value (arrayDeclV as NumericLiteral).number shouldBe 1000.0 val waDeclV = (st[5] as VarDecl).value (waDeclV as NumericLiteral).number shouldBe 40960.0 } test("address of a const uword pointer array expression") { val src=""" main { sub start() { const uword buffer = ${'$'}2000 uword @shared addr = &buffer[2] const ubyte width = 100 ubyte @shared i ubyte @shared j uword @shared addr2 = &buffer[i * width + j] } }""" val result = compileText(Cx16Target(), true, src, writeAssembly = true)!! val st = result.compilerAst.entrypoint.statements st.size shouldBe 11 val assignAddr = (st[2] as Assignment).value (assignAddr as NumericLiteral).number shouldBe 8194.0 val assignAddr2 = ((st[9] as Assignment).value as AddressOf) assignAddr2.identifier.nameInSource shouldBe listOf("buffer") assignAddr2.arrayIndex!!.indexExpr shouldBe instanceOf() } test("out of range const byte and word give correct error") { var src=""" main { sub start() { const byte MIN_BYTE = -129 const word MIN_WORD = -32769 const byte MAX_BYTE = 128 const word MAX_WORD = 32768 } }""" val errors = ErrorReporterForTests() compileText(C64Target(), true, src, writeAssembly = false, errors=errors) shouldBe null errors.errors.size shouldBe 4 errors.errors[0] shouldContain "out of range" errors.errors[1] shouldContain "out of range" errors.errors[2] shouldContain "out of range" errors.errors[3] shouldContain "out of range" } test("out of range var byte and word give correct error") { var src=""" main { sub start() { byte @shared v_MIN_BYTE = -129 word @shared v_MIN_WORD = -32769 byte @shared v_MAX_BYTE = 128 word @shared v_MAX_WORD = 32768 } }""" val errors = ErrorReporterForTests() compileText(C64Target(), true, src, writeAssembly = false, errors=errors) shouldBe null errors.errors.size shouldBe 8 errors.errors[0] shouldContain "out of range" errors.errors[2] shouldContain "out of range" errors.errors[4] shouldContain "out of range" errors.errors[6] shouldContain "out of range" } test("out of range const byte and word no errors with explicit cast if possible") { var src=""" main { sub start() { const byte MIN_BYTE = -129 as byte ; still error const word MIN_WORD = -32769 as word ; still error const byte MAX_BYTE = 128 as byte const word MAX_WORD = 32768 as word } }""" val errors = ErrorReporterForTests() compileText(C64Target(), true, src, writeAssembly = false, errors=errors) shouldBe null errors.errors.size shouldBe 4 errors.errors[0] shouldContain(":4:31: const declaration needs a compile-time constant") errors.errors[1] shouldContain(":4:32: no cast available") errors.errors[2] shouldContain(":5:31: const declaration needs a compile-time constant") errors.errors[3] shouldContain(":5:32: no cast available") } test("out of range var byte and word no errors with explicit cast if possible") { var src=""" main { sub start() { byte @shared v_min_byte2 = -129 as byte ; still error word @shared v_min_word2 = -32769 as word ; still error byte @shared v_min_byte3 = 255 as byte word @shared v_min_word3 = 50000 as word } }""" val errors = ErrorReporterForTests() compileText(C64Target(), true, src, writeAssembly = false, errors=errors) shouldBe null errors.errors.size shouldBe 2 errors.errors[0] shouldContain(":4:37: no cast available") errors.errors[1] shouldContain(":5:37: no cast available") } })