/* uLisp ARM 3.2 - www.ulisp.com David Johnson-Davies - www.technoblogy.com - 29th April 2020 Licensed under the MIT license: https://opensource.org/licenses/MIT */ // Lisp Library const char LispLibrary[] PROGMEM = ""; // Compile options // #define resetautorun #define printfreespace // #define printgcs // #define sdcardsupport // #define gfxsupport // #define lisplibrary #define assemblerlist // #define lineeditor // #define vt100 // Includes // #include "LispLibrary.h" #include #include #include #include #if defined(gfxsupport) #include // Core graphics library #include // Hardware-specific library for ST7735 #define COLOR_WHITE 0xffff #define COLOR_BLACK 0 // Adafruit PyBadge/PyGamer #define TFT_CS 44 // Chip select #define TFT_RST 46 // Display reset #define TFT_DC 45 // Display data/command select #define TFT_BACKLIGHT 47 // Display backlight pin #define TFT_MOSI 41 // Data out #define TFT_SCLK 42 // Clock out Adafruit_ST7735 tft = Adafruit_ST7735(TFT_CS, TFT_DC, TFT_MOSI, TFT_SCLK, TFT_RST); #endif #if defined(sdcardsupport) #include #define SDSIZE 172 #else #define SDSIZE 0 #endif // C Macros #define nil NULL #define car(x) (((object *) (x))->car) #define cdr(x) (((object *) (x))->cdr) #define first(x) (((object *) (x))->car) #define second(x) (car(cdr(x))) #define cddr(x) (cdr(cdr(x))) #define third(x) (car(cdr(cdr(x)))) #define push(x, y) ((y) = cons((x),(y))) #define pop(y) ((y) = cdr(y)) #define integerp(x) ((x) != NULL && (x)->type == NUMBER) #define floatp(x) ((x) != NULL && (x)->type == FLOAT) #define symbolp(x) ((x) != NULL && (x)->type == SYMBOL) #define stringp(x) ((x) != NULL && (x)->type == STRING) #define characterp(x) ((x) != NULL && (x)->type == CHARACTER) #define arrayp(x) ((x) != NULL && (x)->type == ARRAY) #define streamp(x) ((x) != NULL && (x)->type == STREAM) #define mark(x) (car(x) = (object *)(((uintptr_t)(car(x))) | MARKBIT)) #define unmark(x) (car(x) = (object *)(((uintptr_t)(car(x))) & ~MARKBIT)) #define marked(x) ((((uintptr_t)(car(x))) & MARKBIT) != 0) #define MARKBIT 1 #define setflag(x) (Flags = Flags | 1<<(x)) #define clrflag(x) (Flags = Flags & ~(1<<(x))) #define tstflag(x) (Flags & 1<<(x)) // Code marker stores start and end of code block #define startblock(x) ((x->integer) & 0xFFFF) #define endblock(x) ((x->integer) >> 16 & 0xFFFF) // Constants const int TRACEMAX = 3; // Number of traced functions enum type { ZZERO=0, SYMBOL=2, CODE=4, NUMBER=6, STREAM=8, CHARACTER=10, FLOAT=12, ARRAY=14, STRING=16, PAIR=18 }; // ARRAY STRING and PAIR must be last enum token { UNUSED, BRA, KET, QUO, DOT }; enum stream { SERIALSTREAM, I2CSTREAM, SPISTREAM, SDSTREAM, STRINGSTREAM, GFXSTREAM }; enum function { NIL, TEE, NOTHING, OPTIONAL, INITIALELEMENT, AMPREST, LAMBDA, LET, LETSTAR, CLOSURE, SPECIAL_FORMS, QUOTE, DEFUN, DEFVAR, SETQ, LOOP, RETURN, PUSH, POP, INCF, DECF, SETF, DOLIST, DOTIMES, TRACE, UNTRACE, FORMILLIS, WITHOUTPUTTOSTRING, WITHSERIAL, WITHI2C, WITHSPI, WITHSDCARD, WITHGFX, DEFCODE, TAIL_FORMS, PROGN, IF, COND, WHEN, UNLESS, CASE, AND, OR, FUNCTIONS, NOT, NULLFN, CONS, ATOM, LISTP, CONSP, SYMBOLP, ARRAYP, BOUNDP, SETFN, STREAMP, EQ, CAR, FIRST, CDR, REST, CAAR, CADR, SECOND, CDAR, CDDR, CAAAR, CAADR, CADAR, CADDR, THIRD, CDAAR, CDADR, CDDAR, CDDDR, LENGTH, ARRAYDIMENSIONS, LIST, MAKEARRAY, REVERSE, NTH, AREF, ASSOC, MEMBER, APPLY, FUNCALL, APPEND, MAPC, MAPCAR, MAPCAN, ADD, SUBTRACT, MULTIPLY, DIVIDE, MOD, ONEPLUS, ONEMINUS, ABS, RANDOM, MAXFN, MINFN, NOTEQ, NUMEQ, LESS, LESSEQ, GREATER, GREATEREQ, PLUSP, MINUSP, ZEROP, ODDP, EVENP, INTEGERP, NUMBERP, FLOATFN, FLOATP, SIN, COS, TAN, ASIN, ACOS, ATAN, SINH, COSH, TANH, EXP, SQRT, LOG, EXPT, CEILING, FLOOR, TRUNCATE, ROUND, CHAR, CHARCODE, CODECHAR, CHARACTERP, STRINGP, STRINGEQ, STRINGLESS, STRINGGREATER, SORT, STRINGFN, CONCATENATE, SUBSEQ, READFROMSTRING, PRINCTOSTRING, PRIN1TOSTRING, LOGAND, LOGIOR, LOGXOR, LOGNOT, ASH, LOGBITP, EVAL, GLOBALS, LOCALS, MAKUNBOUND, BREAK, READ, PRIN1, PRINT, PRINC, TERPRI, READBYTE, READLINE, WRITEBYTE, WRITESTRING, WRITELINE, RESTARTI2C, GC, ROOM, SAVEIMAGE, LOADIMAGE, CLS, PINMODE, DIGITALREAD, DIGITALWRITE, ANALOGREAD, ANALOGWRITE, DELAY, MILLIS, SLEEP, NOTE, EDIT, PPRINT, PPRINTALL, FORMAT, REQUIRE, LISTLIBRARY, DRAWPIXEL, DRAWLINE, DRAWRECT, FILLRECT, DRAWCIRCLE, FILLCIRCLE, DRAWROUNDRECT, FILLROUNDRECT, DRAWTRIANGLE, FILLTRIANGLE, DRAWCHAR, SETCURSOR, SETTEXTCOLOR, SETTEXTSIZE, SETTEXTWRAP, FILLSCREEN, SETROTATION, INVERTDISPLAY, ENDFUNCTIONS }; // Typedefs typedef unsigned int symbol_t; typedef struct sobject { union { struct { sobject *car; sobject *cdr; }; struct { unsigned int type; union { symbol_t name; int integer; int chars; // For strings float single_float; }; }; }; } object; typedef object *(*fn_ptr_type)(object *, object *); typedef int (*intfn_ptr_type)(int w, int x, int y, int z); typedef struct { const char *string; fn_ptr_type fptr; uint8_t minmax; } tbl_entry_t; typedef int (*gfun_t)(); typedef void (*pfun_t)(char); typedef int PinMode; // Workspace #define PERSIST __attribute__((section(".text"))) #define WORDALIGNED __attribute__((aligned (4))) #define BUFFERSIZE 34 // Number of bits+2 #define RAMFUNC __attribute__ ((section (".ramfunctions"))) #if defined(ARDUINO_ITSYBITSY_M0) || defined(ARDUINO_SAMD_FEATHER_M0_EXPRESS) #define WORKSPACESIZE 2816-SDSIZE /* Objects (8*bytes) */ #define DATAFLASHSIZE 2048000 /* 2 MBytes */ #define SYMBOLTABLESIZE 512 /* Bytes */ #define CODESIZE 128 /* Bytes */ #define SDCARD_SS_PIN 4 #define STACKDIFF 320 #elif defined(ARDUINO_GEMMA_M0) #define WORKSPACESIZE 2816-SDSIZE /* Objects (8*bytes) */ #define SYMBOLTABLESIZE 512 /* Bytes */ #define CODESIZE 128 /* Bytes */ #define STACKDIFF 320 #elif defined(ARDUINO_METRO_M4) || defined(ARDUINO_ITSYBITSY_M4) || defined(ARDUINO_FEATHER_M4) || defined(ARDUINO_PYBADGE_M4) || defined(ARDUINO_PYGAMER_M4) #define WORKSPACESIZE 20480-SDSIZE /* Objects (8*bytes) */ #define DATAFLASHSIZE 2048000 /* 2 MBytes */ #define SYMBOLTABLESIZE 1024 /* Bytes */ #define CODESIZE 256 /* Bytes */ #define STACKDIFF 400 #elif defined(ARDUINO_GRAND_CENTRAL_M4) #define WORKSPACESIZE 28672-SDSIZE /* Objects (8*bytes) */ #define DATAFLASHSIZE 8192000 /* 8 MBytes */ #define SYMBOLTABLESIZE 1024 /* Bytes */ #define CODESIZE 256 /* Bytes */ #define STACKDIFF 400 #elif defined(ARDUINO_SAMD_MKRZERO) #define WORKSPACESIZE 2816-SDSIZE /* Objects (8*bytes) */ #define SYMBOLTABLESIZE 512 /* Bytes */ #define CODESIZE 128 /* Bytes */ #define STACKDIFF 840 #elif defined(ARDUINO_SAMD_ZERO) /* Put this last, otherwise overrides the Adafruit boards */ #define WORKSPACESIZE 2816-SDSIZE /* Objects (8*bytes) */ #define SYMBOLTABLESIZE 512 /* Bytes */ #define CODESIZE 128 /* Bytes */ #define SDCARD_SS_PIN 10 #define STACKDIFF 320 #elif defined(_VARIANT_BBC_MICROBIT_) #define WORKSPACESIZE 1280 /* Objects (8*bytes) */ #define SYMBOLTABLESIZE 512 /* Bytes */ #define CODESIZE 64 /* Bytes */ #define STACKDIFF 320 #elif defined(ARDUINO_NRF52840_ITSYBITSY) #define WORKSPACESIZE 20992-SDSIZE /* Objects (8*bytes) */ #define DATAFLASHSIZE 2048000 /* 2 MBytes */ #define SYMBOLTABLESIZE 1024 /* Bytes */ #define CODESIZE 256 /* Bytes */ #define STACKDIFF 1200 #elif defined(ARDUINO_NRF52840_CLUE) #define WORKSPACESIZE 19456-SDSIZE /* Objects (8*bytes) */ #define DATAFLASHSIZE 2048000 /* 2 MBytes */ #define SYMBOLTABLESIZE 1024 /* Bytes */ #define CODESIZE 256 /* Bytes */ #define STACKDIFF 0 #elif defined(MAX32620) #define WORKSPACESIZE 24576-SDSIZE /* Objects (8*bytes) */ #define SYMBOLTABLESIZE 1024 /* Bytes */ #define CODESIZE 256 /* Bytes */ #define STACKDIFF 320 #elif defined(ARDUINO_FEATHER_F405) #define WORKSPACESIZE 11840-SDSIZE /* Objects (8*bytes) */ #define SYMBOLTABLESIZE 1024 /* Bytes */ #define CODESIZE 256 /* Bytes */ #define STACKDIFF 320 #endif object Workspace[WORKSPACESIZE] WORDALIGNED; char SymbolTable[SYMBOLTABLESIZE]; RAMFUNC uint8_t MyCode[CODESIZE] WORDALIGNED; // Global variables jmp_buf exception; unsigned int Freespace = 0; object *Freelist; char *SymbolTop = SymbolTable; unsigned int I2CCount; unsigned int TraceFn[TRACEMAX]; unsigned int TraceDepth[TRACEMAX]; object *GlobalEnv; object *GCStack = NULL; object *GlobalString; int GlobalStringIndex = 0; uint8_t PrintCount = 0; uint8_t BreakLevel = 0; char LastChar = 0; char LastPrint = 0; // Flags enum flag { PRINTREADABLY, RETURNFLAG, ESCAPE, EXITEDITOR, LIBRARYLOADED, NOESC }; volatile char Flags = 0b00001; // PRINTREADABLY set by default // Forward references object *tee; object *tf_progn (object *form, object *env); object *eval (object *form, object *env); object *read (gfun_t gfun); void repl (object *env); void printobject (object *form, pfun_t pfun); char *lookupbuiltin (symbol_t name); intptr_t lookupfn (symbol_t name); int builtin (char* n); // Error handling void errorsub (symbol_t fname, PGM_P string) { pfl(pserial); pfstring(PSTR("Error: "), pserial); if (fname) { pserial('\''); pstring(symbolname(fname), pserial); pfstring(PSTR("' "), pserial); } pfstring(string, pserial); } void error (symbol_t fname, PGM_P string, object *symbol) { errorsub(fname, string); pfstring(PSTR(": "), pserial); printobject(symbol, pserial); pln(pserial); GCStack = NULL; longjmp(exception, 1); } void error2 (symbol_t fname, PGM_P string) { errorsub(fname, string); pln(pserial); GCStack = NULL; longjmp(exception, 1); } // Save space as these are used multiple times const char notanumber[] PROGMEM = "argument is not a number"; const char notastring[] PROGMEM = "argument is not a string"; const char notalist[] PROGMEM = "argument is not a list"; const char notasymbol[] PROGMEM = "argument is not a symbol"; const char notproper[] PROGMEM = "argument is not a proper list"; const char toomanyargs[] PROGMEM = "too many arguments"; const char toofewargs[] PROGMEM = "too few arguments"; const char noargument[] PROGMEM = "missing argument"; const char nostream[] PROGMEM = "missing stream argument"; const char overflow[] PROGMEM = "arithmetic overflow"; const char invalidarg[] PROGMEM = "invalid argument"; const char invalidpin[] PROGMEM = "invalid pin"; const char resultproper[] PROGMEM = "result is not a proper list"; const char oddargs[] PROGMEM = "odd number of arguments"; // Set up workspace void initworkspace () { Freelist = NULL; for (int i=WORKSPACESIZE-1; i>=0; i--) { object *obj = &Workspace[i]; car(obj) = NULL; cdr(obj) = Freelist; Freelist = obj; Freespace++; } } object *myalloc () { if (Freespace == 0) error2(0, PSTR("no room")); object *temp = Freelist; Freelist = cdr(Freelist); Freespace--; return temp; } inline void myfree (object *obj) { car(obj) = NULL; cdr(obj) = Freelist; Freelist = obj; Freespace++; } // Make each type of object object *number (int n) { object *ptr = myalloc(); ptr->type = NUMBER; ptr->integer = n; return ptr; } object *makefloat (float f) { object *ptr = myalloc(); ptr->type = FLOAT; ptr->single_float = f; return ptr; } object *character (char c) { object *ptr = myalloc(); ptr->type = CHARACTER; ptr->integer = c; return ptr; } object *cons (object *arg1, object *arg2) { object *ptr = myalloc(); ptr->car = arg1; ptr->cdr = arg2; return ptr; } object *symbol (symbol_t name) { object *ptr = myalloc(); ptr->type = SYMBOL; ptr->name = name; return ptr; } object *codehead (int entry) { object *ptr = myalloc(); ptr->type = CODE; ptr->integer = entry; return ptr; } object *newsymbol (symbol_t name) { for (int i=WORKSPACESIZE-1; i>=0; i--) { object *obj = &Workspace[i]; if (obj->type == SYMBOL && obj->name == name) return obj; } return symbol(name); } object *stream (unsigned char streamtype, unsigned char address) { object *ptr = myalloc(); ptr->type = STREAM; ptr->integer = streamtype<<8 | address; return ptr; } // Garbage collection void markobject (object *obj) { MARK: if (obj == NULL) return; if (marked(obj)) return; object* arg = car(obj); unsigned int type = obj->type; mark(obj); if (type >= PAIR || type == ZZERO) { // cons markobject(arg); obj = cdr(obj); goto MARK; } if (type == ARRAY) { obj = cdr(obj); goto MARK; } if (type == STRING) { obj = cdr(obj); while (obj != NULL) { arg = car(obj); mark(obj); obj = arg; } } } void sweep () { Freelist = NULL; Freespace = 0; for (int i=WORKSPACESIZE-1; i>=0; i--) { object *obj = &Workspace[i]; if (!marked(obj)) myfree(obj); else unmark(obj); } } void gc (object *form, object *env) { #if defined(printgcs) int start = Freespace; #endif markobject(tee); markobject(GlobalEnv); markobject(GCStack); markobject(form); markobject(env); sweep(); #if defined(printgcs) pfl(pserial); pserial('{'); pint(Freespace - start, pserial); pserial('}'); #endif } // Compact image void movepointer (object *from, object *to) { for (int i=0; itype) & ~MARKBIT; if (marked(obj) && (type >= ARRAY || type==ZZERO)) { if (car(obj) == (object *)((uintptr_t)from | MARKBIT)) car(obj) = (object *)((uintptr_t)to | MARKBIT); if (cdr(obj) == from) cdr(obj) = to; } } // Fix strings for (int i=0; itype) & ~MARKBIT) == STRING) { obj = cdr(obj); while (obj != NULL) { if (cdr(obj) == to) cdr(obj) = from; obj = (object *)((uintptr_t)(car(obj)) & ~MARKBIT); } } } } uintptr_t compactimage (object **arg) { markobject(tee); markobject(GlobalEnv); markobject(GCStack); object *firstfree = Workspace; while (marked(firstfree)) firstfree++; object *obj = &Workspace[WORKSPACESIZE-1]; while (firstfree < obj) { if (marked(obj)) { car(firstfree) = car(obj); cdr(firstfree) = cdr(obj); unmark(obj); movepointer(obj, firstfree); if (GlobalEnv == obj) GlobalEnv = firstfree; if (GCStack == obj) GCStack = firstfree; if (*arg == obj) *arg = firstfree; while (marked(firstfree)) firstfree++; } obj--; } sweep(); return firstfree - Workspace; } // Make SD card filename char *MakeFilename (object *arg) { char *buffer = SymbolTop; int max = maxbuffer(buffer); int i = 0; do { char c = nthchar(arg, i); if (c == '\0') break; buffer[i++] = c; } while (i>8 & 0xFF); file.write(data>>16 & 0xFF); file.write(data>>24 & 0xFF); } #elif defined(DATAFLASHSIZE) // Winbond DataFlash support for Adafruit M4 Express boards #define PAGEPROG 0x02 #define READSTATUS 0x05 #define READDATA 0x03 #define WRITEENABLE 0x06 #define BLOCK64K 0xD8 #define READID 0x90 // Arduino pins used for dataflash #if defined(ARDUINO_ITSYBITSY_M0) const int sck = 38, ssel = 39, mosi = 37, miso = 36; #elif defined(EXTERNAL_FLASH_USE_QSPI) const int sck = PIN_QSPI_SCK, ssel = PIN_QSPI_CS, mosi = PIN_QSPI_IO0, miso = PIN_QSPI_IO1; #endif boolean FlashSetup () { uint8_t manID, devID; digitalWrite(ssel, HIGH); pinMode(ssel, OUTPUT); pinMode(sck, OUTPUT); pinMode(mosi, OUTPUT); pinMode(miso, INPUT); digitalWrite(sck, LOW); digitalWrite(mosi, HIGH); digitalWrite(ssel, LOW); FlashWrite(READID); for(uint8_t i=0; i<4; i++) manID = FlashRead(); devID = FlashRead(); digitalWrite(ssel, HIGH); return (devID == 0x14 || devID == 0x15 || devID == 0x16); // Found correct device } inline void FlashWrite (uint8_t data) { shiftOut(mosi, sck, MSBFIRST, data); } void FlashBusy () { digitalWrite(ssel, 0); FlashWrite(READSTATUS); while (FlashRead() & 1 != 0); digitalWrite(ssel, 1); } void FlashWriteEnable () { digitalWrite(ssel, 0); FlashWrite(WRITEENABLE); digitalWrite(ssel, 1); } void FlashBeginRead () { FlashBusy(); digitalWrite(ssel, 0); FlashWrite(READDATA); FlashWrite(0); FlashWrite(0); FlashWrite(0); } inline uint8_t FlashRead () { int data; return shiftIn(miso, sck, MSBFIRST); } inline void FlashEndRead(void) { digitalWrite(ssel, 1); } void FlashBeginWrite (int blocks) { // Erase 64K for (int b=0; b>16); FlashWrite((*addr)>>8); FlashWrite(0); } FlashWrite(data); (*addr)++; } inline void FlashEndWrite (void) { digitalWrite(ssel, 1); FlashBusy(); } void FlashWriteInt (uint32_t *addr, int data) { FlashWriteByte(addr, data & 0xFF); FlashWriteByte(addr, data>>8 & 0xFF); FlashWriteByte(addr, data>>16 & 0xFF); FlashWriteByte(addr, data>>24 & 0xFF); } #endif int saveimage (object *arg) { unsigned int imagesize = compactimage(&arg); #if defined(sdcardsupport) SD.begin(SDCARD_SS_PIN); File file; if (stringp(arg)) { file = SD.open(MakeFilename(arg), O_RDWR | O_CREAT | O_TRUNC); arg = NULL; } else if (arg == NULL || listp(arg)) file = SD.open("ULISP.IMG", O_RDWR | O_CREAT | O_TRUNC); else error(SAVEIMAGE, PSTR("illegal argument"), arg); if (!file) error2(SAVEIMAGE, PSTR("problem saving to SD card")); SDWriteInt(file, (uintptr_t)arg); SDWriteInt(file, imagesize); SDWriteInt(file, (uintptr_t)GlobalEnv); SDWriteInt(file, (uintptr_t)GCStack); #if SYMBOLTABLESIZE > BUFFERSIZE SDWriteInt(file, (uintptr_t)SymbolTop); for (int i=0; i DATAFLASHSIZE) error(SAVEIMAGE, PSTR("image size too large"), number(imagesize)); uint32_t addr = 0; FlashBeginWrite((bytesneeded+65535)/65536); FlashWriteInt(&addr, (uintptr_t)arg); FlashWriteInt(&addr, imagesize); FlashWriteInt(&addr, (uintptr_t)GlobalEnv); FlashWriteInt(&addr, (uintptr_t)GCStack); #if SYMBOLTABLESIZE > BUFFERSIZE FlashWriteInt(&addr, (uintptr_t)SymbolTop); for (int i=0; i BUFFERSIZE SymbolTop = (char *)SDReadInt(file); for (int i=0; i BUFFERSIZE SymbolTop = (char *)FlashReadInt(); for (int i=0; itype; return type >= PAIR || type == ZZERO; } bool atom (object *x) { if (x == NULL) return true; unsigned int type = x->type; return type < PAIR && type != ZZERO; } bool listp (object *x) { if (x == NULL) return true; unsigned int type = x->type; return type >= PAIR || type == ZZERO; } bool improperp (object *x) { if (x == NULL) return false; unsigned int type = x->type; return type < PAIR && type != ZZERO; } object *quote (object *arg) { return cons(symbol(QUOTE), cons(arg,NULL)); } // Radix 40 encoding #define MAXSYMBOL 4096000000 int toradix40 (char ch) { if (ch == 0) return 0; if (ch >= '0' && ch <= '9') return ch-'0'+30; if (ch == '$') return 27; if (ch == '*') return 28; if (ch == '-') return 29; ch = ch | 0x20; if (ch >= 'a' && ch <= 'z') return ch-'a'+1; return -1; // Invalid } int fromradix40 (int n) { if (n >= 1 && n <= 26) return 'a'+n-1; if (n == 27) return '$'; if (n == 28) return '*'; if (n == 29) return '-'; if (n >= 30 && n <= 39) return '0'+n-30; return 0; } int pack40 (char *buffer) { int x = 0; for (int i=0; i<6; i++) x = x * 40 + toradix40(buffer[i]); return x; } bool valid40 (char *buffer) { for (int i=0; i<6; i++) if (toradix40(buffer[i]) == -1) return false; return true; } char *symbolname (symbol_t x) { if (x < ENDFUNCTIONS) return lookupbuiltin(x); else if (x >= MAXSYMBOL) return lookupsymbol(x); char *buffer = SymbolTop; buffer[3] = '\0'; buffer[4] = '\0'; buffer[5] = '\0'; buffer[6] = '\0'; for (int n=5; n>=0; n--) { buffer[n] = fromradix40(x % 40); x = x / 40; } return buffer; } int digitvalue (char d) { if (d>='0' && d<='9') return d-'0'; d = d | 0x20; if (d>='a' && d<='f') return d-'a'+10; return 16; } int checkinteger (symbol_t name, object *obj) { if (!integerp(obj)) error(name, notanumber, obj); return obj->integer; } float checkintfloat (symbol_t name, object *obj){ if (integerp(obj)) return obj->integer; if (floatp(obj)) return obj->single_float; error(name, notanumber, obj); } int checkchar (symbol_t name, object *obj) { if (!characterp(obj)) error(name, PSTR("argument is not a character"), obj); return obj->integer; } int isstream (object *obj){ if (!streamp(obj)) error(0, PSTR("not a stream"), obj); return obj->integer; } int issymbol (object *obj, symbol_t n) { return symbolp(obj) && obj->name == n; } void checkargs (symbol_t name, object *args) { int nargs = listlength(name, args); if (name >= ENDFUNCTIONS) error(0, PSTR("not valid here"), symbol(name)); checkminmax(name, nargs); } int eq (object *arg1, object *arg2) { if (arg1 == arg2) return true; // Same object if ((arg1 == nil) || (arg2 == nil)) return false; // Not both values if (arg1->cdr != arg2->cdr) return false; // Different values if (symbolp(arg1) && symbolp(arg2)) return true; // Same symbol if (integerp(arg1) && integerp(arg2)) return true; // Same integer if (floatp(arg1) && floatp(arg2)) return true; // Same float if (characterp(arg1) && characterp(arg2)) return true; // Same character return false; } int listlength (symbol_t name, object *list) { int length = 0; while (list != NULL) { if (improperp(list)) error2(name, notproper); list = cdr(list); length++; } return length; } // Association lists object *assoc (object *key, object *list) { while (list != NULL) { if (improperp(list)) error(ASSOC, notproper, list); object *pair = first(list); if (!listp(pair)) error(ASSOC, PSTR("element is not a list"), pair); if (pair != NULL && eq(key,car(pair))) return pair; list = cdr(list); } return nil; } object *delassoc (object *key, object **alist) { object *list = *alist; object *prev = NULL; while (list != NULL) { object *pair = first(list); if (eq(key,car(pair))) { if (prev == NULL) *alist = cdr(list); else cdr(prev) = cdr(list); return key; } prev = list; list = cdr(list); } return nil; } // Array utilities int nextpower2 (int n) { n--; n |= n >> 1; n |= n >> 2; n |= n >> 4; n |= n >> 8; n |= n >> 16; n++; return n<2 ? 2 : n; } object *buildarray (int n, int s, object *def) { int s2 = s>>1; if (s2 == 1) { if (n == 2) return cons(def, def); else if (n == 1) return cons(def, NULL); else return NULL; } else if (n >= s2) return cons(buildarray(s2, s2, def), buildarray(n - s2, s2, def)); else return cons(buildarray(n, s2, def), nil); } object *makearray (symbol_t name, object *dims, object *def) { int size = 1; object *dimensions = dims; while (dims != NULL) { int d = car(dims)->integer; if (d < 0) error2(MAKEARRAY, PSTR("dimension can't be negative")); size = size * d; dims = cdr(dims); } object *ptr = myalloc(); ptr->type = ARRAY; object *tree = nil; if (size != 0) tree = buildarray(size, nextpower2(size), def); ptr->cdr = cons(tree, dimensions); return ptr; } object **arrayref (object *array, int index, int size) { int mask = nextpower2(size)>>1; object **p = &car(cdr(array)); while (mask) { if ((index & mask) == 0) p = &(car(*p)); else p = &(cdr(*p)); mask = mask>>1; } return p; } object **getarray (symbol_t name, object *array, object *subs, object *env) { int index = 0, size = 1, s; object *dims = cddr(array); while (dims != NULL && subs != NULL) { int d = car(dims)->integer; if (env) s = checkinteger(name, eval(car(subs), env)); else s = checkinteger(name, car(subs)); if (s < 0 || s >= d) error(name, PSTR("subscript out of range"), car(subs)); size = size * d; index = index * d + s; dims = cdr(dims); subs = cdr(subs); } if (dims != NULL) error2(name, PSTR("too few subscripts")); if (subs != NULL) error2(name, PSTR("too many subscripts")); return arrayref(array, index, size); } void rslice (object *array, int size, int slice, object *dims, object *args) { int d = first(dims)->integer; for (int i = 0; i < d; i++) { int index = slice * d + i; if (cdr(dims) == NULL) { if (args == NULL) error2(0, PSTR("initial contents don't match array type")); object **p = arrayref(array, index, size); *p = car(args); } else rslice(array, size, index, cdr(dims), car(args)); args = cdr(args); } } object *readarray (int d, object *args) { object *list = args; object *dims = NULL; object *head = NULL; int size = 1; for (int i = 0; i < d; i++) { int l = listlength(0, list); if (dims == NULL) { dims = cons(number(l), NULL); head = dims; } else { cdr(dims) = cons(number(l), NULL); dims = cdr(dims); } size = size * l; if (list != NULL) list = car(list); } object *array = makearray(0, head, NULL); rslice(array, size, 0, head, args); return array; } void pslice (object *array, int size, int slice, object *dims, pfun_t pfun) { pfun('('); int d = first(dims)->integer; for (int i = 0; i < d; i++) { if (i) pfun(' '); int index = slice * d + i; if (cdr(dims) == NULL) { printobject(*arrayref(array, index, size), pfun); } else pslice(array, size, index, cdr(dims), pfun); } pfun(')'); } void printarray (object *array, pfun_t pfun) { object *dimensions = cddr(array); object *dims = dimensions; int size = 1, n = 0; while (dims != NULL) { size = size * car(dims)->integer; dims = cdr(dims); n++; } pfun('#'); if (n > 1) { pint(n, pfun); pfun('A'); } pslice(array, size, 0, dimensions, pfun); } // String utilities void indent (uint8_t spaces, char ch, pfun_t pfun) { for (uint8_t i=0; itype = STRING; GlobalString = NULL; GlobalStringIndex = 0; return string; } void buildstring (char ch, int *chars, object **head) { static object* tail; static uint8_t shift; if (*chars == 0) { shift = (sizeof(int)-1)*8; *chars = ch<car = cell; cell->car = NULL; cell->chars = *chars; tail = cell; } else { shift = shift - 8; *chars = *chars | ch<chars = *chars; if (shift == 0) *chars = 0; } } object *readstring (char delim, gfun_t gfun) { object *obj = myalloc(); obj->type = STRING; int ch = gfun(); if (ch == -1) return nil; object *head = NULL; int chars = 0; while ((ch != delim) && (ch != -1)) { if (ch == '\\') ch = gfun(); buildstring(ch, &chars, &head); ch = gfun(); } obj->cdr = head; return obj; } int stringlength (object *form) { int length = 0; form = cdr(form); while (form != NULL) { int chars = form->chars; for (int i=(sizeof(int)-1)*8; i>=0; i=i-8) { if (chars>>i & 0xFF) length++; } form = car(form); } return length; } char nthchar (object *string, int n) { object *arg = cdr(string); int top; if (sizeof(int) == 4) { top = n>>2; n = 3 - (n&3); } else { top = n>>1; n = 1 - (n&1); } for (int i=0; ichars)>>(n*8) & 0xFF; } int gstr () { if (LastChar) { char temp = LastChar; LastChar = 0; return temp; } char c = nthchar(GlobalString, GlobalStringIndex++); if (c != 0) return c; return '\n'; // -1? } void pstr (char c) { buildstring(c, &GlobalStringIndex, &GlobalString); } // Lookup variable in environment object *value (symbol_t n, object *env) { while (env != NULL) { object *pair = car(env); if (pair != NULL && car(pair)->name == n) return pair; env = cdr(env); } return nil; } bool boundp (object *var, object *env) { symbol_t varname = var->name; if (value(varname, env) != NULL) return true; if (value(varname, GlobalEnv) != NULL) return true; return false; } object *findvalue (object *var, object *env) { symbol_t varname = var->name; object *pair = value(varname, env); if (pair == NULL) pair = value(varname, GlobalEnv); if (pair == NULL) error(0, PSTR("unknown variable"), var); return pair; } // Handling closures object *closure (int tc, symbol_t name, object *state, object *function, object *args, object **env) { int trace = 0; if (name) trace = tracing(name); if (trace) { indent(TraceDepth[trace-1]<<1, ' ', pserial); pint(TraceDepth[trace-1]++, pserial); pserial(':'); pserial(' '); pserial('('); pstring(symbolname(name), pserial); } object *params = first(function); function = cdr(function); // Dropframe if (tc) { if (*env != NULL && car(*env) == NULL) { pop(*env); while (*env != NULL && car(*env) != NULL) pop(*env); } else push(nil, *env); } // Push state while (state != NULL) { object *pair = first(state); push(pair, *env); state = cdr(state); } // Add arguments to environment bool optional = false; while (params != NULL) { object *value; object *var = first(params); if (symbolp(var) && var->name == OPTIONAL) optional = true; else { if (consp(var)) { if (!optional) error(name, PSTR("invalid default value"), var); if (args == NULL) value = eval(second(var), *env); else { value = first(args); args = cdr(args); } var = first(var); if (!symbolp(var)) error(name, PSTR("illegal optional parameter"), var); } else if (!symbolp(var)) { error2(name, PSTR("illegal parameter")); } else if (var->name == AMPREST) { params = cdr(params); var = first(params); value = args; args = NULL; } else { if (args == NULL) { if (optional) value = nil; else { if (name) error2(name, toofewargs); else error2(0, PSTR("function has too few arguments")); } } else { value = first(args); args = cdr(args); } } push(cons(var,value), *env); if (trace) { pserial(' '); printobject(value, pserial); } } params = cdr(params); } if (args != NULL) { if (name) error2(name, toomanyargs); else error2(0, PSTR("function has too many arguments")); } if (trace) { pserial(')'); pln(pserial); } // Do an implicit progn if (tc) push(nil, *env); return tf_progn(function, *env); } object *apply (symbol_t name, object *function, object *args, object *env) { if (symbolp(function)) { symbol_t fname = function->name; checkargs(fname, args); return ((fn_ptr_type)lookupfn(fname))(args, env); } if (consp(function) && issymbol(car(function), LAMBDA)) { function = cdr(function); object *result = closure(0, 0, NULL, function, args, &env); return eval(result, env); } if (consp(function) && issymbol(car(function), CLOSURE)) { function = cdr(function); object *result = closure(0, 0, car(function), cdr(function), args, &env); return eval(result, env); } error(name, PSTR("illegal function"), function); return NULL; } // In-place operations object **place (symbol_t name, object *args, object *env) { if (atom(args)) return &cdr(findvalue(args, env)); object* function = first(args); if (issymbol(function, CAR) || issymbol(function, FIRST)) { object *value = eval(second(args), env); if (!listp(value)) error(name, PSTR("can't take car"), value); return &car(value); } if (issymbol(function, CDR) || issymbol(function, REST)) { object *value = eval(second(args), env); if (!listp(value)) error(name, PSTR("can't take cdr"), value); return &cdr(value); } if (issymbol(function, NTH)) { int index = checkinteger(NTH, eval(second(args), env)); object *list = eval(third(args), env); if (atom(list)) error(name, PSTR("second argument to nth is not a list"), list); while (index > 0) { list = cdr(list); if (list == NULL) error2(name, PSTR("index to nth is out of range")); index--; } return &car(list); } if (issymbol(function, AREF)) { object *array = eval(second(args), env); if (!arrayp(array)) error(AREF, PSTR("first argument is not an array"), array); return getarray(AREF, array, cddr(args), env); } error2(name, PSTR("illegal place")); return nil; } // Checked car and cdr inline object *carx (object *arg) { if (!listp(arg)) error(0, PSTR("can't take car"), arg); if (arg == nil) return nil; return car(arg); } inline object *cdrx (object *arg) { if (!listp(arg)) error(0, PSTR("can't take cdr"), arg); if (arg == nil) return nil; return cdr(arg); } // I2C interface void I2Cinit (bool enablePullup) { (void) enablePullup; Wire.begin(); } inline int I2Cread () { return Wire.read(); } inline bool I2Cwrite (uint8_t data) { return Wire.write(data); } bool I2Cstart (uint8_t address, uint8_t read) { int ok = true; if (read == 0) { Wire.beginTransmission(address); ok = (Wire.endTransmission(true) == 0); Wire.beginTransmission(address); } else Wire.requestFrom(address, I2CCount); return ok; } bool I2Crestart (uint8_t address, uint8_t read) { int error = (Wire.endTransmission(false) != 0); if (read == 0) Wire.beginTransmission(address); else Wire.requestFrom(address, I2CCount); return error ? false : true; } void I2Cstop (uint8_t read) { if (read == 0) Wire.endTransmission(); // Check for error? } // Streams inline int spiread () { return SPI.transfer(0); } #if defined(ARDUINO_NRF52840_CLUE) || defined(ARDUINO_GRAND_CENTRAL_M4) || defined(ARDUINO_PYBADGE_M4) || defined(ARDUINO_PYGAMER_M4) inline int spi1read () { return SPI1.transfer(0); } #endif #if defined(ARDUINO_SAM_DUE) inline int serial1read () { while (!Serial1.available()) testescape(); return Serial1.read(); } inline int serial2read () { while (!Serial2.available()) testescape(); return Serial2.read(); } inline int serial3read () { while (!Serial3.available()) testescape(); return Serial3.read(); } #elif !defined(_VARIANT_BBC_MICROBIT_) && !defined(ARDUINO_FEATHER_F405) inline int serial1read () { while (!Serial1.available()) testescape(); return Serial1.read(); } #endif #if defined(sdcardsupport) File SDpfile, SDgfile; inline int SDread () { if (LastChar) { char temp = LastChar; LastChar = 0; return temp; } return SDgfile.read(); } #endif void serialbegin (int address, int baud) { #if defined(_VARIANT_BBC_MICROBIT_) || defined(ARDUINO_FEATHER_F405) error(WITHSERIAL, PSTR("port not supported"), number(address)); #elif defined(ARDUINO_SAM_DUE) if (address == 1) Serial1.begin((long)baud*100); else if (address == 2) Serial2.begin((long)baud*100); else if (address == 3) Serial3.begin((long)baud*100); else error(WITHSERIAL, PSTR("port not supported"), number(address)); #else if (address == 1) Serial1.begin((long)baud*100); else error(WITHSERIAL, PSTR("port not supported"), number(address)); #endif } void serialend (int address) { #if defined(ARDUINO_SAM_DUE) if (address == 1) {Serial1.flush(); Serial1.end(); } else if (address == 2) {Serial2.flush(); Serial2.end(); } else if (address == 3) {Serial3.flush(); Serial3.end(); } #elif !defined(_VARIANT_BBC_MICROBIT_) && !defined(ARDUINO_FEATHER_F405) if (address == 1) {Serial1.flush(); Serial1.end(); } #endif } gfun_t gstreamfun (object *args) { int streamtype = SERIALSTREAM; int address = 0; gfun_t gfun = gserial; if (args != NULL) { int stream = isstream(first(args)); streamtype = stream>>8; address = stream & 0xFF; } if (streamtype == I2CSTREAM) gfun = (gfun_t)I2Cread; else if (streamtype == SPISTREAM) { if (address < 128) gfun = spiread; #if defined(ARDUINO_NRF52840_CLUE) || defined(ARDUINO_GRAND_CENTRAL_M4) || defined(ARDUINO_PYBADGE_M4) || defined(ARDUINO_PYGAMER_M4) else gfun = spi1read; #endif } else if (streamtype == SERIALSTREAM) { if (address == 0) gfun = gserial; #if defined(ARDUINO_SAM_DUE) else if (address == 1) gfun = serial1read; else if (address == 2) gfun = serial2read; else if (address == 3) gfun = serial3read; #elif !defined(_VARIANT_BBC_MICROBIT_) && !defined(ARDUINO_FEATHER_F405) else if (address == 1) gfun = serial1read; #endif } #if defined(sdcardsupport) else if (streamtype == SDSTREAM) gfun = (gfun_t)SDread; #endif else error2(0, PSTR("unknown stream type")); return gfun; } inline void spiwrite (char c) { SPI.transfer(c); } #if defined(ARDUINO_NRF52840_CLUE) || defined(ARDUINO_GRAND_CENTRAL_M4) || defined(ARDUINO_PYBADGE_M4) || defined(ARDUINO_PYGAMER_M4) inline void spi1write (char c) { SPI1.transfer(c); } #endif #if defined(ARDUINO_SAM_DUE) inline void serial1write (char c) { Serial1.write(c); } inline void serial2write (char c) { Serial2.write(c); } inline void serial3write (char c) { Serial3.write(c); } #elif !defined(_VARIANT_BBC_MICROBIT_) inline void serial1write (char c) { Serial1.write(c); } #endif #if defined(sdcardsupport) inline void SDwrite (char c) { SDpfile.write(c); } #endif #if defined(gfxsupport) inline void gfxwrite (char c) { tft.write(c); } #endif pfun_t pstreamfun (object *args) { int streamtype = SERIALSTREAM; int address = 0; pfun_t pfun = pserial; if (args != NULL && first(args) != NULL) { int stream = isstream(first(args)); streamtype = stream>>8; address = stream & 0xFF; } if (streamtype == I2CSTREAM) pfun = (pfun_t)I2Cwrite; else if (streamtype == SPISTREAM) { if (address < 128) pfun = spiwrite; #if defined(ARDUINO_NRF52840_CLUE) || defined(ARDUINO_GRAND_CENTRAL_M4) || defined(ARDUINO_PYBADGE_M4) || defined(ARDUINO_PYGAMER_M4) else pfun = spi1write; #endif } else if (streamtype == SERIALSTREAM) { if (address == 0) pfun = pserial; #if defined(ARDUINO_SAM_DUE) else if (address == 1) pfun = serial1write; else if (address == 2) pfun = serial2write; else if (address == 3) pfun = serial3write; #elif !defined(_VARIANT_BBC_MICROBIT_) && !defined(ARDUINO_FEATHER_F405) else if (address == 1) pfun = serial1write; #endif } else if (streamtype == STRINGSTREAM) { pfun = pstr; } #if defined(sdcardsupport) else if (streamtype == SDSTREAM) pfun = (pfun_t)SDwrite; #endif #if defined(gfxsupport) else if (streamtype == GFXSTREAM) pfun = (pfun_t)gfxwrite; #endif else error2(0, PSTR("unknown stream type")); return pfun; } // Check pins void checkanalogread (int pin) { #if defined(ARDUINO_SAM_DUE) if (!(pin>=54 && pin<=65)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_SAMD_ZERO) if (!(pin>=14 && pin<=19)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_SAMD_MKRZERO) if (!(pin>=15 && pin<=21)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_ITSYBITSY_M0) if (!(pin>=14 && pin<=25)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_GEMMA_M0) if (!(pin>=8 && pin<=10)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_METRO_M4) if (!(pin>=14 && pin<=21)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_ITSYBITSY_M4) if (!(pin>=14 && pin<=19)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_FEATHER_M4) if (!(pin>=14 && pin<=19)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_GRAND_CENTRAL_M4) if (!((pin>=67 && pin<=74) || (pin>=54 && pin<=61))) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(_VARIANT_BBC_MICROBIT_) if (!((pin>=0 && pin<=4) || pin==10)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_NRF52840_ITSYBITSY) if (!(pin>=14 && pin<=20)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(ARDUINO_NRF52840_CLUE) if (!((pin>=0 && pin<=4) || pin==10 || pin==12 || pin==16)) error(ANALOGREAD, invalidpin, number(pin)); #elif defined(MAX32620) if (!(pin>=49 && pin<=52)) error(ANALOGREAD, invalidpin, number(pin)); #endif } void checkanalogwrite (int pin) { #if defined(ARDUINO_SAM_DUE) if (!((pin>=2 && pin<=13) || pin==66 || pin==67)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_SAMD_ZERO) if (!((pin>=3 && pin<=6) || (pin>=8 && pin<=13) || pin==14)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_SAMD_MKRZERO) if (!((pin>=0 && pin<=8) || pin==10 || pin==18 || pin==19)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_ITSYBITSY_M0) if (!((pin>=3 && pin<=6) || (pin>=8 && pin<=13) || (pin>=15 && pin<=16) || (pin>=22 && pin<=25))) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_GEMMA_M0) if (!(pin==0 || pin==2 || pin==9 || pin==10)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_METRO_M4) if (!(pin>=0 && pin<=15)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_ITSYBITSY_M4) if (!(pin==0 || pin==1 || pin==4 || pin==5 || pin==7 || (pin>=9 && pin<=15) || pin==21 || pin==22)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_FEATHER_M4) if (!(pin==0 || pin==1 || (pin>=4 && pin<=6) || (pin>=9 && pin<=13) || pin==14 || pin==15 || pin==17 || pin==21 || pin==22)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_GRAND_CENTRAL_M4) if (!((pin>=2 && pin<=9) || pin==11 || (pin>=13 && pin<=45) || pin==48 || (pin>=50 && pin<=53) || pin==58 || pin==61 || pin==68 || pin==69)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(_VARIANT_BBC_MICROBIT_) if (!(pin>=0 && pin<=2)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_NRF52840_ITSYBITSY) if (!(pin>=0 && pin<=25)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(ARDUINO_NRF52840_CLUE) if (!(pin>=0 && pin<=46)) error(ANALOGWRITE, invalidpin, number(pin)); #elif defined(MAX32620) if (!((pin>=20 && pin<=29) || pin==32 || (pin>=40 && pin<=48))) error(ANALOGWRITE, invalidpin, number(pin)); #endif } // Note const int scale[] PROGMEM = {4186,4435,4699,4978,5274,5588,5920,6272,6645,7040,7459,7902}; void playnote (int pin, int note, int octave) { #if defined(ARDUINO_NRF52840_CLUE) int prescaler = 8 - octave - note/12; if (prescaler<0 || prescaler>8) error(NOTE, PSTR("octave out of range"), number(prescaler)); tone(pin, scale[note%12]>>prescaler); #endif } void nonote (int pin) { #if defined(ARDUINO_NRF52840_CLUE) noTone(pin); #endif } // Sleep #if defined(ARDUINO_SAMD_ZERO) || defined(ARDUINO_SAMD_MKRZERO) void WDT_Handler(void) { // ISR for watchdog early warning WDT->CTRL.bit.ENABLE = 0; // Disable watchdog while(WDT->STATUS.bit.SYNCBUSY); // Sync CTRL write WDT->INTFLAG.bit.EW = 1; // Clear interrupt flag } #endif void initsleep () { #if defined(ARDUINO_SAMD_ZERO) || defined(ARDUINO_SAMD_MKRZERO) // One-time initialization of watchdog timer. // Generic clock generator 2, divisor = 32 (2^(DIV+1)) GCLK->GENDIV.reg = GCLK_GENDIV_ID(2) | GCLK_GENDIV_DIV(4); // Enable clock generator 2 using low-power 32KHz oscillator. // With /32 divisor above, this yields 1024Hz clock. GCLK->GENCTRL.reg = GCLK_GENCTRL_ID(2) | GCLK_GENCTRL_GENEN | GCLK_GENCTRL_SRC_OSCULP32K | GCLK_GENCTRL_DIVSEL; while(GCLK->STATUS.bit.SYNCBUSY); // WDT clock = clock gen 2 GCLK->CLKCTRL.reg = GCLK_CLKCTRL_ID_WDT | GCLK_CLKCTRL_CLKEN | GCLK_CLKCTRL_GEN_GCLK2; // Enable WDT early-warning interrupt NVIC_DisableIRQ(WDT_IRQn); NVIC_ClearPendingIRQ(WDT_IRQn); NVIC_SetPriority(WDT_IRQn, 0); // Top priority NVIC_EnableIRQ(WDT_IRQn); #endif } void sleep (int secs) { #if defined(ARDUINO_SAMD_ZERO) || defined(ARDUINO_SAMD_MKRZERO) WDT->CTRL.reg = 0; // Disable watchdog for config while(WDT->STATUS.bit.SYNCBUSY); WDT->INTENSET.bit.EW = 1; // Enable early warning interrupt WDT->CONFIG.bit.PER = 0xB; // Period = max WDT->CONFIG.bit.WINDOW = 0x7; // Set time of interrupt = 1024 cycles = 1 sec WDT->CTRL.bit.WEN = 1; // Enable window mode while(WDT->STATUS.bit.SYNCBUSY); // Sync CTRL write SysTick->CTRL = 0; // Stop SysTick interrupts while (secs > 0) { WDT->CLEAR.reg = WDT_CLEAR_CLEAR_KEY;// Clear watchdog interval while(WDT->STATUS.bit.SYNCBUSY); WDT->CTRL.bit.ENABLE = 1; // Start watchdog now! while(WDT->STATUS.bit.SYNCBUSY); SCB->SCR |= SCB_SCR_SLEEPDEEP_Msk; // Deepest sleep __DSB(); __WFI(); // Wait for interrupt secs--; } SysTick->CTRL = 7; // Restart SysTick interrupts #else delay(1000*secs); #endif } // Prettyprint const int PPINDENT = 2; const int PPWIDTH = 80; const int GFXPPWIDTH = 52; // 320 pixel wide screen int ppwidth = PPWIDTH; void pcount (char c) { if (c == '\n') PrintCount++; PrintCount++; } uint8_t atomwidth (object *obj) { PrintCount = 0; printobject(obj, pcount); return PrintCount; } uint8_t hexwidth (object *obj) { PrintCount = 0; pinthex(obj->integer, pcount); return PrintCount; } boolean quoted (object *obj) { return (consp(obj) && car(obj) != NULL && car(obj)->name == QUOTE && consp(cdr(obj)) && cddr(obj) == NULL); } int subwidth (object *obj, int w) { if (atom(obj)) return w - atomwidth(obj); if (quoted(obj)) return subwidthlist(car(cdr(obj)), w - 1); return subwidthlist(obj, w - 1); } int subwidthlist (object *form, int w) { while (form != NULL && w >= 0) { if (atom(form)) return w - (2 + atomwidth(form)); w = subwidth(car(form), w - 1); form = cdr(form); } return w; } void superprint (object *form, int lm, pfun_t pfun) { if (atom(form)) { if (symbolp(form) && form->name == NOTHING) pstring(symbolname(form->name), pfun); else printobject(form, pfun); } else if (quoted(form)) { pfun('\''); superprint(car(cdr(form)), lm + 1, pfun); } else if (subwidth(form, ppwidth - lm) >= 0) supersub(form, lm + PPINDENT, 0, pfun); else supersub(form, lm + PPINDENT, 1, pfun); } const int ppspecials = 18; const char ppspecial[ppspecials] PROGMEM = { DOTIMES, DOLIST, IF, SETQ, TEE, LET, LETSTAR, LAMBDA, WHEN, UNLESS, WITHI2C, WITHSERIAL, WITHSPI, WITHSDCARD, WITHGFX, WITHOUTPUTTOSTRING, FORMILLIS }; void supersub (object *form, int lm, int super, pfun_t pfun) { int special = 0, separate = 1; object *arg = car(form); if (symbolp(arg)) { int name = arg->name; if (name == DEFUN || name == DEFCODE) special = 2; else for (int i=0; iinteger; else param[i] = (uintptr_t)arg; args = cdr(args); } int w = ((intfn_ptr_type)&MyCode[entry])(param[0], param[1], param[2], param[3]); return number(w); } void putcode (object *arg, int origin, int pc) { int code = checkinteger(DEFCODE, arg); MyCode[origin+pc] = code & 0xff; MyCode[origin+pc+1] = (code>>8) & 0xff; #if defined(assemblerlist) printhex4(pc, pserial); printhex4(code, pserial); #endif } int assemble (int pass, int origin, object *entries, object *env, object *pcpair) { int pc = 0; cdr(pcpair) = number(pc); while (entries != NULL) { object *arg = first(entries); if (symbolp(arg)) { if (pass == 2) { #if defined(assemblerlist) printhex4(pc, pserial); pfstring(PSTR(" "), pserial); printobject(arg, pserial); pln(pserial); #endif } else { object *pair = findvalue(arg, env); cdr(pair) = number(pc); } } else { object *argval = eval(arg, env); if (listp(argval)) { object *arglist = argval; while (arglist != NULL) { if (pass == 2) { putcode(first(arglist), origin, pc); #if defined(assemblerlist) if (arglist == argval) superprint(arg, 0, pserial); pln(pserial); #endif } pc = pc + 2; cdr(pcpair) = number(pc); arglist = cdr(arglist); } } else if (integerp(argval)) { if (pass == 2) { putcode(argval, origin, pc); #if defined(assemblerlist) superprint(arg, 0, pserial); pln(pserial); #endif } pc = pc + 2; cdr(pcpair) = number(pc); } else error(DEFCODE, PSTR("illegal entry"), arg); } entries = cdr(entries); } // Round up to multiple of 4 to give code size if (pc%4 != 0) pc = pc + 4 - pc%4; return pc; } // Special forms object *sp_quote (object *args, object *env) { (void) env; checkargs(QUOTE, args); return first(args); } object *sp_defun (object *args, object *env) { (void) env; checkargs(DEFUN, args); object *var = first(args); if (!symbolp(var)) error(DEFUN, notasymbol, var); object *val = cons(symbol(LAMBDA), cdr(args)); object *pair = value(var->name,GlobalEnv); if (pair != NULL) cdr(pair) = val; else push(cons(var, val), GlobalEnv); return var; } object *sp_defvar (object *args, object *env) { checkargs(DEFVAR, args); object *var = first(args); if (!symbolp(var)) error(DEFVAR, notasymbol, var); object *val = NULL; args = cdr(args); if (args != NULL) { setflag(NOESC); val = eval(first(args), env); clrflag(NOESC); } object *pair = value(var->name, GlobalEnv); if (pair != NULL) cdr(pair) = val; else push(cons(var, val), GlobalEnv); return var; } object *sp_setq (object *args, object *env) { object *arg = nil; while (args != NULL) { if (cdr(args) == NULL) error2(SETQ, oddargs); object *pair = findvalue(first(args), env); arg = eval(second(args), env); cdr(pair) = arg; args = cddr(args); } return arg; } object *sp_loop (object *args, object *env) { object *start = args; for (;;) { args = start; while (args != NULL) { object *result = eval(car(args),env); if (tstflag(RETURNFLAG)) { clrflag(RETURNFLAG); return result; } args = cdr(args); } } } object *sp_return (object *args, object *env) { object *result = eval(tf_progn(args,env), env); setflag(RETURNFLAG); return result; } object *sp_push (object *args, object *env) { checkargs(PUSH, args); object *item = eval(first(args), env); object **loc = place(PUSH, second(args), env); push(item, *loc); return *loc; } object *sp_pop (object *args, object *env) { checkargs(POP, args); object **loc = place(POP, first(args), env); object *result = car(*loc); pop(*loc); return result; } // Accessors object *sp_incf (object *args, object *env) { checkargs(INCF, args); object **loc = place(INCF, first(args), env); args = cdr(args); object *x = *loc; object *inc = (args != NULL) ? eval(first(args), env) : NULL; if (floatp(x) || floatp(inc)) { float increment; float value = checkintfloat(INCF, x); if (inc == NULL) increment = 1.0; else increment = checkintfloat(INCF, inc); *loc = makefloat(value + increment); } else if (integerp(x) && (integerp(inc) || inc == NULL)) { int increment; int value = x->integer; if (inc == NULL) increment = 1; else increment = inc->integer; if (increment < 1) { if (INT_MIN - increment > value) *loc = makefloat((float)value + (float)increment); else *loc = number(value + increment); } else { if (INT_MAX - increment < value) *loc = makefloat((float)value + (float)increment); else *loc = number(value + increment); } } else error2(INCF, notanumber); return *loc; } object *sp_decf (object *args, object *env) { checkargs(DECF, args); object **loc = place(DECF, first(args), env); args = cdr(args); object *x = *loc; object *dec = (args != NULL) ? eval(first(args), env) : NULL; if (floatp(x) || floatp(dec)) { float decrement; float value = checkintfloat(DECF, x); if (dec == NULL) decrement = 1.0; else decrement = checkintfloat(DECF, dec); *loc = makefloat(value - decrement); } if (integerp(x) && (integerp(dec) || dec == NULL)) { int decrement; int value = x->integer; if (dec == NULL) decrement = 1; else decrement = dec->integer; if (decrement < 1) { if (INT_MAX + decrement < value) *loc = makefloat((float)value - (float)decrement); else *loc = number(value - decrement); } else { if (INT_MIN + decrement > value) *loc = makefloat((float)value - (float)decrement); else *loc = number(value - decrement); } } else error2(DECF, notanumber); return *loc; } object *sp_setf (object *args, object *env) { object *arg = nil; while (args != NULL) { if (cdr(args) == NULL) error2(SETF, oddargs); object **loc = place(SETF, first(args), env); arg = eval(second(args), env); *loc = arg; args = cddr(args); } return arg; } // Other special forms object *sp_dolist (object *args, object *env) { if (args == NULL) error2(DOLIST, noargument); object *params = first(args); object *var = first(params); object *list = eval(second(params), env); push(list, GCStack); // Don't GC the list object *pair = cons(var,nil); push(pair,env); params = cdr(cdr(params)); args = cdr(args); while (list != NULL) { if (improperp(list)) error(DOLIST, notproper, list); cdr(pair) = first(list); object *forms = args; while (forms != NULL) { object *result = eval(car(forms), env); if (tstflag(RETURNFLAG)) { clrflag(RETURNFLAG); pop(GCStack); return result; } forms = cdr(forms); } list = cdr(list); } cdr(pair) = nil; pop(GCStack); if (params == NULL) return nil; return eval(car(params), env); } object *sp_dotimes (object *args, object *env) { if (args == NULL) error2(DOTIMES, noargument); object *params = first(args); object *var = first(params); int count = checkinteger(DOTIMES, eval(second(params), env)); int index = 0; params = cdr(cdr(params)); object *pair = cons(var,number(0)); push(pair,env); args = cdr(args); while (index < count) { cdr(pair) = number(index); object *forms = args; while (forms != NULL) { object *result = eval(car(forms), env); if (tstflag(RETURNFLAG)) { clrflag(RETURNFLAG); return result; } forms = cdr(forms); } index++; } cdr(pair) = number(index); if (params == NULL) return nil; return eval(car(params), env); } object *sp_trace (object *args, object *env) { (void) env; while (args != NULL) { trace(first(args)->name); args = cdr(args); } int i = 0; while (i < TRACEMAX) { if (TraceFn[i] != 0) args = cons(symbol(TraceFn[i]), args); i++; } return args; } object *sp_untrace (object *args, object *env) { (void) env; if (args == NULL) { int i = 0; while (i < TRACEMAX) { if (TraceFn[i] != 0) args = cons(symbol(TraceFn[i]), args); TraceFn[i] = 0; i++; } } else { while (args != NULL) { untrace(first(args)->name); args = cdr(args); } } return args; } object *sp_formillis (object *args, object *env) { object *param = first(args); unsigned long start = millis(); unsigned long now, total = 0; if (param != NULL) total = checkinteger(FORMILLIS, eval(first(param), env)); eval(tf_progn(cdr(args),env), env); do { now = millis() - start; testescape(); } while (now < total); if (now <= INT_MAX) return number(now); return nil; } object *sp_withoutputtostring (object *args, object *env) { object *params = first(args); if (params == NULL) error2(WITHOUTPUTTOSTRING, nostream); object *var = first(params); object *pair = cons(var, stream(STRINGSTREAM, 0)); push(pair,env); object *string = startstring(WITHOUTPUTTOSTRING); object *forms = cdr(args); eval(tf_progn(forms,env), env); string->cdr = GlobalString; GlobalString = NULL; return string; } object *sp_withserial (object *args, object *env) { object *params = first(args); if (params == NULL) error2(WITHSERIAL, nostream); object *var = first(params); int address = checkinteger(WITHSERIAL, eval(second(params), env)); params = cddr(params); int baud = 96; if (params != NULL) baud = checkinteger(WITHSERIAL, eval(first(params), env)); object *pair = cons(var, stream(SERIALSTREAM, address)); push(pair,env); serialbegin(address, baud); object *forms = cdr(args); object *result = eval(tf_progn(forms,env), env); serialend(address); return result; } object *sp_withi2c (object *args, object *env) { object *params = first(args); if (params == NULL) error2(WITHI2C, nostream); object *var = first(params); int address = checkinteger(WITHI2C, eval(second(params), env)); params = cddr(params); int read = 0; // Write I2CCount = 0; if (params != NULL) { object *rw = eval(first(params), env); if (integerp(rw)) I2CCount = rw->integer; read = (rw != NULL); } I2Cinit(1); // Pullups object *pair = cons(var, (I2Cstart(address, read)) ? stream(I2CSTREAM, address) : nil); push(pair,env); object *forms = cdr(args); object *result = eval(tf_progn(forms,env), env); I2Cstop(read); return result; } object *sp_withspi (object *args, object *env) { object *params = first(args); if (params == NULL) error2(WITHSPI, nostream); object *var = first(params); params = cdr(params); if (params == NULL) error2(WITHSPI, nostream); int pin = checkinteger(WITHSPI, eval(car(params), env)); pinMode(pin, OUTPUT); digitalWrite(pin, HIGH); params = cdr(params); int clock = 4000, mode = SPI_MODE0, address = 0; // Defaults BitOrder bitorder = MSBFIRST; if (params != NULL) { clock = checkinteger(WITHSPI, eval(car(params), env)); params = cdr(params); if (params != NULL) { bitorder = (checkinteger(WITHSPI, eval(car(params), env)) == 0) ? LSBFIRST : MSBFIRST; params = cdr(params); if (params != NULL) { int modeval = checkinteger(WITHSPI, eval(car(params), env)); mode = (modeval == 3) ? SPI_MODE3 : (modeval == 2) ? SPI_MODE2 : (modeval == 1) ? SPI_MODE1 : SPI_MODE0; params = cdr(params); if (params != NULL) { address = checkinteger(WITHSPI, eval(car(params), env)); } } } } object *pair = cons(var, stream(SPISTREAM, pin + 128*address)); push(pair,env); SPIClass *spiClass = &SPI; #if defined(ARDUINO_NRF52840_CLUE) || defined(ARDUINO_GRAND_CENTRAL_M4) || defined(ARDUINO_PYBADGE_M4) || defined(ARDUINO_PYGAMER_M4) if (address == 1) spiClass = &SPI1; #endif (*spiClass).begin(); (*spiClass).beginTransaction(SPISettings(((unsigned long)clock * 1000), bitorder, mode)); digitalWrite(pin, LOW); object *forms = cdr(args); object *result = eval(tf_progn(forms,env), env); digitalWrite(pin, HIGH); (*spiClass).endTransaction(); return result; } object *sp_withsdcard (object *args, object *env) { #if defined(sdcardsupport) object *params = first(args); if (params == NULL) error2(WITHSDCARD, nostream); object *var = first(params); object *filename = eval(second(params), env); params = cddr(params); SD.begin(SDCARD_SS_PIN); int mode = 0; if (params != NULL && first(params) != NULL) mode = checkinteger(WITHSDCARD, first(params)); int oflag = O_READ; if (mode == 1) oflag = O_RDWR | O_CREAT | O_APPEND; else if (mode == 2) oflag = O_RDWR | O_CREAT | O_TRUNC; if (mode >= 1) { SDpfile = SD.open(MakeFilename(filename), oflag); if (!SDpfile) error2(WITHSDCARD, PSTR("problem writing to SD card")); } else { SDgfile = SD.open(MakeFilename(filename), oflag); if (!SDgfile) error2(WITHSDCARD, PSTR("problem reading from SD card")); } object *pair = cons(var, stream(SDSTREAM, 1)); push(pair,env); object *forms = cdr(args); object *result = eval(tf_progn(forms,env), env); if (mode >= 1) SDpfile.close(); else SDgfile.close(); return result; #else (void) args, (void) env; error2(WITHSDCARD, PSTR("not supported")); return nil; #endif } object *sp_withgfx (object *args, object *env) { #if defined(gfxsupport) object *params = first(args); object *var = first(params); object *pair = cons(var, stream(GFXSTREAM, 1)); push(pair,env); object *forms = cdr(args); object *result = eval(tf_progn(forms,env), env); return result; #else (void) args, (void) env; error2(WITHGFX, PSTR("not supported")); return nil; #endif } // Assembler object *sp_defcode (object *args, object *env) { setflag(NOESC); checkargs(DEFCODE, args); object *var = first(args); object *params = second(args); if (!symbolp(var)) error(DEFCODE, PSTR("not a symbol"), var); // Make parameters into synonyms for registers r0, r1, etc int regn = 0; while (params != NULL) { if (regn > 3) error(DEFCODE, PSTR("more than 4 parameters"), var); object *regpair = cons(car(params), newsymbol((18*40+30+regn)*2560000)); // Symbol for r0 etc push(regpair,env); regn++; params = cdr(params); } // Make *pc* a local variable object *pcpair = cons(newsymbol(pack40((char*)"*pc*\0\0")), number(0)); push(pcpair,env); args = cdr(args); // Make labels into local variables object *entries = cdr(args); while (entries != NULL) { object *arg = first(entries); if (symbolp(arg)) { object *pair = cons(arg,number(0)); push(pair,env); } entries = cdr(entries); } // First pass int origin = 0; int codesize = assemble(1, origin, cdr(args), env, pcpair); // See if it will fit object *globals = GlobalEnv; while (globals != NULL) { object *pair = car(globals); if (pair != NULL && car(pair) != var) { // Exclude me if I already exist object *codeid = second(pair); if (codeid->type == CODE) { codesize = codesize + endblock(codeid) - startblock(codeid); } } globals = cdr(globals); } if (codesize > CODESIZE) error(DEFCODE, PSTR("not enough room for code"), var); // Compact the code block, removing gaps origin = 0; object *block; int smallest; do { smallest = CODESIZE; globals = GlobalEnv; while (globals != NULL) { object *pair = car(globals); if (pair != NULL && car(pair) != var) { // Exclude me if I already exist object *codeid = second(pair); if (codeid->type == CODE) { if (startblock(codeid) < smallest && startblock(codeid) >= origin) { smallest = startblock(codeid); block = codeid; } } } globals = cdr(globals); } // Compact fragmentation if necessary if (smallest == origin) origin = endblock(block); // No gap else if (smallest < CODESIZE) { // Slide block down int target = origin; for (int i=startblock(block); iinteger = target<<16 | origin; origin = target; } } while (smallest < CODESIZE); // Second pass - origin is first free location codesize = assemble(2, origin, cdr(args), env, pcpair); object *val = cons(codehead((origin+codesize)<<16 | origin), args); object *pair = value(var->name, GlobalEnv); if (pair != NULL) cdr(pair) = val; else push(cons(var, val), GlobalEnv); clrflag(NOESC); return var; } // Tail-recursive forms object *tf_progn (object *args, object *env) { if (args == NULL) return nil; object *more = cdr(args); while (more != NULL) { object *result = eval(car(args),env); if (tstflag(RETURNFLAG)) return result; args = more; more = cdr(args); } return car(args); } object *tf_if (object *args, object *env) { if (args == NULL || cdr(args) == NULL) error2(IF, PSTR("missing argument(s)")); if (eval(first(args), env) != nil) return second(args); args = cddr(args); return (args != NULL) ? first(args) : nil; } object *tf_cond (object *args, object *env) { while (args != NULL) { object *clause = first(args); if (!consp(clause)) error(COND, PSTR("illegal clause"), clause); object *test = eval(first(clause), env); object *forms = cdr(clause); if (test != nil) { if (forms == NULL) return quote(test); else return tf_progn(forms, env); } args = cdr(args); } return nil; } object *tf_when (object *args, object *env) { if (args == NULL) error2(WHEN, noargument); if (eval(first(args), env) != nil) return tf_progn(cdr(args),env); else return nil; } object *tf_unless (object *args, object *env) { if (args == NULL) error2(UNLESS, noargument); if (eval(first(args), env) != nil) return nil; else return tf_progn(cdr(args),env); } object *tf_case (object *args, object *env) { object *test = eval(first(args), env); args = cdr(args); while (args != NULL) { object *clause = first(args); if (!consp(clause)) error(CASE, PSTR("illegal clause"), clause); object *key = car(clause); object *forms = cdr(clause); if (consp(key)) { while (key != NULL) { if (eq(test,car(key))) return tf_progn(forms, env); key = cdr(key); } } else if (eq(test,key) || eq(key,tee)) return tf_progn(forms, env); args = cdr(args); } return nil; } object *tf_and (object *args, object *env) { if (args == NULL) return tee; object *more = cdr(args); while (more != NULL) { if (eval(car(args), env) == NULL) return nil; args = more; more = cdr(args); } return car(args); } object *tf_or (object *args, object *env) { while (args != NULL) { if (eval(car(args), env) != NULL) return car(args); args = cdr(args); } return nil; } // Core functions object *fn_not (object *args, object *env) { (void) env; return (first(args) == nil) ? tee : nil; } object *fn_cons (object *args, object *env) { (void) env; return cons(first(args), second(args)); } object *fn_atom (object *args, object *env) { (void) env; return atom(first(args)) ? tee : nil; } object *fn_listp (object *args, object *env) { (void) env; return listp(first(args)) ? tee : nil; } object *fn_consp (object *args, object *env) { (void) env; return consp(first(args)) ? tee : nil; } object *fn_symbolp (object *args, object *env) { (void) env; object *arg = first(args); return symbolp(arg) ? tee : nil; } object *fn_arrayp (object *args, object *env) { (void) env; return arrayp(first(args)) ? tee : nil; } object *fn_boundp (object *args, object *env) { (void) env; object *var = first(args); if (!symbolp(var)) error(BOUNDP, notasymbol, var); return boundp(var, env) ? tee : nil; } object *fn_setfn (object *args, object *env) { object *arg = nil; while (args != NULL) { if (cdr(args) == NULL) error2(SETFN, oddargs); object *pair = findvalue(first(args), env); arg = second(args); cdr(pair) = arg; args = cddr(args); } return arg; } object *fn_streamp (object *args, object *env) { (void) env; object *arg = first(args); return streamp(arg) ? tee : nil; } object *fn_eq (object *args, object *env) { (void) env; return eq(first(args), second(args)) ? tee : nil; } // List functions object *fn_car (object *args, object *env) { (void) env; return carx(first(args)); } object *fn_cdr (object *args, object *env) { (void) env; return cdrx(first(args)); } object *fn_caar (object *args, object *env) { (void) env; return carx(carx(first(args))); } object *fn_cadr (object *args, object *env) { (void) env; return carx(cdrx(first(args))); } object *fn_cdar (object *args, object *env) { (void) env; return cdrx(carx(first(args))); } object *fn_cddr (object *args, object *env) { (void) env; return cdrx(cdrx(first(args))); } object *fn_caaar (object *args, object *env) { (void) env; return carx(carx(carx(first(args)))); } object *fn_caadr (object *args, object *env) { (void) env; return carx(carx(cdrx(first(args)))); } object *fn_cadar (object *args, object *env) { (void) env; return carx(cdrx(carx(first(args)))); } object *fn_caddr (object *args, object *env) { (void) env; return carx(cdrx(cdrx(first(args)))); } object *fn_cdaar (object *args, object *env) { (void) env; return cdrx(carx(carx(first(args)))); } object *fn_cdadr (object *args, object *env) { (void) env; return cdrx(carx(cdrx(first(args)))); } object *fn_cddar (object *args, object *env) { (void) env; return cdrx(cdrx(carx(first(args)))); } object *fn_cdddr (object *args, object *env) { (void) env; return cdrx(cdrx(cdrx(first(args)))); } object *fn_length (object *args, object *env) { (void) env; object *arg = first(args); if (listp(arg)) return number(listlength(LENGTH, arg)); if (stringp(arg)) return number(stringlength(arg)); if (arrayp(arg) && cdr(cddr(arg)) == NULL) return first(cddr(arg)); error(LENGTH, PSTR("argument is not a list, 1d array, or string"), arg); } object *fn_arraydimensions (object *args, object *env) { object *array = first(args); if (!arrayp(array)) error(ARRAYDIMENSIONS, PSTR("argument is not an array"), array); return cddr(array); } object *fn_list (object *args, object *env) { (void) env; return args; } object *fn_makearray (object *args, object *env) { (void) env; object *def = nil; object *dims = first(args); if (dims == NULL) error2(MAKEARRAY, PSTR("dimensions can't be nil")); else if (atom(dims)) dims = cons(dims, NULL); if (cdr(args) != NULL) { object *var = second(args); if (!symbolp(var) || var->name != INITIALELEMENT) error(MAKEARRAY, PSTR("illegal second argument"), var); if (cddr(args) != NULL) def = third(args); } return makearray(MAKEARRAY, dims, def); } object *fn_reverse (object *args, object *env) { (void) env; object *list = first(args); object *result = NULL; while (list != NULL) { if (improperp(list)) error(REVERSE, notproper, list); push(first(list),result); list = cdr(list); } return result; } object *fn_nth (object *args, object *env) { (void) env; int n = checkinteger(NTH, first(args)); object *list = second(args); while (list != NULL) { if (improperp(list)) error(NTH, notproper, list); if (n == 0) return car(list); list = cdr(list); n--; } return nil; } object *fn_aref (object *args, object *env) { object *array = first(args); if (!arrayp(array)) error(AREF, PSTR("first argument is not an array"), array); return *getarray(AREF, array, cdr(args), 0); } object *fn_assoc (object *args, object *env) { (void) env; object *key = first(args); object *list = second(args); return assoc(key,list); } object *fn_member (object *args, object *env) { (void) env; object *item = first(args); object *list = second(args); while (list != NULL) { if (improperp(list)) error(MEMBER, notproper, list); if (eq(item,car(list))) return list; list = cdr(list); } return nil; } object *fn_apply (object *args, object *env) { object *previous = NULL; object *last = args; while (cdr(last) != NULL) { previous = last; last = cdr(last); } object *arg = car(last); if (!listp(arg)) error(APPLY, PSTR("last argument is not a list"), arg); cdr(previous) = arg; return apply(APPLY, first(args), cdr(args), env); } object *fn_funcall (object *args, object *env) { return apply(FUNCALL, first(args), cdr(args), env); } object *fn_append (object *args, object *env) { (void) env; object *head = NULL; object *tail; while (args != NULL) { object *list = first(args); if (!listp(list)) error(APPEND, notalist, list); while (consp(list)) { object *obj = cons(car(list), cdr(list)); if (head == NULL) head = obj; else cdr(tail) = obj; tail = obj; list = cdr(list); if (cdr(args) != NULL && improperp(list)) error(APPEND, notproper, first(args)); } args = cdr(args); } return head; } object *fn_mapc (object *args, object *env) { object *function = first(args); args = cdr(args); object *result = first(args); object *params = cons(NULL, NULL); push(params,GCStack); // Make parameters while (true) { object *tailp = params; object *lists = args; while (lists != NULL) { object *list = car(lists); if (list == NULL) { pop(GCStack); return result; } if (improperp(list)) error(MAPC, notproper, list); object *obj = cons(first(list),NULL); car(lists) = cdr(list); cdr(tailp) = obj; tailp = obj; lists = cdr(lists); } apply(MAPC, function, cdr(params), env); } } object *fn_mapcar (object *args, object *env) { object *function = first(args); args = cdr(args); object *params = cons(NULL, NULL); push(params,GCStack); object *head = cons(NULL, NULL); push(head,GCStack); object *tail = head; // Make parameters while (true) { object *tailp = params; object *lists = args; while (lists != NULL) { object *list = car(lists); if (list == NULL) { pop(GCStack); pop(GCStack); return cdr(head); } if (improperp(list)) error(MAPCAR, notproper, list); object *obj = cons(first(list),NULL); car(lists) = cdr(list); cdr(tailp) = obj; tailp = obj; lists = cdr(lists); } object *result = apply(MAPCAR, function, cdr(params), env); object *obj = cons(result,NULL); cdr(tail) = obj; tail = obj; } } object *fn_mapcan (object *args, object *env) { object *function = first(args); args = cdr(args); object *params = cons(NULL, NULL); push(params,GCStack); object *head = cons(NULL, NULL); push(head,GCStack); object *tail = head; // Make parameters while (true) { object *tailp = params; object *lists = args; while (lists != NULL) { object *list = car(lists); if (list == NULL) { pop(GCStack); pop(GCStack); return cdr(head); } if (improperp(list)) error(MAPCAN, notproper, list); object *obj = cons(first(list),NULL); car(lists) = cdr(list); cdr(tailp) = obj; tailp = obj; lists = cdr(lists); } object *result = apply(MAPCAN, function, cdr(params), env); while (consp(result)) { cdr(tail) = result; tail = result; result = cdr(result); } if (result != NULL) error(MAPCAN, resultproper, result); } } // Arithmetic functions object *add_floats (object *args, float fresult) { while (args != NULL) { object *arg = car(args); fresult = fresult + checkintfloat(ADD, arg); args = cdr(args); } return makefloat(fresult); } object *fn_add (object *args, object *env) { (void) env; int result = 0; while (args != NULL) { object *arg = car(args); if (floatp(arg)) return add_floats(args, (float)result); else if (integerp(arg)) { int val = arg->integer; if (val < 1) { if (INT_MIN - val > result) return add_floats(args, (float)result); } else { if (INT_MAX - val < result) return add_floats(args, (float)result); } result = result + val; } else error(ADD, notanumber, arg); args = cdr(args); } return number(result); } object *subtract_floats (object *args, float fresult) { while (args != NULL) { object *arg = car(args); fresult = fresult - checkintfloat(SUBTRACT, arg); args = cdr(args); } return makefloat(fresult); } object *negate (object *arg) { if (integerp(arg)) { int result = arg->integer; if (result == INT_MIN) return makefloat(-result); else return number(-result); } else if (floatp(arg)) return makefloat(-(arg->single_float)); else error(SUBTRACT, notanumber, arg); } object *fn_subtract (object *args, object *env) { (void) env; object *arg = car(args); args = cdr(args); if (args == NULL) return negate(arg); else if (floatp(arg)) return subtract_floats(args, arg->single_float); else if (integerp(arg)) { int result = arg->integer; while (args != NULL) { arg = car(args); if (floatp(arg)) return subtract_floats(args, result); else if (integerp(arg)) { int val = (car(args))->integer; if (val < 1) { if (INT_MAX + val < result) return subtract_floats(args, result); } else { if (INT_MIN + val > result) return subtract_floats(args, result); } result = result - val; } else error(SUBTRACT, notanumber, arg); args = cdr(args); } return number(result); } else error(SUBTRACT, notanumber, arg); } object *multiply_floats (object *args, float fresult) { while (args != NULL) { object *arg = car(args); fresult = fresult * checkintfloat(MULTIPLY, arg); args = cdr(args); } return makefloat(fresult); } object *fn_multiply (object *args, object *env) { (void) env; int result = 1; while (args != NULL){ object *arg = car(args); if (floatp(arg)) return multiply_floats(args, result); else if (integerp(arg)) { int64_t val = result * (int64_t)(arg->integer); if ((val > INT_MAX) || (val < INT_MIN)) return multiply_floats(args, result); result = val; } else error(MULTIPLY, notanumber, arg); args = cdr(args); } return number(result); } object *divide_floats (object *args, float fresult) { while (args != NULL) { object *arg = car(args); float f = checkintfloat(DIVIDE, arg); if (f == 0.0) error2(DIVIDE, PSTR("division by zero")); fresult = fresult / f; args = cdr(args); } return makefloat(fresult); } object *fn_divide (object *args, object *env) { (void) env; object* arg = first(args); args = cdr(args); // One argument if (args == NULL) { if (floatp(arg)) { float f = arg->single_float; if (f == 0.0) error2(DIVIDE, PSTR("division by zero")); return makefloat(1.0 / f); } else if (integerp(arg)) { int i = arg->integer; if (i == 0) error2(DIVIDE, PSTR("division by zero")); else if (i == 1) return number(1); else return makefloat(1.0 / i); } else error(DIVIDE, notanumber, arg); } // Multiple arguments if (floatp(arg)) return divide_floats(args, arg->single_float); else if (integerp(arg)) { int result = arg->integer; while (args != NULL) { arg = car(args); if (floatp(arg)) { return divide_floats(args, result); } else if (integerp(arg)) { int i = arg->integer; if (i == 0) error2(DIVIDE, PSTR("division by zero")); if ((result % i) != 0) return divide_floats(args, result); if ((result == INT_MIN) && (i == -1)) return divide_floats(args, result); result = result / i; args = cdr(args); } else error(DIVIDE, notanumber, arg); } return number(result); } else error(DIVIDE, notanumber, arg); } object *fn_mod (object *args, object *env) { (void) env; object *arg1 = first(args); object *arg2 = second(args); if (integerp(arg1) && integerp(arg2)) { int divisor = arg2->integer; if (divisor == 0) error2(MOD, PSTR("division by zero")); int dividend = arg1->integer; int remainder = dividend % divisor; if ((dividend<0) != (divisor<0)) remainder = remainder + divisor; return number(remainder); } else { float fdivisor = checkintfloat(MOD, arg2); if (fdivisor == 0.0) error2(MOD, PSTR("division by zero")); float fdividend = checkintfloat(MOD, arg1); float fremainder = fmod(fdividend , fdivisor); if ((fdividend<0) != (fdivisor<0)) fremainder = fremainder + fdivisor; return makefloat(fremainder); } } object *fn_oneplus (object *args, object *env) { (void) env; object* arg = first(args); if (floatp(arg)) return makefloat((arg->single_float) + 1.0); else if (integerp(arg)) { int result = arg->integer; if (result == INT_MAX) return makefloat((arg->integer) + 1.0); else return number(result + 1); } else error(ONEPLUS, notanumber, arg); } object *fn_oneminus (object *args, object *env) { (void) env; object* arg = first(args); if (floatp(arg)) return makefloat((arg->single_float) - 1.0); else if (integerp(arg)) { int result = arg->integer; if (result == INT_MIN) return makefloat((arg->integer) - 1.0); else return number(result - 1); } else error(ONEMINUS, notanumber, arg); } object *fn_abs (object *args, object *env) { (void) env; object *arg = first(args); if (floatp(arg)) return makefloat(abs(arg->single_float)); else if (integerp(arg)) { int result = arg->integer; if (result == INT_MIN) return makefloat(abs((float)result)); else return number(abs(result)); } else error(ABS, notanumber, arg); } object *fn_random (object *args, object *env) { (void) env; object *arg = first(args); if (integerp(arg)) return number(random(arg->integer)); else if (floatp(arg)) return makefloat((float)rand()/(float)(RAND_MAX/(arg->single_float))); else error(RANDOM, notanumber, arg); } object *fn_maxfn (object *args, object *env) { (void) env; object* result = first(args); args = cdr(args); while (args != NULL) { object *arg = car(args); if (integerp(result) && integerp(arg)) { if ((arg->integer) > (result->integer)) result = arg; } else if ((checkintfloat(MAXFN, arg) > checkintfloat(MAXFN, result))) result = arg; args = cdr(args); } return result; } object *fn_minfn (object *args, object *env) { (void) env; object* result = first(args); args = cdr(args); while (args != NULL) { object *arg = car(args); if (integerp(result) && integerp(arg)) { if ((arg->integer) < (result->integer)) result = arg; } else if ((checkintfloat(MINFN, arg) < checkintfloat(MINFN, result))) result = arg; args = cdr(args); } return result; } // Arithmetic comparisons object *fn_noteq (object *args, object *env) { (void) env; while (args != NULL) { object *nargs = args; object *arg1 = first(nargs); nargs = cdr(nargs); while (nargs != NULL) { object *arg2 = first(nargs); if (integerp(arg1) && integerp(arg2)) { if ((arg1->integer) == (arg2->integer)) return nil; } else if ((checkintfloat(NOTEQ, arg1) == checkintfloat(NOTEQ, arg2))) return nil; nargs = cdr(nargs); } args = cdr(args); } return tee; } object *fn_numeq (object *args, object *env) { (void) env; object *arg1 = first(args); args = cdr(args); while (args != NULL) { object *arg2 = first(args); if (integerp(arg1) && integerp(arg2)) { if (!((arg1->integer) == (arg2->integer))) return nil; } else if (!(checkintfloat(NUMEQ, arg1) == checkintfloat(NUMEQ, arg2))) return nil; arg1 = arg2; args = cdr(args); } return tee; } object *fn_less (object *args, object *env) { (void) env; object *arg1 = first(args); args = cdr(args); while (args != NULL) { object *arg2 = first(args); if (integerp(arg1) && integerp(arg2)) { if (!((arg1->integer) < (arg2->integer))) return nil; } else if (!(checkintfloat(LESS, arg1) < checkintfloat(LESS, arg2))) return nil; arg1 = arg2; args = cdr(args); } return tee; } object *fn_lesseq (object *args, object *env) { (void) env; object *arg1 = first(args); args = cdr(args); while (args != NULL) { object *arg2 = first(args); if (integerp(arg1) && integerp(arg2)) { if (!((arg1->integer) <= (arg2->integer))) return nil; } else if (!(checkintfloat(LESSEQ, arg1) <= checkintfloat(LESSEQ, arg2))) return nil; arg1 = arg2; args = cdr(args); } return tee; } object *fn_greater (object *args, object *env) { (void) env; object *arg1 = first(args); args = cdr(args); while (args != NULL) { object *arg2 = first(args); if (integerp(arg1) && integerp(arg2)) { if (!((arg1->integer) > (arg2->integer))) return nil; } else if (!(checkintfloat(GREATER, arg1) > checkintfloat(GREATER, arg2))) return nil; arg1 = arg2; args = cdr(args); } return tee; } object *fn_greatereq (object *args, object *env) { (void) env; object *arg1 = first(args); args = cdr(args); while (args != NULL) { object *arg2 = first(args); if (integerp(arg1) && integerp(arg2)) { if (!((arg1->integer) >= (arg2->integer))) return nil; } else if (!(checkintfloat(GREATEREQ, arg1) >= checkintfloat(GREATEREQ, arg2))) return nil; arg1 = arg2; args = cdr(args); } return tee; } object *fn_plusp (object *args, object *env) { (void) env; object *arg = first(args); if (floatp(arg)) return ((arg->single_float) > 0.0) ? tee : nil; else if (integerp(arg)) return ((arg->integer) > 0) ? tee : nil; else error(PLUSP, notanumber, arg); } object *fn_minusp (object *args, object *env) { (void) env; object *arg = first(args); if (floatp(arg)) return ((arg->single_float) < 0.0) ? tee : nil; else if (integerp(arg)) return ((arg->integer) < 0) ? tee : nil; else error(MINUSP, notanumber, arg); } object *fn_zerop (object *args, object *env) { (void) env; object *arg = first(args); if (floatp(arg)) return ((arg->single_float) == 0.0) ? tee : nil; else if (integerp(arg)) return ((arg->integer) == 0) ? tee : nil; else error(ZEROP, notanumber, arg); } object *fn_oddp (object *args, object *env) { (void) env; int arg = checkinteger(ODDP, first(args)); return ((arg & 1) == 1) ? tee : nil; } object *fn_evenp (object *args, object *env) { (void) env; int arg = checkinteger(EVENP, first(args)); return ((arg & 1) == 0) ? tee : nil; } // Number functions object *fn_integerp (object *args, object *env) { (void) env; return integerp(first(args)) ? tee : nil; } object *fn_numberp (object *args, object *env) { (void) env; object *arg = first(args); return (integerp(arg) || floatp(arg)) ? tee : nil; } // Floating-point functions object *fn_floatfn (object *args, object *env) { (void) env; object *arg = first(args); return (floatp(arg)) ? arg : makefloat((float)(arg->integer)); } object *fn_floatp (object *args, object *env) { (void) env; return floatp(first(args)) ? tee : nil; } object *fn_sin (object *args, object *env) { (void) env; return makefloat(sin(checkintfloat(SIN, first(args)))); } object *fn_cos (object *args, object *env) { (void) env; return makefloat(cos(checkintfloat(COS, first(args)))); } object *fn_tan (object *args, object *env) { (void) env; return makefloat(tan(checkintfloat(TAN, first(args)))); } object *fn_asin (object *args, object *env) { (void) env; return makefloat(asin(checkintfloat(ASIN, first(args)))); } object *fn_acos (object *args, object *env) { (void) env; return makefloat(acos(checkintfloat(ACOS, first(args)))); } object *fn_atan (object *args, object *env) { (void) env; object *arg = first(args); float div = 1.0; args = cdr(args); if (args != NULL) div = checkintfloat(ATAN, first(args)); return makefloat(atan2(checkintfloat(ATAN, arg), div)); } object *fn_sinh (object *args, object *env) { (void) env; return makefloat(sinh(checkintfloat(SINH, first(args)))); } object *fn_cosh (object *args, object *env) { (void) env; return makefloat(cosh(checkintfloat(COSH, first(args)))); } object *fn_tanh (object *args, object *env) { (void) env; return makefloat(tanh(checkintfloat(TANH, first(args)))); } object *fn_exp (object *args, object *env) { (void) env; return makefloat(exp(checkintfloat(EXP, first(args)))); } object *fn_sqrt (object *args, object *env) { (void) env; return makefloat(sqrt(checkintfloat(SQRT, first(args)))); } object *fn_log (object *args, object *env) { (void) env; object *arg = first(args); float fresult = log(checkintfloat(LOG, arg)); args = cdr(args); if (args == NULL) return makefloat(fresult); else return makefloat(fresult / log(checkintfloat(LOG, first(args)))); } int intpower (int base, int exp) { int result = 1; while (exp) { if (exp & 1) result = result * base; exp = exp / 2; base = base * base; } return result; } object *fn_expt (object *args, object *env) { (void) env; object *arg1 = first(args); object *arg2 = second(args); float float1 = checkintfloat(EXPT, arg1); float value = log(abs(float1)) * checkintfloat(EXPT, arg2); if (integerp(arg1) && integerp(arg2) && ((arg2->integer) > 0) && (abs(value) < 21.4875)) return number(intpower(arg1->integer, arg2->integer)); if (float1 < 0) error2(EXPT, PSTR("invalid result")); return makefloat(exp(value)); } object *fn_ceiling (object *args, object *env) { (void) env; object *arg = first(args); args = cdr(args); if (args != NULL) return number(ceil(checkintfloat(CEILING, arg) / checkintfloat(CEILING, first(args)))); else return number(ceil(checkintfloat(CEILING, arg))); } object *fn_floor (object *args, object *env) { (void) env; object *arg = first(args); args = cdr(args); if (args != NULL) return number(floor(checkintfloat(FLOOR, arg) / checkintfloat(FLOOR, first(args)))); else return number(floor(checkintfloat(FLOOR, arg))); } object *fn_truncate (object *args, object *env) { (void) env; object *arg = first(args); args = cdr(args); if (args != NULL) return number((int)(checkintfloat(TRUNCATE, arg) / checkintfloat(TRUNCATE, first(args)))); else return number((int)(checkintfloat(TRUNCATE, arg))); } int myround (float number) { return (number >= 0) ? (int)(number + 0.5) : (int)(number - 0.5); } object *fn_round (object *args, object *env) { (void) env; object *arg = first(args); args = cdr(args); if (args != NULL) return number(myround(checkintfloat(ROUND, arg) / checkintfloat(ROUND, first(args)))); else return number(myround(checkintfloat(ROUND, arg))); } // Characters object *fn_char (object *args, object *env) { (void) env; object *arg = first(args); if (!stringp(arg)) error(CHAR, notastring, arg); char c = nthchar(arg, checkinteger(CHAR, second(args))); if (c == 0) error2(CHAR, PSTR("index out of range")); return character(c); } object *fn_charcode (object *args, object *env) { (void) env; return number(checkchar(CHARCODE, first(args))); } object *fn_codechar (object *args, object *env) { (void) env; return character(checkinteger(CODECHAR, first(args))); } object *fn_characterp (object *args, object *env) { (void) env; return characterp(first(args)) ? tee : nil; } // Strings object *fn_stringp (object *args, object *env) { (void) env; return stringp(first(args)) ? tee : nil; } bool stringcompare (symbol_t name, object *args, bool lt, bool gt, bool eq) { object *arg1 = first(args); if (!stringp(arg1)) error(name, notastring, arg1); object *arg2 = second(args); if (!stringp(arg2)) error(name, notastring, arg2); arg1 = cdr(arg1); arg2 = cdr(arg2); while ((arg1 != NULL) || (arg2 != NULL)) { if (arg1 == NULL) return lt; if (arg2 == NULL) return gt; if (arg1->chars < arg2->chars) return lt; if (arg1->chars > arg2->chars) return gt; arg1 = car(arg1); arg2 = car(arg2); } return eq; } object *fn_stringeq (object *args, object *env) { (void) env; return stringcompare(STRINGEQ, args, false, false, true) ? tee : nil; } object *fn_stringless (object *args, object *env) { (void) env; return stringcompare(STRINGLESS, args, true, false, false) ? tee : nil; } object *fn_stringgreater (object *args, object *env) { (void) env; return stringcompare(STRINGGREATER, args, false, true, false) ? tee : nil; } object *fn_sort (object *args, object *env) { if (first(args) == NULL) return nil; object *list = cons(nil,first(args)); push(list,GCStack); object *predicate = second(args); object *compare = cons(NULL, cons(NULL, NULL)); push(compare,GCStack); object *ptr = cdr(list); while (cdr(ptr) != NULL) { object *go = list; while (go != ptr) { car(compare) = car(cdr(ptr)); car(cdr(compare)) = car(cdr(go)); if (apply(SORT, predicate, compare, env)) break; go = cdr(go); } if (go != ptr) { object *obj = cdr(ptr); cdr(ptr) = cdr(obj); cdr(obj) = cdr(go); cdr(go) = obj; } else ptr = cdr(ptr); } pop(GCStack); pop(GCStack); return cdr(list); } object *fn_stringfn (object *args, object *env) { (void) env; object *arg = first(args); int type = arg->type; if (type == STRING) return arg; object *obj = myalloc(); obj->type = STRING; if (type == CHARACTER) { object *cell = myalloc(); cell->car = NULL; uint8_t shift = (sizeof(int)-1)*8; cell->chars = (arg->chars)<cdr = cell; } else if (type == SYMBOL) { char *s = symbolname(arg->name); char ch = *s++; object *head = NULL; int chars = 0; while (ch) { if (ch == '\\') ch = *s++; buildstring(ch, &chars, &head); ch = *s++; } obj->cdr = head; } else error(STRINGFN, PSTR("can't convert to string"), arg); return obj; } object *fn_concatenate (object *args, object *env) { (void) env; object *arg = first(args); symbol_t name = arg->name; if (name != STRINGFN) error2(CONCATENATE, PSTR("only supports strings")); args = cdr(args); object *result = myalloc(); result->type = STRING; object *head = NULL; int chars = 0; while (args != NULL) { object *obj = first(args); if (!stringp(obj)) error(CONCATENATE, notastring, obj); obj = cdr(obj); while (obj != NULL) { int quad = obj->chars; while (quad != 0) { char ch = quad>>((sizeof(int)-1)*8) & 0xFF; buildstring(ch, &chars, &head); quad = quad<<8; } obj = car(obj); } args = cdr(args); } result->cdr = head; return result; } object *fn_subseq (object *args, object *env) { (void) env; object *arg = first(args); if (!stringp(arg)) error(SUBSEQ, notastring, arg); int start = checkinteger(SUBSEQ, second(args)); int end; args = cddr(args); if (args != NULL) end = checkinteger(SUBSEQ, car(args)); else end = stringlength(arg); object *result = myalloc(); result->type = STRING; object *head = NULL; int chars = 0; for (int i=start; icdr = head; return result; } object *fn_readfromstring (object *args, object *env) { (void) env; object *arg = first(args); if (!stringp(arg)) error(READFROMSTRING, notastring, arg); GlobalString = arg; GlobalStringIndex = 0; return read(gstr); } object *fn_princtostring (object *args, object *env) { (void) env; object *arg = first(args); object *obj = startstring(PRINCTOSTRING); prin1object(arg, pstr); obj->cdr = GlobalString; return obj; } object *fn_prin1tostring (object *args, object *env) { (void) env; object *arg = first(args); object *obj = startstring(PRIN1TOSTRING); printobject(arg, pstr); obj->cdr = GlobalString; return obj; } // Bitwise operators object *fn_logand (object *args, object *env) { (void) env; int result = -1; while (args != NULL) { result = result & checkinteger(LOGAND, first(args)); args = cdr(args); } return number(result); } object *fn_logior (object *args, object *env) { (void) env; int result = 0; while (args != NULL) { result = result | checkinteger(LOGIOR, first(args)); args = cdr(args); } return number(result); } object *fn_logxor (object *args, object *env) { (void) env; int result = 0; while (args != NULL) { result = result ^ checkinteger(LOGXOR, first(args)); args = cdr(args); } return number(result); } object *fn_lognot (object *args, object *env) { (void) env; int result = checkinteger(LOGNOT, car(args)); return number(~result); } object *fn_ash (object *args, object *env) { (void) env; int value = checkinteger(ASH, first(args)); int count = checkinteger(ASH, second(args)); if (count >= 0) return number(value << count); else return number(value >> abs(count)); } object *fn_logbitp (object *args, object *env) { (void) env; int index = checkinteger(LOGBITP, first(args)); int value = checkinteger(LOGBITP, second(args)); return (bitRead(value, index) == 1) ? tee : nil; } // System functions object *fn_eval (object *args, object *env) { return eval(first(args), env); } object *fn_globals (object *args, object *env) { (void) args; if (GlobalEnv == NULL) return nil; return fn_mapcar(cons(symbol(CAR),cons(GlobalEnv,nil)), env); } object *fn_locals (object *args, object *env) { (void) args; return env; } object *fn_makunbound (object *args, object *env) { (void) env; object *var = first(args); if (!symbolp(var)) error(MAKUNBOUND, notasymbol, var); delassoc(var, &GlobalEnv); return var; } object *fn_break (object *args, object *env) { (void) args; pfstring(PSTR("\rBreak!\r"), pserial); BreakLevel++; repl(env); BreakLevel--; return nil; } object *fn_read (object *args, object *env) { (void) env; gfun_t gfun = gstreamfun(args); return read(gfun); } object *fn_prin1 (object *args, object *env) { (void) env; object *obj = first(args); pfun_t pfun = pstreamfun(cdr(args)); printobject(obj, pfun); return obj; } object *fn_print (object *args, object *env) { (void) env; object *obj = first(args); pfun_t pfun = pstreamfun(cdr(args)); pln(pfun); printobject(obj, pfun); pfun(' '); return obj; } object *fn_princ (object *args, object *env) { (void) env; object *obj = first(args); pfun_t pfun = pstreamfun(cdr(args)); prin1object(obj, pfun); return obj; } object *fn_terpri (object *args, object *env) { (void) env; pfun_t pfun = pstreamfun(args); pln(pfun); return nil; } object *fn_readbyte (object *args, object *env) { (void) env; gfun_t gfun = gstreamfun(args); int c = gfun(); return (c == -1) ? nil : number(c); } object *fn_readline (object *args, object *env) { (void) env; gfun_t gfun = gstreamfun(args); return readstring('\n', gfun); } object *fn_writebyte (object *args, object *env) { (void) env; int value = checkinteger(WRITEBYTE, first(args)); pfun_t pfun = pstreamfun(cdr(args)); (pfun)(value); return nil; } object *fn_writestring (object *args, object *env) { (void) env; object *obj = first(args); pfun_t pfun = pstreamfun(cdr(args)); char temp = Flags; clrflag(PRINTREADABLY); printstring(obj, pfun); Flags = temp; return nil; } object *fn_writeline (object *args, object *env) { (void) env; object *obj = first(args); pfun_t pfun = pstreamfun(cdr(args)); char temp = Flags; clrflag(PRINTREADABLY); printstring(obj, pfun); pln(pfun); Flags = temp; return nil; } object *fn_restarti2c (object *args, object *env) { (void) env; int stream = first(args)->integer; args = cdr(args); int read = 0; // Write I2CCount = 0; if (args != NULL) { object *rw = first(args); if (integerp(rw)) I2CCount = rw->integer; read = (rw != NULL); } int address = stream & 0xFF; if (stream>>8 != I2CSTREAM) error2(RESTARTI2C, PSTR("not an i2c stream")); return I2Crestart(address, read) ? tee : nil; } object *fn_gc (object *obj, object *env) { int initial = Freespace; unsigned long start = micros(); gc(obj, env); unsigned long elapsed = micros() - start; pfstring(PSTR("Space: "), pserial); pint(Freespace - initial, pserial); pfstring(PSTR(" bytes, Time: "), pserial); pint(elapsed, pserial); pfstring(PSTR(" us\r"), pserial); return nil; } object *fn_room (object *args, object *env) { (void) args, (void) env; return number(Freespace); } object *fn_saveimage (object *args, object *env) { if (args != NULL) args = eval(first(args), env); return number(saveimage(args)); } object *fn_loadimage (object *args, object *env) { (void) env; if (args != NULL) args = first(args); return number(loadimage(args)); } object *fn_cls (object *args, object *env) { (void) args, (void) env; pserial(12); return nil; } // Arduino procedures object *fn_pinmode (object *args, object *env) { (void) env; int pin = checkinteger(PINMODE, first(args)); PinMode pm = INPUT; object *mode = second(args); if (integerp(mode)) { int nmode = mode->integer; if (nmode == 1) pm = OUTPUT; else if (nmode == 2) pm = INPUT_PULLUP; #if defined(INPUT_PULLDOWN) else if (nmode == 4) pm = INPUT_PULLDOWN; #endif } else if (mode != nil) pm = OUTPUT; pinMode(pin, pm); return nil; } object *fn_digitalread (object *args, object *env) { (void) env; int pin = checkinteger(DIGITALREAD, first(args)); if (digitalRead(pin) != 0) return tee; else return nil; } object *fn_digitalwrite (object *args, object *env) { (void) env; int pin = checkinteger(DIGITALWRITE, first(args)); object *mode = second(args); if (integerp(mode)) digitalWrite(pin, mode->integer ? HIGH : LOW); else digitalWrite(pin, (mode != nil) ? HIGH : LOW); return mode; } object *fn_analogread (object *args, object *env) { (void) env; int pin = checkinteger(ANALOGREAD, first(args)); checkanalogread(pin); return number(analogRead(pin)); } object *fn_analogwrite (object *args, object *env) { (void) env; int pin = checkinteger(ANALOGWRITE, first(args)); checkanalogwrite(pin); object *value = second(args); analogWrite(pin, checkinteger(ANALOGWRITE, value)); return value; } object *fn_delay (object *args, object *env) { (void) env; object *arg1 = first(args); delay(checkinteger(DELAY, arg1)); return arg1; } object *fn_millis (object *args, object *env) { (void) args, (void) env; return number(millis()); } object *fn_sleep (object *args, object *env) { (void) env; object *arg1 = first(args); sleep(checkinteger(SLEEP, arg1)); return arg1; } object *fn_note (object *args, object *env) { (void) env; static int pin = 255; if (args != NULL) { pin = checkinteger(NOTE, first(args)); int note = 0; if (cddr(args) != NULL) note = checkinteger(NOTE, second(args)); int octave = 0; if (cddr(args) != NULL) octave = checkinteger(NOTE, third(args)); playnote(pin, note, octave); } else nonote(pin); return nil; } // Tree Editor object *fn_edit (object *args, object *env) { object *fun = first(args); object *pair = findvalue(fun, env); clrflag(EXITEDITOR); object *arg = edit(eval(fun, env)); cdr(pair) = arg; return arg; } object *edit (object *fun) { while (1) { if (tstflag(EXITEDITOR)) return fun; char c = gserial(); if (c == 'q') setflag(EXITEDITOR); else if (c == 'b') return fun; else if (c == 'r') fun = read(gserial); else if (c == '\n') { pfl(pserial); superprint(fun, 0, pserial); pln(pserial); } else if (c == 'c') fun = cons(read(gserial), fun); else if (atom(fun)) pserial('!'); else if (c == 'd') fun = cons(car(fun), edit(cdr(fun))); else if (c == 'a') fun = cons(edit(car(fun)), cdr(fun)); else if (c == 'x') fun = cdr(fun); else pserial('?'); } } // Pretty printer object *fn_pprint (object *args, object *env) { (void) env; object *obj = first(args); pfun_t pfun = pstreamfun(cdr(args)); #if defined(gfxsupport) if (pfun == gfxwrite) ppwidth = GFXPPWIDTH; #endif pln(pfun); superprint(obj, 0, pfun); ppwidth = PPWIDTH; return symbol(NOTHING); } object *fn_pprintall (object *args, object *env) { (void) env; pfun_t pfun = pstreamfun(args); #if defined(gfxsupport) if (pfun == gfxwrite) ppwidth = GFXPPWIDTH; #endif object *globals = GlobalEnv; while (globals != NULL) { object *pair = first(globals); object *var = car(pair); object *val = cdr(pair); pln(pfun); if (consp(val) && symbolp(car(val)) && car(val)->name == LAMBDA) { superprint(cons(symbol(DEFUN), cons(var, cdr(val))), 0, pfun); } else if (consp(val) && car(val)->type == CODE) { superprint(cons(symbol(DEFCODE), cons(var, cdr(val))), 0, pfun); } else { superprint(cons(symbol(DEFVAR), cons(var, cons(quote(val), NULL))), 0, pserial); } pln(pfun); testescape(); globals = cdr(globals); } ppwidth = PPWIDTH; return symbol(NOTHING); } // Format void formaterr (object *formatstr, PGM_P string, uint8_t p) { pln(pserial); indent(4, ' ', pserial); printstring(formatstr, pserial); pln(pserial); indent(p+5, ' ', pserial); pserial('^'); errorsub(FORMAT, string); pln(pserial); GCStack = NULL; longjmp(exception, 1); } object *fn_format (object *args, object *env) { (void) env; pfun_t pfun = pserial; object *output = first(args); object *obj; if (output == nil) { obj = startstring(FORMAT); pfun = pstr; } else if (output != tee) pfun = pstreamfun(args); object *formatstr = second(args); if (!stringp(formatstr)) error(FORMAT, notastring, formatstr); object *save = NULL; args = cddr(args); int len = stringlength(formatstr); uint8_t n = 0, width = 0, w, bra = 0; char pad = ' '; bool tilde = false, comma, quote; while (n < len) { char ch = nthchar(formatstr, n); char ch2 = ch & ~0x20; // force to upper case if (tilde) { if (comma && quote) { pad = ch; comma = false, quote = false; } else if (ch == '\'') { if (comma) quote = true; else formaterr(formatstr, PSTR("quote not valid"), n); } else if (ch == '~') { pfun('~'); tilde = false; } else if (ch >= '0' && ch <= '9') width = width*10 + ch - '0'; else if (ch == ',') comma = true; else if (ch == '%') { pln(pfun); tilde = false; } else if (ch == '&') { pfl(pfun); tilde = false; } else if (ch == '{') { if (save != NULL) formaterr(formatstr, PSTR("can't nest ~{"), n); if (args == NULL) formaterr(formatstr, noargument, n); if (!listp(first(args))) formaterr(formatstr, notalist, n); save = args; args = first(args); bra = n; tilde = false; } else if (ch == '}') { if (save == NULL) formaterr(formatstr, PSTR("no matching ~{"), n); if (args == NULL) { args = cdr(save); save = NULL; } else n = bra; tilde = false; } else if (ch2 == 'A' || ch2 == 'S' || ch2 == 'D' || ch2 == 'G' || ch2 == 'X') { if (args == NULL) formaterr(formatstr, noargument, n); object *arg = first(args); args = cdr(args); uint8_t aw = atomwidth(arg); if (width < aw) w = 0; else w = width-aw; tilde = false; if (ch2 == 'A') { prin1object(arg, pfun); indent(w, pad, pfun); } else if (ch2 == 'S') { printobject(arg, pfun); indent(w, pad, pfun); } else if (ch2 == 'D' || ch2 == 'G') { indent(w, pad, pfun); prin1object(arg, pfun); } else if (ch2 == 'X' && integerp(arg)) { uint8_t hw = hexwidth(arg); if (width < hw) w = 0; else w = width-hw; indent(w, pad, pfun); pinthex(arg->integer, pfun); } else if (ch2 == 'X') { indent(w, pad, pfun); prin1object(arg, pfun); } tilde = false; } else formaterr(formatstr, PSTR("invalid directive"), n); } else { if (ch == '~') { tilde = true; pad = ' '; width = 0; comma = false; quote = false; } else pfun(ch); } n++; } if (output == nil) { obj->cdr = GlobalString; return obj; } else return nil; } // LispLibrary object *fn_require (object *args, object *env) { object *arg = first(args); object *globals = GlobalEnv; if (!symbolp(arg)) error(REQUIRE, notasymbol, arg); while (globals != NULL) { object *pair = first(globals); object *var = car(pair); if (symbolp(var) && var == arg) return nil; globals = cdr(globals); } GlobalStringIndex = 0; object *line = read(glibrary); while (line != NULL) { // Is this the definition we want int fname = first(line)->name; if ((fname == DEFUN || fname == DEFVAR) && symbolp(second(line)) && second(line)->name == arg->name) { eval(line, env); return tee; } line = read(glibrary); } return nil; } object *fn_listlibrary (object *args, object *env) { (void) args, (void) env; GlobalStringIndex = 0; object *line = read(glibrary); while (line != NULL) { int fname = first(line)->name; if (fname == DEFUN || fname == DEFVAR) { pstring(symbolname(second(line)->name), pserial); pserial(' '); } line = read(glibrary); } return symbol(NOTHING); } // Graphics functions object *fn_drawpixel (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t colour = COLOR_WHITE; if (cddr(args) != NULL) colour = checkinteger(DRAWPIXEL, third(args)); tft.drawPixel(checkinteger(DRAWPIXEL, first(args)), checkinteger(DRAWPIXEL, second(args)), colour); return nil; #endif } object *fn_drawline (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t params[4], colour = COLOR_WHITE; for (int i=0; i<4; i++) { params[i] = checkinteger(DRAWLINE, car(args)); args = cdr(args); } if (args != NULL) colour = checkinteger(DRAWLINE, car(args)); tft.drawLine(params[0], params[1], params[2], params[3], colour); return nil; #endif } object *fn_drawrect (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t params[4], colour = COLOR_WHITE; for (int i=0; i<4; i++) { params[i] = checkinteger(DRAWRECT, car(args)); args = cdr(args); } if (args != NULL) colour = checkinteger(DRAWRECT, car(args)); tft.drawRect(params[0], params[1], params[2], params[3], colour); return nil; #endif } object *fn_fillrect (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t params[4], colour = COLOR_WHITE; for (int i=0; i<4; i++) { params[i] = checkinteger(FILLRECT, car(args)); args = cdr(args); } if (args != NULL) colour = checkinteger(FILLRECT, car(args)); tft.fillRect(params[0], params[1], params[2], params[3], colour); return nil; #endif } object *fn_drawcircle (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t params[3], colour = COLOR_WHITE; for (int i=0; i<3; i++) { params[i] = checkinteger(DRAWCIRCLE, car(args)); args = cdr(args); } if (args != NULL) colour = checkinteger(DRAWCIRCLE, car(args)); tft.drawCircle(params[0], params[1], params[2], colour); return nil; #endif } object *fn_fillcircle (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t params[3], colour = COLOR_WHITE; for (int i=0; i<3; i++) { params[i] = checkinteger(FILLCIRCLE, car(args)); args = cdr(args); } if (args != NULL) colour = checkinteger(FILLCIRCLE, car(args)); tft.fillCircle(params[0], params[1], params[2], colour); return nil; #endif } object *fn_drawroundrect (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t params[5], colour = COLOR_WHITE; for (int i=0; i<5; i++) { params[i] = checkinteger(DRAWROUNDRECT, car(args)); args = cdr(args); } if (args != NULL) colour = checkinteger(DRAWROUNDRECT, car(args)); tft.drawRoundRect(params[0], params[1], params[2], params[3], params[4], colour); return nil; #endif } object *fn_fillroundrect (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t params[5], colour = COLOR_WHITE; for (int i=0; i<5; i++) { params[i] = checkinteger(FILLROUNDRECT, car(args)); args = cdr(args); } if (args != NULL) colour = checkinteger(FILLROUNDRECT, car(args)); tft.fillRoundRect(params[0], params[1], params[2], params[3], params[4], colour); return nil; #endif } object *fn_drawtriangle (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t params[6], colour = COLOR_WHITE; for (int i=0; i<6; i++) { params[i] = checkinteger(DRAWTRIANGLE, car(args)); args = cdr(args); } if (args != NULL) colour = checkinteger(DRAWTRIANGLE, car(args)); tft.drawTriangle(params[0], params[1], params[2], params[3], params[4], params[5], colour); return nil; #endif } object *fn_filltriangle (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t params[6], colour = COLOR_WHITE; for (int i=0; i<6; i++) { params[i] = checkinteger(FILLTRIANGLE, car(args)); args = cdr(args); } if (args != NULL) colour = checkinteger(FILLTRIANGLE, car(args)); tft.fillTriangle(params[0], params[1], params[2], params[3], params[4], params[5], colour); return nil; #endif } object *fn_drawchar (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t colour = COLOR_WHITE, bg = COLOR_BLACK, size = 1; object *more = cdr(cddr(args)); if (more != NULL) { colour = checkinteger(DRAWCHAR, car(more)); more = cdr(more); if (more != NULL) { bg = checkinteger(DRAWCHAR, car(more)); more = cdr(more); if (more != NULL) size = checkinteger(DRAWCHAR, car(more)); } } tft.drawChar(checkinteger(DRAWCHAR, first(args)), checkinteger(DRAWCHAR, second(args)), checkchar(DRAWCHAR, third(args)), colour, bg, size); return nil; #endif } object *fn_setcursor (object *args, object *env) { #if defined(gfxsupport) (void) env; tft.setCursor(checkinteger(SETCURSOR, first(args)), checkinteger(SETCURSOR, second(args))); return nil; #endif } object *fn_settextcolor (object *args, object *env) { #if defined(gfxsupport) (void) env; if (cdr(args) != NULL) tft.setTextColor(checkinteger(SETTEXTCOLOR, first(args)), checkinteger(SETTEXTCOLOR, second(args))); else tft.setTextColor(checkinteger(SETTEXTCOLOR, first(args))); return nil; #endif } object *fn_settextsize (object *args, object *env) { #if defined(gfxsupport) (void) env; tft.setTextSize(checkinteger(SETTEXTSIZE, first(args))); return nil; #endif } object *fn_settextwrap (object *args, object *env) { #if defined(gfxsupport) (void) env; tft.setTextWrap(first(args) != NULL); return nil; #endif } object *fn_fillscreen (object *args, object *env) { #if defined(gfxsupport) (void) env; uint16_t colour = COLOR_BLACK; if (args != NULL) colour = checkinteger(FILLSCREEN, first(args)); tft.fillScreen(colour); return nil; #endif } object *fn_setrotation (object *args, object *env) { #if defined(gfxsupport) (void) env; tft.setRotation(checkinteger(SETROTATION, first(args))); return nil; #endif } object *fn_invertdisplay (object *args, object *env) { #if defined(gfxsupport) (void) env; tft.invertDisplay(first(args) != NULL); return nil; #endif } // Insert your own function definitions here // Built-in procedure names - stored in PROGMEM const char string0[] PROGMEM = "nil"; const char string1[] PROGMEM = "t"; const char string2[] PROGMEM = "nothing"; const char string3[] PROGMEM = "&optional"; const char string4[] PROGMEM = ":initial-element"; const char string5[] PROGMEM = "&rest"; const char string6[] PROGMEM = "lambda"; const char string7[] PROGMEM = "let"; const char string8[] PROGMEM = "let*"; const char string9[] PROGMEM = "closure"; const char string10[] PROGMEM = ""; const char string11[] PROGMEM = "quote"; const char string12[] PROGMEM = "defun"; const char string13[] PROGMEM = "defvar"; const char string14[] PROGMEM = "setq"; const char string15[] PROGMEM = "loop"; const char string16[] PROGMEM = "return"; const char string17[] PROGMEM = "push"; const char string18[] PROGMEM = "pop"; const char string19[] PROGMEM = "incf"; const char string20[] PROGMEM = "decf"; const char string21[] PROGMEM = "setf"; const char string22[] PROGMEM = "dolist"; const char string23[] PROGMEM = "dotimes"; const char string24[] PROGMEM = "trace"; const char string25[] PROGMEM = "untrace"; const char string26[] PROGMEM = "for-millis"; const char string27[] PROGMEM = "with-output-to-string"; const char string28[] PROGMEM = "with-serial"; const char string29[] PROGMEM = "with-i2c"; const char string30[] PROGMEM = "with-spi"; const char string31[] PROGMEM = "with-sd-card"; const char string32[] PROGMEM = "with-gfx"; const char string33[] PROGMEM = "defcode"; const char string34[] PROGMEM = ""; const char string35[] PROGMEM = "progn"; const char string36[] PROGMEM = "if"; const char string37[] PROGMEM = "cond"; const char string38[] PROGMEM = "when"; const char string39[] PROGMEM = "unless"; const char string40[] PROGMEM = "case"; const char string41[] PROGMEM = "and"; const char string42[] PROGMEM = "or"; const char string43[] PROGMEM = ""; const char string44[] PROGMEM = "not"; const char string45[] PROGMEM = "null"; const char string46[] PROGMEM = "cons"; const char string47[] PROGMEM = "atom"; const char string48[] PROGMEM = "listp"; const char string49[] PROGMEM = "consp"; const char string50[] PROGMEM = "symbolp"; const char string51[] PROGMEM = "arrayp"; const char string52[] PROGMEM = "boundp"; const char string53[] PROGMEM = "setfn"; const char string54[] PROGMEM = "streamp"; const char string55[] PROGMEM = "eq"; const char string56[] PROGMEM = "car"; const char string57[] PROGMEM = "first"; const char string58[] PROGMEM = "cdr"; const char string59[] PROGMEM = "rest"; const char string60[] PROGMEM = "caar"; const char string61[] PROGMEM = "cadr"; const char string62[] PROGMEM = "second"; const char string63[] PROGMEM = "cdar"; const char string64[] PROGMEM = "cddr"; const char string65[] PROGMEM = "caaar"; const char string66[] PROGMEM = "caadr"; const char string67[] PROGMEM = "cadar"; const char string68[] PROGMEM = "caddr"; const char string69[] PROGMEM = "third"; const char string70[] PROGMEM = "cdaar"; const char string71[] PROGMEM = "cdadr"; const char string72[] PROGMEM = "cddar"; const char string73[] PROGMEM = "cdddr"; const char string74[] PROGMEM = "length"; const char string75[] PROGMEM = "array-dimensions"; const char string76[] PROGMEM = "list"; const char string77[] PROGMEM = "make-array"; const char string78[] PROGMEM = "reverse"; const char string79[] PROGMEM = "nth"; const char string80[] PROGMEM = "aref"; const char string81[] PROGMEM = "assoc"; const char string82[] PROGMEM = "member"; const char string83[] PROGMEM = "apply"; const char string84[] PROGMEM = "funcall"; const char string85[] PROGMEM = "append"; const char string86[] PROGMEM = "mapc"; const char string87[] PROGMEM = "mapcar"; const char string88[] PROGMEM = "mapcan"; const char string89[] PROGMEM = "+"; const char string90[] PROGMEM = "-"; const char string91[] PROGMEM = "*"; const char string92[] PROGMEM = "/"; const char string93[] PROGMEM = "mod"; const char string94[] PROGMEM = "1+"; const char string95[] PROGMEM = "1-"; const char string96[] PROGMEM = "abs"; const char string97[] PROGMEM = "random"; const char string98[] PROGMEM = "max"; const char string99[] PROGMEM = "min"; const char string100[] PROGMEM = "/="; const char string101[] PROGMEM = "="; const char string102[] PROGMEM = "<"; const char string103[] PROGMEM = "<="; const char string104[] PROGMEM = ">"; const char string105[] PROGMEM = ">="; const char string106[] PROGMEM = "plusp"; const char string107[] PROGMEM = "minusp"; const char string108[] PROGMEM = "zerop"; const char string109[] PROGMEM = "oddp"; const char string110[] PROGMEM = "evenp"; const char string111[] PROGMEM = "integerp"; const char string112[] PROGMEM = "numberp"; const char string113[] PROGMEM = "float"; const char string114[] PROGMEM = "floatp"; const char string115[] PROGMEM = "sin"; const char string116[] PROGMEM = "cos"; const char string117[] PROGMEM = "tan"; const char string118[] PROGMEM = "asin"; const char string119[] PROGMEM = "acos"; const char string120[] PROGMEM = "atan"; const char string121[] PROGMEM = "sinh"; const char string122[] PROGMEM = "cosh"; const char string123[] PROGMEM = "tanh"; const char string124[] PROGMEM = "exp"; const char string125[] PROGMEM = "sqrt"; const char string126[] PROGMEM = "log"; const char string127[] PROGMEM = "expt"; const char string128[] PROGMEM = "ceiling"; const char string129[] PROGMEM = "floor"; const char string130[] PROGMEM = "truncate"; const char string131[] PROGMEM = "round"; const char string132[] PROGMEM = "char"; const char string133[] PROGMEM = "char-code"; const char string134[] PROGMEM = "code-char"; const char string135[] PROGMEM = "characterp"; const char string136[] PROGMEM = "stringp"; const char string137[] PROGMEM = "string="; const char string138[] PROGMEM = "string<"; const char string139[] PROGMEM = "string>"; const char string140[] PROGMEM = "sort"; const char string141[] PROGMEM = "string"; const char string142[] PROGMEM = "concatenate"; const char string143[] PROGMEM = "subseq"; const char string144[] PROGMEM = "read-from-string"; const char string145[] PROGMEM = "princ-to-string"; const char string146[] PROGMEM = "prin1-to-string"; const char string147[] PROGMEM = "logand"; const char string148[] PROGMEM = "logior"; const char string149[] PROGMEM = "logxor"; const char string150[] PROGMEM = "lognot"; const char string151[] PROGMEM = "ash"; const char string152[] PROGMEM = "logbitp"; const char string153[] PROGMEM = "eval"; const char string154[] PROGMEM = "globals"; const char string155[] PROGMEM = "locals"; const char string156[] PROGMEM = "makunbound"; const char string157[] PROGMEM = "break"; const char string158[] PROGMEM = "read"; const char string159[] PROGMEM = "prin1"; const char string160[] PROGMEM = "print"; const char string161[] PROGMEM = "princ"; const char string162[] PROGMEM = "terpri"; const char string163[] PROGMEM = "read-byte"; const char string164[] PROGMEM = "read-line"; const char string165[] PROGMEM = "write-byte"; const char string166[] PROGMEM = "write-string"; const char string167[] PROGMEM = "write-line"; const char string168[] PROGMEM = "restart-i2c"; const char string169[] PROGMEM = "gc"; const char string170[] PROGMEM = "room"; const char string171[] PROGMEM = "save-image"; const char string172[] PROGMEM = "load-image"; const char string173[] PROGMEM = "cls"; const char string174[] PROGMEM = "pinmode"; const char string175[] PROGMEM = "digitalread"; const char string176[] PROGMEM = "digitalwrite"; const char string177[] PROGMEM = "analogread"; const char string178[] PROGMEM = "analogwrite"; const char string179[] PROGMEM = "delay"; const char string180[] PROGMEM = "millis"; const char string181[] PROGMEM = "sleep"; const char string182[] PROGMEM = "note"; const char string183[] PROGMEM = "edit"; const char string184[] PROGMEM = "pprint"; const char string185[] PROGMEM = "pprintall"; const char string186[] PROGMEM = "format"; const char string187[] PROGMEM = "require"; const char string188[] PROGMEM = "list-library"; const char string189[] PROGMEM = "draw-pixel"; const char string190[] PROGMEM = "draw-line"; const char string191[] PROGMEM = "draw-rect"; const char string192[] PROGMEM = "fill-rect"; const char string193[] PROGMEM = "draw-circle"; const char string194[] PROGMEM = "fill-circle"; const char string195[] PROGMEM = "draw-round-rect"; const char string196[] PROGMEM = "fill-round-rect"; const char string197[] PROGMEM = "draw-triangle"; const char string198[] PROGMEM = "fill-triangle"; const char string199[] PROGMEM = "draw-char"; const char string200[] PROGMEM = "set-cursor"; const char string201[] PROGMEM = "set-text-color"; const char string202[] PROGMEM = "set-text-size"; const char string203[] PROGMEM = "set-text-wrap"; const char string204[] PROGMEM = "fill-screen"; const char string205[] PROGMEM = "set-rotation"; const char string206[] PROGMEM = "invert-display"; // Third parameter is no. of arguments; 1st hex digit is min, 2nd hex digit is max, 0xF is unlimited const tbl_entry_t lookup_table[] PROGMEM = { { string0, NULL, 0x00 }, { string1, NULL, 0x00 }, { string2, NULL, 0x00 }, { string3, NULL, 0x00 }, { string4, NULL, 0x00 }, { string5, NULL, 0x00 }, { string6, NULL, 0x0F }, { string7, NULL, 0x0F }, { string8, NULL, 0x0F }, { string9, NULL, 0x0F }, { string10, NULL, 0x00 }, { string11, sp_quote, 0x11 }, { string12, sp_defun, 0x2F }, { string13, sp_defvar, 0x12 }, { string14, sp_setq, 0x2F }, { string15, sp_loop, 0x0F }, { string16, sp_return, 0x0F }, { string17, sp_push, 0x22 }, { string18, sp_pop, 0x11 }, { string19, sp_incf, 0x12 }, { string20, sp_decf, 0x12 }, { string21, sp_setf, 0x2F }, { string22, sp_dolist, 0x1F }, { string23, sp_dotimes, 0x1F }, { string24, sp_trace, 0x01 }, { string25, sp_untrace, 0x01 }, { string26, sp_formillis, 0x1F }, { string27, sp_withoutputtostring, 0x1F }, { string28, sp_withserial, 0x1F }, { string29, sp_withi2c, 0x1F }, { string30, sp_withspi, 0x1F }, { string31, sp_withsdcard, 0x2F }, { string32, sp_withgfx, 0x1F }, { string33, sp_defcode, 0x0F }, { string34, NULL, 0x00 }, { string35, tf_progn, 0x0F }, { string36, tf_if, 0x23 }, { string37, tf_cond, 0x0F }, { string38, tf_when, 0x1F }, { string39, tf_unless, 0x1F }, { string40, tf_case, 0x1F }, { string41, tf_and, 0x0F }, { string42, tf_or, 0x0F }, { string43, NULL, 0x00 }, { string44, fn_not, 0x11 }, { string45, fn_not, 0x11 }, { string46, fn_cons, 0x22 }, { string47, fn_atom, 0x11 }, { string48, fn_listp, 0x11 }, { string49, fn_consp, 0x11 }, { string50, fn_symbolp, 0x11 }, { string51, fn_arrayp, 0x11 }, { string52, fn_boundp, 0x11 }, { string53, fn_setfn, 0x2F }, { string54, fn_streamp, 0x11 }, { string55, fn_eq, 0x22 }, { string56, fn_car, 0x11 }, { string57, fn_car, 0x11 }, { string58, fn_cdr, 0x11 }, { string59, fn_cdr, 0x11 }, { string60, fn_caar, 0x11 }, { string61, fn_cadr, 0x11 }, { string62, fn_cadr, 0x11 }, { string63, fn_cdar, 0x11 }, { string64, fn_cddr, 0x11 }, { string65, fn_caaar, 0x11 }, { string66, fn_caadr, 0x11 }, { string67, fn_cadar, 0x11 }, { string68, fn_caddr, 0x11 }, { string69, fn_caddr, 0x11 }, { string70, fn_cdaar, 0x11 }, { string71, fn_cdadr, 0x11 }, { string72, fn_cddar, 0x11 }, { string73, fn_cdddr, 0x11 }, { string74, fn_length, 0x11 }, { string75, fn_arraydimensions, 0x11 }, { string76, fn_list, 0x0F }, { string77, fn_makearray, 0x13 }, { string78, fn_reverse, 0x11 }, { string79, fn_nth, 0x22 }, { string80, fn_aref, 0x2F }, { string81, fn_assoc, 0x22 }, { string82, fn_member, 0x22 }, { string83, fn_apply, 0x2F }, { string84, fn_funcall, 0x1F }, { string85, fn_append, 0x0F }, { string86, fn_mapc, 0x2F }, { string87, fn_mapcar, 0x2F }, { string88, fn_mapcan, 0x2F }, { string89, fn_add, 0x0F }, { string90, fn_subtract, 0x1F }, { string91, fn_multiply, 0x0F }, { string92, fn_divide, 0x1F }, { string93, fn_mod, 0x22 }, { string94, fn_oneplus, 0x11 }, { string95, fn_oneminus, 0x11 }, { string96, fn_abs, 0x11 }, { string97, fn_random, 0x11 }, { string98, fn_maxfn, 0x1F }, { string99, fn_minfn, 0x1F }, { string100, fn_noteq, 0x1F }, { string101, fn_numeq, 0x1F }, { string102, fn_less, 0x1F }, { string103, fn_lesseq, 0x1F }, { string104, fn_greater, 0x1F }, { string105, fn_greatereq, 0x1F }, { string106, fn_plusp, 0x11 }, { string107, fn_minusp, 0x11 }, { string108, fn_zerop, 0x11 }, { string109, fn_oddp, 0x11 }, { string110, fn_evenp, 0x11 }, { string111, fn_integerp, 0x11 }, { string112, fn_numberp, 0x11 }, { string113, fn_floatfn, 0x11 }, { string114, fn_floatp, 0x11 }, { string115, fn_sin, 0x11 }, { string116, fn_cos, 0x11 }, { string117, fn_tan, 0x11 }, { string118, fn_asin, 0x11 }, { string119, fn_acos, 0x11 }, { string120, fn_atan, 0x12 }, { string121, fn_sinh, 0x11 }, { string122, fn_cosh, 0x11 }, { string123, fn_tanh, 0x11 }, { string124, fn_exp, 0x11 }, { string125, fn_sqrt, 0x11 }, { string126, fn_log, 0x12 }, { string127, fn_expt, 0x22 }, { string128, fn_ceiling, 0x12 }, { string129, fn_floor, 0x12 }, { string130, fn_truncate, 0x12 }, { string131, fn_round, 0x12 }, { string132, fn_char, 0x22 }, { string133, fn_charcode, 0x11 }, { string134, fn_codechar, 0x11 }, { string135, fn_characterp, 0x11 }, { string136, fn_stringp, 0x11 }, { string137, fn_stringeq, 0x22 }, { string138, fn_stringless, 0x22 }, { string139, fn_stringgreater, 0x22 }, { string140, fn_sort, 0x22 }, { string141, fn_stringfn, 0x11 }, { string142, fn_concatenate, 0x1F }, { string143, fn_subseq, 0x23 }, { string144, fn_readfromstring, 0x11 }, { string145, fn_princtostring, 0x11 }, { string146, fn_prin1tostring, 0x11 }, { string147, fn_logand, 0x0F }, { string148, fn_logior, 0x0F }, { string149, fn_logxor, 0x0F }, { string150, fn_lognot, 0x11 }, { string151, fn_ash, 0x22 }, { string152, fn_logbitp, 0x22 }, { string153, fn_eval, 0x11 }, { string154, fn_globals, 0x00 }, { string155, fn_locals, 0x00 }, { string156, fn_makunbound, 0x11 }, { string157, fn_break, 0x00 }, { string158, fn_read, 0x01 }, { string159, fn_prin1, 0x12 }, { string160, fn_print, 0x12 }, { string161, fn_princ, 0x12 }, { string162, fn_terpri, 0x01 }, { string163, fn_readbyte, 0x02 }, { string164, fn_readline, 0x01 }, { string165, fn_writebyte, 0x12 }, { string166, fn_writestring, 0x12 }, { string167, fn_writeline, 0x12 }, { string168, fn_restarti2c, 0x12 }, { string169, fn_gc, 0x00 }, { string170, fn_room, 0x00 }, { string171, fn_saveimage, 0x01 }, { string172, fn_loadimage, 0x01 }, { string173, fn_cls, 0x00 }, { string174, fn_pinmode, 0x22 }, { string175, fn_digitalread, 0x11 }, { string176, fn_digitalwrite, 0x22 }, { string177, fn_analogread, 0x11 }, { string178, fn_analogwrite, 0x22 }, { string179, fn_delay, 0x11 }, { string180, fn_millis, 0x00 }, { string181, fn_sleep, 0x11 }, { string182, fn_note, 0x03 }, { string183, fn_edit, 0x11 }, { string184, fn_pprint, 0x12 }, { string185, fn_pprintall, 0x01 }, { string186, fn_format, 0x2F }, { string187, fn_require, 0x11 }, { string188, fn_listlibrary, 0x00 }, { string189, fn_drawpixel, 0x23 }, { string190, fn_drawline, 0x45 }, { string191, fn_drawrect, 0x45 }, { string192, fn_fillrect, 0x45 }, { string193, fn_drawcircle, 0x34 }, { string194, fn_fillcircle, 0x34 }, { string195, fn_drawroundrect, 0x56 }, { string196, fn_fillroundrect, 0x56 }, { string197, fn_drawtriangle, 0x67 }, { string198, fn_filltriangle, 0x67 }, { string199, fn_drawchar, 0x36 }, { string200, fn_setcursor, 0x22 }, { string201, fn_settextcolor, 0x12 }, { string202, fn_settextsize, 0x11 }, { string203, fn_settextwrap, 0x11 }, { string204, fn_fillscreen, 0x01 }, { string205, fn_setrotation, 0x11 }, { string206, fn_invertdisplay, 0x11 }, }; // Table lookup functions int builtin (char* n) { int entry = 0; while (entry < ENDFUNCTIONS) { if (strcasecmp(n, (char*)lookup_table[entry].string) == 0) return entry; entry++; } return ENDFUNCTIONS; } int longsymbol (char *buffer) { char *p = SymbolTable; int i = 0; while (strcasecmp(p, buffer) != 0) {p = p + strlen(p) + 1; i++; } if (p == buffer) { // Add to symbol table? char *newtop = SymbolTop + strlen(p) + 1; if (SYMBOLTABLESIZE - (newtop - SymbolTable) < BUFFERSIZE) error2(0, PSTR("symbol table full")); SymbolTop = newtop; } return i + MAXSYMBOL; // First number unused by radix40 } intptr_t lookupfn (symbol_t name) { return (intptr_t)lookup_table[name].fptr; } void checkminmax (symbol_t name, int nargs) { uint8_t minmax = lookup_table[name].minmax; if (nargs<(minmax >> 4)) error2(name, toofewargs); if ((minmax & 0x0f) != 0x0f && nargs>(minmax & 0x0f)) error2(name, toomanyargs); } char *lookupbuiltin (symbol_t name) { char *buffer = SymbolTop; strcpy(buffer, (char *)lookup_table[name].string); return buffer; } char *lookupsymbol (symbol_t name) { char *p = SymbolTable; int i = name - MAXSYMBOL; while (i > 0 && p < SymbolTop) {p = p + strlen(p) + 1; i--; } if (p == SymbolTop) return NULL; else return p; } void deletesymbol (symbol_t name) { char *p = lookupsymbol(name); if (p == NULL) return; char *q = p + strlen(p) + 1; *p = '\0'; p++; while (q < SymbolTop) *(p++) = *(q++); SymbolTop = p; } void testescape () { if (Serial.read() == '~') error2(0, PSTR("escape!")); } // Main evaluator extern uint32_t end; // Bottom of stack object *eval (object *form, object *env) { register int *sp asm ("r13"); int TC=0; EVAL: // Enough space? // Serial.println((uint32_t)sp - (uint32_t)&end); if (((uint32_t)sp - (uint32_t)&end) < STACKDIFF) error2(0, PSTR("Stack overflow")); if (Freespace <= WORKSPACESIZE>>4) gc(form, env); // Escape if (tstflag(ESCAPE)) { clrflag(ESCAPE); error2(0, PSTR("Escape!"));} if (!tstflag(NOESC)) testescape(); if (form == NULL) return nil; if (form->type >= NUMBER && form->type <= STRING) return form; if (symbolp(form)) { symbol_t name = form->name; object *pair = value(name, env); if (pair != NULL) return cdr(pair); pair = value(name, GlobalEnv); if (pair != NULL) return cdr(pair); else if (name <= ENDFUNCTIONS) return form; error(0, PSTR("undefined"), form); } if (form->type == CODE) error2(0, PSTR("can't evaluate CODE header")); // It's a list object *function = car(form); object *args = cdr(form); if (function == NULL) error(0, PSTR("illegal function"), nil); if (!listp(args)) error(0, PSTR("can't evaluate a dotted pair"), args); // List starts with a symbol? if (symbolp(function)) { symbol_t name = function->name; if ((name == LET) || (name == LETSTAR)) { int TCstart = TC; object *assigns = first(args); if (!listp(assigns)) error(name, PSTR("first argument is not a list"), assigns); object *forms = cdr(args); object *newenv = env; push(newenv, GCStack); while (assigns != NULL) { object *assign = car(assigns); if (!consp(assign)) push(cons(assign,nil), newenv); else if (cdr(assign) == NULL) push(cons(first(assign),nil), newenv); else push(cons(first(assign),eval(second(assign),env)), newenv); car(GCStack) = newenv; if (name == LETSTAR) env = newenv; assigns = cdr(assigns); } env = newenv; pop(GCStack); form = tf_progn(forms,env); TC = TCstart; goto EVAL; } if (name == LAMBDA) { if (env == NULL) return form; object *envcopy = NULL; while (env != NULL) { object *pair = first(env); if (pair != NULL) push(pair, envcopy); env = cdr(env); } return cons(symbol(CLOSURE), cons(envcopy,args)); } if ((name > SPECIAL_FORMS) && (name < TAIL_FORMS)) { return ((fn_ptr_type)lookupfn(name))(args, env); } if ((name > TAIL_FORMS) && (name < FUNCTIONS)) { form = ((fn_ptr_type)lookupfn(name))(args, env); TC = 1; goto EVAL; } if (name < SPECIAL_FORMS) error2((uintptr_t)function, PSTR("can't be used as a function")); } // Evaluate the parameters - result in head object *fname = car(form); int TCstart = TC; object *head = cons(eval(fname, env), NULL); push(head, GCStack); // Don't GC the result list object *tail = head; form = cdr(form); int nargs = 0; while (form != NULL){ object *obj = cons(eval(car(form),env),NULL); cdr(tail) = obj; tail = obj; form = cdr(form); nargs++; } function = car(head); args = cdr(head); if (symbolp(function)) { symbol_t name = function->name; if (name >= ENDFUNCTIONS) error(0, PSTR("not valid here"), fname); checkminmax(name, nargs); object *result = ((fn_ptr_type)lookupfn(name))(args, env); pop(GCStack); return result; } if (consp(function)) { if (issymbol(car(function), LAMBDA)) { form = closure(TCstart, fname->name, NULL, cdr(function), args, &env); pop(GCStack); int trace = tracing(fname->name); if (trace) { object *result = eval(form, env); indent((--(TraceDepth[trace-1]))<<1, ' ', pserial); pint(TraceDepth[trace-1], pserial); pserial(':'); pserial(' '); printobject(fname, pserial); pfstring(PSTR(" returned "), pserial); printobject(result, pserial); pln(pserial); return result; } else { TC = 1; goto EVAL; } } if (issymbol(car(function), CLOSURE)) { function = cdr(function); form = closure(TCstart, fname->name, car(function), cdr(function), args, &env); pop(GCStack); TC = 1; goto EVAL; } if (car(function)->type == CODE) { int n = listlength(DEFCODE, second(function)); if (nargsname, toofewargs); if (nargs>n) error2(fname->name, toomanyargs); uint32_t entry = startblock(car(function)) + 1; pop(GCStack); return call(entry, n, args, env); } } error(0, PSTR("illegal function"), fname); return nil; } // Print functions inline int maxbuffer (char *buffer) { return SYMBOLTABLESIZE-(buffer-SymbolTable)-1; } void pserial (char c) { LastPrint = c; if (c == '\n') Serial.write('\r'); Serial.write(c); } const char ControlCodes[] PROGMEM = "Null\0SOH\0STX\0ETX\0EOT\0ENQ\0ACK\0Bell\0Backspace\0Tab\0Newline\0VT\0" "Page\0Return\0SO\0SI\0DLE\0DC1\0DC2\0DC3\0DC4\0NAK\0SYN\0ETB\0CAN\0EM\0SUB\0Escape\0FS\0GS\0RS\0US\0Space\0"; void pcharacter (char c, pfun_t pfun) { if (!tstflag(PRINTREADABLY)) pfun(c); else { pfun('#'); pfun('\\'); if (c > 32) pfun(c); else { const char *p = ControlCodes; while (c > 0) {p = p + strlen(p) + 1; c--; } pfstring(p, pfun); } } } void pstring (char *s, pfun_t pfun) { while (*s) pfun(*s++); } void printstring (object *form, pfun_t pfun) { if (tstflag(PRINTREADABLY)) pfun('"'); form = cdr(form); while (form != NULL) { int chars = form->chars; for (int i=(sizeof(int)-1)*8; i>=0; i=i-8) { char ch = chars>>i & 0xFF; if (tstflag(PRINTREADABLY) && (ch == '"' || ch == '\\')) pfun('\\'); if (ch) pfun(ch); } form = car(form); } if (tstflag(PRINTREADABLY)) pfun('"'); } void pfstring (const char *s, pfun_t pfun) { int p = 0; while (1) { char c = s[p++]; if (c == 0) return; pfun(c); } } void pint (int i, pfun_t pfun) { int lead = 0; #if INT_MAX == 32767 int p = 10000; #else int p = 1000000000; #endif if (i<0) pfun('-'); for (int d=p; d>0; d=d/10) { int j = i/d; if (j!=0 || lead || d==1) { pfun(abs(j)+'0'); lead=1;} i = i - j*d; } } void pinthex (uint32_t i, pfun_t pfun) { int lead = 0; #if INT_MAX == 32767 uint32_t p = 0x1000; #else uint32_t p = 0x10000000; #endif for (uint32_t d=p; d>0; d=d/16) { uint32_t j = i/d; if (j!=0 || lead || d==1) { pfun((j<10) ? j+'0' : j+'W'); lead=1;} i = i - j*d; } } void printhex4 (int i, pfun_t pfun) { int p = 0x1000; for (int d=p; d>0; d=d/16) { int j = i/d; pfun((j<10) ? j+'0' : j + 'W'); i = i - j*d; } pfun(' '); } void pmantissa (float f, pfun_t pfun) { int sig = floor(log10(f)); int mul = pow(10, 5 - sig); int i = round(f * mul); bool point = false; if (i == 1000000) { i = 100000; sig++; } if (sig < 0) { pfun('0'); pfun('.'); point = true; for (int j=0; j < - sig - 1; j++) pfun('0'); } mul = 100000; for (int j=0; j<7; j++) { int d = (int)(i / mul); pfun(d + '0'); i = i - d * mul; if (i == 0) { if (!point) { for (int k=j; k= 0) { pfun('.'); point = true; } mul = mul / 10; } } void pfloat (float f, pfun_t pfun) { if (isnan(f)) { pfstring(PSTR("NaN"), pfun); return; } if (f == 0.0) { pfun('0'); return; } if (isinf(f)) { pfstring(PSTR("Inf"), pfun); return; } if (f < 0) { pfun('-'); f = -f; } // Calculate exponent int e = 0; if (f < 1e-3 || f >= 1e5) { e = floor(log(f) / 2.302585); // log10 gives wrong result f = f / pow(10, e); } pmantissa (f, pfun); // Exponent if (e != 0) { pfun('e'); pint(e, pfun); } } inline void pln (pfun_t pfun) { pfun('\n'); } void pfl (pfun_t pfun) { if (LastPrint != '\n') pfun('\n'); } void printobject (object *form, pfun_t pfun) { if (form == NULL) pfstring(PSTR("nil"), pfun); else if (listp(form) && issymbol(car(form), CLOSURE)) pfstring(PSTR(""), pfun); else if (listp(form)) { pfun('('); printobject(car(form), pfun); form = cdr(form); while (form != NULL && listp(form)) { pfun(' '); printobject(car(form), pfun); form = cdr(form); } if (form != NULL) { pfstring(PSTR(" . "), pfun); printobject(form, pfun); } pfun(')'); } else if (integerp(form)) pint(form->integer, pfun); else if (floatp(form)) pfloat(form->single_float, pfun); else if (symbolp(form)) { if (form->name != NOTHING) pstring(symbolname(form->name), pfun); } else if (characterp(form)) pcharacter(form->chars, pfun); else if (stringp(form)) printstring(form, pfun); else if (arrayp(form)) printarray(form, pfun); else if (form->type == CODE) pfstring(PSTR("code"), pfun); else if (streamp(form)) { pfun('<'); if ((form->integer)>>8 == SPISTREAM) pfstring(PSTR("spi"), pfun); else if ((form->integer)>>8 == I2CSTREAM) pfstring(PSTR("i2c"), pfun); else if ((form->integer)>>8 == SDSTREAM) pfstring(PSTR("sd"), pfun); else pfstring(PSTR("serial"), pfun); pfstring(PSTR("-stream "), pfun); pint(form->integer & 0xFF, pfun); pfun('>'); } else error2(0, PSTR("Error in print")); } void prin1object (object *form, pfun_t pfun) { char temp = Flags; clrflag(PRINTREADABLY); printobject(form, pfun); Flags = temp; } // Read functions int glibrary () { if (LastChar) { char temp = LastChar; LastChar = 0; return temp; } char c = LispLibrary[GlobalStringIndex++]; return (c != 0) ? c : -1; // -1? } void loadfromlibrary (object *env) { GlobalStringIndex = 0; object *line = read(glibrary); while (line != NULL) { eval(line, env); line = read(glibrary); } } // For line editor const int TerminalWidth = 80; volatile int WritePtr = 0, ReadPtr = 0; const int KybdBufSize = 333; // 42*8 - 3 char KybdBuf[KybdBufSize]; volatile uint8_t KybdAvailable = 0; // Parenthesis highlighting void esc (int p, char c) { Serial.write('\e'); Serial.write('['); Serial.write((char)('0'+ p/100)); Serial.write((char)('0'+ (p/10) % 10)); Serial.write((char)('0'+ p % 10)); Serial.write(c); } void hilight (char c) { Serial.write('\e'); Serial.write('['); Serial.write(c); Serial.write('m'); } void Highlight (int p, int wp, uint8_t invert) { wp = wp + 2; // Prompt #if defined (printfreespace) int f = Freespace; while (f) { wp++; f=f/10; } #endif int line = wp/TerminalWidth; int col = wp%TerminalWidth; int targetline = (wp - p)/TerminalWidth; int targetcol = (wp - p)%TerminalWidth; int up = line-targetline, left = col-targetcol; if (p) { if (up) esc(up, 'A'); if (col > targetcol) esc(left, 'D'); else esc(-left, 'C'); if (invert) hilight('7'); Serial.write('('); Serial.write('\b'); // Go back if (up) esc(up, 'B'); // Down if (col > targetcol) esc(left, 'C'); else esc(-left, 'D'); Serial.write('\b'); Serial.write(')'); if (invert) hilight('0'); } } void processkey (char c) { if (c == 27) { setflag(ESCAPE); return; } // Escape key #if defined(vt100) static int parenthesis = 0, wp = 0; // Undo previous parenthesis highlight Highlight(parenthesis, wp, 0); parenthesis = 0; #endif // Edit buffer if (c == '\n' || c == '\r') { pserial('\n'); KybdAvailable = 1; ReadPtr = 0; return; } if (c == 8 || c == 0x7f) { // Backspace key if (WritePtr > 0) { WritePtr--; Serial.write(8); Serial.write(' '); Serial.write(8); if (WritePtr) c = KybdBuf[WritePtr-1]; } } else if (WritePtr < KybdBufSize) { KybdBuf[WritePtr++] = c; Serial.write(c); } #if defined(vt100) // Do new parenthesis highlight if (c == ')') { int search = WritePtr-1, level = 0; while (search >= 0 && parenthesis == 0) { c = KybdBuf[search--]; if (c == ')') level++; if (c == '(') { level--; if (level == 0) {parenthesis = WritePtr-search-1; wp = WritePtr; } } } Highlight(parenthesis, wp, 1); } #endif return; } int gserial () { if (LastChar) { char temp = LastChar; LastChar = 0; return temp; } #if defined(lineeditor) while (!KybdAvailable) { while (!Serial.available()); char temp = Serial.read(); processkey(temp); } if (ReadPtr != WritePtr) return KybdBuf[ReadPtr++]; KybdAvailable = 0; WritePtr = 0; return '\n'; #else while (!Serial.available()); char temp = Serial.read(); if (temp != '\n') pserial(temp); return temp; #endif } #define issp(x) (x == ' ' || x == '\n' || x == '\r' || x == '\t') object *nextitem (gfun_t gfun) { int ch = gfun(); while(issp(ch)) ch = gfun(); if (ch == ';') { while(ch != '(') ch = gfun(); ch = '('; } if (ch == '\n') ch = gfun(); if (ch == -1) return nil; if (ch == ')') return (object *)KET; if (ch == '(') return (object *)BRA; if (ch == '\'') return (object *)QUO; // Parse string if (ch == '"') return readstring('"', gfun); // Parse symbol, character, or number int index = 0, base = 10, sign = 1; char *buffer = SymbolTop; int bufmax = maxbuffer(buffer); // Max index unsigned int result = 0; bool isfloat = false; float fresult = 0.0; if (ch == '+') { buffer[index++] = ch; ch = gfun(); } else if (ch == '-') { sign = -1; buffer[index++] = ch; ch = gfun(); } else if (ch == '.') { buffer[index++] = ch; ch = gfun(); if (ch == ' ') return (object *)DOT; isfloat = true; } // Parse reader macros else if (ch == '#') { ch = gfun(); char ch2 = ch & ~0x20; // force to upper case if (ch == '\\') { // Character base = 0; ch = gfun(); if (issp(ch) || ch == ')' || ch == '(') return character(ch); else LastChar = ch; } else if (ch == '|') { do { while (gfun() != '|'); } while (gfun() != '#'); return nextitem(gfun); } else if (ch2 == 'B') base = 2; else if (ch2 == 'O') base = 8; else if (ch2 == 'X') base = 16; else if (ch == '\'') return nextitem(gfun); else if (ch == '.') { setflag(NOESC); object *result = eval(read(gfun), NULL); clrflag(NOESC); return result; } else if (ch == '(') { LastChar = ch; return readarray(1, read(gfun)); } else if (ch >= '1' && ch <= '9' && (gfun() & ~0x20) == 'A') return readarray(ch - '0', read(gfun)); else error2(0, PSTR("illegal character after #")); ch = gfun(); } int valid; // 0=undecided, -1=invalid, +1=valid if (ch == '.') valid = 0; else if (digitvalue(ch) ((unsigned int)INT_MAX+(1-sign)/2)) return makefloat((float)result*sign); return number(result*sign); } else if (base == 0) { if (index == 1) return character(buffer[0]); const char* p = ControlCodes; char c = 0; while (c < 33) { if (strcasecmp(buffer, p) == 0) return character(c); p = p + strlen(p) + 1; c++; } error2(0, PSTR("unknown character")); } int x = builtin(buffer); if (x == NIL) return nil; if (x < ENDFUNCTIONS) return newsymbol(x); else if (index <= 6 && valid40(buffer)) return newsymbol(pack40(buffer)); else return newsymbol(longsymbol(buffer)); } object *readrest (gfun_t gfun) { object *item = nextitem(gfun); object *head = NULL; object *tail = NULL; while (item != (object *)KET) { if (item == (object *)BRA) { item = readrest(gfun); } else if (item == (object *)QUO) { item = cons(symbol(QUOTE), cons(read(gfun), NULL)); } else if (item == (object *)DOT) { tail->cdr = read(gfun); if (readrest(gfun) != NULL) error2(0, PSTR("malformed list")); return head; } else { object *cell = cons(item, NULL); if (head == NULL) head = cell; else tail->cdr = cell; tail = cell; item = nextitem(gfun); } } return head; } object *read (gfun_t gfun) { object *item = nextitem(gfun); if (item == (object *)KET) error2(0, PSTR("incomplete list")); if (item == (object *)BRA) return readrest(gfun); if (item == (object *)DOT) return read(gfun); if (item == (object *)QUO) return cons(symbol(QUOTE), cons(read(gfun), NULL)); return item; } // Setup void initgfx () { #if defined(gfxsupport) tft.initR(INITR_BLACKTAB); tft.setRotation(1); pinMode(TFT_BACKLIGHT, OUTPUT); digitalWrite(TFT_BACKLIGHT, HIGH); tft.fillScreen(ST77XX_BLACK); #endif } void initenv () { GlobalEnv = NULL; tee = symbol(TEE); } void setup () { Serial.begin(9600); int start = millis(); while ((millis() - start) < 5000) { if (Serial) break; } initworkspace(); initenv(); initsleep(); initgfx(); pfstring(PSTR("uLisp 3.2 "), pserial); pln(pserial); } // Read/Evaluate/Print loop void repl (object *env) { for (;;) { randomSeed(micros()); gc(NULL, env); #if defined (printfreespace) pint(Freespace, pserial); #endif if (BreakLevel) { pfstring(PSTR(" : "), pserial); pint(BreakLevel, pserial); } pfstring(PSTR("> "), pserial); object *line = read(gserial); if (BreakLevel && line == nil) { pln(pserial); return; } if (line == (object *)KET) error2(0, PSTR("unmatched right bracket")); push(line, GCStack); pfl(pserial); line = eval(line, env); pfl(pserial); printobject(line, pserial); pop(GCStack); pfl(pserial); pln(pserial); } } void loop () { if (!setjmp(exception)) { #if defined(resetautorun) volatile int autorun = 12; // Fudge to keep code size the same #else volatile int autorun = 13; #endif if (autorun == 12) autorunimage(); } // Come here after error delay(100); while (Serial.available()) Serial.read(); clrflag(NOESC); for (int i=0; i