Import bind 9.5.2 vendor sources.

[dragonfly.git] / contrib / bind-9.5.2 / lib / bind / isc / ctl_srvr.c

#if !defined(lint) && !defined(SABER)
static const char rcsid[] = "$Id: ctl_srvr.c,v 1.8.246.1 2008/02/18 04:10:16 marka Exp $";
#endif /* not lint */

/*
 * Copyright (c) 2004 by Internet Systems Consortium, Inc. ("ISC")
 * Copyright (c) 1998,1999 by Internet Software Consortium.
 *
 * Permission to use, copy, modify, and distribute this software for any
 * purpose with or without fee is hereby granted, provided that the above
 * copyright notice and this permission notice appear in all copies.
 *
 * THE SOFTWARE IS PROVIDED "AS IS" AND ISC DISCLAIMS ALL WARRANTIES
 * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
 * MERCHANTABILITY AND FITNESS.  IN NO EVENT SHALL ISC BE LIABLE FOR
 * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
 * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
 * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT
 * OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
 */

/* Extern. */

#include "port_before.h"

#include <sys/param.h>
#include <sys/file.h>
#include <sys/socket.h>
#include <sys/un.h>

#include <netinet/in.h>
#include <arpa/nameser.h>
#include <arpa/inet.h>

#include <ctype.h>
#include <errno.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
#include <fcntl.h>
#ifdef HAVE_MEMORY_H
#include <memory.h>
#endif

#include <isc/assertions.h>
#include <isc/ctl.h>
#include <isc/eventlib.h>
#include <isc/list.h>
#include <isc/logging.h>
#include <isc/memcluster.h>

#include "ctl_p.h"

#include "port_after.h"

#ifdef SPRINTF_CHAR
# define SPRINTF(x) strlen(sprintf/**/x)
#else
# define SPRINTF(x) ((size_t)sprintf x)
#endif

/* Macros. */

#define lastverb_p(verb)        (verb->name == NULL || verb->func == NULL)
#define address_expr            ctl_sa_ntop((struct sockaddr *)&sess->sa, \
                                            tmp, sizeof tmp, ctx->logger)

/* Types. */

enum state {
        available = 0, initializing, writing, reading, reading_data,
        processing, idling, quitting, closing
};

union sa_un {
        struct sockaddr_in in;
#ifndef NO_SOCKADDR_UN
        struct sockaddr_un un;
#endif
};

struct ctl_sess {
        LINK(struct ctl_sess)   link;
        struct ctl_sctx *       ctx;
        enum state              state;
        int                     sock;
        union sa_un             sa;
        evFileID                rdID;
        evStreamID              wrID;
        evTimerID               rdtiID;
        evTimerID               wrtiID;
        struct ctl_buf          inbuf;
        struct ctl_buf          outbuf;
        const struct ctl_verb * verb;
        u_int                   helpcode;
        const void *            respctx;
        u_int                   respflags;
        ctl_srvrdone            donefunc;
        void *                  uap;
        void *                  csctx;
};

struct ctl_sctx {
        evContext               ev;
        void *                  uctx;
        u_int                   unkncode;
        u_int                   timeoutcode;
        const struct ctl_verb * verbs;
        const struct ctl_verb * connverb;
        int                     sock;
        int                     max_sess;
        int                     cur_sess;
        struct timespec         timeout;
        ctl_logfunc             logger;
        evConnID                acID;
        LIST(struct ctl_sess)   sess;
};

/* Forward. */

static void                     ctl_accept(evContext, void *, int,
                                           const void *, int,
                                           const void *, int);
static void                     ctl_close(struct ctl_sess *);
static void                     ctl_new_state(struct ctl_sess *,
                                              enum state,
                                              const char *);
static void                     ctl_start_read(struct ctl_sess *);
static void                     ctl_stop_read(struct ctl_sess *);
static void                     ctl_readable(evContext, void *, int, int);
static void                     ctl_rdtimeout(evContext, void *,
                                              struct timespec,
                                              struct timespec);
static void                     ctl_wrtimeout(evContext, void *,
                                              struct timespec,
                                              struct timespec);
static void                     ctl_docommand(struct ctl_sess *);
static void                     ctl_writedone(evContext, void *, int, int);
static void                     ctl_morehelp(struct ctl_sctx *,
                                             struct ctl_sess *,
                                             const struct ctl_verb *,
                                             const char *,
                                             u_int, const void *, void *);
static void                     ctl_signal_done(struct ctl_sctx *,
                                                struct ctl_sess *);

/* Private data. */

static const char *             state_names[] = {
        "available", "initializing", "writing", "reading",
        "reading_data", "processing", "idling", "quitting", "closing"
};

static const char               space[] = " ";

static const struct ctl_verb    fakehelpverb = {
        "fakehelp", ctl_morehelp , NULL
};

/* Public. */

/*%
 * void
 * ctl_server()
 *      create, condition, and start a listener on the control port.
 */
struct ctl_sctx *
ctl_server(evContext lev, const struct sockaddr *sap, size_t sap_len,
           const struct ctl_verb *verbs,
           u_int unkncode, u_int timeoutcode,
           u_int timeout, int backlog, int max_sess,
           ctl_logfunc logger, void *uctx)
{
        static const char me[] = "ctl_server";
        static const int on = 1;
        const struct ctl_verb *connverb;
        struct ctl_sctx *ctx;
        int save_errno;

        if (logger == NULL)
                logger = ctl_logger;
        for (connverb = verbs;
             connverb->name != NULL && connverb->func != NULL;
             connverb++)
                if (connverb->name[0] == '\0')
                        break;
        if (connverb->func == NULL) {
                (*logger)(ctl_error, "%s: no connection verb found", me);
                return (NULL);
        }
        ctx = memget(sizeof *ctx);
        if (ctx == NULL) {
                (*logger)(ctl_error, "%s: getmem: %s", me, strerror(errno));
                return (NULL);
        }
        ctx->ev = lev;
        ctx->uctx = uctx;
        ctx->unkncode = unkncode;
        ctx->timeoutcode = timeoutcode;
        ctx->verbs = verbs;
        ctx->timeout = evConsTime(timeout, 0);
        ctx->logger = logger;
        ctx->connverb = connverb;
        ctx->max_sess = max_sess;
        ctx->cur_sess = 0;
        INIT_LIST(ctx->sess);
        ctx->sock = socket(sap->sa_family, SOCK_STREAM, PF_UNSPEC);
        if (ctx->sock > evHighestFD(ctx->ev)) {
                ctx->sock = -1;
                errno = ENOTSOCK;
        }
        if (ctx->sock < 0) {
                save_errno = errno;
                (*ctx->logger)(ctl_error, "%s: socket: %s",
                               me, strerror(errno));
                memput(ctx, sizeof *ctx);
                errno = save_errno;
                return (NULL);
        }
        if (ctx->sock > evHighestFD(lev)) {
                close(ctx->sock);
                (*ctx->logger)(ctl_error, "%s: file descriptor > evHighestFD");
                errno = ENFILE;
                memput(ctx, sizeof *ctx);
                return (NULL);
        }
#ifdef NO_UNIX_REUSEADDR
        if (sap->sa_family != AF_UNIX)
#endif
                if (setsockopt(ctx->sock, SOL_SOCKET, SO_REUSEADDR,
                               (const char *)&on, sizeof on) != 0) {
                        (*ctx->logger)(ctl_warning,
                                       "%s: setsockopt(REUSEADDR): %s",
                                       me, strerror(errno));
                }
        if (bind(ctx->sock, sap, sap_len) < 0) {
                char tmp[MAX_NTOP];
                save_errno = errno;
                (*ctx->logger)(ctl_error, "%s: bind: %s: %s",
                               me, ctl_sa_ntop((const struct sockaddr *)sap,
                               tmp, sizeof tmp, ctx->logger),
                               strerror(save_errno));
                close(ctx->sock);
                memput(ctx, sizeof *ctx);
                errno = save_errno;
                return (NULL);
        }
        if (fcntl(ctx->sock, F_SETFD, 1) < 0) {
                (*ctx->logger)(ctl_warning, "%s: fcntl: %s", me,
                               strerror(errno));
        }
        if (evListen(lev, ctx->sock, backlog, ctl_accept, ctx,
                     &ctx->acID) < 0) {
                save_errno = errno;
                (*ctx->logger)(ctl_error, "%s: evListen(fd %d): %s",
                               me, ctx->sock, strerror(errno));
                close(ctx->sock);
                memput(ctx, sizeof *ctx);
                errno = save_errno;
                return (NULL);
        }
        (*ctx->logger)(ctl_debug, "%s: new ctx %p, sock %d",
                       me, ctx, ctx->sock);
        return (ctx);
}

/*%
 * void
 * ctl_endserver(ctx)
 *      if the control listener is open, close it.  clean out all eventlib
 *      stuff.  close all active sessions.
 */
void
ctl_endserver(struct ctl_sctx *ctx) {
        static const char me[] = "ctl_endserver";
        struct ctl_sess *this, *next;

        (*ctx->logger)(ctl_debug, "%s: ctx %p, sock %d, acID %p, sess %p",
                       me, ctx, ctx->sock, ctx->acID.opaque, ctx->sess);
        if (ctx->acID.opaque != NULL) {
                (void)evCancelConn(ctx->ev, ctx->acID);
                ctx->acID.opaque = NULL;
        }
        if (ctx->sock != -1) {
                (void) close(ctx->sock);
                ctx->sock = -1;
        }
        for (this = HEAD(ctx->sess); this != NULL; this = next) {
                next = NEXT(this, link);
                ctl_close(this);
        }
        memput(ctx, sizeof *ctx);
}

/*%
 * If body is non-NULL then it we add a "." line after it.
 * Caller must have  escaped lines with leading ".".
 */
void
ctl_response(struct ctl_sess *sess, u_int code, const char *text,
             u_int flags, const void *respctx, ctl_srvrdone donefunc,
             void *uap, const char *body, size_t bodylen)
{
        static const char me[] = "ctl_response";
        struct iovec iov[3], *iovp = iov;
        struct ctl_sctx *ctx = sess->ctx;
        char tmp[MAX_NTOP], *pc;
        int n;

        REQUIRE(sess->state == initializing ||
                sess->state == processing ||
                sess->state == reading_data ||
                sess->state == writing);
        REQUIRE(sess->wrtiID.opaque == NULL);
        REQUIRE(sess->wrID.opaque == NULL);
        ctl_new_state(sess, writing, me);
        sess->donefunc = donefunc;
        sess->uap = uap;
        if (!allocated_p(sess->outbuf) &&
            ctl_bufget(&sess->outbuf, ctx->logger) < 0) {
                (*ctx->logger)(ctl_error, "%s: %s: cant get an output buffer",
                               me, address_expr);
                goto untimely;
        }
        if (sizeof "000-\r\n" + strlen(text) > (size_t)MAX_LINELEN) {
                (*ctx->logger)(ctl_error, "%s: %s: output buffer ovf, closing",
                               me, address_expr);
                goto untimely;
        }
        sess->outbuf.used = SPRINTF((sess->outbuf.text, "%03d%c%s\r\n",
                                     code, (flags & CTL_MORE) != 0 ? '-' : ' ',
                                     text));
        for (pc = sess->outbuf.text, n = 0;
             n < (int)sess->outbuf.used-2; pc++, n++)
                if (!isascii((unsigned char)*pc) ||
                    !isprint((unsigned char)*pc))
                        *pc = '\040';
        *iovp++ = evConsIovec(sess->outbuf.text, sess->outbuf.used);
        if (body != NULL) {
                char *tmp;
                DE_CONST(body, tmp);
                *iovp++ = evConsIovec(tmp, bodylen);
                DE_CONST(".\r\n", tmp);
                *iovp++ = evConsIovec(tmp, 3);
        }
        (*ctx->logger)(ctl_debug, "%s: [%d] %s", me,
                       sess->outbuf.used, sess->outbuf.text);
        if (evWrite(ctx->ev, sess->sock, iov, iovp - iov,
                    ctl_writedone, sess, &sess->wrID) < 0) {
                (*ctx->logger)(ctl_error, "%s: %s: evWrite: %s", me,
                               address_expr, strerror(errno));
                goto untimely;
        }
        if (evSetIdleTimer(ctx->ev, ctl_wrtimeout, sess, ctx->timeout,
                           &sess->wrtiID) < 0)
        {
                (*ctx->logger)(ctl_error, "%s: %s: evSetIdleTimer: %s", me,
                               address_expr, strerror(errno));
                goto untimely;
        }
        if (evTimeRW(ctx->ev, sess->wrID, sess->wrtiID) < 0) {
                (*ctx->logger)(ctl_error, "%s: %s: evTimeRW: %s", me,
                               address_expr, strerror(errno));
 untimely:
                ctl_signal_done(ctx, sess);
                ctl_close(sess);
                return;
        }
        sess->respctx = respctx;
        sess->respflags = flags;
}

void
ctl_sendhelp(struct ctl_sess *sess, u_int code) {
        static const char me[] = "ctl_sendhelp";
        struct ctl_sctx *ctx = sess->ctx;

        sess->helpcode = code;
        sess->verb = &fakehelpverb;
        ctl_morehelp(ctx, sess, NULL, me, CTL_MORE,
                     (const void *)ctx->verbs, NULL);
}

void *
ctl_getcsctx(struct ctl_sess *sess) {
        return (sess->csctx);
}

void *
ctl_setcsctx(struct ctl_sess *sess, void *csctx) {
        void *old = sess->csctx;

        sess->csctx = csctx;
        return (old);
}

/* Private functions. */

static void
ctl_accept(evContext lev, void *uap, int fd,
           const void *lav, int lalen,
           const void *rav, int ralen)
{
        static const char me[] = "ctl_accept";
        struct ctl_sctx *ctx = uap;
        struct ctl_sess *sess = NULL;
        char tmp[MAX_NTOP];

        UNUSED(lev);
        UNUSED(lalen);
        UNUSED(ralen);

        if (fd < 0) {
                (*ctx->logger)(ctl_error, "%s: accept: %s",
                               me, strerror(errno));
                return;
        }
        if (ctx->cur_sess == ctx->max_sess) {
                (*ctx->logger)(ctl_error, "%s: %s: too many control sessions",
                               me, ctl_sa_ntop((const struct sockaddr *)rav,
                                               tmp, sizeof tmp,
                                               ctx->logger));
                (void) close(fd);
                return;
        }
        sess = memget(sizeof *sess);
        if (sess == NULL) {
                (*ctx->logger)(ctl_error, "%s: memget: %s", me,
                               strerror(errno));
                (void) close(fd);
                return;
        }
        if (fcntl(fd, F_SETFD, 1) < 0) {
                (*ctx->logger)(ctl_warning, "%s: fcntl: %s", me,
                               strerror(errno));
        }
        ctx->cur_sess++;
        INIT_LINK(sess, link);
        APPEND(ctx->sess, sess, link);
        sess->ctx = ctx;
        sess->sock = fd;
        sess->wrID.opaque = NULL;
        sess->rdID.opaque = NULL;
        sess->wrtiID.opaque = NULL;
        sess->rdtiID.opaque = NULL;
        sess->respctx = NULL;
        sess->csctx = NULL;
        if (((const struct sockaddr *)rav)->sa_family == AF_UNIX)
                ctl_sa_copy((const struct sockaddr *)lav,
                            (struct sockaddr *)&sess->sa);
        else
                ctl_sa_copy((const struct sockaddr *)rav,
                            (struct sockaddr *)&sess->sa);
        sess->donefunc = NULL;
        buffer_init(sess->inbuf);
        buffer_init(sess->outbuf);
        sess->state = available;
        ctl_new_state(sess, initializing, me);
        sess->verb = ctx->connverb;
        (*ctx->logger)(ctl_debug, "%s: %s: accepting (fd %d)",
                       me, address_expr, sess->sock);
        (*ctx->connverb->func)(ctx, sess, ctx->connverb, "", 0,
                               (const struct sockaddr *)rav, ctx->uctx);
}

static void
ctl_new_state(struct ctl_sess *sess, enum state new_state, const char *reason)
{
        static const char me[] = "ctl_new_state";
        struct ctl_sctx *ctx = sess->ctx;
        char tmp[MAX_NTOP];

        (*ctx->logger)(ctl_debug, "%s: %s: %s -> %s (%s)",
                       me, address_expr,
                       state_names[sess->state],
                       state_names[new_state], reason);
        sess->state = new_state;
}

static void
ctl_close(struct ctl_sess *sess) {
        static const char me[] = "ctl_close";
        struct ctl_sctx *ctx = sess->ctx;
        char tmp[MAX_NTOP];

        REQUIRE(sess->state == initializing ||
                sess->state == writing ||
                sess->state == reading ||
                sess->state == processing ||
                sess->state == reading_data ||
                sess->state == idling);
        REQUIRE(sess->sock != -1);
        if (sess->state == reading || sess->state == reading_data)
                ctl_stop_read(sess);
        else if (sess->state == writing) {
                if (sess->wrID.opaque != NULL) {
                        (void) evCancelRW(ctx->ev, sess->wrID);
                        sess->wrID.opaque = NULL;
                }
                if (sess->wrtiID.opaque != NULL) {
                        (void) evClearIdleTimer(ctx->ev, sess->wrtiID);
                        sess->wrtiID.opaque = NULL;
                }
        }
        ctl_new_state(sess, closing, me);
        (void) close(sess->sock);
        if (allocated_p(sess->inbuf))
                ctl_bufput(&sess->inbuf);
        if (allocated_p(sess->outbuf))
                ctl_bufput(&sess->outbuf);
        (*ctx->logger)(ctl_debug, "%s: %s: closed (fd %d)",
                       me, address_expr, sess->sock);
        UNLINK(ctx->sess, sess, link);
        memput(sess, sizeof *sess);
        ctx->cur_sess--;
}

static void
ctl_start_read(struct ctl_sess *sess) {
        static const char me[] = "ctl_start_read";
        struct ctl_sctx *ctx = sess->ctx;
        char tmp[MAX_NTOP];

        REQUIRE(sess->state == initializing ||
                sess->state == writing ||
                sess->state == processing ||
                sess->state == idling);
        REQUIRE(sess->rdtiID.opaque == NULL);
        REQUIRE(sess->rdID.opaque == NULL);
        sess->inbuf.used = 0;
        if (evSetIdleTimer(ctx->ev, ctl_rdtimeout, sess, ctx->timeout,
                           &sess->rdtiID) < 0)
        {
                (*ctx->logger)(ctl_error, "%s: %s: evSetIdleTimer: %s", me,
                               address_expr, strerror(errno));
                ctl_close(sess);
                return;
        }
        if (evSelectFD(ctx->ev, sess->sock, EV_READ,
                       ctl_readable, sess, &sess->rdID) < 0) {
                (*ctx->logger)(ctl_error, "%s: %s: evSelectFD: %s", me,
                               address_expr, strerror(errno));
                return;
        }
        ctl_new_state(sess, reading, me);
}

static void
ctl_stop_read(struct ctl_sess *sess) {
        static const char me[] = "ctl_stop_read";
        struct ctl_sctx *ctx = sess->ctx;

        REQUIRE(sess->state == reading || sess->state == reading_data);
        REQUIRE(sess->rdID.opaque != NULL);
        (void) evDeselectFD(ctx->ev, sess->rdID);
        sess->rdID.opaque = NULL;
        if (sess->rdtiID.opaque != NULL) {
                (void) evClearIdleTimer(ctx->ev, sess->rdtiID);
                sess->rdtiID.opaque = NULL;
        }
        ctl_new_state(sess, idling, me);
}

static void
ctl_readable(evContext lev, void *uap, int fd, int evmask) {
        static const char me[] = "ctl_readable";
        struct ctl_sess *sess = uap;
        struct ctl_sctx *ctx;
        char *eos, tmp[MAX_NTOP];
        ssize_t n;

        REQUIRE(sess != NULL);
        REQUIRE(fd >= 0);
        REQUIRE(evmask == EV_READ);
        REQUIRE(sess->state == reading || sess->state == reading_data);

        ctx = sess->ctx;
        evTouchIdleTimer(lev, sess->rdtiID);
        if (!allocated_p(sess->inbuf) &&
            ctl_bufget(&sess->inbuf, ctx->logger) < 0) {
                (*ctx->logger)(ctl_error, "%s: %s: cant get an input buffer",
                               me, address_expr);
                ctl_close(sess);
                return;
        }
        n = read(sess->sock, sess->inbuf.text + sess->inbuf.used,
                 MAX_LINELEN - sess->inbuf.used);
        if (n <= 0) {
                (*ctx->logger)(ctl_debug, "%s: %s: read: %s",
                               me, address_expr,
                               (n == 0) ? "Unexpected EOF" : strerror(errno));
                ctl_close(sess);
                return;
        }
        sess->inbuf.used += n;
        eos = memchr(sess->inbuf.text, '\n', sess->inbuf.used);
        if (eos != NULL && eos != sess->inbuf.text && eos[-1] == '\r') {
                eos[-1] = '\0';
                if ((sess->respflags & CTL_DATA) != 0) {
                        INSIST(sess->verb != NULL);
                        (*sess->verb->func)(sess->ctx, sess, sess->verb,
                                            sess->inbuf.text,
                                            CTL_DATA, sess->respctx,
                                            sess->ctx->uctx);
                } else {
                        ctl_stop_read(sess);
                        ctl_docommand(sess);
                }
                sess->inbuf.used -= ((eos - sess->inbuf.text) + 1);
                if (sess->inbuf.used == 0U)
                        ctl_bufput(&sess->inbuf);
                else
                        memmove(sess->inbuf.text, eos + 1, sess->inbuf.used);
                return;
        }
        if (sess->inbuf.used == (size_t)MAX_LINELEN) {
                (*ctx->logger)(ctl_error, "%s: %s: line too long, closing",
                               me, address_expr);
                ctl_close(sess);
        }
}

static void
ctl_wrtimeout(evContext lev, void *uap,
              struct timespec due,
              struct timespec itv)
{
        static const char me[] = "ctl_wrtimeout";
        struct ctl_sess *sess = uap;
        struct ctl_sctx *ctx = sess->ctx;
        char tmp[MAX_NTOP];
        
        UNUSED(lev);
        UNUSED(due);
        UNUSED(itv);

        REQUIRE(sess->state == writing);
        sess->wrtiID.opaque = NULL;
        (*ctx->logger)(ctl_warning, "%s: %s: write timeout, closing",
                       me, address_expr);
        if (sess->wrID.opaque != NULL) {
                (void) evCancelRW(ctx->ev, sess->wrID);
                sess->wrID.opaque = NULL;
        }
        ctl_signal_done(ctx, sess);
        ctl_new_state(sess, processing, me);
        ctl_close(sess);
}

static void
ctl_rdtimeout(evContext lev, void *uap,
              struct timespec due,
              struct timespec itv)
{
        static const char me[] = "ctl_rdtimeout";
        struct ctl_sess *sess = uap;
        struct ctl_sctx *ctx = sess->ctx;
        char tmp[MAX_NTOP];

        UNUSED(lev);
        UNUSED(due);
        UNUSED(itv);

        REQUIRE(sess->state == reading);
        sess->rdtiID.opaque = NULL;
        (*ctx->logger)(ctl_warning, "%s: %s: timeout, closing",
                       me, address_expr);
        if (sess->state == reading || sess->state == reading_data)
                ctl_stop_read(sess);
        ctl_signal_done(ctx, sess);
        ctl_new_state(sess, processing, me);
        ctl_response(sess, ctx->timeoutcode, "Timeout.", CTL_EXIT, NULL,
                     NULL, NULL, NULL, 0);
}

static void
ctl_docommand(struct ctl_sess *sess) {
        static const char me[] = "ctl_docommand";
        char *name, *rest, tmp[MAX_NTOP];
        struct ctl_sctx *ctx = sess->ctx;
        const struct ctl_verb *verb;

        REQUIRE(allocated_p(sess->inbuf));
        (*ctx->logger)(ctl_debug, "%s: %s: \"%s\" [%u]",
                       me, address_expr,
                       sess->inbuf.text, (u_int)sess->inbuf.used);
        ctl_new_state(sess, processing, me);
        name = sess->inbuf.text + strspn(sess->inbuf.text, space);
        rest = name + strcspn(name, space);
        if (*rest != '\0') {
                *rest++ = '\0';
                rest += strspn(rest, space);
        }
        for (verb = ctx->verbs;
             verb != NULL && verb->name != NULL && verb->func != NULL;
             verb++)
                if (verb->name[0] != '\0' && strcasecmp(name, verb->name) == 0)
                        break;
        if (verb != NULL && verb->name != NULL && verb->func != NULL) {
                sess->verb = verb;
                (*verb->func)(ctx, sess, verb, rest, 0, NULL, ctx->uctx);
        } else {
                char buf[1100];

                if (sizeof "Unrecognized command \"\" (args \"\")" +
                    strlen(name) + strlen(rest) > sizeof buf)
                        strcpy(buf, "Unrecognized command (buf ovf)");
                else
                        sprintf(buf,
                                "Unrecognized command \"%s\" (args \"%s\")",
                                name, rest);
                ctl_response(sess, ctx->unkncode, buf, 0, NULL, NULL, NULL,
                             NULL, 0);
        }
}

static void
ctl_writedone(evContext lev, void *uap, int fd, int bytes) {
        static const char me[] = "ctl_writedone";
        struct ctl_sess *sess = uap;
        struct ctl_sctx *ctx = sess->ctx;
        char tmp[MAX_NTOP];
        int save_errno = errno;

        UNUSED(lev);
        UNUSED(uap);

        REQUIRE(sess->state == writing);
        REQUIRE(fd == sess->sock);
        REQUIRE(sess->wrtiID.opaque != NULL);
        sess->wrID.opaque = NULL;
        (void) evClearIdleTimer(ctx->ev, sess->wrtiID);
        sess->wrtiID.opaque = NULL;
        if (bytes < 0) {
                (*ctx->logger)(ctl_error, "%s: %s: %s",
                               me, address_expr, strerror(save_errno));
                ctl_close(sess);
                return;
        }

        INSIST(allocated_p(sess->outbuf));
        ctl_bufput(&sess->outbuf);
        if ((sess->respflags & CTL_EXIT) != 0) {
                ctl_signal_done(ctx, sess);
                ctl_close(sess);
                return;
        } else if ((sess->respflags & CTL_MORE) != 0) {
                INSIST(sess->verb != NULL);
                (*sess->verb->func)(sess->ctx, sess, sess->verb, "",
                                    CTL_MORE, sess->respctx, sess->ctx->uctx);
        } else {
                ctl_signal_done(ctx, sess);
                ctl_start_read(sess);
        }
}

static void
ctl_morehelp(struct ctl_sctx *ctx, struct ctl_sess *sess,
             const struct ctl_verb *verb, const char *text,
             u_int respflags, const void *respctx, void *uctx)
{
        const struct ctl_verb *this = respctx, *next = this + 1;

        UNUSED(ctx);
        UNUSED(verb);
        UNUSED(text);
        UNUSED(uctx);

        REQUIRE(!lastverb_p(this));
        REQUIRE((respflags & CTL_MORE) != 0);
        if (lastverb_p(next))
                respflags &= ~CTL_MORE;
        ctl_response(sess, sess->helpcode, this->help, respflags, next,
                     NULL, NULL, NULL, 0);
}

static void
ctl_signal_done(struct ctl_sctx *ctx, struct ctl_sess *sess) {
        if (sess->donefunc != NULL) {
                (*sess->donefunc)(ctx, sess, sess->uap);
                sess->donefunc = NULL;
        }
}

/*! \file */