(load "mu.arc") (reset) (add-fns '((test1 ((1 integer) <- literal 1)))) (run 'test1) ;? (prn memory*) (if (~iso memory* (obj 1 1)) (prn "F - 'literal' writes a literal value (its lone 'arg' after the instruction name) to a location in memory (an address) specified by its lone 'oarg' or output arg before the arrow")) ;? (quit) (reset) (add-fns '((test1 ((1 integer) <- literal 1) ((2 integer) <- literal 3) ((3 integer) <- add (1 integer) (2 integer))))) (run 'test1) (if (~iso memory* (obj 1 1 2 3 3 4)) (prn "F - 'add' operates on two addresses")) (reset) (add-fns '((test1 ((3 integer) <- add (1 integer) (2 integer))) (main ((1 integer) <- literal 1) ((2 integer) <- literal 3) (test1)))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 3 3 4)) (prn "F - calling a user-defined function runs its instructions")) ;? (quit) (reset) (add-fns '((test1 ((1 integer) <- literal 1)) (main (test1)))) (if (~iso 2 (run 'main)) (prn "F - calling a user-defined function runs its instructions exactly once")) ;? (quit) (reset) (add-fns '((test1 ((3 integer) <- add (1 integer) (2 integer)) (reply) ((4 integer) <- literal 34)) (main ((1 integer) <- literal 1) ((2 integer) <- literal 3) (test1)))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 3 3 4)) (prn "F - 'reply' stops executing the current function")) ;? (quit) (reset) (add-fns `((test1 ((3 integer) <- test2)) (test2 (reply (2 integer))) (main ((2 integer) <- literal 34) (test1)))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 2 34 3 34)) (prn "F - 'reply' stops executing any callers as necessary")) ;? (quit) (reset) (add-fns '((test1 ((3 integer) <- add (1 integer) (2 integer)) (reply) ((4 integer) <- literal 34)) (main ((1 integer) <- literal 1) ((2 integer) <- literal 3) (test1)))) (if (~iso 4 (run 'main)) ; last reply sometimes not counted. worth fixing? (prn "F - 'reply' executes instructions exactly once")) ;? (quit) (reset) (add-fns '((test1 ((4 integer) <- arg) ((5 integer) <- arg) ((3 integer) <- add (4 integer) (5 integer)) (reply) ((4 integer) <- literal 34)) (main ((1 integer) <- literal 1) ((2 integer) <- literal 3) (test1 (1 integer) (2 integer)) ))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 3 3 4 ; add-fn's temporaries 4 1 5 3)) (prn "F - 'arg' accesses in order the operands of the most recent function call (the caller)")) ;? (quit) (reset) (add-fns '((test1 ((5 integer) <- arg 1) ((4 integer) <- arg 0) ((3 integer) <- add (4 integer) (5 integer)) (reply) ((4 integer) <- literal 34)) (main ((1 integer) <- literal 1) ((2 integer) <- literal 3) (test1 (1 integer) (2 integer)) ))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 3 3 4 ; add-fn's temporaries 4 1 5 3)) (prn "F - 'arg' with index can access function call arguments out of order")) ;? (quit) ; todo: test that too few args throws an error ; how should errors be handled? will be unclear until we support concurrency and routine trees. (reset) (add-fns '((test1 ((4 integer) <- arg) ((5 integer) <- arg) ((6 integer) <- add (4 integer) (5 integer)) (reply (6 integer)) ((4 integer) <- literal 34)) (main ((1 integer) <- literal 1) ((2 integer) <- literal 3) ((3 integer) <- test1 (1 integer) (2 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 3 3 4 ; add-fn's temporaries 4 1 5 3 6 4)) (prn "F - 'reply' can take aguments that are returned, or written back into output args of caller")) (reset) (add-fns '((test1 ((4 integer) <- arg) ((5 integer) <- arg) ((6 integer) <- add (4 integer) (5 integer)) (reply (6 integer) (5 integer)) ((4 integer) <- literal 34)) (main ((1 integer) <- literal 1) ((2 integer) <- literal 3) ((3 integer) (7 integer) <- test1 (1 integer) (2 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 3 3 4 7 3 ; add-fn's temporaries 4 1 5 3 6 4)) (prn "F - 'reply' permits a function to return multiple values at once")) (reset) (add-fns '((test1 ((1 integer) <- add (2 literal) (3 literal))))) (run 'test1) (if (~iso memory* (obj 1 5)) (prn "F - ops can take 'literal' operands (but not return them)")) (reset) (add-fns '((main ((1 integer) <- literal 1) ((2 integer) <- literal 3) ((3 integer) <- sub (1 integer) (2 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 3 3 -2)) (prn "F - 'sub' subtracts the value at one address from the value at another")) (reset) (add-fns '((main ((1 integer) <- literal 2) ((2 integer) <- literal 3) ((3 integer) <- mul (1 integer) (2 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 2 2 3 3 6)) (prn "F - 'mul' multiplies like 'add' adds")) (reset) (add-fns '((main ((1 integer) <- literal 8) ((2 integer) <- literal 3) ((3 integer) <- div (1 integer) (2 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 8 2 3 3 (/ real.8 3))) (prn "F - 'div' divides like 'add' adds")) (reset) (add-fns '((main ((1 integer) <- literal 8) ((2 integer) <- literal 3) ((3 integer) (4 integer) <- idiv (1 integer) (2 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 8 2 3 3 2 4 2)) (prn "F - 'idiv' performs integer division, returning quotient and remainder")) (reset) (add-fns '((main ((1 boolean) <- literal t) ((2 boolean) <- literal nil) ((3 boolean) <- and (1 boolean) (2 boolean))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 t 2 nil 3 nil)) (prn "F - logical 'and' for booleans")) (reset) (add-fns '((main ((1 boolean) <- literal 4) ((2 boolean) <- literal 3) ((3 boolean) <- lt (1 boolean) (2 boolean))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 4 2 3 3 nil)) (prn "F - 'lt' is the less-than inequality operator")) (reset) (add-fns '((main ((1 boolean) <- literal 4) ((2 boolean) <- literal 3) ((3 boolean) <- le (1 boolean) (2 boolean))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 4 2 3 3 nil)) (prn "F - 'le' is the <= inequality operator")) (reset) (add-fns '((main ((1 boolean) <- literal 4) ((2 boolean) <- literal 4) ((3 boolean) <- le (1 boolean) (2 boolean))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 4 2 4 3 t)) (prn "F - 'le' returns true for equal operands")) (reset) (add-fns '((main ((1 boolean) <- literal 4) ((2 boolean) <- literal 5) ((3 boolean) <- le (1 boolean) (2 boolean))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 4 2 5 3 t)) (prn "F - le is the <= inequality operator - 2")) (reset) (add-fns '((main ((1 integer) <- literal 8) (jmp (1 offset)) ((2 integer) <- literal 3) (reply)))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 8)) (prn "F - 'jmp' skips some instructions")) (reset) (add-fns '((main ((1 integer) <- literal 8) (jmp (1 offset)) ((2 integer) <- literal 3) (reply) ((3 integer) <- literal 34)))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 8)) (prn "F - 'jmp' doesn't skip too many instructions")) ;? (quit) (reset) (add-fns '((main ((1 integer) <- literal 1) ((2 integer) <- literal 1) ((3 boolean) <- eq (1 integer) (2 integer)) (jif (3 boolean) (1 offset)) ((2 integer) <- literal 3) (reply) ((3 integer) <- literal 34)))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 1 3 t)) (prn "F - 'jif' is a conditional 'jmp'")) (reset) (add-fns '((main ((1 integer) <- literal 1) ((2 integer) <- literal 2) ((3 boolean) <- eq (1 integer) (2 integer)) (jif (3 boolean) (1 offset)) ((4 integer) <- literal 3) (reply) ((3 integer) <- literal 34)))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 2 3 nil 4 3)) (prn "F - if 'jif's first arg is false, it doesn't skip any instructions")) (reset) (add-fns '((main ((1 integer) <- literal 2) ((2 integer) <- literal 1) ((2 integer) <- add (2 integer) (2 integer)) ((3 boolean) <- eq (1 integer) (2 integer)) (jif (3 boolean) (-3 offset)) ((4 integer) <- literal 3) (reply) ((3 integer) <- literal 34)))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 2 2 4 3 nil 4 3)) (prn "F - 'jif' can take a negative offset to make backward jumps")) (reset) (add-fns '((main ((1 integer) <- literal 34) ((2 integer) <- copy (1 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 34 2 34)) (prn "F - 'copy' performs direct addressing")) (reset) (add-fns '((main ((1 integer-address) <- literal 2) ((2 integer) <- literal 34) ((3 integer) <- copy (1 integer-address deref))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 2 2 34 3 34)) (prn "F - 'copy' performs indirect addressing")) (reset) (add-fns '((main ((1 integer-address) <- literal 2) ((2 integer) <- literal 34) ((3 integer) <- literal 2) ((1 integer-address deref) <- add (2 integer) (3 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 2 2 36 3 2)) (prn "F - instructions can perform indirect addressing on output arg")) (reset) (add-fns '((main ((1 integer) <- literal 34) ((2 boolean) <- literal nil) ((3 boolean) <- get (1 integer-boolean-pair) (1 offset)) ((4 integer) <- get (1 integer-boolean-pair) (0 offset))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 34 2 nil 3 nil 4 34)) (prn "F - 'get' accesses fields of records")) (reset) (add-fns '((main ((1 integer) <- literal 34) ((2 boolean) <- literal nil) ((3 integer-boolean-pair-address) <- literal 1) ((4 boolean) <- get (3 integer-boolean-pair-address deref) (1 offset)) ((5 integer) <- get (3 integer-boolean-pair-address deref) (0 offset))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 34 2 nil 3 1 4 nil 5 34)) (prn "F - 'get' accesses fields of record address")) (reset) (add-fns '((main ((1 integer) <- literal 34) ((2 integer) <- literal 35) ((3 integer) <- literal 36) ((4 integer-integer-pair) <- get (1 integer-point-pair) (1 offset))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 34 2 35 3 36 4 35 5 36)) (prn "F - 'get' accesses fields spanning multiple locations")) (reset) (add-fns '((main ((1 integer) <- literal 34) ((2 integer) <- literal t) ((3 integer-boolean-pair-address) <- get-address (1 integer-point-pair) (1 offset))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 34 2 t 3 2)) (prn "F - 'get-address' returns address of fields of records")) (reset) (add-fns '((main ((1 integer) <- literal 2) ((2 integer) <- literal 23) ((3 boolean) <- literal nil) ((4 integer) <- literal 24) ((5 boolean) <- literal t) ((6 integer-boolean-pair) <- get (1 integer-boolean-pair-array) (1 offset))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 2 2 23 3 nil 4 24 5 t 6 24 7 t)) (prn "F - 'get' accesses indices of arrays")) (reset) (add-fns '((main ((1 integer) <- literal 2) ((2 integer) <- literal 23) ((3 boolean) <- literal nil) ((4 integer) <- literal 24) ((5 boolean) <- literal t) ((6 integer-boolean-pair-address) <- get-address (1 integer-boolean-pair-array) (1 offset))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 2 2 23 3 nil 4 24 5 t 6 4)) (prn "F - 'get-address' returns addresses of indices of arrays")) (reset) (add-fns '((main ((1 integer) <- literal 2) ((2 integer) <- literal 23) ((3 boolean) <- literal nil) ((4 integer) <- literal 24) ((5 boolean) <- literal t) ((6 integer) <- len (1 integer-boolean-pair-array))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 2 2 23 3 nil 4 24 5 t 6 2)) (prn "F - 'len' accesses length of array")) (reset) (add-fns '((main ((1 integer) <- sizeof (integer-boolean-pair type))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 2)) (prn "F - 'sizeof' returns space required by arg")) (reset) (add-fns '((main ((1 integer) <- sizeof (integer-point-pair type))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 3)) (prn "F - 'sizeof' is different from number of elems")) ; todo: test that out-of-bounds access throws an error (reset) (add-fns '((main ((1 integer) <- literal 34) ((2 boolean) <- literal nil) ((4 boolean) <- literal t) ((3 integer-boolean-pair) <- copy (1 integer-boolean-pair))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 34 2 nil 3 34 4 nil)) (prn "F - ops can operate on records spanning multiple locations")) (reset) (add-fns '((test1 ((4 type) <- otype 0) ((5 type) <- literal integer) ((6 boolean) <- neq (4 type) (5 type)) (jif (6 boolean) (3 offset)) ((7 integer) <- arg) ((8 integer) <- arg) ((9 integer) <- add (7 integer) (8 integer)) (reply (9 integer))) (main ((1 integer) <- literal 1) ((2 integer) <- literal 3) ((3 integer) <- test1 (1 integer) (2 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 1 2 3 3 4 ; add-fn's temporaries 4 'integer 5 'integer 6 nil 7 1 8 3 9 4)) (prn "F - an example function that checks that its args are integers")) ;? (quit) ; todo - test that reply increments pc for caller frame after popping current frame (reset) (add-fns '((add-fn ((4 type) <- otype 0) ((5 type) <- literal integer) ((6 boolean) <- neq (4 type) (5 type)) (jif (6 boolean) (4 offset)) ((7 integer) <- arg) ((8 integer) <- arg) ((9 integer) <- add (7 integer) (8 integer)) (reply (9 integer)) ((5 type) <- literal boolean) ((6 boolean) <- neq (4 type) (5 type)) (jif (6 boolean) (4 offset)) ((7 boolean) <- arg) ((8 boolean) <- arg) ((9 boolean) <- or (7 boolean) (8 boolean)) (reply (9 boolean))) (main ((1 boolean) <- literal t) ((2 boolean) <- literal t) ((3 boolean) <- add-fn (1 boolean) (2 boolean))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj ; first call to add-fn 1 t 2 t 3 t ; add-fn's temporaries 4 'boolean 5 'boolean 6 nil 7 t 8 t 9 t)) (prn "F - an example function that can do different things (dispatch) based on the type of its args or oargs")) ;? (quit) (reset) (add-fns '((add-fn ((4 type) <- otype 0) ((5 type) <- literal integer) ((6 boolean) <- neq (4 type) (5 type)) (jif (6 boolean) (4 offset)) ((7 integer) <- arg) ((8 integer) <- arg) ((9 integer) <- add (7 integer) (8 integer)) (reply (9 integer)) ((5 type) <- literal boolean) ((6 boolean) <- neq (4 type) (5 type)) (jif (6 boolean) (6 offset)) ((7 boolean) <- arg) ((8 boolean) <- arg) ((9 boolean) <- or (7 boolean) (8 boolean)) (reply (9 boolean))) (main ((1 boolean) <- literal t) ((2 boolean) <- literal t) ((3 boolean) <- add-fn (1 boolean) (2 boolean)) ((10 integer) <- literal 3) ((11 integer) <- literal 4) ((12 integer) <- add-fn (10 integer) (11 integer))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj ; first call to add-fn 1 t 2 t 3 t ; second call to add-fn 10 3 11 4 12 7 ; temporaries for most recent call to add-fn 4 'integer 5 'integer 6 nil 7 3 8 4 9 7)) (prn "F - different calls can exercise different clauses of the same function")) (if (~iso (convert-braces '(((1 integer) <- literal 4) ((2 integer) <- literal 2) ((3 integer) <- add (2 integer) (2 integer)) { begin ; 'begin' is just a hack because racket turns curlies into parens ((4 boolean) <- neq (1 integer) (3 integer)) (breakif (4 boolean)) ((5 integer) <- literal 34) } (reply))) '(((1 integer) <- literal 4) ((2 integer) <- literal 2) ((3 integer) <- add (2 integer) (2 integer)) ((4 boolean) <- neq (1 integer) (3 integer)) (jif (4 boolean) (1 offset)) ((5 integer) <- literal 34) (reply))) (prn "F - convert-braces replaces breakif with a jif to after the next close curly")) (if (~iso (convert-braces '(((1 integer) <- literal 4) ((2 integer) <- literal 2) ((3 integer) <- add (2 integer) (2 integer)) { begin (break) } (reply))) '(((1 integer) <- literal 4) ((2 integer) <- literal 2) ((3 integer) <- add (2 integer) (2 integer)) (jmp (0 offset)) (reply))) (prn "F - convert-braces works for degenerate blocks")) (if (~iso (convert-braces '(((1 integer) <- literal 4) ((2 integer) <- literal 2) ((3 integer) <- add (2 integer) (2 integer)) { begin ((4 boolean) <- neq (1 integer) (3 integer)) (breakif (4 boolean)) { begin ((5 integer) <- literal 34) } } (reply))) '(((1 integer) <- literal 4) ((2 integer) <- literal 2) ((3 integer) <- add (2 integer) (2 integer)) ((4 boolean) <- neq (1 integer) (3 integer)) (jif (4 boolean) (1 offset)) ((5 integer) <- literal 34) (reply))) (prn "F - convert-braces balances curlies when converting break")) (if (~iso (convert-braces '(((1 integer) <- literal 4) ((2 integer) <- literal 2) { begin ((3 integer) <- add (2 integer) (2 integer)) { begin ((4 boolean) <- neq (1 integer) (3 integer)) } (continueif (4 boolean)) ((5 integer) <- literal 34) } (reply))) '(((1 integer) <- literal 4) ((2 integer) <- literal 2) ((3 integer) <- add (2 integer) (2 integer)) ((4 boolean) <- neq (1 integer) (3 integer)) (jif (4 boolean) (-3 offset)) ((5 integer) <- literal 34) (reply))) (prn "F - convert-braces balances curlies when converting continue")) (reset) (add-fns `((main ,@(convert-braces '(((1 integer) <- literal 4) ((2 integer) <- literal 1) { begin ((2 integer) <- add (2 integer) (2 integer)) { begin ((3 boolean) <- neq (1 integer) (2 integer)) } (continueif (3 boolean)) ((4 integer) <- literal 34) } (reply)))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 4 2 4 3 nil 4 34)) (prn "F - continue correctly loops")) (reset) (add-fns `((main ,@(convert-braces '(((1 integer) <- literal 4) ((2 integer) <- literal 2) { begin ((2 integer) <- add (2 integer) (2 integer)) { begin ((3 boolean) <- neq (1 integer) (2 integer)) } (continueif (3 boolean)) ((4 integer) <- literal 34) } (reply)))))) (run 'main) ;? (prn memory*) (if (~iso memory* (obj 1 4 2 4 3 nil 4 34)) (prn "F - continue might never trigger")) (reset) (let before Memory-in-use-until (add-fns '((main ((1 integer-address) <- new (integer type))))) (run 'main) ;? (prn memory*) (if (~iso memory*.1 before) (prn "F - 'new' returns current high-water mark")) (if (~iso Memory-in-use-until (+ before 1)) (prn "F - 'new' on primitive types increments high-water mark by their size"))) (reset) (let before Memory-in-use-until (add-fns '((main ((1 type-array-address) <- new (type-array type) (5 literal))))) (run 'main) ;? (prn memory*) (if (~iso memory*.1 before) (prn "F - 'new' returns current high-water mark")) (if (~iso Memory-in-use-until (+ before 5)) (prn "F - 'new' on primitive arrays increments high-water mark by their size"))) (reset) (add-fns '((f1 ((1 integer) <- literal 3)) (f2 ((2 integer) <- literal 4)))) (let ninsts (run 'f1 'f2) (when (~iso 2 ninsts) (prn "F - scheduler didn't run the right number of instructions: " ninsts))) (if (~iso memory* (obj 1 3 2 4)) (prn "F - scheduler runs multiple functions: " memory*)) (check-trace-contents "scheduler orders functions correctly" '(("schedule" "f1") ("schedule" "f2") )) (check-trace-contents "scheduler orders schedule and run events correctly" '(("schedule" "f1") ("run" "f1 0") ("schedule" "f2") ("run" "f2 0") ))