/* This code was written as part of the CMU Common Lisp project at Carnegie Mellon University, and has been placed in the public domain. */ #include #include #include "lisp.h" #include "internals.h" #include "alloc.h" #include "globals.h" #include "gc.h" #ifdef ibmrt #define GET_FREE_POINTER() ((lispobj *)SymbolValue(ALLOCATION_POINTER)) #define SET_FREE_POINTER(new_value) \ (SetSymbolValue(ALLOCATION_POINTER,(lispobj)(new_value))) #define GET_GC_TRIGGER() ((lispobj *)SymbolValue(INTERNAL_GC_TRIGGER)) #define SET_GC_TRIGGER(new_value) \ (SetSymbolValue(INTERNAL_GC_TRIGGER,(lispobj)(new_value))) #else #define GET_FREE_POINTER() current_dynamic_space_free_pointer #define SET_FREE_POINTER(new_value) \ (current_dynamic_space_free_pointer = (new_value)) #define GET_GC_TRIGGER() current_auto_gc_trigger #define SET_GC_TRIGGER(new_value) \ clear_auto_gc_trigger(); set_auto_gc_trigger(new_value); #endif #define ALIGNED_SIZE(n) (n+lowtag_Mask) & ~lowtag_Mask /**************************************************************** Allocation Routines. ****************************************************************/ #if defined GENCGC #define alloc(nbytes) alloc_pseudo_atomic(nbytes) #include "gencgc.h" #elif defined(WANT_CGC) extern lispobj *alloc(int bytes); #else static lispobj * alloc(int bytes) { lispobj *result; /* Round to dual word boundry. */ bytes = (bytes + lowtag_Mask) & ~lowtag_Mask; result = GET_FREE_POINTER(); SET_FREE_POINTER(result + (bytes / sizeof(lispobj))); if (GET_GC_TRIGGER() && GET_FREE_POINTER() > GET_GC_TRIGGER()) { SET_GC_TRIGGER((char *) GET_FREE_POINTER() - (char *) current_dynamic_space); } return result; } #endif static lispobj * alloc_unboxed(int type, int words) { lispobj *result; result = (lispobj *) alloc(ALIGNED_SIZE((1 + words) * sizeof(lispobj))); *result = (lispobj) (words << type_Bits) | type; return result; } static lispobj alloc_vector(int type, int length, int size) { struct vector *result; result = (struct vector *) alloc(ALIGNED_SIZE((2 + (length * size + 31) / 32) * sizeof(lispobj))); result->header = type; result->length = make_fixnum(length); return ((lispobj) result) | type_OtherPointer; } lispobj alloc_cons(lispobj car, lispobj cdr) { struct cons *ptr = (struct cons *) alloc(ALIGNED_SIZE(sizeof(struct cons))); ptr->car = car; ptr->cdr = cdr; return (lispobj) ptr | type_ListPointer; } lispobj alloc_number(long n) { struct bignum *ptr; #ifdef __x86_64 if (-0x2000000000000000 < n && n < 0x2000000000000000) /* -2^61 to 2^61 */ #else if (-0x20000000 < n && n < 0x20000000) #endif return make_fixnum(n); else { ptr = (struct bignum *) alloc_unboxed(type_Bignum, 1); ptr->digits[0] = n; return (lispobj) ptr | type_OtherPointer; } } #ifndef UNICODE lispobj alloc_string(const char *str) { int len = strlen(str); lispobj result = alloc_vector(type_SimpleString, len + 1, 8); struct vector *vec = (struct vector *) PTR(result); vec->length = make_fixnum(len); strcpy((char *) vec->data, str); return result; } #else lispobj alloc_string(const char *str) { int k; int len = strlen(str); lispobj result = alloc_vector(type_SimpleString, len + 1, 16); struct vector *vec = (struct vector *) PTR(result); unsigned short int *wide_char_data; vec->length = make_fixnum(len); wide_char_data = (unsigned short int*) vec->data; for (k = 0; k < len; ++k) { wide_char_data[k] = str[k] & 0xff; } #if 0 fprintf(stderr, "alloc-string: 0x%lx %d -> `%s'\n", result, len, str); #endif return result; } #endif lispobj alloc_sap(void *ptr) { #ifndef alpha struct sap *sap_ptr = (struct sap *) alloc_unboxed(type_Sap, 1); #else struct sap *sap_ptr = (struct sap *) alloc_unboxed(type_Sap, 3); #endif sap_ptr->pointer = ptr; return (lispobj) sap_ptr | type_OtherPointer; }