#include #include #include #include "gc.h" #include "vstring.h" #include "value.h" #include "buffer.h" /* Print the bytecode for a FuncDef */ static void FuncDefBytecodePrint(FuncDef * def) { uint32_t count, i; count = def->byteCodeLen; printf("(bytecode)["); if (count) { for (i = 0; i < count - 1; ++i) { printf("%04x ", def->byteCode[i]); } printf("%04x", def->byteCode[i]); } printf("]"); } /* Print a value recursively. Used for debugging */ void ValuePrint(Value * x, uint32_t indent) { uint32_t i; for (i = 0; i < indent; ++i) fputc(' ', stdout); switch (x->type) { case TYPE_NIL: printf(""); break; case TYPE_BOOLEAN: printf(x->data.boolean ? "" : ""); break; case TYPE_NUMBER: printf("%f", x->data.number); break; case TYPE_FORM: case TYPE_ARRAY: if (x->type == TYPE_ARRAY) printf(" [\n"); else printf(" (\n"); for (i = 0; i < x->data.array->count; ++i) { ValuePrint(x->data.array->data + i, indent + 4); printf("\n"); } for (i = 0; i < indent; ++i) fputc(' ', stdout); if (x->type == TYPE_ARRAY) printf(" ]\n"); else printf(" )\n"); break; case TYPE_STRING: printf("\"%.*s\"", VStringSize(x->data.string), (char *) x->data.string); break; case TYPE_SYMBOL: printf("%.*s", VStringSize(x->data.string), (char *) x->data.string); break; case TYPE_CFUNCTION: printf(""); break; case TYPE_FUNCTION: printf("data.func->def); printf(">"); break; case TYPE_DICTIONARY: printf(""); break; case TYPE_BYTEBUFFER: printf(""); break; case TYPE_FUNCDEF: printf("data.funcdef); printf(">"); break; case TYPE_FUNCENV: printf(""); break; case TYPE_THREAD: printf(""); break; } } static uint8_t * LoadCString(GC * gc, const char * string, uint32_t len) { uint8_t * data = GCAlloc(gc, len + 2 * sizeof(uint32_t)); data += 2 * sizeof(uint32_t); VStringHash(data) = 0; VStringSize(data) = len; memcpy(data, string, len); return data; } Value ValueLoadCString(GC * gc, const char * string) { Value ret; ret.type = TYPE_STRING; ret.data.string = LoadCString(gc, string, strlen(string)); return ret; } static uint8_t * NumberToString(GC * gc, Number x) { static const uint32_t SIZE = 20; uint8_t * data = GCAlloc(gc, SIZE + 2 * sizeof(uint32_t)); data += 2 * sizeof(uint32_t); snprintf((char *) data, SIZE, "%.17g", x); VStringHash(data) = 0; VStringSize(data) = strlen((char *) data); return data; } static const char * HEX_CHARACTERS = "0123456789ABCDEF"; #define HEX(i) (((uint8_t *) HEX_CHARACTERS)[(i)]) /* Returns a string description for a pointer */ static uint8_t * StringDescription(GC * gc, const char * title, uint32_t titlelen, void * pointer) { uint32_t len = 3 + titlelen + sizeof(pointer) * 2; uint32_t i; uint8_t * data = GCAlloc(gc, len + 2 * sizeof(uint32_t)); uint8_t * c; union { uint8_t bytes[sizeof(void *)]; void * p; } buf; buf.p = pointer; data += 2 * sizeof(uint32_t); c = data; *c++ = '<'; for (i = 0; i < titlelen; ++i) { *c++ = ((uint8_t *)title) [i]; } *c++ = ' '; for (i = 0; i < sizeof(void *); ++i) { uint8_t byte = buf.bytes[i]; *c++ = HEX(byte >> 4); *c++ = HEX(byte & 0xF); } *c++ = '>'; return data; } /* Returns a string pointer or NULL if could not allocate memory. */ uint8_t * ValueToString(GC * gc, Value * x) { switch (x->type) { case TYPE_NIL: return LoadCString(gc, "nil", 3); case TYPE_BOOLEAN: if (x->data.boolean) { return LoadCString(gc, "true", 4); } else { return LoadCString(gc, "false", 5); } case TYPE_NUMBER: return NumberToString(gc, x->data.number); case TYPE_ARRAY: return StringDescription(gc, "array", 5, x->data.array); case TYPE_FORM: return StringDescription(gc, "form", 4, x->data.array); case TYPE_STRING: case TYPE_SYMBOL: return x->data.string; case TYPE_BYTEBUFFER: return StringDescription(gc, "buffer", 6, x->data.buffer); case TYPE_CFUNCTION: return StringDescription(gc, "cfunction", 9, x->data.cfunction); case TYPE_FUNCTION: return StringDescription(gc, "function", 8, x->data.func); case TYPE_DICTIONARY: return StringDescription(gc, "dictionary", 10, x->data.dict); case TYPE_FUNCDEF: return StringDescription(gc, "funcdef", 7, x->data.funcdef); case TYPE_FUNCENV: return StringDescription(gc, "funcenv", 7, x->data.funcenv); case TYPE_THREAD: return StringDescription(gc, "thread", 6, x->data.array); } return NULL; } /* Simple hash function */ uint32_t djb2(const uint8_t * str) { const uint8_t * end = str + VStringSize(str); uint32_t hash = 5381; while (str < end) hash = (hash << 5) + hash + *str++; return hash; } /* Check if two values are equal. This is strict equality with no conversion. */ int ValueEqual(Value * x, Value * y) { int result; if (x->type != y->type) { result = 0; } else { switch (x->type) { case TYPE_NIL: result = 1; break; case TYPE_BOOLEAN: result = x->data.boolean == y->data.boolean; break; case TYPE_NUMBER: result = x->data.number == y->data.number; break; /* Assume that when strings are created, equal strings * are set to the same string */ case TYPE_STRING: case TYPE_SYMBOL: if (x->data.string == y->data.string) { result = 1; break; } if (ValueHash(x) != ValueHash(y) || VStringSize(x->data.string) != VStringSize(y->data.string)) { result = 0; break; } /* If two different strings are equal, merge them to share the same data */ if (!strncmp((char *) x->data.string, (char *) y->data.string, VStringSize(x->data.string))) { /* Use the lower pointer in memory. This means that in long running * programs, repeated string compares will eventually all use identical * pointers for identical strings. */ if (x->data.string < y->data.string) { y->data.string = x->data.string; } else { x->data.string = y->data.string; } result = 1; break; } result = 0; break; case TYPE_ARRAY: case TYPE_FORM: case TYPE_BYTEBUFFER: case TYPE_CFUNCTION: case TYPE_DICTIONARY: case TYPE_FUNCTION: case TYPE_FUNCDEF: case TYPE_FUNCENV: case TYPE_THREAD: /* compare pointers */ result = x->data.array == y->data.array; break; } } return result; } /* Computes a hash value for a function */ uint32_t ValueHash(Value * x) { uint32_t hash; switch (x->type) { case TYPE_NIL: hash = 0; break; case TYPE_BOOLEAN: hash = x->data.boolean; break; case TYPE_NUMBER: { union { uint32_t hash; Number number; } u; u.number = x->data.number; hash = u.hash; } break; /* String hashes */ case TYPE_SYMBOL: case TYPE_STRING: /* Assume 0 is not hashed. */ if (VStringHash(x->data.string)) hash = VStringHash(x->data.string); else hash = VStringHash(x->data.string) = djb2(x->data.string); break; case TYPE_ARRAY: case TYPE_FORM: case TYPE_BYTEBUFFER: case TYPE_CFUNCTION: case TYPE_DICTIONARY: case TYPE_FUNCTION: case TYPE_FUNCDEF: case TYPE_FUNCENV: case TYPE_THREAD: /* Cast the pointer */ { union { void * pointer; uint32_t hash; } u; u.pointer = x->data.pointer; hash = u.hash; } break; } return hash; } /* Compares x to y. If they are equal retuns 0. If x is less, returns -1. * If y is less, returns 1. All types are comparable * and should have strict ordering. */ int ValueCompare(Value * x, Value * y) { if (x->type == y->type) { switch (x->type) { case TYPE_NIL: return 0; case TYPE_BOOLEAN: if (x->data.boolean == y->data.boolean) { return 0; } else { return x->data.boolean ? 1 : -1; } case TYPE_NUMBER: /* TODO: define behavior for NaN and infinties. */ if (x->data.number == y->data.number) { return 0; } else { return x->data.number > y->data.number ? 1 : -1; } case TYPE_STRING: case TYPE_SYMBOL: if (x->data.string == y->data.string) { return 0; } else { uint32_t xlen = VStringSize(x->data.string); uint32_t ylen = VStringSize(y->data.string); uint32_t len = xlen > ylen ? ylen : xlen; uint32_t i; for (i = 0; i < len; ++i) { if (x->data.string[i] == y->data.string[i]) { continue; } else if (x->data.string[i] < y->data.string[i]) { return 1; /* x is less then y */ } else { return -1; /* y is less than x */ } } if (xlen == ylen) { /* Merge the two strings */ if (x->data.string < y->data.string) { y->data.string = x->data.string; } else { x->data.string = y->data.string; } return 0; } else { return xlen < ylen ? -1 : 1; } } case TYPE_ARRAY: case TYPE_FORM: case TYPE_BYTEBUFFER: case TYPE_CFUNCTION: case TYPE_FUNCTION: case TYPE_DICTIONARY: case TYPE_FUNCDEF: case TYPE_FUNCENV: case TYPE_THREAD: if (x->data.string == y->data.string) { return 0; } else { return x->data.string > y->data.string ? 1 : -1; } } } else if (x->type < y->type) { return -1; } return 1; }