/* * ntp_lists.h - linked lists common code * * SLIST: singly-linked lists * ========================== * * These macros implement a simple singly-linked list template. Both * the listhead and per-entry next fields are declared as pointers to * the list entry struct type. Initialization to NULL is typically * implicit (for globals and statics) or handled by zeroing of the * containing structure. * * The name of the next link field is passed as an argument to allow * membership in several lists at once using multiple next link fields. * * When possible, placing the link field first in the entry structure * allows slightly smaller code to be generated on some platforms. * * LINK_SLIST(listhead, pentry, nextlink) * add entry at head * * LINK_TAIL_SLIST(listhead, pentry, nextlink, entrytype) * add entry at tail. This is O(n), if this is a common * operation the FIFO template may be more appropriate. * * LINK_SORT_SLIST(listhead, pentry, beforecur, nextlink, entrytype) * add entry in sorted order. beforecur is an expression comparing * pentry with the current list entry. The current entry can be * referenced within beforecur as L_S_S_CUR(), which is short for * LINK_SORT_SLIST_CUR(). beforecur is nonzero if pentry sorts * before L_S_S_CUR(). * * UNLINK_HEAD_SLIST(punlinked, listhead, nextlink) * unlink first entry and point punlinked to it, or set punlinked * to NULL if the list is empty. * * UNLINK_SLIST(punlinked, listhead, ptounlink, nextlink, entrytype) * unlink entry pointed to by ptounlink. punlinked is set to NULL * if the entry is not found on the list, otherwise it is set to * ptounlink. * * UNLINK_EXPR_SLIST(punlinked, listhead, expr, nextlink, entrytype) * unlink entry where expression expr is nonzero. expr can refer * to the entry being tested using UNLINK_EXPR_SLIST_CURRENT(), * alias U_E_S_CUR(). See the implementation of UNLINK_SLIST() * below for an example. U_E_S_CUR() is NULL iff the list is empty. * punlinked is pointed to the removed entry or NULL if none * satisfy expr. * * FIFO: singly-linked lists plus tail pointer * =========================================== * * This is the same as FreeBSD's sys/queue.h STAILQ -- a singly-linked * list implementation with tail-pointer maintenance, so that adding * at the tail for first-in, first-out access is O(1). * * DECL_FIFO_ANCHOR(entrytype) * provides the type specification portion of the declaration for * a variable to refer to a FIFO queue (similar to listhead). The * anchor contains the head and indirect tail pointers. Example: * * #include "ntp_lists.h" * * typedef struct myentry_tag myentry; * struct myentry_tag { * myentry *next_link; * ... * }; * * DECL_FIFO_ANCHOR(myentry) my_fifo; * * void somefunc(myentry *pentry) * { * LINK_FIFO(my_fifo, pentry, next_link); * } * * If DECL_FIFO_ANCHOR is used with stack or heap storage, it * should be initialized to NULL pointers using a = { NULL }; * initializer or memset. * * HEAD_FIFO(anchor) * TAIL_FIFO(anchor) * Pointer to first/last entry, NULL if FIFO is empty. * * LINK_FIFO(anchor, pentry, nextlink) * add entry at tail. * * UNLINK_FIFO(punlinked, anchor, nextlink) * unlink head entry and point punlinked to it, or set punlinked * to NULL if the list is empty. * * CONCAT_FIFO(q1, q2, nextlink) * empty fifoq q2 moving its nodes to q1 following q1's existing * nodes. * * DLIST: doubly-linked lists * ========================== * * Elements on DLISTs always have non-NULL forward and back links, * because both link chains are circular. The beginning/end is marked * by the listhead, which is the same type as elements for simplicity. * An empty list's listhead has both links set to its own address. * * */ #ifndef NTP_LISTS_H #define NTP_LISTS_H #include "ntp_types.h" /* TRUE and FALSE */ #include "ntp_assert.h" #ifdef DEBUG # define NTP_DEBUG_LISTS_H #endif /* * If list debugging is not enabled, save a little time by not clearing * an entry's link pointer when it is unlinked, as the stale pointer * is harmless as long as it is ignored when the entry is not in a * list. */ #ifndef NTP_DEBUG_LISTS_H #define MAYBE_Z_LISTS(p) do { } while (FALSE) #else #define MAYBE_Z_LISTS(p) (p) = NULL #endif #define LINK_SLIST(listhead, pentry, nextlink) \ do { \ (pentry)->nextlink = (listhead); \ (listhead) = (pentry); \ } while (FALSE) #define LINK_TAIL_SLIST(listhead, pentry, nextlink, entrytype) \ do { \ entrytype **pptail; \ \ pptail = &(listhead); \ while (*pptail != NULL) \ pptail = &((*pptail)->nextlink); \ \ (pentry)->nextlink = NULL; \ *pptail = (pentry); \ } while (FALSE) #define LINK_SORT_SLIST_CURRENT() (*ppentry) #define L_S_S_CUR() LINK_SORT_SLIST_CURRENT() #define LINK_SORT_SLIST(listhead, pentry, beforecur, nextlink, \ entrytype) \ do { \ entrytype **ppentry; \ \ ppentry = &(listhead); \ while (TRUE) { \ if (NULL == *ppentry || (beforecur)) { \ (pentry)->nextlink = *ppentry; \ *ppentry = (pentry); \ break; \ } \ ppentry = &((*ppentry)->nextlink); \ if (NULL == *ppentry) { \ (pentry)->nextlink = NULL; \ *ppentry = (pentry); \ break; \ } \ } \ } while (FALSE) #define UNLINK_HEAD_SLIST(punlinked, listhead, nextlink) \ do { \ (punlinked) = (listhead); \ if (NULL != (punlinked)) { \ (listhead) = (punlinked)->nextlink; \ MAYBE_Z_LISTS((punlinked)->nextlink); \ } \ } while (FALSE) #define UNLINK_EXPR_SLIST_CURRENT() (*ppentry) #define U_E_S_CUR() UNLINK_EXPR_SLIST_CURRENT() #define UNLINK_EXPR_SLIST(punlinked, listhead, expr, nextlink, \ entrytype) \ do { \ entrytype **ppentry; \ \ ppentry = &(listhead); \ \ while (!(expr)) \ if (*ppentry != NULL && \ (*ppentry)->nextlink != NULL) { \ ppentry = &((*ppentry)->nextlink); \ } else { \ ppentry = NULL; \ break; \ } \ \ if (ppentry != NULL) { \ (punlinked) = *ppentry; \ *ppentry = (punlinked)->nextlink; \ MAYBE_Z_LISTS((punlinked)->nextlink); \ } else { \ (punlinked) = NULL; \ } \ } while (FALSE) #define UNLINK_SLIST(punlinked, listhead, ptounlink, nextlink, \ entrytype) \ UNLINK_EXPR_SLIST(punlinked, listhead, (ptounlink) == \ U_E_S_CUR(), nextlink, entrytype) #define CHECK_SLIST(listhead, nextlink, entrytype) \ do { \ entrytype *pentry; \ \ for (pentry = (listhead); \ pentry != NULL; \ pentry = pentry->nextlink){ \ NTP_INSIST(pentry != pentry->nextlink); \ NTP_INSIST((listhead) != pentry->nextlink); \ } \ } while (FALSE) /* * FIFO */ #define DECL_FIFO_ANCHOR(entrytype) \ struct { \ entrytype * phead; /* NULL if list empty */ \ entrytype ** pptail; /* NULL if list empty */ \ } #define HEAD_FIFO(anchor) ((anchor).phead) #define TAIL_FIFO(anchor) ((NULL == (anchor).pptail) \ ? NULL \ : *((anchor).pptail)) /* * For DEBUG builds only, verify both or neither of the anchor pointers * are NULL with each operation. */ #if !defined(NTP_DEBUG_LISTS_H) #define CHECK_FIFO_CONSISTENCY(anchor) do { } while (FALSE) #else #define CHECK_FIFO_CONSISTENCY(anchor) \ check_gen_fifo_consistency(&(anchor)) void check_gen_fifo_consistency(void *fifo); #endif /* * generic FIFO element used to access any FIFO where each element * begins with the link pointer */ typedef struct gen_node_tag gen_node; struct gen_node_tag { gen_node * link; }; /* generic FIFO */ typedef DECL_FIFO_ANCHOR(gen_node) gen_fifo; #define LINK_FIFO(anchor, pentry, nextlink) \ do { \ CHECK_FIFO_CONSISTENCY(anchor); \ \ (pentry)->nextlink = NULL; \ if (NULL != (anchor).pptail) { \ (*((anchor).pptail))->nextlink = (pentry); \ (anchor).pptail = \ &(*((anchor).pptail))->nextlink; \ } else { \ (anchor).phead = (pentry); \ (anchor).pptail = &(anchor).phead; \ } \ \ CHECK_FIFO_CONSISTENCY(anchor); \ } while (FALSE) #define UNLINK_FIFO(punlinked, anchor, nextlink) \ do { \ CHECK_FIFO_CONSISTENCY(anchor); \ \ (punlinked) = (anchor).phead; \ if (NULL != (punlinked)) { \ (anchor).phead = (punlinked)->nextlink; \ if (NULL == (anchor).phead) \ (anchor).pptail = NULL; \ else if ((anchor).pptail == \ &(punlinked)->nextlink) \ (anchor).pptail = &(anchor).phead; \ MAYBE_Z_LISTS((punlinked)->nextlink); \ CHECK_FIFO_CONSISTENCY(anchor); \ } \ } while (FALSE) #define UNLINK_MID_FIFO(punlinked, anchor, tounlink, nextlink, \ entrytype) \ do { \ entrytype **ppentry; \ \ CHECK_FIFO_CONSISTENCY(anchor); \ \ ppentry = &(anchor).phead; \ \ while ((tounlink) != *ppentry) \ if ((*ppentry)->nextlink != NULL) { \ ppentry = &((*ppentry)->nextlink); \ } else { \ ppentry = NULL; \ break; \ } \ \ if (ppentry != NULL) { \ (punlinked) = *ppentry; \ *ppentry = (punlinked)->nextlink; \ if (NULL == *ppentry) \ (anchor).pptail = NULL; \ else if ((anchor).pptail == \ &(punlinked)->nextlink) \ (anchor).pptail = &(anchor).phead; \ MAYBE_Z_LISTS((punlinked)->nextlink); \ CHECK_FIFO_CONSISTENCY(anchor); \ } else { \ (punlinked) = NULL; \ } \ } while (FALSE) #define CONCAT_FIFO(f1, f2, nextlink) \ do { \ CHECK_FIFO_CONSISTENCY(f1); \ CHECK_FIFO_CONSISTENCY(f2); \ \ if ((f2).pptail != NULL) { \ if ((f1).pptail != NULL) { \ (*(f1).pptail)->nextlink = (f2).phead; \ if ((f2).pptail == &(f2).phead) \ (f1).pptail = \ &(*(f1).pptail)->nextlink; \ else \ (f1).pptail = (f2).pptail; \ CHECK_FIFO_CONSISTENCY(f1); \ } else { \ (f1) = (f2); \ } \ MAYBE_Z_LISTS((f2).phead); \ MAYBE_Z_LISTS((f2).pptail); \ } \ } while (FALSE) /* * DLIST */ #define DECL_DLIST_LINK(entrytype, link) \ struct { \ entrytype * b; \ entrytype * f; \ } link #define INIT_DLIST(listhead, link) \ do { \ (listhead).link.f = &(listhead); \ (listhead).link.b = &(listhead); \ } while (FALSE) #define HEAD_DLIST(listhead, link) \ ( \ (&(listhead) != (listhead).link.f) \ ? (listhead).link.f \ : NULL \ ) #define TAIL_DLIST(listhead, link) \ ( \ (&(listhead) != (listhead).link.b) \ ? (listhead).link.b \ : NULL \ ) #define NEXT_DLIST(listhead, entry, link) \ ( \ (&(listhead) != (entry)->link.f) \ ? (entry)->link.f \ : NULL \ ) #define PREV_DLIST(listhead, entry, link) \ ( \ (&(listhead) != (entry)->link.b) \ ? (entry)->link.b \ : NULL \ ) #define LINK_DLIST(listhead, pentry, link) \ do { \ (pentry)->link.f = (listhead).link.f; \ (pentry)->link.b = &(listhead); \ (listhead).link.f->link.b = (pentry); \ (listhead).link.f = (pentry); \ } while (FALSE) #define LINK_TAIL_DLIST(listhead, pentry, link) \ do { \ (pentry)->link.b = (listhead).link.b; \ (pentry)->link.f = &(listhead); \ (listhead).link.b->link.f = (pentry); \ (listhead).link.b = (pentry); \ } while (FALSE) #define UNLINK_DLIST(ptounlink, link) \ do { \ (ptounlink)->link.b->link.f = (ptounlink)->link.f; \ (ptounlink)->link.f->link.b = (ptounlink)->link.b; \ MAYBE_Z_LISTS((ptounlink)->link.b); \ MAYBE_Z_LISTS((ptounlink)->link.f); \ } while (FALSE) #define ITER_DLIST_BEGIN(listhead, iter, link, entrytype) \ { \ entrytype *i_dl_nextiter; \ \ for ((iter) = (listhead).link.f; \ (iter) != &(listhead) \ && ((i_dl_nextiter = (iter)->link.f), TRUE); \ (iter) = i_dl_nextiter) { #define ITER_DLIST_END() \ } \ } #define REV_ITER_DLIST_BEGIN(listhead, iter, link, entrytype) \ { \ entrytype *i_dl_nextiter; \ \ for ((iter) = (listhead).link.b; \ (iter) != &(listhead) \ && ((i_dl_nextiter = (iter)->link.b), TRUE); \ (iter) = i_dl_nextiter) { #define REV_ITER_DLIST_END() \ } \ } #endif /* NTP_LISTS_H */