Construct a syntax-directed translation scheme that translates arithmetic expressions from infix notation into prefix notation in which an operator appears before its operands; e.g. , -xy is the prefix notation for x - y. Give annotated parse trees for the inputs 9-5+2 and 9-5*2.
productions:
expr -> expr + term | expr - term | term term -> term * factor | term / factor | factor factor -> digit | (expr)
translation schemes:
expr -> {print("+")} expr + term | {print("-")} expr - term | term term -> {print("*")} term * factor | {print("/")} term / factor | factor factor -> digit {print(digit)} | (expr)
Construct a syntax-directed translation scheme that translates arithmetic expressions from postfix notation into infix notation. Give annotated parse trees for the inputs 95-2 and 952-.
expr -> expr expr + | expr expr - | expr expr * | expr expr / | digit
expr -> expr {print("+")} expr + | expr {print("-")} expr - | {print("(")} expr {print(")*(")} expr {print(")")} * | {print("(")} expr {print(")/(")} expr {print(")")} / | digit {print(digit)}
E -> {print("(")} E {print(op)} E {print(")"}} op | digit {print(digit)}
Construct a syntax-directed translation scheme that translates integers into roman numerals.
assistant function:
repeat(sign, times) // repeat('a',2) = 'aa'
num -> thousand hundred ten digit { num.roman = thousand.roman || hundred.roman || ten.roman || digit.roman; print(num.roman)} thousand -> low {thousand.roman = repeat('M', low.v)} hundred -> low {hundred.roman = repeat('C', low.v)} | 4 {hundred.roman = 'CD'} | high {hundred.roman = 'D' || repeat('X', high.v - 5)} | 9 {hundred.roman = 'CM'} ten -> low {ten.roman = repeat('X', low.v)} | 4 {ten.roman = 'XL'} | high {ten.roman = 'L' || repeat('X', high.v - 5)} | 9 {ten.roman = 'XC'} digit -> low {digit.roman = repeat('I', low.v)} | 4 {digit.roman = 'IV'} | high {digit.roman = 'V' || repeat('I', high.v - 5)} | 9 {digit.roman = 'IX'} low -> 0 {low.v = 0} | 1 {low.v = 1} | 2 {low.v = 2} | 3 {low.v = 3} high -> 5 {high.v = 5} | 6 {high.v = 6} | 7 {high.v = 7} | 8 {high.v = 8}
Construct a syntax-directed translation scheme that trans lates roman numerals into integers.
romanNum -> thousand hundred ten digit thousand -> M | MM | MMM | ε hundred -> smallHundred | C D | D smallHundred | C M smallHundred -> C | CC | CCC | ε ten -> smallTen | X L | L smallTen | X C smallTen -> X | XX | XXX | ε digit -> smallDigit | I V | V smallDigit | I X smallDigit -> I | II | III | ε
romanNum -> thousand hundred ten digit {romanNum.v = thousand.v || hundred.v || ten.v || digit.v; print(romanNun.v)} thousand -> M {thousand.v = 1} | MM {thousand.v = 2} | MMM {thousand.v = 3} | ε {thousand.v = 0} hundred -> smallHundred {hundred.v = smallHundred.v} | C D {hundred.v = smallHundred.v} | D smallHundred {hundred.v = 5 + smallHundred.v} | C M {hundred.v = 9} smallHundred -> C {smallHundred.v = 1} | CC {smallHundred.v = 2} | CCC {smallHundred.v = 3} | ε {hundred.v = 0} ten -> smallTen {ten.v = smallTen.v} | X L {ten.v = 4} | L smallTen {ten.v = 5 + smallTen.v} | X C {ten.v = 9} smallTen -> X {smallTen.v = 1} | XX {smallTen.v = 2} | XXX {smallTen.v = 3} | ε {smallTen.v = 0} digit -> smallDigit {digit.v = smallDigit.v} | I V {digit.v = 4} | V smallDigit {digit.v = 5 + smallDigit.v} | I X {digit.v = 9} smallDigit -> I {smallDigit.v = 1} | II {smallDigit.v = 2} | III {smallDigit.v = 3} | ε {smallDigit.v = 0}
Construct a syntax-directed translation scheme that translates postfix arithmetic expressions into equivalent prefix arithmetic expressions.
production:
expr -> expr expr op | digit
translation scheme:
expr -> {print(op)} expr expr op | digit {print(digit)}
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