X-Git-Url: https://git.rrq.au/?a=blobdiff_plain;f=main.asm;h=5985b997af8095926394802fd7e6c59b636a5510;hb=bcba0c88f4eaddac8e0d8c0fa68264b2e81ee272;hp=edcba0ae9421c712218041e64d4fc0872370f8d9;hpb=2d2c007e5b5e2f9b79271d638863d77338969f38;p=rrq%2Fjonasforth.git diff --git a/main.asm b/main.asm index edcba0a..5985b99 100644 --- a/main.asm +++ b/main.asm @@ -1,4 +1,75 @@ -format ELF64 executable +;; vim: syntax=fasm + +;; At compile-time we load the module given by the environment variable +;; OS_INCLUDE. This module should define the following macros: +;; +;; Each of these functions should preserve the value of RSI and RSP. They may +;; use other registers as they like. +;; +;; os_initialize +;; Called at initialization. +;; +;; os_print_string +;; Takes a string buffer in RCX and the length in RDX, and prints the string +;; to the console. +;; +;; os_read_char +;; Wait for the user to type a key, and then put the corresponding ASCII byte +;; into the buffer pointed to by RCX. +;; +;; os_terminate +;; Shut down the system. +include '%OS_INCLUDE%' + +;; Print a string of a given length. +;; +;; Input: +;; - RCX = Pointer to buffer +;; - RDX = Buffer length +;; +;; Clobbers: RAX, RCX, R11, RDI, RSI +macro sys_print_string { + push r8 + push r9 + push r10 + + call os_print_string + + pop r10 + pop r9 + pop r8 +} + +;; Read a character from the user into the given buffer. +;; +;; Input: +;; - RSI = Character buffer +;; +;; Output: +;; - BYTE [RSI] = Character +;; +;; Clobbers: RAX, RCX, R11, RDI, RSI, RDX +macro sys_read_char { + push rbx + push r8 + push r9 + push r10 + push r15 + + mov rcx, rsi + call os_read_char + + pop r15 + pop r10 + pop r9 + pop r8 + pop rbx +} + +macro sys_terminate code { + mov rax, code + call os_terminate +} ;; The code in this macro is placed at the end of each Forth word. When we are ;; executing a definition, this code is what causes execution to resume at the @@ -32,11 +103,16 @@ macro popr x { ;; ;; This macro also defines a label LABEL_entry. initial_latest_entry = 0 -macro header label, name { +macro header label, name, immediate { local .string_end label#_entry: dq initial_latest_entry + if immediate eq + db 0 + else + db 1 + end if db .string_end - ($ + 1) db name .string_end: @@ -46,31 +122,23 @@ initial_latest_entry = label#_entry } ;; Define a Forth word that is implemented in assembly. See 'header' for details. -macro forth_asm label, name { - header label, name +macro forth_asm label, name, immediate { + header label, name, immediate dq .start .start: } -;; Define a Forth word that is implemented in Forth. (The body will be a list of -;; 'dq' statements.) -macro forth label, name { - header label, name - dq docol -} - - +section '.text' code readable executable -segment readable executable - -entry main - -include "impl.asm" +include "impl.asm" ; Misc. subroutines +include "bootstrap.asm" ; Forth words encoded in Assembly main: cld ; Clear direction flag so LODSQ does the right thing. mov rbp, return_stack_top ; Initialize return stack + call os_initialize + mov rax, MAIN jmp qword [rax] @@ -79,13 +147,13 @@ program: dq MAIN ;; The codeword is the code that will be executed at the beginning of a forth ;; word. It needs to save the old RSI and update it to point to the next word to ;; execute. -docol: +header DOCOL, 'DOCOL' pushr rsi ; Save old value of RSI on return stack; we will continue execution there after we are done executing this word lea rsi, [rax + 8] ; RAX currently points to the address of the codeword, so we want to continue at RAX+8 next ; Execute word pointed to by RSI ;; This word is called at the end of a Forth definition. It just needs to -;; restore the old value of RSI (saved by 'docol') and resume execution. +;; restore the old value of RSI (saved by 'DOCOL') and resume execution. forth_asm EXIT, 'EXIT' popr rsi next @@ -97,6 +165,17 @@ forth_asm LIT, 'LIT' push rax next +;; When LITSTRING is encountered while executing a word, it instead reads a +;; string from the definition of that word, and places that string on the stack +;; as (buffer, length). +forth_asm LITSTRING, 'LITSTRING' + lodsb + push rsi ; Buffer + movzx rax, al + push rax ; Length + add rsi, rax ; Skip over string before resuming execution + next + ;; Given a string (a pointer following by a size), return the location of the ;; dictionary entry for that word. If no such word exists, return 0. forth_asm FIND, 'FIND' @@ -119,7 +198,7 @@ forth_asm FIND, 'FIND' ;; entry. forth_asm TCFA, '>CFA' pop rax - add rax, 8 ; [rax] = length of name + add rax, 8 + 1 ; [rax] = length of name movzx rbx, byte [rax] inc rax add rax, rbx ; [rax] = codeword @@ -158,45 +237,94 @@ forth_asm EXEC, 'EXEC' forth_asm EMIT, 'EMIT' pushr rsi pushr rax - mov rax, 1 - mov rdi, 1 - lea rsi, [rsp] + + lea rcx, [rsp] mov rdx, 1 - syscall + sys_print_string + add rsp, 8 popr rax popr rsi next -;; Prints a newline to standard output. -forth NEWLINE, 'NEWLINE' - dq LIT, $A - dq EMIT - dq EXIT +;; Read a single character from the current input stream. Usually, this will wait +;; for the user to press a key, and then return the corresponding character. When +;; reading from a special buffer, it will instead return the next characater from +;; that buffer. +;; +;; The ASCII character code is placed on the stack. +forth_asm KEY, 'KEY' + call .impl + push rax + next -;; Prints a space to standard output. -forth SPACE, 'SPACE' - dq LIT, ' ' - dq EMIT - dq EXIT +;; Result in RAX +.impl: + ;; Are we reading from user input or from the input buffer? + cmp [input_buffer], 0 + jne .from_buffer + + ;; Reading user input + push rsi + mov rsi, .buffer + sys_read_char + pop rsi + + movzx rax, byte [.buffer] + ret -;; Read a word from standard input and push it onto the stack as a pointer and a -;; size. The pointer is valid until the next call to READ_WORD. +.from_buffer: + ;; Reading from buffer + mov rax, [input_buffer] + movzx rax, byte [rax] + + inc [input_buffer] + dec [input_buffer_length] + ret + +;; Read a word and push it onto the stack as a pointer and a size. The pointer +;; is valid until the next call to READ_WORD. forth_asm READ_WORD, 'READ-WORD' - mov [.rsi], rsi + push rsi +.skip_whitespace: + ;; Read characters until one of them is not whitespace. + call KEY.impl + ;; We consider newlines and spaces to be whitespace. + cmp al, ' ' + je .skip_whitespace + cmp al, $A + je .skip_whitespace + + ;; We got a character that wasn't whitespace. Now read the actual word. + mov [.length], 0 - call read_word - push rdi ; Buffer - push rdx ; Length +.read_alpha: + movzx rbx, [.length] + mov rsi, .buffer + add rsi, rbx + mov [rsi], al + inc [.length] + + call KEY.impl + + cmp al, ' ' + je .end + cmp al, $A + jne .read_alpha + +.end: + pop rsi + push .buffer + movzx rax, [.length] + push rax - mov rsi, [.rsi] next ;; Takes a string on the stack and replaces it with the decimal number that the ;; string represents. forth_asm PARSE_NUMBER, 'PARSE-NUMBER' - pop [parse_number.length] ; Length - pop [parse_number.buffer] ; String pointer + pop rcx ; Length + pop rdi ; String pointer push rsi call parse_number @@ -205,51 +333,57 @@ forth_asm PARSE_NUMBER, 'PARSE-NUMBER' push rax ; Result next -forth READ_NUMBER, 'READ-NUMBER' - dq READ_WORD - dq PARSE_NUMBER - dq EXIT - ;; Takes a string (in the form of a pointer and a length on the stack) and ;; prints it to standard output. forth_asm TELL, 'TELL' - mov rbx, rsi - mov rcx, rax + pushr rax + pushr rsi - mov rax, 1 - mov rdi, 1 - pop rdx ; Length - pop rsi ; Buffer - syscall + pop rdx ; Length + pop rcx ; Buffer + sys_print_string - mov rax, rcx - mov rsi, rbx + popr rsi + popr rax next ;; Exit the program cleanly. forth_asm TERMINATE, 'TERMINATE' - mov rax, $3C - mov rdi, 0 - syscall - -forth HELLO, 'HELLO' - dq LIT, 'H', EMIT - dq LIT, 'e', EMIT - dq LIT, 'l', EMIT - dq LIT, 'l', EMIT - dq LIT, 'o', EMIT - dq LIT, '!', EMIT - dq NEWLINE - dq EXIT + sys_terminate 0 -;; The INTERPRET word reads and interprets user input. It's behavior depends on -;; the current STATE. It provides special handling for integers. (TODO) -forth INTERPRET, 'INTERPRET' - dq READ_WORD - dq FIND - dq TCFA - dq EXEC - dq EXIT +;; Duplicate a pair of elements. +forth_asm PAIRDUP, '2DUP' + pop rbx + pop rax + push rax + push rbx + push rax + push rbx + next + +;; Swap the top two elements on the stack. +forth_asm SWAP, 'SWAP' + pop rax + pop rbx + push rax + push rbx + next + +;; Remove the top element from the stack. +forth_asm DROP, 'DROP' + add rsp, 8 + next + +forth_asm NOT_, 'NOT' + pop rax + cmp rax, 0 + jz .false +.true: + push 0 + next +.false: + push 1 + next ;; .U prints the value on the stack as an unsigned integer in hexadecimal. forth_asm DOTU, '.U' @@ -302,11 +436,9 @@ forth_asm DOTU, '.U' loop .flip ;; Print the buffer - mov rax, 1 - mov rdi, 1 - mov rsi, .buffer + mov rcx, .buffer mov rdx, [.printed_length] - syscall + sys_print_string ;; Restore RSI and continue execution pop rsi @@ -326,37 +458,262 @@ forth_asm GET, '@' push rax next -;; Get the location of the STATE variable. It can be set with '!' and read with -;; '@'. -forth STATE, 'STATE' - dq LIT, var_STATE - dq EXIT +forth_asm PUT_BYTE, 'C!' + pop rbx + pop rax ; Value + mov [rbx], al + next + +forth_asm GET_BYTE, 'C@' + pop rax + movzx rax, byte [rax] + push rax + next + +;; Add two integers on the stack. +forth_asm PLUS, '+' + pop rax + pop rbx + add rax, rbx + push rax + next + +;; Calculate difference between two integers on the stack. The second number is +;; subtracted from the first. +forth_asm MINUS, '-' + pop rax + pop rbx + sub rbx, rax + push rbx + next + +;; Given two integers a and b on the stack, pushes the quotient and remainder of +;; division of a by b. +forth_asm TIMESMOD, '/MOD' + pop rbx ; b + pop rax ; a + mov rdx, 0 + div rbx + push rax ; a / b + push rdx ; a % b + next + +;; Read input until next " character is found. Push a string containing the +;; input on the stack as (buffer length). Note that the buffer is only valid +;; until the next call to S" and that no more than 255 characters can be read. +forth_asm READ_STRING, 'S"' + ;; If the input buffer is set, we should read from there instead. + cmp [input_buffer], 0 + jne read_string_buffer + + push rsi + + mov [.length], 0 + +.read_char: + mov rsi, .char_buffer + sys_read_char + + mov al, [.char_buffer] + cmp al, '"' + je .done + + mov rdx, .buffer + add rdx, [.length] + mov [rdx], al + inc [.length] + jmp .read_char + +.done: + pop rsi + + push .buffer + push [.length] + + next + +read_string_buffer: + push rsi + + ;; We borrow READ_STRING's buffer. They won't mind. + mov [READ_STRING.length], 0 + +.read_char: + mov rbx, [input_buffer] + mov al, [rbx] + cmp al, '"' + je .done + + mov rdx, READ_STRING.buffer + add rdx, [READ_STRING.length] + mov [rdx], al + inc [READ_STRING.length] + + inc [input_buffer] + dec [input_buffer_length] + + jmp .read_char + +.done: + pop rsi + + ;; Skip closing " + inc [input_buffer] + dec [input_buffer_length] + + push READ_STRING.buffer + push [READ_STRING.length] + + next + +;; CREATE inserts a new header in the dictionary, and updates LATEST so that it +;; points to the header. To compile a word, the user can then call ',' to +;; continue to append data after the header. +;; +;; It takes the name of the word as a string (address length) on the stack. +forth_asm CREATE, 'CREATE' + pop rcx ; Word string length + pop rdx ; Word string pointer + + mov rdi, [here] ; rdi = Address at which to insert this entry + mov rax, [latest_entry] ; rax = Address of the previous entry + mov [rdi], rax ; Insert link to previous entry + mov [latest_entry], rdi ; Update LATEST to point to this word + + add rdi, 8 + mov [rdi], byte 0 ; Insert immediate flag + + add rdi, 1 + mov [rdi], byte cl ; Insert length + + ;; Insert word string + add rdi, 1 + + push rsi + mov rsi, rdx ; rsi = Word string pointer + rep movsb + pop rsi + + ;; Update HERE + mov [here], rdi + + next + +forth_asm TICK, "'" + lodsq + push rax + next + +forth_asm ROT, 'ROT' + pop rax + pop rbx + pop rdx + push rax + push rdx + push rbx + next + +forth_asm PICK, 'PICK' + pop rax + lea rax, [rsp + 8 * rax] + mov rax, [rax] + push rax + next + +forth_asm EQL, '=' + pop rax + pop rbx + cmp rax, rbx + je .eq +.noteq: + push 0 + next +.eq: + push 1 + next forth MAIN, 'MAIN' - dq HELLO + dq SYSCODE + dq INTERPRET_STRING dq INTERPRET dq BRANCH, -8 * 2 dq TERMINATE -segment readable writable +;; Built-in variables: +forth STATE, 'STATE' + dq LIT, var_STATE + dq EXIT + +forth LATEST, 'LATEST' + dq LIT, latest_entry + dq EXIT + +forth HERE, 'HERE' + dq LIT, here + dq EXIT + +forth SYSCODE, 'SYSCODE' + dq LIT, sysf + dq LIT, sysf.len + dq EXIT + +forth INPUT_BUFFER, 'INPUT-BUFFER' + dq LIT, input_buffer + dq EXIT + +forth INPUT_LENGTH, 'INPUT-LENGTH' + dq LIT, input_buffer_length + dq EXIT + +section '.data' readable writable + +;; The LATEST variable holds a pointer to the word that was last added to the +;; dictionary. This pointer is updated as new words are added, and its value is +;; used by FIND to look up words. latest_entry dq initial_latest_entry ;; The STATE variable is 0 when the interpreter is executing, and non-zero when ;; it is compiling. var_STATE dq 0 +;; The interpreter can read either from standard input or from a buffer. When +;; input-buffer is set (non-null), words like READ-WORD and S" will use this +;; buffer instead of reading user input. +input_buffer dq 0 +input_buffer_length dq 0 + FIND.rsi dq ? READ_WORD.rsi dq ? READ_WORD.rbp dq ? +READ_STRING.char_buffer db ? +READ_STRING.buffer rb $FF +READ_STRING.length dq ? + DOTU.chars db '0123456789ABCDEF' DOTU.buffer rq 16 ; 64-bit number has no more than 16 digits in hex DOTU.rbuffer rq 16 DOTU.length dq ? DOTU.printed_length dq ? +KEY.buffer dq ? + +READ_WORD.buffer rb $FF +READ_WORD.length db ? + +;; Reserve space for compiled words, accessed through HERE. +here dq here_top +here_top rq $4000 + ;; Return stack rq $2000 return_stack_top: + +;; We store some Forth code in sys.f that defined common words that the user +;; would expect to have available at startup. To execute these words, we just +;; include the file directly in the binary, and then interpret it at startup. +sysf file 'sys.f' +sysf.len = $ - sysf +