/* * VMM Bus * * COPYRIGHT (C) 2013-2014, Shanghai Real-Thread Technology Co., Ltd * * This file is part of RT-Thread (http://www.rt-thread.org) * * All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * * Change Logs: * Date Author Notes * 2013-11-04 Grissiom add comment */ #include #include #include #include "vbus.h" #include "prio_queue.h" #include "vbus_hw.h" //#define RT_VBUS_STATISTICS #define RT_VBUS_RB_LOW_TICK (RT_VMM_RB_BLK_NR * 2 / 3) #define RT_VBUS_RB_TICK_STEP (100) #ifndef RT_USING_LOGTRACE /* console could be run on vbus. If we log on it, there will be oops. */ #define vbus_debug(...) #define vbus_verbose(...) #define vbus_info(...) #define vbus_error(...) #else // have RT_USING_LOGTRACE #include #if defined(log_session_lvl) /* Define log_trace_session as const so the compiler could optimize some log * out. */ const static struct log_trace_session _lgs = { .id = {.name = "vbus"}, .lvl = LOG_TRACE_LEVEL_VERBOSE, }; #define vbus_debug(fmt, ...) log_session_lvl(&_lgs, LOG_TRACE_LEVEL_DEBUG, fmt, ##__VA_ARGS__) #define vbus_verbose(fmt, ...) log_session_lvl(&_lgs, LOG_TRACE_LEVEL_VERBOSE, fmt, ##__VA_ARGS__) #define vbus_info(fmt, ...) log_session_lvl(&_lgs, LOG_TRACE_LEVEL_INFO, fmt, ##__VA_ARGS__) #define vbus_error(fmt, ...) log_session_lvl(&_lgs, LOG_TRACE_LEVEL_ERROR, fmt, ##__VA_ARGS__) #else static struct log_trace_session _lgs = { .id = {.name = "vbus"}, .lvl = LOG_TRACE_LEVEL_VERBOSE, }; #define vbus_debug(fmt, ...) log_session(&_lgs, LOG_TRACE_DEBUG""fmt, ##__VA_ARGS__) #define vbus_verbose(fmt, ...) log_session(&_lgs, LOG_TRACE_VERBOSE""fmt, ##__VA_ARGS__) #define vbus_info(fmt, ...) log_session(&_lgs, LOG_TRACE_INFO""fmt, ##__VA_ARGS__) #define vbus_error(fmt, ...) log_session(&_lgs, LOG_TRACE_ERROR""fmt, ##__VA_ARGS__) #endif #endif // RT_USING_LOGTRACE #ifndef ARRAY_SIZE #define ARRAY_SIZE(ar) (sizeof(ar)/sizeof(ar[0])) #endif struct rt_vbus_ring *RT_VBUS_OUT_RING; struct rt_vbus_ring *RT_VBUS_IN_RING; const char *rt_vbus_chn_st2str[] = { "available", "closed", "establishing", "established", "suspended", "closing", }; const char *rt_vbus_sess_st2str[] = { "available", "listening", "establishing", }; const char *rt_vbus_cmd2str[] = { "ENABLE", "DISABLE", "SET", "ACK", "NAK", "SUSPEND", "RESUME", }; static char* dump_cmd_pkt(unsigned char *dp, size_t dsize); /* 4 bytes for the head */ #define LEN2BNR(len) ((len + RT_VBUS_BLK_HEAD_SZ \ + sizeof(struct rt_vbus_blk) - 1) \ / sizeof(struct rt_vbus_blk)) rt_inline void _ring_add_get_bnr(struct rt_vbus_ring *ring, rt_size_t bnr) { int nidx = ring->get_idx + bnr; if (nidx >= RT_VMM_RB_BLK_NR) { nidx -= RT_VMM_RB_BLK_NR; } rt_vbus_smp_wmb(); ring->get_idx = nidx; } rt_inline int _bus_ring_space_nr(struct rt_vbus_ring *rg) { int delta; rt_vbus_smp_rmb(); delta = rg->get_idx - rg->put_idx; if (delta > 0) { /* Put is behind the get. */ return delta - 1; } else { /* delta is negative. */ return RT_VMM_RB_BLK_NR + delta - 1; } } struct rt_vbus_pkg { rt_uint8_t id; rt_uint8_t prio; rt_uint8_t finished; rt_uint8_t len; const void *data; }; /* chn0 is always connected */ static enum rt_vbus_chn_status _chn_status[RT_VBUS_CHANNEL_NR]; rt_inline int _chn_connected(unsigned char chnr) { return _chn_status[chnr] == RT_VBUS_CHN_ST_ESTABLISHED || _chn_status[chnr] == RT_VBUS_CHN_ST_SUSPEND; } #ifdef RT_VBUS_USING_FLOW_CONTROL #include struct rt_watermark_queue _chn_wm_que[RT_VBUS_CHANNEL_NR]; void rt_vbus_set_post_wm(unsigned char chnr, unsigned int low, unsigned int high) { RT_ASSERT((0 < chnr) && (chnr < ARRAY_SIZE(_chn_wm_que))); rt_wm_que_set_mark(&_chn_wm_que[chnr], low, high); } /* Threads suspended by the flow control of other side. */ rt_list_t _chn_suspended_threads[RT_VBUS_CHANNEL_NR]; struct { unsigned int level; unsigned int high_mark; unsigned int low_mark; /* The suspend command does not have ACK. So if the other side still * sending pkg after SUSPEND, warn it again. Also use it as a flag that * tell me whether are we dropping from the high mark or not when reaching * the low mark. */ unsigned int last_warn; } _chn_recv_wm[RT_VBUS_CHANNEL_NR]; void rt_vbus_set_recv_wm(unsigned char chnr, unsigned int low, unsigned int high) { RT_ASSERT((0 < chnr) && (chnr < ARRAY_SIZE(_chn_recv_wm))); _chn_recv_wm[chnr].low_mark = low; _chn_recv_wm[chnr].high_mark = high; } #else void rt_vbus_set_recv_wm(unsigned char chnr, unsigned int low, unsigned int high) {} void rt_vbus_set_post_wm(unsigned char chnr, unsigned int low, unsigned int high) {} #endif struct { rt_vbus_event_listener indicate; void *ctx; } _vbus_rx_indi[RT_VBUS_EVENT_ID_MAX][RT_VBUS_CHANNEL_NR]; void rt_vbus_register_listener(unsigned char chnr, enum rt_vbus_event_id eve, rt_vbus_event_listener indi, void *ctx) { RT_ASSERT(chnr != 0 && chnr < RT_VBUS_CHANNEL_NR); RT_ASSERT(eve < sizeof(_vbus_rx_indi)/sizeof(_vbus_rx_indi[0])); _vbus_rx_indi[eve][chnr].indicate = indi; _vbus_rx_indi[eve][chnr].ctx = ctx; } static void _vbus_indicate(enum rt_vbus_event_id eve, unsigned char chnr) { RT_ASSERT(eve < sizeof(_vbus_rx_indi)/sizeof(_vbus_rx_indi[0])); if (_vbus_rx_indi[eve][chnr].indicate) _vbus_rx_indi[eve][chnr].indicate(_vbus_rx_indi[eve][chnr].ctx); } #define _BUS_OUT_THRD_STACK_SZ 2048 #define _BUS_OUT_THRD_PRIO 8 #define _BUS_OUT_PKG_NR RT_VMM_RB_BLK_NR static struct rt_thread _bus_out_thread; static rt_uint8_t _bus_out_thread_stack[_BUS_OUT_THRD_STACK_SZ]; struct rt_prio_queue *_bus_out_que; static void _bus_out_entry(void *param) { struct rt_vbus_pkg dpkg; _bus_out_que = rt_prio_queue_create("vbus", _BUS_OUT_PKG_NR, sizeof(struct rt_vbus_pkg)); if (!_bus_out_que) { rt_kprintf("could not create vmm bus queue\n"); return; } while (rt_prio_queue_pop(_bus_out_que, &dpkg, RT_WAITING_FOREVER) == RT_EOK) { int sp; rt_uint32_t nxtidx; const int dnr = LEN2BNR(dpkg.len); #ifdef RT_VBUS_USING_FLOW_CONTROL rt_wm_que_dec(&_chn_wm_que[dpkg.id]); #endif if (!_chn_connected(dpkg.id)) continue; sp = _bus_ring_space_nr(RT_VBUS_OUT_RING); vbus_debug("vmm bus out" "(data: %p, len: %d, prio: %d, id: %d)\n", dpkg.data, dpkg.len, dpkg.prio, dpkg.id); /* wait for enough space */ while (sp < dnr) { rt_ubase_t lvl = rt_hw_interrupt_disable(); RT_VBUS_OUT_RING->blocked = 1; rt_vbus_smp_wmb(); /* kick the guest, hoping this could force it do the work */ rt_vbus_tick(0, RT_VBUS_GUEST_VIRQ); rt_thread_suspend(rt_thread_self()); rt_schedule(); RT_VBUS_OUT_RING->blocked = 0; rt_hw_interrupt_enable(lvl); sp = _bus_ring_space_nr(RT_VBUS_OUT_RING); } nxtidx = RT_VBUS_OUT_RING->put_idx + dnr; RT_VBUS_OUT_RING->blks[RT_VBUS_OUT_RING->put_idx].id = dpkg.id; RT_VBUS_OUT_RING->blks[RT_VBUS_OUT_RING->put_idx].qos = dpkg.prio; RT_VBUS_OUT_RING->blks[RT_VBUS_OUT_RING->put_idx].len = dpkg.len; if (nxtidx >= RT_VMM_RB_BLK_NR) { unsigned int tailsz; tailsz = (RT_VMM_RB_BLK_NR - RT_VBUS_OUT_RING->put_idx) * sizeof(RT_VBUS_OUT_RING->blks[0]) - RT_VBUS_BLK_HEAD_SZ; /* the remaining block is sufficient for the data */ if (tailsz > dpkg.len) tailsz = dpkg.len; rt_memcpy(&RT_VBUS_OUT_RING->blks[RT_VBUS_OUT_RING->put_idx].data, dpkg.data, tailsz); rt_memcpy(&RT_VBUS_OUT_RING->blks[0], ((char*)dpkg.data)+tailsz, dpkg.len - tailsz); rt_vbus_smp_wmb(); RT_VBUS_OUT_RING->put_idx = nxtidx - RT_VMM_RB_BLK_NR; } else { rt_memcpy(&RT_VBUS_OUT_RING->blks[RT_VBUS_OUT_RING->put_idx].data, dpkg.data, dpkg.len); rt_vbus_smp_wmb(); RT_VBUS_OUT_RING->put_idx = nxtidx; } rt_vbus_smp_wmb(); rt_vbus_tick(0, RT_VBUS_GUEST_VIRQ); if (dpkg.finished) { _vbus_indicate(RT_VBUS_EVENT_ID_TX, dpkg.id); } } RT_ASSERT(0); } void rt_vbus_resume_out_thread(void) { rt_thread_resume(&_bus_out_thread); rt_schedule(); } rt_err_t rt_vbus_post(rt_uint8_t id, rt_uint8_t prio, const void *data, rt_size_t size, rt_int32_t timeout) { rt_err_t err = RT_EOK; struct rt_vbus_pkg pkg; unsigned int putsz; const unsigned char *dp; if (!_bus_out_que) { rt_kprintf("post (data: %p, size: %d, timeout: %d) " "to bus before initialition\n", data, size, timeout); return -RT_ERROR; } if (id >= RT_VBUS_CHANNEL_NR) return -RT_ERROR; if (timeout != 0) { RT_DEBUG_IN_THREAD_CONTEXT; } #ifdef RT_VBUS_USING_FLOW_CONTROL while (_chn_status[id] == RT_VBUS_CHN_ST_SUSPEND) { rt_thread_t thread; if (timeout == 0) { return -RT_EFULL; } thread = rt_thread_self(); thread->error = RT_EOK; /* We only touch the _chn_suspended_threads in thread, so lock the * scheduler is enough. */ rt_enter_critical(); rt_thread_suspend(thread); rt_list_insert_after(&_chn_suspended_threads[id], &thread->tlist); if (timeout > 0) { rt_timer_control(&(thread->thread_timer), RT_TIMER_CTRL_SET_TIME, &timeout); rt_timer_start(&(thread->thread_timer)); } /* rt_exit_critical will do schedule on need. */ rt_exit_critical(); if (thread->error != RT_EOK) return thread->error; } #endif if (_chn_status[id] != RT_VBUS_CHN_ST_ESTABLISHED) return -RT_ERROR; dp = data; pkg.id = id; pkg.prio = prio; for (putsz = 0; size; size -= putsz) { pkg.data = dp; if (size > RT_VBUS_MAX_PKT_SZ) { putsz = RT_VBUS_MAX_PKT_SZ; pkg.finished = 0; } else { putsz = size; pkg.finished = 1; } pkg.len = putsz; dp += putsz; #ifdef RT_VBUS_USING_FLOW_CONTROL err = rt_wm_que_inc(&_chn_wm_que[id], timeout); if (err != RT_EOK) break; #endif vbus_debug("post (data: %p(%d), size: %d, finshed: %d, timeout: %d)\n", pkg.data, ((unsigned char*)pkg.data)[0], pkg.len, pkg.finished, timeout); err = rt_prio_queue_push(_bus_out_que, prio, &pkg, timeout); if (err != RT_EOK) break; } return err; } struct rt_completion _chn0_post_cmp; void _chn0_tx_listener(void *p) { rt_completion_done(&_chn0_post_cmp); } /* Posts in channel0 should be sync. */ static rt_err_t _chn0_post(const void *data, rt_size_t size, int timeout) { rt_err_t err; rt_completion_init(&_chn0_post_cmp); err = rt_vbus_post(0, 0, data, size, timeout); if (err != RT_EOK) return err; return rt_completion_wait(&_chn0_post_cmp, timeout); } #define _BUS_IN_THRD_STACK_SZ 1024 #define _BUS_IN_THRD_PRIO (_BUS_OUT_THRD_PRIO+1) #if (_BUS_IN_THRD_PRIO == RT_THREAD_PRIORITY_MAX) #error "_BUS_OUT_THRD_PRIO too low" #endif static struct rt_thread _bus_in_thread; static rt_uint8_t _bus_in_thread_stack[_BUS_OUT_THRD_STACK_SZ]; static struct rt_semaphore _bus_in_sem; static struct rt_event _bus_in_event; /* {head, tail} */ #define _IN_ACT_HEAD 0 #define _IN_ACT_TAIL 1 static struct rt_vbus_data *_bus_in_action[RT_VBUS_CHANNEL_NR][2]; #ifdef RT_VBUS_STATISTICS static unsigned int _bus_in_action_nr[RT_VBUS_CHANNEL_NR]; #endif static void rt_vbus_notify_chn(unsigned char chnr, rt_err_t err) { #ifdef RT_VBUS_USING_FLOW_CONTROL /* TODO: get rid of this */ /* Protect the list. */ rt_enter_critical(); while (!rt_list_isempty(&_chn_suspended_threads[chnr])) { rt_thread_t thread; thread = rt_list_entry(_chn_suspended_threads[chnr].next, struct rt_thread, tlist); thread->error = err; rt_thread_resume(thread); } rt_exit_critical(); #endif rt_event_send(&_bus_in_event, 1 << chnr); } static void rt_vbus_notify_set(rt_uint32_t set) { rt_event_send(&_bus_in_event, set); } rt_err_t rt_vbus_listen_on(rt_uint8_t chnr, rt_int32_t timeout) { rt_uint32_t notuse; if (chnr == 0 || chnr >= RT_VBUS_CHANNEL_NR || !_chn_connected(chnr)) return -RT_EIO; return rt_event_recv(&_bus_in_event, 1 << chnr, RT_EVENT_FLAG_OR | RT_EVENT_FLAG_CLEAR, timeout, ¬use); } void rt_vbus_data_push(unsigned int id, struct rt_vbus_data *act) { rt_ubase_t lvl; RT_ASSERT(0 < id && id < RT_VBUS_CHANNEL_NR); lvl = rt_hw_interrupt_disable(); if (_bus_in_action[id][_IN_ACT_HEAD] == RT_NULL) { _bus_in_action[id][_IN_ACT_HEAD] = act; _bus_in_action[id][_IN_ACT_TAIL] = act; } else { _bus_in_action[id][_IN_ACT_TAIL]->next = act; _bus_in_action[id][_IN_ACT_TAIL] = act; } #ifdef RT_VBUS_STATISTICS _bus_in_action_nr[id]++; #endif rt_hw_interrupt_enable(lvl); #ifdef RT_VBUS_USING_FLOW_CONTROL _chn_recv_wm[id].level++; if (_chn_recv_wm[id].level == 0) _chn_recv_wm[id].level = ~0; if (_chn_recv_wm[id].level > _chn_recv_wm[id].high_mark && _chn_recv_wm[id].level > _chn_recv_wm[id].last_warn) { unsigned char buf[2]; buf[0] = RT_VBUS_CHN0_CMD_SUSPEND; buf[1] = id; vbus_debug("%s --> remote\n", dump_cmd_pkt(buf, sizeof(buf))); _chn0_post(buf, sizeof(buf), RT_WAITING_FOREVER); /* Warn the other side in 100 more pkgs. */ _chn_recv_wm[id].last_warn = _chn_recv_wm[id].level + 100; } #endif } struct rt_vbus_data* rt_vbus_data_pop(unsigned int id) { struct rt_vbus_data *act; rt_ubase_t lvl; RT_ASSERT(0 < id && id < RT_VBUS_CHANNEL_NR); lvl = rt_hw_interrupt_disable(); act = _bus_in_action[id][_IN_ACT_HEAD]; if (act) { _bus_in_action[id][_IN_ACT_HEAD] = act->next; } rt_hw_interrupt_enable(lvl); #ifdef RT_VBUS_USING_FLOW_CONTROL if (_chn_recv_wm[id].level != 0) { _chn_recv_wm[id].level--; if (_chn_recv_wm[id].level <= _chn_recv_wm[id].low_mark && _chn_recv_wm[id].last_warn > _chn_recv_wm[id].low_mark) { unsigned char buf[2]; buf[0] = RT_VBUS_CHN0_CMD_RESUME; buf[1] = id; vbus_debug("%s --> remote\n", dump_cmd_pkt(buf, sizeof(buf))); _chn0_post(buf, sizeof(buf), RT_WAITING_FOREVER); _chn_recv_wm[id].last_warn = 0; } } #endif return act; } /* dump cmd that is not start with ACK/NAK */ static size_t __dump_naked_cmd(char *dst, size_t lsize, unsigned char *dp, size_t dsize) { size_t len; if (dp[0] == RT_VBUS_CHN0_CMD_DISABLE || dp[0] == RT_VBUS_CHN0_CMD_SUSPEND || dp[0] == RT_VBUS_CHN0_CMD_RESUME) { len = rt_snprintf(dst, lsize, "%s %d", rt_vbus_cmd2str[dp[0]], dp[1]); } else if (dp[0] == RT_VBUS_CHN0_CMD_ENABLE) { len = rt_snprintf(dst, lsize, "%s %s", rt_vbus_cmd2str[dp[0]], dp+1); } else if (dp[0] < RT_VBUS_CHN0_CMD_MAX) { len = rt_snprintf(dst, lsize, "%s %s %d", rt_vbus_cmd2str[dp[0]], dp+1, dp[2+rt_strlen((char*)dp+1)]); } else { len = rt_snprintf(dst, lsize, "(invalid)%d %d", dp[0], dp[1]); } return len; } static char _cmd_dump_buf[64]; static char* dump_cmd_pkt(unsigned char *dp, size_t dsize) { size_t len; if (dp[0] == RT_VBUS_CHN0_CMD_ACK || dp[0] == RT_VBUS_CHN0_CMD_NAK ) { len = rt_snprintf(_cmd_dump_buf, sizeof(_cmd_dump_buf), "%s ", rt_vbus_cmd2str[dp[0]]); len += __dump_naked_cmd(_cmd_dump_buf+len, sizeof(_cmd_dump_buf)-len, dp+1, dsize-1); } else { len = __dump_naked_cmd(_cmd_dump_buf, sizeof(_cmd_dump_buf), dp, dsize); } if (len > sizeof(_cmd_dump_buf) - 1) len = sizeof(_cmd_dump_buf) - 1; _cmd_dump_buf[len] = '\0'; return _cmd_dump_buf; } static rt_err_t _chn0_echo_with(rt_uint8_t prefix, rt_uint32_t dsize, unsigned char *dp) { rt_err_t err; unsigned char *resp; resp = rt_malloc(dsize+1); if (!resp) return -RT_ENOMEM; *resp = prefix; rt_memcpy(resp+1, dp, dsize); vbus_verbose("%s --> remote\n", dump_cmd_pkt(resp, dsize+1)); err = _chn0_post(resp, dsize+1, RT_WAITING_FOREVER); rt_free(resp); return err; } static rt_err_t _chn0_nak(rt_uint32_t dsize, unsigned char *dp) { return _chn0_echo_with(RT_VBUS_CHN0_CMD_NAK, dsize, dp); } static rt_err_t _chn0_ack(rt_uint32_t dsize, unsigned char *dp) { return _chn0_echo_with(RT_VBUS_CHN0_CMD_ACK, dsize, dp); } enum _vbus_session_st { SESSIOM_AVAILABLE, SESSIOM_LISTENING, SESSIOM_ESTABLISHING, }; struct rt_vbus_conn_session { /* negative value means error */ int chnr; enum _vbus_session_st st; struct rt_completion cmp; struct rt_vbus_request *req; }; static struct rt_vbus_conn_session _sess[RT_VBUS_CHANNEL_NR/2]; static int _sess_find(const unsigned char *name, enum _vbus_session_st st) { int i; for (i = 0; i < ARRAY_SIZE(_sess); i++) { if (_sess[i].st == st && _sess[i].req->name && rt_strcmp(_sess[i].req->name, (char*)name) == 0) break; } return i; } static int _chn0_actor(unsigned char *dp, size_t dsize) { if (*dp != RT_VBUS_CHN0_CMD_SUSPEND && *dp != RT_VBUS_CHN0_CMD_RESUME) vbus_verbose("local <-- %s\n", dump_cmd_pkt(dp, dsize)); switch (*dp) { case RT_VBUS_CHN0_CMD_ENABLE: { int i, chnr; rt_err_t err; unsigned char *resp; i = _sess_find(dp+1, SESSIOM_LISTENING); if (i == ARRAY_SIZE(_sess)) { _chn0_nak(dsize, dp); break; } for (chnr = 0; chnr < ARRAY_SIZE(_chn_status); chnr++) { if (_chn_status[chnr] == RT_VBUS_CHN_ST_AVAILABLE) break; } if (chnr == ARRAY_SIZE(_chn_status)) { _chn0_nak(dsize, dp); break; } resp = rt_malloc(dsize + 1); if (!resp) break; *resp = RT_VBUS_CHN0_CMD_SET; rt_memcpy(resp+1, dp+1, dsize-1); resp[dsize] = chnr; rt_vbus_set_recv_wm(chnr, _sess[i].req->recv_wm.low, _sess[i].req->recv_wm.high); rt_vbus_set_post_wm(chnr, _sess[i].req->post_wm.low, _sess[i].req->post_wm.high); vbus_verbose("%s --> remote\n", dump_cmd_pkt(resp, dsize+1)); err = _chn0_post(resp, dsize+1, RT_WAITING_FOREVER); if (err == RT_EOK) { _sess[i].st = SESSIOM_ESTABLISHING; vbus_debug("set sess %d st: %s\n", i, rt_vbus_sess_st2str[_sess[i].st]); _sess[i].chnr = chnr; _chn_status[chnr] = RT_VBUS_CHN_ST_ESTABLISHING; } rt_free(resp); } break; case RT_VBUS_CHN0_CMD_SET: { int i, chnr; i = _sess_find(dp+1, SESSIOM_ESTABLISHING); if (i == ARRAY_SIZE(_sess)) { vbus_verbose("drop spurious packet\n"); break; } chnr = dp[1+rt_strlen((const char*)dp+1)+1]; if (chnr == 0 || chnr >= RT_VBUS_CHANNEL_NR) { vbus_verbose("SET wrong chnr %d\n", chnr); break; } if (_chn_status[chnr] != RT_VBUS_CHN_ST_AVAILABLE) { _chn0_nak(dsize, dp); vbus_verbose("SET wrong chnr status %d, %s\n", chnr, rt_vbus_chn_st2str[_chn_status[chnr]]); break; } rt_vbus_set_recv_wm(chnr, _sess[i].req->recv_wm.low, _sess[i].req->recv_wm.high); rt_vbus_set_post_wm(chnr, _sess[i].req->post_wm.low, _sess[i].req->post_wm.high); if (_chn0_ack(dsize, dp) >= 0) { _sess[i].chnr = chnr; _chn_status[chnr] = RT_VBUS_CHN_ST_ESTABLISHED; vbus_debug("chn %d %s\n", chnr, rt_vbus_chn_st2str[_chn_status[chnr]]); rt_completion_done(&_sess[i].cmp); } } break; case RT_VBUS_CHN0_CMD_ACK: if (dp[1] == RT_VBUS_CHN0_CMD_SET) { int i, chnr; i = _sess_find(dp+2, SESSIOM_ESTABLISHING); if (i == ARRAY_SIZE(_sess)) /* drop that spurious packet */ break; chnr = dp[1+rt_strlen((const char*)dp+2)+2]; _sess[i].chnr = chnr; _chn_status[chnr] = RT_VBUS_CHN_ST_ESTABLISHED; vbus_debug("chn %d %s\n", chnr, rt_vbus_chn_st2str[_chn_status[chnr]]); rt_completion_done(&_sess[i].cmp); } else if (dp[1] == RT_VBUS_CHN0_CMD_DISABLE) { unsigned char chnr = dp[2]; if (chnr == 0 || chnr >= RT_VBUS_CHANNEL_NR) break; /* We could only get here by sending DISABLE command, which is * initiated by the rt_vbus_close_chn. */ _chn_status[chnr] = RT_VBUS_CHN_ST_AVAILABLE; _vbus_indicate(RT_VBUS_EVENT_ID_DISCONN, chnr); /* notify the thread that the channel has been closed */ rt_vbus_notify_chn(chnr, -RT_ERROR); } else { vbus_info("invalid ACK for %d\n", dp[1]); } break; case RT_VBUS_CHN0_CMD_DISABLE: { unsigned char chnr = dp[1]; if (chnr == 0 || chnr >= RT_VBUS_CHANNEL_NR) break; _chn_status[chnr] = RT_VBUS_CHN_ST_CLOSING; _chn0_ack(dsize, dp); _vbus_indicate(RT_VBUS_EVENT_ID_DISCONN, chnr); /* notify the thread that the channel has been closed */ rt_vbus_notify_chn(chnr, -RT_ERROR); } break; case RT_VBUS_CHN0_CMD_SUSPEND: #ifdef RT_VBUS_USING_FLOW_CONTROL { unsigned char chnr = dp[1]; if (chnr == 0 || chnr >= RT_VBUS_CHANNEL_NR) break; if (_chn_status[chnr] != RT_VBUS_CHN_ST_ESTABLISHED) break; _chn_status[chnr] = RT_VBUS_CHN_ST_SUSPEND; } #endif break; case RT_VBUS_CHN0_CMD_RESUME: #ifdef RT_VBUS_USING_FLOW_CONTROL { unsigned char chnr = dp[1]; if (chnr == 0 || chnr >= RT_VBUS_CHANNEL_NR) break; if (_chn_status[chnr] != RT_VBUS_CHN_ST_SUSPEND) break; _chn_status[chnr] = RT_VBUS_CHN_ST_ESTABLISHED; /* Protect the list. */ rt_enter_critical(); while (!rt_list_isempty(&_chn_suspended_threads[chnr])) { rt_thread_t thread; thread = rt_list_entry(_chn_suspended_threads[chnr].next, struct rt_thread, tlist); rt_thread_resume(thread); } rt_exit_critical(); } #endif break; case RT_VBUS_CHN0_CMD_NAK: if (dp[1] == RT_VBUS_CHN0_CMD_ENABLE) { int i; i = _sess_find(dp+2, SESSIOM_ESTABLISHING); if (i == ARRAY_SIZE(_sess)) /* drop that spurious packet */ break; _sess[i].chnr = -RT_EIO; rt_completion_done(&_sess[i].cmp); } else if (dp[1] == RT_VBUS_CHN0_CMD_SET) { vbus_info("NAK for %d not implemented\n", dp[1]); } else { vbus_info("invalid NAK for %d\n", dp[1]); } break; default: /* just ignore the invalid cmd */ vbus_info("drop unknown cmd %d on chn0\n", *dp); break; }; return RT_EOK; } int rt_vbus_request_chn(struct rt_vbus_request *req, int timeout) { int i, chnr, err; size_t plen = rt_strlen(req->name) + 2; unsigned char *pbuf; rt_ubase_t lvl; lvl = rt_hw_interrupt_disable(); for (i = 0; i < ARRAY_SIZE(_sess); i++) { if (_sess[i].st == SESSIOM_AVAILABLE) break; } if (i == ARRAY_SIZE(_sess)) { rt_hw_interrupt_enable(lvl); return -RT_ERROR; } rt_completion_init(&_sess[i].cmp); _sess[i].req = req; if (req->is_server) { _sess[i].st = SESSIOM_LISTENING; rt_hw_interrupt_enable(lvl); vbus_debug("request listening %s on %d\n", req->name, i); /* always wait on the condition */ err = RT_EOK; goto _waitforcmp; } pbuf = rt_malloc(plen); if (!pbuf) { rt_hw_interrupt_enable(lvl); return -RT_ENOMEM; } _sess[i].st = SESSIOM_ESTABLISHING; rt_hw_interrupt_enable(lvl); pbuf[0] = RT_VBUS_CHN0_CMD_ENABLE; rt_memcpy(pbuf+1, req->name, plen-1); vbus_verbose("%s --> remote\n", dump_cmd_pkt(pbuf, plen)); err = _chn0_post(pbuf, plen, RT_WAITING_FOREVER); rt_free(pbuf); _waitforcmp: if (err == RT_EOK) err = rt_completion_wait(&_sess[i].cmp, timeout); vbus_debug("request wait cmp done %d, chnr %d\n", err, _sess[i].chnr); if (err) { /* cleanup the mass when the wait is time out but we have done some job */ if (_sess[i].st == SESSIOM_ESTABLISHING) _chn_status[_sess[i].chnr] = RT_VBUS_CHN_ST_AVAILABLE; chnr = err; goto Out; } RT_ASSERT(_sess[i].chnr != 0); chnr = _sess[i].chnr; Out: /* detach the sess as we finished the job */ _sess[i].st = SESSIOM_AVAILABLE; _sess[i].req = RT_NULL; return chnr; } void rt_vbus_close_chn(unsigned char chnr) { void *p; rt_err_t err; unsigned char buf[2]; buf[0] = RT_VBUS_CHN0_CMD_DISABLE; buf[1] = chnr; RT_ASSERT(0 < chnr && chnr < RT_VBUS_CHANNEL_NR); if (_chn_status[chnr] == RT_VBUS_CHN_ST_CLOSED || _chn_status[chnr] == RT_VBUS_CHN_ST_CLOSING) { _chn_status[chnr] = RT_VBUS_CHN_ST_AVAILABLE; return; } if (!_chn_connected(chnr)) return; _chn_status[chnr] = RT_VBUS_CHN_ST_CLOSING; vbus_info("%s --> remote\n", dump_cmd_pkt(buf, sizeof(buf))); err = _chn0_post(&buf, sizeof(buf), RT_WAITING_FOREVER); if (err == RT_EOK) /* wait for the ack */ rt_vbus_listen_on(chnr, 10 * RT_TICK_PER_SECOND); /* cleanup the remaining data */ for (p = rt_vbus_data_pop(chnr); p; p = rt_vbus_data_pop(chnr)) rt_free(p); /* FIXME: there is a chance that there are some data left on the send * buffer. So if we connect other channel with the same number immediately, * the new channel will receive some garbage data. However, this is highly * un-probable. */ } #ifdef RT_VBUS_STATISTICS static unsigned int _total_data_sz; #endif static void _bus_in_entry(void *param) { rt_sem_init(&_bus_in_sem, "vbus", 0, RT_IPC_FLAG_FIFO); rt_event_init(&_bus_in_event, "vbus", RT_IPC_FLAG_FIFO); rt_memset(_bus_in_action, 0, sizeof(_bus_in_action)); while (rt_sem_take(&_bus_in_sem, RT_WAITING_FOREVER) == RT_EOK) { rt_uint32_t event_set = 0; /* while(not empty) */ while (RT_VBUS_IN_RING->get_idx != RT_VBUS_IN_RING->put_idx) { unsigned int id, nxtidx; rt_size_t size; struct rt_vbus_data *act; rt_vbus_smp_rmb(); size = RT_VBUS_IN_RING->blks[RT_VBUS_IN_RING->get_idx].len; id = RT_VBUS_IN_RING->blks[RT_VBUS_IN_RING->get_idx].id; vbus_debug("vmm bus in: chnr %d, size %d\n", id, size); /* Suspended channel can still recv data. */ if (id > RT_VBUS_CHANNEL_NR || !_chn_connected(id)) { vbus_error("drop on invalid chn %d\n", id); /* drop the invalid packet */ _ring_add_get_bnr(RT_VBUS_IN_RING, LEN2BNR(size)); continue; } if (id == 0) { if (size > 60) vbus_error("too big(%d) packet on chn0\n", size); else _chn0_actor(RT_VBUS_IN_RING->blks[RT_VBUS_IN_RING->get_idx].data, size); _ring_add_get_bnr(RT_VBUS_IN_RING, LEN2BNR(size)); continue; } #ifdef RT_VBUS_STATISTICS _total_data_sz += size; #endif act = rt_malloc(sizeof(*act) + size); if (act == RT_NULL) { //vbus_error("drop on OOM (%d, %d)\n", id, size); /* drop the packet on malloc fall */ _ring_add_get_bnr(RT_VBUS_IN_RING, LEN2BNR(size)); continue; } act->size = size; act->next = RT_NULL; nxtidx = RT_VBUS_IN_RING->get_idx + LEN2BNR(size); if (nxtidx >= RT_VMM_RB_BLK_NR) { unsigned int tailsz; tailsz = (RT_VMM_RB_BLK_NR - RT_VBUS_IN_RING->get_idx) * sizeof(RT_VBUS_IN_RING->blks[0]) - RT_VBUS_BLK_HEAD_SZ; /* the remaining block is sufficient for the data */ if (tailsz > size) tailsz = size; rt_memcpy(act+1, &RT_VBUS_IN_RING->blks[RT_VBUS_IN_RING->get_idx].data, tailsz); rt_memcpy((char*)(act+1) + tailsz, &RT_VBUS_IN_RING->blks[0], size - tailsz); /* It shall make sure the CPU has finished reading the item * before it writes the new tail pointer, which will erase the * item. */ rt_vbus_smp_wmb(); RT_VBUS_IN_RING->get_idx = nxtidx - RT_VMM_RB_BLK_NR; } else { rt_memcpy(act+1, &RT_VBUS_IN_RING->blks[RT_VBUS_IN_RING->get_idx].data, size); rt_vbus_smp_wmb(); RT_VBUS_IN_RING->get_idx = nxtidx; } rt_vbus_data_push(id, act); _vbus_indicate(RT_VBUS_EVENT_ID_RX, id); event_set |= 1 << id; if (RT_VBUS_IN_RING->blocked) rt_vbus_tick(0, RT_VBUS_GUEST_VIRQ); } if (event_set != 0) rt_vbus_notify_set(event_set); } RT_ASSERT(0); } void rt_vbus_isr(int irqnr, void *param) { if (RT_VBUS_OUT_RING->blocked) rt_vbus_resume_out_thread(); rt_sem_release(&_bus_in_sem); rt_vbus_hw_eoi(irqnr, param); } int rt_vbus_init(void *outr, void *inr) { int i; #ifdef RT_USING_LOGTRACE log_trace_register_session(&_lgs); #endif if (outr > inr) { RT_ASSERT((char*)outr - (char*)inr >= sizeof(struct rt_vbus_ring)); } else { RT_ASSERT((char*)inr - (char*)outr >= sizeof(struct rt_vbus_ring)); } RT_VBUS_OUT_RING = outr; RT_VBUS_IN_RING = inr; rt_memset(RT_VBUS_OUT_RING, 0, sizeof(*RT_VBUS_OUT_RING)); rt_memset(RT_VBUS_IN_RING, 0, sizeof(*RT_VBUS_IN_RING)); _chn_status[0] = RT_VBUS_CHN_ST_ESTABLISHED; for (i = 1; i < ARRAY_SIZE(_chn_status); i++) { _chn_status[i] = RT_VBUS_CHN_ST_AVAILABLE; } for (i = 0; i < ARRAY_SIZE(_sess); i++) { _sess[i].req = RT_NULL; _sess[i].st = SESSIOM_AVAILABLE; } _vbus_rx_indi[RT_VBUS_EVENT_ID_TX][0].indicate = _chn0_tx_listener; _vbus_rx_indi[RT_VBUS_EVENT_ID_TX][0].ctx = RT_NULL; #ifdef RT_VBUS_USING_FLOW_CONTROL for (i = 0; i < ARRAY_SIZE(_chn_wm_que); i++) { rt_wm_que_init(&_chn_wm_que[i], RT_VMM_RB_BLK_NR / 3, RT_VMM_RB_BLK_NR * 2 / 3); } /* Channel 0 has the full channel. */ rt_wm_que_set_mark(&_chn_wm_que[0], 0, ~0); for (i = 0; i < ARRAY_SIZE(_chn_suspended_threads); i++) { rt_list_init(&_chn_suspended_threads[i]); } for (i = 1; i < ARRAY_SIZE(_chn_recv_wm); i++) { rt_vbus_set_recv_wm(i, RT_VMM_RB_BLK_NR / 3, RT_VMM_RB_BLK_NR * 2 / 3); _chn_recv_wm[i].level = 0; _chn_recv_wm[i].last_warn = 0; } /* Channel 0 has the full channel. Don't suspend it. */ _chn_recv_wm[0].low_mark = 0; _chn_recv_wm[0].high_mark = ~0; _chn_recv_wm[0].level = 0; _chn_recv_wm[0].last_warn = 0; #endif rt_thread_init(&_bus_out_thread, "vbusout", _bus_out_entry, RT_NULL, _bus_out_thread_stack, sizeof(_bus_out_thread_stack), _BUS_OUT_THRD_PRIO, 20); rt_thread_startup(&_bus_out_thread); rt_thread_init(&_bus_in_thread, "vbusin", _bus_in_entry, RT_NULL, _bus_in_thread_stack, sizeof(_bus_in_thread_stack), _BUS_IN_THRD_PRIO, 20); rt_thread_startup(&_bus_in_thread); rt_vbus_hw_init(); rt_kprintf("VBus loaded: %d out blocks, %d in blocks\n", RT_VMM_RB_BLK_NR, RT_VMM_RB_BLK_NR); rt_vbus_chnx_init(); return 0; } void rt_vbus_rb_dump(void) { rt_kprintf("OUT ring:(%s blocked)\n", RT_VBUS_OUT_RING->blocked ? "is" : "not"); rt_kprintf("put idx: %8x, get idx: %8x\n", RT_VBUS_OUT_RING->put_idx, RT_VBUS_OUT_RING->get_idx); rt_kprintf("space: %d\n", _bus_ring_space_nr(RT_VBUS_OUT_RING)); rt_kprintf("IN ring:(%s blocked)\n", RT_VBUS_IN_RING->blocked ? "is" : "not"); rt_kprintf("put idx: %8x, get idx: %8x\n", RT_VBUS_IN_RING->put_idx, RT_VBUS_IN_RING->get_idx); rt_kprintf("space: %d\n", _bus_ring_space_nr(RT_VBUS_IN_RING)); } void rt_vbus_chn_dump(void) { int i; rt_kprintf("vbus channel status:\n"); for (i = 0; i < ARRAY_SIZE(_chn_status); i++) { rt_kprintf("%2d:%s\n", i, rt_vbus_chn_st2str[_chn_status[i]]); } } void rt_vbus_sess_dump(void) { int i; rt_kprintf("vbus conn session:\n"); for (i = 0; i < ARRAY_SIZE(_sess); i++) { rt_kprintf("%2d(%s):%s\n", i, _sess[i].req ? _sess[i].req->name : "", rt_vbus_sess_st2str[_sess[i].st]); } } void rt_vbus_que_dump(void) { rt_kprintf("out que:\n"); rt_prio_queue_dump(_bus_out_que); } unsigned int rt_vbus_total_data_sz(void) { #ifdef RT_VBUS_STATISTICS return _total_data_sz; #else return (unsigned int)-1; #endif } void rt_vbus_data_pkt_dump(void) { int i; for (i = 0; i < ARRAY_SIZE(_bus_in_action); i++) { struct rt_vbus_data *dp; #ifdef RT_VBUS_STATISTICS rt_kprintf("%2d %4d: ", i, _bus_in_action_nr[i]); #else rt_kprintf("%2d: ", i); #endif for (dp = _bus_in_action[i][_IN_ACT_HEAD]; dp; dp = dp->next) { rt_kprintf("%p(%d) -> ", dp, dp->size); } rt_kprintf(" nil\n"); } } #ifdef RT_VBUS_USING_FLOW_CONTROL void rt_vbus_chm_wm_dump(void) { int i; rt_kprintf("post wm:\n"); for (i = 0; i < ARRAY_SIZE(_chn_wm_que); i++) rt_wm_que_dump(&_chn_wm_que[i]); rt_kprintf("recv wm:\n"); rt_kprintf(" low, high, cur, last warn\n"); for (i = 0; i < ARRAY_SIZE(_chn_recv_wm); i++) { rt_kprintf("%8x, %8x, %8x, %8x\n", _chn_recv_wm[i].low_mark, _chn_recv_wm[i].high_mark, _chn_recv_wm[i].level, _chn_recv_wm[i].last_warn); } } #endif #ifdef RT_USING_FINSH #include FINSH_FUNCTION_EXPORT_ALIAS(rt_vbus_rb_dump, vbrb, dump vbus ringbuffer status); FINSH_FUNCTION_EXPORT_ALIAS(rt_vbus_chn_dump, vbchn, dump vbus channel status); FINSH_FUNCTION_EXPORT_ALIAS(rt_vbus_sess_dump, vbses, dump vbus session status); FINSH_FUNCTION_EXPORT_ALIAS(rt_vbus_que_dump, vbque, dump vbus out queue status); FINSH_FUNCTION_EXPORT_ALIAS(rt_vbus_total_data_sz, vbtsz, total in data); FINSH_FUNCTION_EXPORT_ALIAS(rt_vbus_data_pkt_dump, vbdq, dump the data queue); #ifdef RT_VBUS_USING_FLOW_CONTROL FINSH_FUNCTION_EXPORT_ALIAS(rt_vbus_chm_wm_dump, vbwm, dump vbus water mark status); #endif #endif