(in-package #:parse) (defparameter line-number 0 "The number of real instructions processed up until this point.") (defparameter var-offset 0 "The number of variables processed up until this point.") (esrap:defrule space (+ (or #\space #\tab)) (:constant nil)) (esrap:defrule nl (+ #\newline) (:constant nil)) (esrap:defrule nl-inc (+ #\newline) (:lambda (n) (declare (ignore n)) (incf line-number) nil)) (esrap:defrule sign (or #\+ #\-)) (esrap:defrule alpha (+ (alphanumericp character)) (:text t)) ;;; defines rules to parse an integer in various bases (defmacro define-number-rule ()) (esrap:defrule binary (and #\0 #\B (+ (or "0" "1"))) (:lambda (e) (parse-integer (esrap:text (cddr e)) :radix 2))) (esrap:defrule octal (and #\0 #\O (+ (or (esrap:character-ranges (#\0 #\7))))) (:lambda (e) (parse-integer (esrap:text (cddr e)) :radix 8))) (esrap:defrule decimal (+ (or (esrap:character-ranges (#\0 #\9)))) (:lambda (e) (parse-integer (esrap:text e) :radix 10))) (esrap:defrule hex (and #\0 #\X (+ (or (esrap:character-ranges (#\0 #\9)) "A" "B" "C" "D" "E" "F"))) (:lambda (e) (parse-integer (esrap:text (cddr e)) :radix 16))) (esrap:defrule int (and (esrap:? sign) (or binary octal hex decimal)) (:destructure (s i) (if (and s (string= s "-")) (- i) i))) ;;; defines rules to parse an operand (esrap:defrule register (and #\$ int) (:function cadr) (:lambda (e) (list 'emit::rr e))) (esrap:defrule variable alpha (:lambda (e) (list 'emit::var e))) (esrap:defrule dereference (and int #\( register #\)) (:destructure (i1 w1 r w2) (declare (ignore w1 w2)) (list r (list 'emit::imm i1)))) (esrap:defrule immediate (or int variable) (:lambda (e) (list 'emit::imm e))) ;;; defines rules to parse labels (esrap:defrule label alpha (:lambda (e) (list 'emit::l e line-number))) (esrap:defrule label-decl (and alpha #\:) (:function car) (:lambda (e) (util:add-label e line-number) nil)) ;;; defines rules to parse instruction types (defun generate-mnemonic (name ops) (let ((expr `(or ,@ops))) (esrap:add-rule name (make-instance 'esrap:rule :expression expr)))) ;; define special cases first (generate-mnemonic 'r-type-1-m '("NOT")) (generate-mnemonic 'r-type-2-m '("CMP" "CEV")) (generate-mnemonic 'i-type-1-m '("LOADV" "LOAD")) (generate-mnemonic 'i-type-2-m '("STOREV" "STORE")) (generate-mnemonic 'j-type-1-m '("JMP" "JAL")) (generate-mnemonic 'j-type-2-m '("PUSH" "POP")) ;; we need to reverse to ensure rules like "ADDV" are matched before "ADD" (generate-mnemonic 'r-type-3-m (reverse util:r-type)) (generate-mnemonic 'i-type-3-m (reverse util:i-type)) (generate-mnemonic 'j-type-3-m (reverse util:j-type)) ;; TODO this is pretty gross (defmacro defrule-instr (name type-id order &rest destructure-pattern) "Defines the boilerplate for a common esrap instruction rule. NAME is the name of the non-terminal symbol. TYPE-ID is the symbol which appears as the first element of a successful parse. ORDER is the order to place the parsed tokens in the resulting list. DESTRUCTURE-PATTERN is the list of non-terminals on the right side of the grammar rule." (let* ((pattern-size (length destructure-pattern)) (spaces (mapcar (lambda (x) (read-from-string (format nil "w~A" x))) (util:iota pattern-size))) (vars (mapcar (lambda (x) (read-from-string (format nil "s~A" x))) (util:iota pattern-size)))) `(esrap:defrule ,name (and ,(read-from-string (format nil "~A-m" name)) ,@(util:riffle (make-list pattern-size :initial-element 'space) destructure-pattern)) (:destructure (m ,@(util:riffle spaces vars)) (declare (ignore ,@spaces)) (list ,type-id m ,@(mapcar (lambda (x) (or (nth x vars) ''(emit::rr 0))) order)))))) (defrule-instr r-type-1 'emit::r (1 2 0) register register) (defrule-instr r-type-2 'emit::r (0 1 2) register register) (defrule-instr r-type-3 'emit::r (1 2 0) register register register) (defrule-instr i-type-3 'emit::i (1 0 2) register register immediate) (defrule-instr j-type-3 'emit::j (1 0) label) (esrap:defrule i-type-1 (and i-type-1-m space register space dereference) (:destructure (m w1 s w2 di) (declare (ignore w1 w2)) `(emit::i ,m ,s ,@di))) (esrap:defrule i-type-2 (and i-type-2-m space register space dereference) (:destructure (m w1 s w2 di) (declare (ignore w1 w2)) `(emit::i ,m ,@(util:insert-in-middle di s)))) (esrap:defrule j-type-1 (and j-type-1-m space dereference) (:destructure (m w di) (declare (ignore w)) `(emit::j ,m ,@di))) (esrap:defrule j-type-2 (and j-type-2-m space register) (:destructure (m w r) (declare (ignore w)) `(emit::j ,m ,r (emit::imm 0)))) (esrap:defrule instr (or r-type-1 r-type-2 r-type-3 i-type-1 i-type-2 i-type-3 j-type-1 j-type-2 j-type-3)) ;;; defines rules to parse the .text segment (esrap:defrule instr-clean (and (esrap:? space) instr (esrap:? space) nl-inc) (:function cadr)) (esrap:defrule label-clean (and label-decl (esrap:? space) nl) (:function car)) (esrap:defrule text-line (or instr-clean label-clean)) (esrap:defrule text (and ".TEXT" (esrap:? space) nl (* text-line)) (:function cadddr) (:lambda (e) `(emit::x ,@(remove nil e)))) ;;; defines rules to parse the .data segment (esrap:defrule data-word (and (esrap:? space) int) (:function cadr) (:lambda (e) (incf var-offset) e)) (esrap:defrule var-decl alpha (:lambda (e) (util:add-variable e var-offset) nil)) (esrap:defrule data-line (and (esrap:? space) var-decl (+ data-word) (esrap:? space) nl) (:function caddr)) (esrap:defrule data (and ".DATA" (esrap:? space) nl (* data-line)) (:function cadddr) (:lambda (e) `(emit::d ,@(apply #'append e)))) ;;; defines rules to parse a program (esrap:defrule str->ast (and (* (or space nl)) data text) (:function cdr) (:lambda (e) `(emit::p ,@e)))