#include "ikarus.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include int total_allocated_pages = 0; extern char **environ; #define segment_size (pagesize*pagesize/wordsize) #define segment_shift (pageshift+pageshift-wordshift) #define segment_index(x) (((unsigned int)(x)) >> segment_shift) static void extend_table_maybe(unsigned char*p, int size, ikpcb* pcb){ assert(size == align_to_next_page(size)); unsigned char* q = p + size; if(p < pcb->memory_base){ int new_lo = segment_index(p); int old_lo = segment_index(pcb->memory_base); int hi = segment_index(pcb->memory_end); int new_vec_size = (hi - new_lo) * pagesize; int old_vec_size = (hi - old_lo) * pagesize; unsigned char* v = ik_mmap(new_vec_size); bzero(v, new_vec_size - old_vec_size); memcpy(v+new_vec_size-old_vec_size, pcb->dirty_vector_base, old_vec_size); ik_munmap(pcb->dirty_vector_base, old_vec_size); pcb->dirty_vector_base = (unsigned int*) v; pcb->dirty_vector = (unsigned int*)(v - new_lo * pagesize); unsigned char* s = ik_mmap(new_vec_size); bzero(s, new_vec_size - old_vec_size); memcpy(s+new_vec_size-old_vec_size, pcb->segment_vector_base, old_vec_size); ik_munmap(pcb->segment_vector_base, old_vec_size); pcb->segment_vector_base = (unsigned int*) s; pcb->segment_vector = (unsigned int*)(s - new_lo * pagesize); pcb->memory_base = (unsigned char*)(new_lo * segment_size); } else if (q > pcb->memory_end){ int lo = segment_index(pcb->memory_base); int old_hi = segment_index(pcb->memory_end); int new_hi = segment_index(q+segment_size-1); int new_vec_size = (new_hi - lo) * pagesize; int old_vec_size = (old_hi - lo) * pagesize; unsigned char* v = ik_mmap(new_vec_size); memcpy(v, pcb->dirty_vector_base, old_vec_size); bzero(v+old_vec_size, new_vec_size - old_vec_size); ik_munmap(pcb->dirty_vector_base, old_vec_size); pcb->dirty_vector_base = (unsigned int*) v; pcb->dirty_vector = (unsigned int*)(v - lo * pagesize); unsigned char* s = ik_mmap(new_vec_size); memcpy(s, pcb->segment_vector_base, old_vec_size); bzero(s+old_vec_size, new_vec_size - old_vec_size); ik_munmap(pcb->segment_vector_base, old_vec_size); pcb->segment_vector_base = (unsigned int*) s; pcb->segment_vector = (unsigned int*)(s - lo * pagesize); pcb->memory_end = (unsigned char*)(new_hi * segment_size); } } static void set_segment_type(unsigned char* base, int size, unsigned int type, ikpcb* pcb){ assert(base >= pcb->memory_base); assert((base+size) <= pcb->memory_end); assert(size == align_to_next_page(size)); unsigned int* p = pcb->segment_vector + page_index(base); unsigned int* q = p + page_index(size); while(p < q){ *p = type; p++; } } void ik_munmap_from_segment(unsigned char* base, int size, ikpcb* pcb){ assert(base >= pcb->memory_base); assert((base+size) <= pcb->memory_end); assert(size == align_to_next_page(size)); unsigned int* p = pcb->segment_vector + page_index(base); unsigned int* s = pcb->dirty_vector + page_index(base); unsigned int* q = p + page_index(size); while(p < q){ assert(*p != hole_mt); *p = hole_mt; /* holes */ *s = 0; p++; s++; } ikpage* r = pcb->uncached_pages; if (r){ ikpage* cache = pcb->cached_pages; do{ r->base = base; ikpage* next = r->next; r->next = cache; cache = r; r = next; base += pagesize; size -= pagesize; } while(r && size); pcb->cached_pages = cache; pcb->uncached_pages = r; } if(size){ ik_munmap(base, size); } } void* ik_mmap_typed(int size, unsigned int type, ikpcb* pcb){ unsigned char* p; if(size == pagesize) { ikpage* s = pcb->cached_pages; if(s){ p = s->base; pcb->cached_pages = s->next; s->next = pcb->uncached_pages; pcb->uncached_pages = s; } else { p = ik_mmap(size); } } else { p = ik_mmap(size); } extend_table_maybe(p, size, pcb); set_segment_type(p, size, type, pcb); return p; } void* ik_mmap_ptr(int size, int gen, ikpcb* pcb){ return ik_mmap_typed(size, pointers_mt | gen, pcb); } void* ik_mmap_data(int size, int gen, ikpcb* pcb){ return ik_mmap_typed(size, data_mt | gen, pcb); } void* ik_mmap_code(int size, int gen, ikpcb* pcb){ ikp p = ik_mmap_typed(size, code_mt | gen, pcb); if(size > pagesize){ set_segment_type(p+pagesize, size-pagesize, data_mt|gen, pcb); } int err = mprotect(p, size, PROT_READ | PROT_WRITE | PROT_EXEC); if(err){ fprintf(stderr, "cannot mprotect code: %s\n", strerror(errno)); exit(-1); } return p; } void* ik_mmap_mixed(int size, ikpcb* pcb){ return ik_mmap_typed(size, mainheap_mt, pcb); } void* ik_mmap(int size){ int pages = (size + pagesize - 1) / pagesize; total_allocated_pages += pages; int mapsize = pages * pagesize; assert(size == mapsize); char* mem = mmap( 0, mapsize, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANON, -1, 0); if(mem == MAP_FAILED){ fprintf(stderr, "Mapping failed: %s\n", strerror(errno)); exit(-1); } memset(mem, -1, mapsize); return mem; } void ik_munmap(void* mem, int size){ int pages = (size + pagesize - 1) / pagesize; int mapsize = pages * pagesize; assert(size == mapsize); assert(((-pagesize) & (int)mem) == (int)mem); total_allocated_pages -= pages; int err = munmap(mem, mapsize); if(err != 0){ fprintf(stderr, "ik_munmap failed: %s\n", strerror(errno)); exit(-1); } } int total_malloced = 0; void* ik_malloc(int size){ void* x = malloc(size); if(x == NULL){ fprintf(stderr, "malloc failed: %s\n", strerror(errno)); exit(-1); } total_malloced += size; return x; } void ik_free(void* x, int size){ total_malloced -= size; free(x); } ikp ik_mmap_protected(int size){ ikp x = ik_mmap(size + 2*pagesize); { int err = mprotect(x, pagesize, PROT_NONE); if(err){ fprintf(stderr, "mprotect failed: %s\n", strerror(errno)); exit(-1); } } { int err = mprotect(x+pagesize+size, pagesize, PROT_NONE); if(err){ fprintf(stderr, "mprotect failed: %s\n", strerror(errno)); exit(-1); } } return x+pagesize; } #define CACHE_SIZE (pagesize * 8) /* must be multiple of pagesize*/ ikpcb* ik_make_pcb(){ ikpcb* pcb = ik_malloc(sizeof(ikpcb)); bzero(pcb, sizeof(ikpcb)); #define HEAPSIZE (1024 * 4096) #define STAKSIZE (1024 * 4096) //#define STAKSIZE (256 * 4096) pcb->heap_base = ik_mmap_protected(HEAPSIZE); pcb->heap_size = HEAPSIZE; pcb->allocation_pointer = pcb->heap_base; pcb->allocation_redline = pcb->heap_base + HEAPSIZE - 2 * 4096; pcb->stack_base = ik_mmap(STAKSIZE); pcb->stack_size = STAKSIZE; pcb->frame_pointer = pcb->stack_base + pcb->stack_size; pcb->frame_base = pcb->frame_pointer; pcb->frame_redline = pcb->stack_base + 2 * 4096; { /* make cache ikpage */ ikpage* p = ik_mmap(CACHE_SIZE * sizeof(ikpage)); ikpage* q = 0; ikpage* e = p + CACHE_SIZE; while(p < e){ p->next = q; q = p; p++; } pcb->uncached_pages = q; } { /* compute extent of heap and stack */ unsigned char* lo_mem; unsigned char* hi_mem; if(pcb->heap_base < pcb->stack_base){ lo_mem = pcb->heap_base - pagesize; hi_mem = pcb->stack_base + pcb->stack_size + pagesize; } else { lo_mem = pcb->stack_base - pagesize; hi_mem = pcb->heap_base + pcb->heap_size + pagesize; } int lo_seg = segment_index(lo_mem); int hi_seg = segment_index(hi_mem+segment_size-1); int vec_size = (hi_seg - lo_seg) * pagesize; char* dvec = ik_mmap(vec_size); bzero(dvec, vec_size); pcb->dirty_vector_base = (unsigned int*) (dvec); pcb->dirty_vector = (unsigned int*) (dvec - lo_seg * pagesize); char* svec = ik_mmap(vec_size); bzero(svec, vec_size); pcb->segment_vector_base = (unsigned int*) (svec); pcb->segment_vector = (unsigned int*) (svec - lo_seg * pagesize); pcb->memory_base = (unsigned char*)(lo_seg * segment_size); pcb->memory_end = (unsigned char*)(hi_seg * segment_size); set_segment_type(pcb->heap_base-pagesize, pcb->heap_size+2*pagesize, mainheap_mt, pcb); set_segment_type(pcb->stack_base, pcb->stack_size, mainstack_mt, pcb); } /* initialize base rtd */ { ikp s = ik_cstring_to_symbol("$base-rtd", pcb); ikp r = ik_alloc(pcb, align(rtd_size)) + rtd_tag; ref(r, off_rtd_rtd) = r; ref(r, off_rtd_length) = (ikp) (rtd_size-wordsize); ref(r, off_rtd_name) = 0; ref(r, off_rtd_fields) = 0; ref(r, off_rtd_printer) = 0; ref(r, off_rtd_symbol) = 0; ref(s, off_symbol_system_value) = r; ref(s, off_symbol_value) = r; } return pcb; } void ik_delete_pcb(ikpcb* pcb){ unsigned char* base = pcb->memory_base; unsigned char* end = pcb->memory_end; unsigned int* segment_vec = pcb->segment_vector; int i = page_index(base); int j = page_index(end); while(i < j){ unsigned int t = segment_vec[i]; if(t != hole_mt){ ik_munmap((ikp)(i<dirty_vector_base, vecsize); ik_munmap(pcb->segment_vector_base, vecsize); ik_free(pcb, sizeof(ikpcb)); } ikp ik_alloc(ikpcb* pcb, int size){ assert(size == align(size)); ikp ap = pcb->allocation_pointer; ikp ep = pcb->heap_base + pcb->heap_size; ikp nap = ap + size; if(nap < ep){ pcb->allocation_pointer = nap; return ap; } else { if(ap){ ikpages* p = ik_malloc(sizeof(ikpages)); p->base = pcb->heap_base; p->size = pcb->heap_size; p->next = pcb->heap_pages; pcb->heap_pages = p; } { /* ACCOUNTING */ int bytes = ((int)pcb->allocation_pointer) - ((int)pcb->heap_base); int minor = bytes + pcb->allocation_count_minor; while(minor >= most_bytes_in_minor){ minor -= most_bytes_in_minor; pcb->allocation_count_major++; } pcb->allocation_count_minor = minor; } int new_size = (size > IK_HEAP_EXT_SIZE) ? size : IK_HEAP_EXT_SIZE; new_size += 2 * 4096; new_size = align_to_next_page(new_size); ap = ik_mmap_mixed(new_size, pcb); pcb->heap_base = ap; pcb->heap_size = new_size; pcb->allocation_redline = ap + new_size - 2 * 4096; nap = ap + size; pcb->allocation_pointer = nap; return ap; } } void ik_error(ikp args){ fprintf(stderr, "Error: "); ik_fprint(stderr, args); fprintf(stderr, "\n"); exit(0); } void ik_stack_overflow(ikpcb* pcb){ #ifndef NDEBUG fprintf(stderr, "entered ik_stack_overflow pcb=0x%08x\n", (int)pcb); #endif set_segment_type(pcb->stack_base, pcb->stack_size, data_mt, pcb); ikp frame_base = pcb->frame_base; ikp underflow_handler = ref(frame_base, -wordsize); #ifndef NDEBUG fprintf(stderr, "underflow_handler = 0x%08x\n", (int)underflow_handler); #endif /* capture continuation and set it as next_k */ ikp k = ik_alloc(pcb, align(continuation_size)) + vector_tag; ref(k, -vector_tag) = continuation_tag; ref(k, off_continuation_top) = pcb->frame_pointer; ref(k, off_continuation_size) = pcb->frame_base - (int)pcb->frame_pointer - wordsize; ref(k, off_continuation_next) = pcb->next_k; pcb->next_k = k; pcb->stack_base = ik_mmap_typed(STAKSIZE, mainstack_mt, pcb); pcb->stack_size = STAKSIZE; pcb->frame_base = pcb->stack_base + pcb->stack_size; pcb->frame_pointer = pcb->frame_base - wordsize; pcb->frame_redline = pcb->stack_base + 2 * 4096; ref(pcb->frame_pointer, 0) = underflow_handler; return; } /* char* ik_uuid(char* str){ assert((36 << fx_shift) == (int) ref(str, disp_string_length - string_tag)); uuid_t u; uuid_clear(u); uuid_generate(u); uuid_unparse_upper(u, str + disp_string_data - string_tag); return str; } */ static const char* uuid_chars = "!$%&/0123456789<=>?ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz"; static int uuid_strlen = 1; ikp ik_uuid(ikp str){ static int fd = -1; if(fd == -1){ fd = open("/dev/urandom", O_RDONLY); if(fd == -1){ return false_object; } uuid_strlen = strlen(uuid_chars); } int n = unfix(ref(str, off_string_length)); unsigned char* data = str+off_string_data; read(fd, data, n); unsigned char* p = data; unsigned char* q = data + n; while(p < q){ *p = uuid_chars[*p % uuid_strlen]; p++; } return str; } ikp ik_read(ikp fdptr, ikp bufptr, ikp lenptr){ int fd = unfix(fdptr); int len = unfix(lenptr); char* buf = (char*)(bufptr+disp_string_data-string_tag); int bytes = read(fd, buf, len); if(bytes == -1){ perror("S_read"); exit(-10); } return fix(bytes); } ikp ik_write(ikp fdptr, ikp idx, ikp str){ fprintf(stderr, "IK_WRITE\n"); int fd = unfix(fdptr); int len = unfix(idx); char* buf = (char*)(str+disp_string_data-string_tag); int bytes = write(fd, buf, len); if(bytes != len){ perror("S_write"); exit(-10); } return true_object; } /* * From the manpages: * * int open(const char *pathname, int flags); * int open(const char *pathname, int flags, mode_t mode); * flags = (O_RDONLY | O_WRONLY | O_RDWR) ? O_CREAT ? O_TRUNC ? O_APPEND * return -1 on failure * * int unlink(const char *pathname); */ ikp ik_open_file(ikp str, ikp flagptr){ int flags; int f = unfix(flagptr); char* path = (char*)(str + disp_string_data - string_tag); if(f == 0){ flags = O_WRONLY | O_CREAT; } else if(f == 1){ flags = O_WRONLY | O_APPEND; } else if(f == 2){ unlink(path); flags = O_WRONLY | O_CREAT; } else if(f == 3){ flags = O_WRONLY | O_TRUNC; } else if(f == 4){ flags = O_RDONLY; } else { fprintf(stderr, "Error in S_open_file: invalid mode 0x%08x\n", (int)flagptr); exit(-10); } int fd = open(path, flags, S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH); if(fd == -1){ fprintf(stderr, "Cannot open %s\n", path); perror("S_open_file"); exit(-10); } if(fd != unfix(fix(fd))){ fprintf(stderr, "fd %d too big\n", fd); exit(-10); } return fix(fd); } /* #include #include int stat(const char *path, struct stat *sb); ERRORS Stat() and lstat() will fail if: [ENOTDIR] A component of the path prefix is not a directory. [ENAMETOOLONG] A component of a pathname exceeded {NAME_MAX} charac- ters, or an entire path name exceeded {PATH_MAX} char- acters. [ENOENT] The named file does not exist. [EACCES] Search permission is denied for a component of the path prefix. [ELOOP] Too many symbolic links were encountered in translat- ing the pathname. [EFAULT] Sb or name points to an invalid address. [EIO] An I/O error occurred while reading from or writing to the file system. */ ikp ikrt_file_exists(ikp filename){ char* str = string_data(filename); struct stat sb; int st = stat(str, &sb); if(st == 0){ /* success */ return true_object; } else { int err = errno; if(err == ENOENT){ return false_object; } else if(err == ENOTDIR){ return fix(1); } else if(err == ENAMETOOLONG){ return fix(2); } else if(err == EACCES){ return fix(3); } else if(err == ELOOP){ return fix(4); } else if(err == EFAULT){ return fix(5); } else if(err == EIO){ return fix(6); } else { return fix(-1); } } } /* [ENOTDIR] A component of the path prefix is not a directory. [ENAMETOOLONG] A component of a pathname exceeded {NAME_MAX} charac- ters, or an entire path name exceeded {PATH_MAX} char- acters. [ENOENT] The named file does not exist. [EACCES] Search permission is denied for a component of the path prefix. [EACCES] Write permission is denied on the directory containing the link to be removed. [ELOOP] Too many symbolic links were encountered in translat- ing the pathname. [EPERM] The named file is a directory and the effective user ID of the process is not the super-user. [EPERM] The directory containing the file is marked sticky, and neither the containing directory nor the file to be removed are owned by the effective user ID. [EBUSY] The entry to be unlinked is the mount point for a mounted file system. [EIO] An I/O error occurred while deleting the directory entry or deallocating the inode. [EROFS] The named file resides on a read-only file system. [EFAULT] Path points outside the process's allocated address space. */ ikp ikrt_delete_file(ikp filename){ char* str = string_data(filename); int err = unlink(str); if(err == 0){ return 0; } switch (err){ case ENOTDIR: return fix(1); case ENAMETOOLONG: return fix(2); case ENOENT: return fix(3); case EACCES: return fix(4); case ELOOP: return fix(5); case EPERM: return fix(6); case EBUSY: return fix(7); case EIO: return fix(8); case EROFS: return fix(9); case EFAULT: return fix(10); } return fix(-1); } ikp ik_close(ikp fd){ int err = close(unfix(fd)); if(err != 0){ perror("S_close"); exit(-10); } return true_object; } ikp ik_system(ikp str){ return fix(system(string_data(str))); } static char* mtname(unsigned int n){ if(n == mainheap_type) { return "HEAP_T"; } if(n == mainstack_type) { return "STAK_T"; } if(n == pointers_type) { return "PTER_T"; } if(n == data_type) { return "DATA_T"; } if(n == code_type) { return "CODE_T"; } if(n == hole_type) { return " "; } return "WHAT_T"; } ikp ik_dump_metatable(ikpcb* pcb){ unsigned int* s = pcb->segment_vector_base; unsigned char* p = pcb->memory_base; unsigned char* hi = pcb->memory_end; while(p < hi){ unsigned int t = *s & type_mask; unsigned char* start = p; p += pagesize; s++; while((p < hi) && ((*s & type_mask) == t)){ p += pagesize; s++; } fprintf(stderr, "0x%08x + %5d pages = %s\n", (int) start, ((int)p-(int)start)/pagesize, mtname(t)); } return void_object; } ikp ik_dump_dirty_vector(ikpcb* pcb){ unsigned int* s = pcb->dirty_vector_base; unsigned char* p = pcb->memory_base; unsigned char* hi = pcb->memory_end; while(p < hi){ unsigned int t = *s; unsigned char* start = p; p += pagesize; s++; while((p < hi) && (*s == t)){ p += pagesize; s++; } fprintf(stderr, "0x%08x + %5d pages = 0x%08x\n", (int) start, ((int)p-(int)start)/pagesize, t); } return void_object; } ikp ikrt_make_code(ikp codesizeptr, ikp freevars, ikp rvec, ikpcb* pcb){ assert((fx_mask & (int)codesizeptr) == 0); int code_size = unfix(codesizeptr); int memreq = align_to_next_page(code_size + disp_code_data); ikp mem = ik_mmap_code(memreq, 0, pcb); bzero(mem, memreq); ref(mem, 0) = code_tag; ref(mem, disp_code_code_size) = codesizeptr; ref(mem, disp_code_freevars) = freevars; ref(mem, disp_code_reloc_vector) = rvec; ik_relocate_code(mem); return mem+vector_tag; } ikp ikrt_set_code_reloc_vector(ikp code, ikp vec, ikpcb* pcb){ ref(code, off_code_reloc_vector) = vec; ik_relocate_code(code-vector_tag); pcb->dirty_vector[page_index(code)] = -1; return void_object; } ikp ikrt_strftime(ikp outstr, ikp fmtstr){ time_t t; struct tm* tmp; t = time(NULL); tmp = localtime(&t); if(tmp == NULL){ fprintf(stderr, "Error in time: %s\n", strerror(errno)); } int rv = strftime((char*)outstr+off_string_data, unfix(ref(outstr, off_string_length)) + 1, (char*)fmtstr+off_string_data, tmp); if(rv == 0){ fprintf(stderr, "Error in strftime: %s\n", strerror(errno)); } return fix(rv); } ikp ikrt_close_file(ikp fd, ikpcb* pcb){ int err = close(unfix(fd)); if(err == -1){ return false_object; } else { return true_object; } } ikp ikrt_read(ikp fd, ikp buff, ikpcb* pcb){ int bytes = read(unfix(fd), string_data(buff), unfix(ref(buff, off_string_length))); ikp fbytes = fix(bytes); if (bytes == unfix(fbytes)){ return fbytes; } else { fprintf(stderr, "ERR: ikrt_read: too big\n"); exit(-1); } } #if 0 if(bytes == -1){ fprintf(stderr, "ERR=%s (%d)\n", strerror(errno), errno); return false_object; } else { return fix(bytes); } } #endif ikp ikrt_open_input_file(ikp fname, ikpcb* pcb){ int fd = open(string_data(fname), O_RDONLY); if(fd == -1){ return false_object; } else { return fix(fd); } } ikp ikrt_open_output_file(ikp fname, ikp flagptr, ikpcb* pcb){ /* [(error) 0] */ /* [(replace) 1] */ /* [(truncate) 2] */ /* [(append) 3] */ int flags; int f = unfix(flagptr); if(f == 0){ flags = O_WRONLY | O_CREAT; } else if(f == 1){ unlink(string_data(fname)); flags = O_WRONLY | O_CREAT; } else if(f == 2){ flags = O_WRONLY | O_TRUNC | O_CREAT; } else if(f == 3){ flags = O_WRONLY | O_APPEND; } else { fprintf(stderr, "Error in S_open_file: invalid mode 0x%08x\n", (int)flagptr); exit(-10); } int fd = open(string_data(fname), flags, S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH); if(fd == -1){ fprintf(stderr, "openfile failed: %s\n", strerror(errno)); return false_object; } else { return fix(fd); } } ikp ikrt_write_file(ikp fd, ikp buff, ikp idx, ikpcb* pcb){ int bytes = write(unfix(fd), string_data(buff), unfix(idx)); return fix(bytes); } ikp ikrt_write_char(){ fprintf(stderr, "ikrt_write_char\n"); return void_object; } ikp ikrt_register_guardian(ikp tc, ikp obj, ikpcb* pcb){ ik_guardian_table* g = pcb->guardians[0]; if((!g) || (g->count == ik_guardian_table_size)){ if(sizeof(ik_guardian_table) != pagesize){ fprintf(stderr, "ERR: invaldi guardian table size\n"); exit(-1); } ik_guardian_table* p = (ik_guardian_table*)ik_mmap(sizeof(ik_guardian_table)); p->next = g; p->count = 0; pcb->guardians[0] = p; g=p; } ik_guardian_pair* p = &(g->p[g->count]); p->tc = tc; p->obj = obj; g->count++; return 0; } ikp ikrt_stats_now(ikp t, ikpcb* pcb){ struct rusage r; struct timeval s; gettimeofday(&s, 0); getrusage(RUSAGE_SELF, &r); ref(t, off_record_data) = fix(r.ru_utime.tv_sec); ref(t, off_record_data + wordsize) = fix(r.ru_utime.tv_usec); ref(t, off_record_data + 2 * wordsize) = fix(r.ru_stime.tv_sec); ref(t, off_record_data + 3 * wordsize) = fix(r.ru_stime.tv_usec); ref(t, off_record_data + 4 * wordsize) = fix(s.tv_sec); ref(t, off_record_data + 5 * wordsize) = fix(s.tv_usec); ref(t, off_record_data + 6 * wordsize) = fix(pcb->collection_id); return void_object; } ikp ikrt_bytes_allocated(ikpcb* pcb){ int bytes_in_heap = ((int) pcb->allocation_pointer) - ((int) pcb->heap_base); int bytes = bytes_in_heap + pcb->allocation_count_minor; return fix(bytes); } ikp ikrt_bytes_allocated_major(ikpcb* pcb){ return fix(pcb->allocation_count_major); } ikp ikrt_fork(){ int pid = fork(); return fix(pid); } ikp ikrt_waitpid(ikp pid){ int status; /*pid_t t = */ waitpid(unfix(pid), &status, 0); return fix(status); } ikp ikrt_getenv(ikp str, ikpcb* pcb){ char* v = getenv(string_data(str)); if(v){ int n = strlen(v); ikp s = ik_alloc(pcb, align(n+disp_string_data+1)) + string_tag; ref(s, -string_tag) = fix(n); memcpy(s+off_string_data, v, n+1); return s; } else { ikp s = ik_alloc(pcb, align(disp_string_data+1)) + string_tag; ref(s, -string_tag) = fix(0); ref(s, off_string_data) = 0; return s; } } ikp ikrt_setenv(ikp key, ikp val, ikp overwrite){ int err = setenv(string_data(key), string_data(val), overwrite!=false_object); if(err){ return false_object; } else { return true_object; } } ikp ikrt_environ(ikpcb* pcb){ char** es = environ; int i; char* e; ikp ac = null_object; for(i=0; (e=es[i]); i++){ int n = strlen(e); ikp s = ik_alloc(pcb, align(n+disp_string_data+1)) + string_tag; ref(s, -string_tag) = fix(n); memcpy(s+off_string_data, e, n+1); ikp p = ik_alloc(pcb, pair_size) + pair_tag; ref(p, off_cdr) = ac; ref(p, off_car) = s; ac = p; } return ac; }