emsApplication/3rdPartner/libhv/event/kcp/hkcp.c

#include "hkcp.h"

#if WITH_KCP

#include "hevent.h"
#include "hlog.h"
#include "hthread.h"

static kcp_setting_t s_kcp_setting;

static int __kcp_output(const char* buf, int len, ikcpcb* ikcp, void* userdata) {
    // printf("ikcp_output len=%d\n", len);
    rudp_entry_t* rudp = (rudp_entry_t*)userdata;
    assert(rudp != NULL && rudp->io != NULL);
    int nsend = sendto(rudp->io->fd, buf, len, 0, &rudp->addr.sa, SOCKADDR_LEN(&rudp->addr));
    // printf("sendto nsend=%d\n", nsend);
    return nsend;
}

static void __kcp_update_timer_cb(htimer_t* timer) {
    rudp_entry_t* rudp = (rudp_entry_t*)timer->privdata;
    assert(rudp != NULL && rudp->io != NULL && rudp->kcp.ikcp != NULL);
    ikcp_update(rudp->kcp.ikcp, (IUINT32)(rudp->io->loop->cur_hrtime / 1000));
}

void kcp_release(kcp_t* kcp) {
    if (kcp->ikcp == NULL) return;
    if (kcp->update_timer) {
        htimer_del(kcp->update_timer);
        kcp->update_timer = NULL;
    }
    HV_FREE(kcp->readbuf.base);
    kcp->readbuf.len = 0;
    // printf("ikcp_release ikcp=%p\n", kcp->ikcp);
    ikcp_release(kcp->ikcp);
    kcp->ikcp = NULL;
}

int hio_set_kcp(hio_t* io, kcp_setting_t* setting) {
    io->io_type = HIO_TYPE_KCP;
    io->kcp_setting = setting;
    return 0;
}

kcp_t* hio_get_kcp(hio_t* io, uint32_t conv) {
    rudp_entry_t* rudp = hio_get_rudp(io);
    assert(rudp != NULL);
    kcp_t* kcp = &rudp->kcp;
    if (kcp->ikcp != NULL) return kcp;
    if (io->kcp_setting == NULL) {
        io->kcp_setting = &s_kcp_setting;
    }
    kcp_setting_t* setting = io->kcp_setting;
    kcp->ikcp = ikcp_create(conv, rudp);
    // printf("ikcp_create conv=%u ikcp=%p\n", conv, kcp->ikcp);
    kcp->ikcp->output = __kcp_output;
    kcp->conv = conv;
    if (setting->interval > 0) {
        ikcp_nodelay(kcp->ikcp, setting->nodelay, setting->interval, setting->fastresend, setting->nocwnd);
    }
    if (setting->sndwnd > 0 && setting->rcvwnd > 0) {
        ikcp_wndsize(kcp->ikcp, setting->sndwnd, setting->rcvwnd);
    }
    if (setting->mtu > 0) {
        ikcp_setmtu(kcp->ikcp, setting->mtu);
    }
    if (kcp->update_timer == NULL) {
        int update_interval = setting->update_interval;
        if (update_interval == 0) {
            update_interval = DEFAULT_KCP_UPDATE_INTERVAL;
        }
        kcp->update_timer = htimer_add(io->loop, __kcp_update_timer_cb, update_interval, INFINITE);
        kcp->update_timer->privdata = rudp;
    }
    // NOTE: alloc kcp->readbuf when hio_read_kcp
    return kcp;
}

static void hio_write_kcp_event_cb(hevent_t* ev) {
    hio_t* io = (hio_t*)ev->userdata;
    hbuf_t* buf = (hbuf_t*)ev->privdata;

    hio_write_kcp(io, buf->base, buf->len);

    HV_FREE(buf);
}

static int hio_write_kcp_async(hio_t* io, const void* data, size_t len) {
    hbuf_t* buf = NULL;
    HV_ALLOC(buf, sizeof(hbuf_t) + len);
    buf->base = (char*)buf + sizeof(hbuf_t);
    buf->len = len;
    memcpy(buf->base, data, len);

    hevent_t ev;
    memset(&ev, 0, sizeof(ev));
    ev.cb = hio_write_kcp_event_cb;
    ev.userdata = io;
    ev.privdata = buf;
    hloop_post_event(io->loop, &ev);
    return len;
}

int hio_write_kcp(hio_t* io, const void* buf, size_t len) {
    if (hv_gettid() != io->loop->tid) {
        return hio_write_kcp_async(io, buf, len);
    }
    IUINT32 conv = io->kcp_setting ? io->kcp_setting->conv : 0;
    kcp_t* kcp = hio_get_kcp(io, conv);
    // printf("hio_write_kcp conv=%u=%u\n", conv, kcp->conv);
    int nsend = ikcp_send(kcp->ikcp, (const char*)buf, len);
    // printf("ikcp_send len=%d nsend=%d\n", (int)len, nsend);
    if (nsend < 0) {
        hloge("ikcp_send error: %d", nsend);
        return nsend;
    }
    ikcp_update(kcp->ikcp, (IUINT32)io->loop->cur_hrtime / 1000);
    return len;
}

int hio_read_kcp (hio_t* io, void* buf, int readbytes) {
    IUINT32 conv = ikcp_getconv(buf);
    kcp_t* kcp = hio_get_kcp(io, conv);
    // printf("hio_read_kcp conv=%u=%u\n", conv, kcp->conv);
    if (kcp->conv != conv) {
        hloge("recv invalid kcp packet!");
        hio_close_rudp(io, io->peeraddr);
        return -1;
    }
    // printf("ikcp_input len=%d\n", readbytes);
    int ret = ikcp_input(kcp->ikcp, (const char*)buf, readbytes);
    // printf("ikcp_input ret=%d\n", ret);
    if (ret != 0) {
        return 0;
    }
    if (kcp->readbuf.base == NULL || kcp->readbuf.len == 0) {
        kcp->readbuf.len = DEFAULT_KCP_READ_BUFSIZE;
        HV_ALLOC(kcp->readbuf.base, kcp->readbuf.len);
    }
    while (1) {
        int nrecv = ikcp_recv(kcp->ikcp, kcp->readbuf.base, kcp->readbuf.len);
        // printf("ikcp_recv nrecv=%d\n", nrecv);
        if (nrecv < 0) break;
        hio_read_cb(io, kcp->readbuf.base, nrecv);
        ret += nrecv;
    }
    return ret;
}

#endif
init 2024-05-24 12:19:45 +08:00			`#include "hkcp.h"`

			`#if WITH_KCP`

			`#include "hevent.h"`
			`#include "hlog.h"`
			`#include "hthread.h"`

			`static kcp_setting_t s_kcp_setting;`

			`static int __kcp_output(const char* buf, int len, ikcpcb* ikcp, void* userdata) {`
			`// printf("ikcp_output len=%d\n", len);`
			`rudp_entry_t* rudp = (rudp_entry_t*)userdata;`
			`assert(rudp != NULL && rudp->io != NULL);`
			`int nsend = sendto(rudp->io->fd, buf, len, 0, &rudp->addr.sa, SOCKADDR_LEN(&rudp->addr));`
			`// printf("sendto nsend=%d\n", nsend);`
			`return nsend;`
			`}`

			`static void __kcp_update_timer_cb(htimer_t* timer) {`
			`rudp_entry_t* rudp = (rudp_entry_t*)timer->privdata;`
			`assert(rudp != NULL && rudp->io != NULL && rudp->kcp.ikcp != NULL);`
			`ikcp_update(rudp->kcp.ikcp, (IUINT32)(rudp->io->loop->cur_hrtime / 1000));`
			`}`

			`void kcp_release(kcp_t* kcp) {`
			`if (kcp->ikcp == NULL) return;`
			`if (kcp->update_timer) {`
			`htimer_del(kcp->update_timer);`
			`kcp->update_timer = NULL;`
			`}`
			`HV_FREE(kcp->readbuf.base);`
			`kcp->readbuf.len = 0;`
			`// printf("ikcp_release ikcp=%p\n", kcp->ikcp);`
			`ikcp_release(kcp->ikcp);`
			`kcp->ikcp = NULL;`
			`}`

			`int hio_set_kcp(hio_t* io, kcp_setting_t* setting) {`
			`io->io_type = HIO_TYPE_KCP;`
			`io->kcp_setting = setting;`
			`return 0;`
			`}`

			`kcp_t* hio_get_kcp(hio_t* io, uint32_t conv) {`
			`rudp_entry_t* rudp = hio_get_rudp(io);`
			`assert(rudp != NULL);`
			`kcp_t* kcp = &rudp->kcp;`
			`if (kcp->ikcp != NULL) return kcp;`
			`if (io->kcp_setting == NULL) {`
			`io->kcp_setting = &s_kcp_setting;`
			`}`
			`kcp_setting_t* setting = io->kcp_setting;`
			`kcp->ikcp = ikcp_create(conv, rudp);`
			`// printf("ikcp_create conv=%u ikcp=%p\n", conv, kcp->ikcp);`
			`kcp->ikcp->output = __kcp_output;`
			`kcp->conv = conv;`
			`if (setting->interval > 0) {`
			`ikcp_nodelay(kcp->ikcp, setting->nodelay, setting->interval, setting->fastresend, setting->nocwnd);`
			`}`
			`if (setting->sndwnd > 0 && setting->rcvwnd > 0) {`
			`ikcp_wndsize(kcp->ikcp, setting->sndwnd, setting->rcvwnd);`
			`}`
			`if (setting->mtu > 0) {`
			`ikcp_setmtu(kcp->ikcp, setting->mtu);`
			`}`
			`if (kcp->update_timer == NULL) {`
			`int update_interval = setting->update_interval;`
			`if (update_interval == 0) {`
			`update_interval = DEFAULT_KCP_UPDATE_INTERVAL;`
			`}`
			`kcp->update_timer = htimer_add(io->loop, __kcp_update_timer_cb, update_interval, INFINITE);`
			`kcp->update_timer->privdata = rudp;`
			`}`
			`// NOTE: alloc kcp->readbuf when hio_read_kcp`
			`return kcp;`
			`}`

			`static void hio_write_kcp_event_cb(hevent_t* ev) {`
			`hio_t* io = (hio_t*)ev->userdata;`
			`hbuf_t* buf = (hbuf_t*)ev->privdata;`

			`hio_write_kcp(io, buf->base, buf->len);`

			`HV_FREE(buf);`
			`}`

			`static int hio_write_kcp_async(hio_t* io, const void* data, size_t len) {`
			`hbuf_t* buf = NULL;`
			`HV_ALLOC(buf, sizeof(hbuf_t) + len);`
			`buf->base = (char*)buf + sizeof(hbuf_t);`
			`buf->len = len;`
			`memcpy(buf->base, data, len);`

			`hevent_t ev;`
			`memset(&ev, 0, sizeof(ev));`
			`ev.cb = hio_write_kcp_event_cb;`
			`ev.userdata = io;`
			`ev.privdata = buf;`
			`hloop_post_event(io->loop, &ev);`
			`return len;`
			`}`

			`int hio_write_kcp(hio_t* io, const void* buf, size_t len) {`
			`if (hv_gettid() != io->loop->tid) {`
			`return hio_write_kcp_async(io, buf, len);`
			`}`
			`IUINT32 conv = io->kcp_setting ? io->kcp_setting->conv : 0;`
			`kcp_t* kcp = hio_get_kcp(io, conv);`
			`// printf("hio_write_kcp conv=%u=%u\n", conv, kcp->conv);`
			`int nsend = ikcp_send(kcp->ikcp, (const char*)buf, len);`
			`// printf("ikcp_send len=%d nsend=%d\n", (int)len, nsend);`
			`if (nsend < 0) {`
			`hloge("ikcp_send error: %d", nsend);`
			`return nsend;`
			`}`
			`ikcp_update(kcp->ikcp, (IUINT32)io->loop->cur_hrtime / 1000);`
			`return len;`
			`}`

			`int hio_read_kcp (hio_t* io, void* buf, int readbytes) {`
			`IUINT32 conv = ikcp_getconv(buf);`
			`kcp_t* kcp = hio_get_kcp(io, conv);`
			`// printf("hio_read_kcp conv=%u=%u\n", conv, kcp->conv);`
			`if (kcp->conv != conv) {`
			`hloge("recv invalid kcp packet!");`
			`hio_close_rudp(io, io->peeraddr);`
			`return -1;`
			`}`
			`// printf("ikcp_input len=%d\n", readbytes);`
			`int ret = ikcp_input(kcp->ikcp, (const char*)buf, readbytes);`
			`// printf("ikcp_input ret=%d\n", ret);`
			`if (ret != 0) {`
			`return 0;`
			`}`
			`if (kcp->readbuf.base == NULL \|\| kcp->readbuf.len == 0) {`
			`kcp->readbuf.len = DEFAULT_KCP_READ_BUFSIZE;`
			`HV_ALLOC(kcp->readbuf.base, kcp->readbuf.len);`
			`}`
			`while (1) {`
			`int nrecv = ikcp_recv(kcp->ikcp, kcp->readbuf.base, kcp->readbuf.len);`
			`// printf("ikcp_recv nrecv=%d\n", nrecv);`
			`if (nrecv < 0) break;`
			`hio_read_cb(io, kcp->readbuf.base, nrecv);`
			`ret += nrecv;`
			`}`
			`return ret;`
			`}`

			`#endif`