- 根目录:
- drivers
- staging
- crystalhd
- crystalhd_cmds.c
/***************************************************************************
* Copyright (c) 2005-2009, Broadcom Corporation.
*
* Name: crystalhd_cmds . c
*
* Description:
* BCM70010 Linux driver user command interfaces.
*
* HISTORY:
*
**********************************************************************
* This file is part of the crystalhd device driver.
*
* This driver 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, version 2 of the License.
*
* This driver 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 driver. If not, see <http://www.gnu.org/licenses/>.
**********************************************************************/
#include "crystalhd_cmds.h"
#include "crystalhd_hw.h"
static struct crystalhd_user *bc_cproc_get_uid(struct crystalhd_cmd *ctx)
{
struct crystalhd_user *user = NULL;
int i;
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
if (!ctx->user[i].in_use) {
user = &ctx->user[i];
break;
}
}
return user;
}
static int bc_cproc_get_user_count(struct crystalhd_cmd *ctx)
{
int i, count = 0;
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
if (ctx->user[i].in_use)
count++;
}
return count;
}
static void bc_cproc_mark_pwr_state(struct crystalhd_cmd *ctx)
{
int i;
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
if (!ctx->user[i].in_use)
continue;
if (ctx->user[i].mode == DTS_DIAG_MODE ||
ctx->user[i].mode == DTS_PLAYBACK_MODE) {
ctx->pwr_state_change = 1;
break;
}
}
}
static enum BC_STATUS bc_cproc_notify_mode(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
int rc = 0, i = 0;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
if (ctx->user[idata->u_id].mode != DTS_MODE_INV) {
BCMLOG_ERR("Close the handle first..\n");
return BC_STS_ERR_USAGE;
}
if (idata->udata.u.NotifyMode.Mode == DTS_MONITOR_MODE) {
ctx->user[idata->u_id].mode = idata->udata.u.NotifyMode.Mode;
return BC_STS_SUCCESS;
}
if (ctx->state != BC_LINK_INVALID) {
BCMLOG_ERR("Link invalid state %d\n", ctx->state);
return BC_STS_ERR_USAGE;
}
/* Check for duplicate playback sessions..*/
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
if (ctx->user[i].mode == DTS_DIAG_MODE ||
ctx->user[i].mode == DTS_PLAYBACK_MODE) {
BCMLOG_ERR("multiple playback sessions are not "
"supported..\n");
return BC_STS_ERR_USAGE;
}
}
ctx->cin_wait_exit = 0;
ctx->user[idata->u_id].mode = idata->udata.u.NotifyMode.Mode;
/* Setup mmap pool for uaddr sgl mapping..*/
rc = crystalhd_create_dio_pool(ctx->adp, BC_LINK_MAX_SGLS);
if (rc)
return BC_STS_ERROR;
/* Setup Hardware DMA rings */
return crystalhd_hw_setup_dma_rings(&ctx->hw_ctx);
}
static enum BC_STATUS bc_cproc_get_version(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
idata->udata.u.VerInfo.DriverMajor = crystalhd_kmod_major;
idata->udata.u.VerInfo.DriverMinor = crystalhd_kmod_minor;
idata->udata.u.VerInfo.DriverRevision = crystalhd_kmod_rev;
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_get_hwtype(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
crystalhd_pci_cfg_rd(ctx->adp, 0, 2,
(uint32_t *)&idata->udata.u.hwType.PciVenId);
crystalhd_pci_cfg_rd(ctx->adp, 2, 2,
(uint32_t *)&idata->udata.u.hwType.PciDevId);
crystalhd_pci_cfg_rd(ctx->adp, 8, 1,
(uint32_t *)&idata->udata.u.hwType.HwRev);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_reg_rd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata)
return BC_STS_INV_ARG;
idata->udata.u.regAcc.Value = bc_dec_reg_rd(ctx->adp,
idata->udata.u.regAcc.Offset);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_reg_wr(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata)
return BC_STS_INV_ARG;
bc_dec_reg_wr(ctx->adp, idata->udata.u.regAcc.Offset,
idata->udata.u.regAcc.Value);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_link_reg_rd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata)
return BC_STS_INV_ARG;
idata->udata.u.regAcc.Value = crystalhd_reg_rd(ctx->adp,
idata->udata.u.regAcc.Offset);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_link_reg_wr(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata)
return BC_STS_INV_ARG;
crystalhd_reg_wr(ctx->adp, idata->udata.u.regAcc.Offset,
idata->udata.u.regAcc.Value);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_mem_rd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata || !idata->add_cdata)
return BC_STS_INV_ARG;
if (idata->udata.u.devMem.NumDwords > (idata->add_cdata_sz / 4)) {
BCMLOG_ERR("insufficient buffer\n");
return BC_STS_INV_ARG;
}
sts = crystalhd_mem_rd(ctx->adp, idata->udata.u.devMem.StartOff,
idata->udata.u.devMem.NumDwords,
(uint32_t *)idata->add_cdata);
return sts;
}
static enum BC_STATUS bc_cproc_mem_wr(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata || !idata->add_cdata)
return BC_STS_INV_ARG;
if (idata->udata.u.devMem.NumDwords > (idata->add_cdata_sz / 4)) {
BCMLOG_ERR("insufficient buffer\n");
return BC_STS_INV_ARG;
}
sts = crystalhd_mem_wr(ctx->adp, idata->udata.u.devMem.StartOff,
idata->udata.u.devMem.NumDwords,
(uint32_t *)idata->add_cdata);
return sts;
}
static enum BC_STATUS bc_cproc_cfg_rd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
uint32_t ix, cnt, off, len;
enum BC_STATUS sts = BC_STS_SUCCESS;
uint32_t *temp;
if (!ctx || !idata)
return BC_STS_INV_ARG;
temp = (uint32_t *) idata->udata.u.pciCfg.pci_cfg_space;
off = idata->udata.u.pciCfg.Offset;
len = idata->udata.u.pciCfg.Size;
if (len <= 4)
return crystalhd_pci_cfg_rd(ctx->adp, off, len, temp);
/* Truncate to dword alignment..*/
len = 4;
cnt = idata->udata.u.pciCfg.Size / len;
for (ix = 0; ix < cnt; ix++) {
sts = crystalhd_pci_cfg_rd(ctx->adp, off, len, &temp[ix]);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("config read : %d\n", sts);
return sts;
}
off += len;
}
return sts;
}
static enum BC_STATUS bc_cproc_cfg_wr(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
uint32_t ix, cnt, off, len;
enum BC_STATUS sts = BC_STS_SUCCESS;
uint32_t *temp;
if (!ctx || !idata)
return BC_STS_INV_ARG;
temp = (uint32_t *) idata->udata.u.pciCfg.pci_cfg_space;
off = idata->udata.u.pciCfg.Offset;
len = idata->udata.u.pciCfg.Size;
if (len <= 4)
return crystalhd_pci_cfg_wr(ctx->adp, off, len, temp[0]);
/* Truncate to dword alignment..*/
len = 4;
cnt = idata->udata.u.pciCfg.Size / len;
for (ix = 0; ix < cnt; ix++) {
sts = crystalhd_pci_cfg_wr(ctx->adp, off, len, temp[ix]);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("config write : %d\n", sts);
return sts;
}
off += len;
}
return sts;
}
static enum BC_STATUS bc_cproc_download_fw(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata || !idata->add_cdata || !idata->add_cdata_sz) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
if (ctx->state != BC_LINK_INVALID) {
BCMLOG_ERR("Link invalid state %d\n", ctx->state);
return BC_STS_ERR_USAGE;
}
sts = crystalhd_download_fw(ctx->adp, (uint8_t *)idata->add_cdata,
idata->add_cdata_sz);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("Firmware Download Failure!! - %d\n", sts);
} else
ctx->state |= BC_LINK_INIT;
return sts;
}
/*
* We use the FW_CMD interface to sync up playback state with application
* and firmware. This function will perform the required pre and post
* processing of the Firmware commands.
*
* Pause -
* Disable capture after decoder pause.
* Resume -
* First enable capture and issue decoder resume command.
* Flush -
* Abort pending input transfers and issue decoder flush command.
*
*/
static enum BC_STATUS bc_cproc_do_fw_cmd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts;
uint32_t *cmd;
if (!(ctx->state & BC_LINK_INIT)) {
BCMLOG_ERR("Link invalid state %d\n", ctx->state);
return BC_STS_ERR_USAGE;
}
cmd = idata->udata.u.fwCmd.cmd;
/* Pre-Process */
if (cmd[0] == eCMD_C011_DEC_CHAN_PAUSE) {
if (!cmd[3]) {
ctx->state &= ~BC_LINK_PAUSED;
crystalhd_hw_unpause(&ctx->hw_ctx);
}
} else if (cmd[0] == eCMD_C011_DEC_CHAN_FLUSH) {
BCMLOG(BCMLOG_INFO, "Flush issued\n");
if (cmd[3])
ctx->cin_wait_exit = 1;
}
sts = crystalhd_do_fw_cmd(&ctx->hw_ctx, &idata->udata.u.fwCmd);
if (sts != BC_STS_SUCCESS) {
BCMLOG(BCMLOG_INFO, "fw cmd %x failed\n", cmd[0]);
return sts;
}
/* Post-Process */
if (cmd[0] == eCMD_C011_DEC_CHAN_PAUSE) {
if (cmd[3]) {
ctx->state |= BC_LINK_PAUSED;
crystalhd_hw_pause(&ctx->hw_ctx);
}
}
return sts;
}
static void bc_proc_in_completion(struct crystalhd_dio_req *dio_hnd,
wait_queue_head_t *event, enum BC_STATUS sts)
{
if (!dio_hnd || !event) {
BCMLOG_ERR("Invalid Arg!!\n");
return;
}
if (sts == BC_STS_IO_USER_ABORT)
return;
dio_hnd->uinfo.comp_sts = sts;
dio_hnd->uinfo.ev_sts = 1;
crystalhd_set_event(event);
}
static enum BC_STATUS bc_cproc_codein_sleep(struct crystalhd_cmd *ctx)
{
wait_queue_head_t sleep_ev;
int rc = 0;
if (ctx->state & BC_LINK_SUSPEND)
return BC_STS_IO_USER_ABORT;
if (ctx->cin_wait_exit) {
ctx->cin_wait_exit = 0;
return BC_STS_CMD_CANCELLED;
}
crystalhd_create_event(&sleep_ev);
crystalhd_wait_on_event(&sleep_ev, 0, 100, rc, 0);
if (rc == -EINTR)
return BC_STS_IO_USER_ABORT;
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_hw_txdma(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata,
struct crystalhd_dio_req *dio)
{
uint32_t tx_listid = 0;
enum BC_STATUS sts = BC_STS_SUCCESS;
wait_queue_head_t event;
int rc = 0;
if (!ctx || !idata || !dio) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
crystalhd_create_event(&event);
ctx->tx_list_id = 0;
/* msleep_interruptible(2000); */
sts = crystalhd_hw_post_tx(&ctx->hw_ctx, dio, bc_proc_in_completion,
&event, &tx_listid,
idata->udata.u.ProcInput.Encrypted);
while (sts == BC_STS_BUSY) {
sts = bc_cproc_codein_sleep(ctx);
if (sts != BC_STS_SUCCESS)
break;
sts = crystalhd_hw_post_tx(&ctx->hw_ctx, dio,
bc_proc_in_completion,
&event, &tx_listid,
idata->udata.u.ProcInput.Encrypted);
}
if (sts != BC_STS_SUCCESS) {
BCMLOG(BCMLOG_DBG, "_hw_txdma returning sts:%d\n", sts);
return sts;
}
if (ctx->cin_wait_exit)
ctx->cin_wait_exit = 0;
ctx->tx_list_id = tx_listid;
/* _post() succeeded.. wait for the completion. */
crystalhd_wait_on_event(&event, (dio->uinfo.ev_sts), 3000, rc, 0);
ctx->tx_list_id = 0;
if (!rc) {
return dio->uinfo.comp_sts;
} else if (rc == -EBUSY) {
BCMLOG(BCMLOG_DBG, "_tx_post() T/O\n");
sts = BC_STS_TIMEOUT;
} else if (rc == -EINTR) {
BCMLOG(BCMLOG_DBG, "Tx Wait Signal int.\n");
sts = BC_STS_IO_USER_ABORT;
} else {
sts = BC_STS_IO_ERROR;
}
/* We are cancelling the IO from the same context as the _post().
* so no need to wait on the event again.. the return itself
* ensures the release of our resources.
*/
crystalhd_hw_cancel_tx(&ctx->hw_ctx, tx_listid);
return sts;
}
/* Helper function to check on user buffers */
static enum BC_STATUS bc_cproc_check_inbuffs(bool pin, void *ubuff, uint32_t ub_sz,
uint32_t uv_off, bool en_422)
{
if (!ubuff || !ub_sz) {
BCMLOG_ERR("%s->Invalid Arg %p %x\n",
((pin) ? "TX" : "RX"), ubuff, ub_sz);
return BC_STS_INV_ARG;
}
/* Check for alignment */
if (((uintptr_t)ubuff) & 0x03) {
BCMLOG_ERR("%s-->Un-aligned address not implemented yet.. %p\n",
((pin) ? "TX" : "RX"), ubuff);
return BC_STS_NOT_IMPL;
}
if (pin)
return BC_STS_SUCCESS;
if (!en_422 && !uv_off) {
BCMLOG_ERR("Need UV offset for 420 mode.\n");
return BC_STS_INV_ARG;
}
if (en_422 && uv_off) {
BCMLOG_ERR("UV offset in 422 mode ??\n");
return BC_STS_INV_ARG;
}
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_proc_input(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
void *ubuff;
uint32_t ub_sz;
struct crystalhd_dio_req *dio_hnd = NULL;
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
ubuff = idata->udata.u.ProcInput.pDmaBuff;
ub_sz = idata->udata.u.ProcInput.BuffSz;
sts = bc_cproc_check_inbuffs(1, ubuff, ub_sz, 0, 0);
if (sts != BC_STS_SUCCESS)
return sts;
sts = crystalhd_map_dio(ctx->adp, ubuff, ub_sz, 0, 0, 1, &dio_hnd);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("dio map - %d\n", sts);
return sts;
}
if (!dio_hnd)
return BC_STS_ERROR;
sts = bc_cproc_hw_txdma(ctx, idata, dio_hnd);
crystalhd_unmap_dio(ctx->adp, dio_hnd);
return sts;
}
static enum BC_STATUS bc_cproc_add_cap_buff(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
void *ubuff;
uint32_t ub_sz, uv_off;
bool en_422;
struct crystalhd_dio_req *dio_hnd = NULL;
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
ubuff = idata->udata.u.RxBuffs.YuvBuff;
ub_sz = idata->udata.u.RxBuffs.YuvBuffSz;
uv_off = idata->udata.u.RxBuffs.UVbuffOffset;
en_422 = idata->udata.u.RxBuffs.b422Mode;
sts = bc_cproc_check_inbuffs(0, ubuff, ub_sz, uv_off, en_422);
if (sts != BC_STS_SUCCESS)
return sts;
sts = crystalhd_map_dio(ctx->adp, ubuff, ub_sz, uv_off,
en_422, 0, &dio_hnd);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("dio map - %d\n", sts);
return sts;
}
if (!dio_hnd)
return BC_STS_ERROR;
sts = crystalhd_hw_add_cap_buffer(&ctx->hw_ctx, dio_hnd, (ctx->state == BC_LINK_READY));
if ((sts != BC_STS_SUCCESS) && (sts != BC_STS_BUSY)) {
crystalhd_unmap_dio(ctx->adp, dio_hnd);
return sts;
}
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_fmt_change(struct crystalhd_cmd *ctx,
struct crystalhd_dio_req *dio)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
sts = crystalhd_hw_add_cap_buffer(&ctx->hw_ctx, dio, 0);
if (sts != BC_STS_SUCCESS)
return sts;
ctx->state |= BC_LINK_FMT_CHG;
if (ctx->state == BC_LINK_READY)
sts = crystalhd_hw_start_capture(&ctx->hw_ctx);
return sts;
}
static enum BC_STATUS bc_cproc_fetch_frame(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
struct crystalhd_dio_req *dio = NULL;
enum BC_STATUS sts = BC_STS_SUCCESS;
struct BC_DEC_OUT_BUFF *frame;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
if (!(ctx->state & BC_LINK_CAP_EN)) {
BCMLOG(BCMLOG_DBG, "Capture not enabled..%x\n", ctx->state);
return BC_STS_ERR_USAGE;
}
frame = &idata->udata.u.DecOutData;
sts = crystalhd_hw_get_cap_buffer(&ctx->hw_ctx, &frame->PibInfo, &dio);
if (sts != BC_STS_SUCCESS)
return (ctx->state & BC_LINK_SUSPEND) ? BC_STS_IO_USER_ABORT : sts;
frame->Flags = dio->uinfo.comp_flags;
if (frame->Flags & COMP_FLAG_FMT_CHANGE)
return bc_cproc_fmt_change(ctx, dio);
frame->OutPutBuffs.YuvBuff = dio->uinfo.xfr_buff;
frame->OutPutBuffs.YuvBuffSz = dio->uinfo.xfr_len;
frame->OutPutBuffs.UVbuffOffset = dio->uinfo.uv_offset;
frame->OutPutBuffs.b422Mode = dio->uinfo.b422mode;
frame->OutPutBuffs.YBuffDoneSz = dio->uinfo.y_done_sz;
frame->OutPutBuffs.UVBuffDoneSz = dio->uinfo.uv_done_sz;
crystalhd_unmap_dio(ctx->adp, dio);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_start_capture(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
ctx->state |= BC_LINK_CAP_EN;
if (ctx->state == BC_LINK_READY)
return crystalhd_hw_start_capture(&ctx->hw_ctx);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_flush_cap_buffs(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
struct crystalhd_dio_req *dio = NULL;
enum BC_STATUS sts = BC_STS_SUCCESS;
struct BC_DEC_OUT_BUFF *frame;
uint32_t count;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
if (!(ctx->state & BC_LINK_CAP_EN))
return BC_STS_ERR_USAGE;
/* We should ack flush even when we are in paused/suspend state */
if (!(ctx->state & BC_LINK_READY))
return crystalhd_hw_stop_capture(&ctx->hw_ctx);
ctx->state &= ~(BC_LINK_CAP_EN|BC_LINK_FMT_CHG);
frame = &idata->udata.u.DecOutData;
for (count = 0; count < BC_RX_LIST_CNT; count++) {
sts = crystalhd_hw_get_cap_buffer(&ctx->hw_ctx, &frame->PibInfo, &dio);
if (sts != BC_STS_SUCCESS)
break;
crystalhd_unmap_dio(ctx->adp, dio);
}
return crystalhd_hw_stop_capture(&ctx->hw_ctx);
}
static enum BC_STATUS bc_cproc_get_stats(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
struct BC_DTS_STATS *stats;
struct crystalhd_hw_stats hw_stats;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
crystalhd_hw_stats(&ctx->hw_ctx, &hw_stats);
stats = &idata->udata.u.drvStat;
stats->drvRLL = hw_stats.rdyq_count;
stats->drvFLL = hw_stats.freeq_count;
stats->DrvTotalFrmDropped = hw_stats.rx_errors;
stats->DrvTotalHWErrs = hw_stats.rx_errors + hw_stats.tx_errors;
stats->intCount = hw_stats.num_interrupts;
stats->DrvIgnIntrCnt = hw_stats.num_interrupts -
hw_stats.dev_interrupts;
stats->TxFifoBsyCnt = hw_stats.cin_busy;
stats->pauseCount = hw_stats.pause_cnt;
if (ctx->pwr_state_change)
stats->pwr_state_change = 1;
if (ctx->state & BC_LINK_PAUSED)
stats->DrvPauseTime = 1;
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_reset_stats(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
crystalhd_hw_stats(&ctx->hw_ctx, NULL);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_chg_clk(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
struct BC_CLOCK *clock;
uint32_t oldClk;
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
clock = &idata->udata.u.clockValue;
oldClk = ctx->hw_ctx.core_clock_mhz;
ctx->hw_ctx.core_clock_mhz = clock->clk;
if (ctx->state & BC_LINK_READY) {
sts = crystalhd_hw_set_core_clock(&ctx->hw_ctx);
if (sts == BC_STS_CLK_NOCHG)
ctx->hw_ctx.core_clock_mhz = oldClk;
}
clock->clk = ctx->hw_ctx.core_clock_mhz;
return sts;
}
/*=============== Cmd Proc Table.. ======================================*/
static const struct crystalhd_cmd_tbl g_crystalhd_cproc_tbl[] = {
{ BCM_IOC_GET_VERSION, bc_cproc_get_version, 0},
{ BCM_IOC_GET_HWTYPE, bc_cproc_get_hwtype, 0},
{ BCM_IOC_REG_RD, bc_cproc_reg_rd, 0},
{ BCM_IOC_REG_WR, bc_cproc_reg_wr, 0},
{ BCM_IOC_FPGA_RD, bc_cproc_link_reg_rd, 0},
{ BCM_IOC_FPGA_WR, bc_cproc_link_reg_wr, 0},
{ BCM_IOC_MEM_RD, bc_cproc_mem_rd, 0},
{ BCM_IOC_MEM_WR, bc_cproc_mem_wr, 0},
{ BCM_IOC_RD_PCI_CFG, bc_cproc_cfg_rd, 0},
{ BCM_IOC_WR_PCI_CFG, bc_cproc_cfg_wr, 1},
{ BCM_IOC_FW_DOWNLOAD, bc_cproc_download_fw, 1},
{ BCM_IOC_FW_CMD, bc_cproc_do_fw_cmd, 1},
{ BCM_IOC_PROC_INPUT, bc_cproc_proc_input, 1},
{ BCM_IOC_ADD_RXBUFFS, bc_cproc_add_cap_buff, 1},
{ BCM_IOC_FETCH_RXBUFF, bc_cproc_fetch_frame, 1},
{ BCM_IOC_START_RX_CAP, bc_cproc_start_capture, 1},
{ BCM_IOC_FLUSH_RX_CAP, bc_cproc_flush_cap_buffs, 1},
{ BCM_IOC_GET_DRV_STAT, bc_cproc_get_stats, 0},
{ BCM_IOC_RST_DRV_STAT, bc_cproc_reset_stats, 0},
{ BCM_IOC_NOTIFY_MODE, bc_cproc_notify_mode, 0},
{ BCM_IOC_CHG_CLK, bc_cproc_chg_clk, 0},
{ BCM_IOC_END, NULL},
};
/*=============== Cmd Proc Functions.. ===================================*/
/**
* crystalhd_suspend - Power management suspend request.
* @ctx: Command layer context.
* @idata: Iodata - required for internal use.
*
* Return:
* status
*
* 1. Set the state to Suspend.
* 2. Flush the Rx Buffers it will unmap all the buffers and
* stop the RxDMA engine.
* 3. Cancel The TX Io and Stop Dma Engine.
* 4. Put the DDR in to deep sleep.
* 5. Stop the hardware putting it in to Reset State.
*
* Current gstreamer frame work does not provide any power management
* related notification to user mode decoder plug-in. As a work-around
* we pass on the power mangement notification to our plug-in by completing
* all outstanding requests with BC_STS_IO_USER_ABORT return code.
*/
enum BC_STATUS crystalhd_suspend(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Parameters\n");
return BC_STS_ERROR;
}
if (ctx->state & BC_LINK_SUSPEND)
return BC_STS_SUCCESS;
if (ctx->state == BC_LINK_INVALID) {
BCMLOG(BCMLOG_DBG, "Nothing To Do Suspend Success\n");
return BC_STS_SUCCESS;
}
ctx->state |= BC_LINK_SUSPEND;
bc_cproc_mark_pwr_state(ctx);
if (ctx->state & BC_LINK_CAP_EN) {
sts = bc_cproc_flush_cap_buffs(ctx, idata);
if (sts != BC_STS_SUCCESS)
return sts;
}
if (ctx->tx_list_id) {
sts = crystalhd_hw_cancel_tx(&ctx->hw_ctx, ctx->tx_list_id);
if (sts != BC_STS_SUCCESS)
return sts;
}
sts = crystalhd_hw_suspend(&ctx->hw_ctx);
if (sts != BC_STS_SUCCESS)
return sts;
BCMLOG(BCMLOG_DBG, "BCM70012 suspend success\n");
return BC_STS_SUCCESS;
}
/**
* crystalhd_resume - Resume frame capture.
* @ctx: Command layer contextx.
*
* Return:
* status
*
*
* Resume frame capture.
*
* PM_Resume can't resume the playback state back to pre-suspend state
* because we don't keep video clip related information within driver.
* To get back to the pre-suspend state App will re-open the device and
* start a new playback session from the pre-suspend clip position.
*
*/
enum BC_STATUS crystalhd_resume(struct crystalhd_cmd *ctx)
{
BCMLOG(BCMLOG_DBG, "crystalhd_resume Success %x\n", ctx->state);
bc_cproc_mark_pwr_state(ctx);
return BC_STS_SUCCESS;
}
/**
* crystalhd_user_open - Create application handle.
* @ctx: Command layer contextx.
* @user_ctx: User ID context.
*
* Return:
* status
*
* Creates an application specific UID and allocates
* application specific resources. HW layer initialization
* is done for the first open request.
*/
enum BC_STATUS crystalhd_user_open(struct crystalhd_cmd *ctx,
struct crystalhd_user **user_ctx)
{
struct crystalhd_user *uc;
if (!ctx || !user_ctx) {
BCMLOG_ERR("Invalid arg..\n");
return BC_STS_INV_ARG;
}
uc = bc_cproc_get_uid(ctx);
if (!uc) {
BCMLOG(BCMLOG_INFO, "No free user context...\n");
return BC_STS_BUSY;
}
BCMLOG(BCMLOG_INFO, "Opening new user[%x] handle\n", uc->uid);
crystalhd_hw_open(&ctx->hw_ctx, ctx->adp);
uc->in_use = 1;
*user_ctx = uc;
return BC_STS_SUCCESS;
}
/**
* crystalhd_user_close - Close application handle.
* @ctx: Command layer contextx.
* @uc: User ID context.
*
* Return:
* status
*
* Closer application handle and release app specific
* resources.
*/
enum BC_STATUS crystalhd_user_close(struct crystalhd_cmd *ctx, struct crystalhd_user *uc)
{
uint32_t mode = uc->mode;
ctx->user[uc->uid].mode = DTS_MODE_INV;
ctx->user[uc->uid].in_use = 0;
ctx->cin_wait_exit = 1;
ctx->pwr_state_change = 0;
BCMLOG(BCMLOG_INFO, "Closing user[%x] handle\n", uc->uid);
if ((mode == DTS_DIAG_MODE) || (mode == DTS_PLAYBACK_MODE)) {
crystalhd_hw_free_dma_rings(&ctx->hw_ctx);
crystalhd_destroy_dio_pool(ctx->adp);
} else if (bc_cproc_get_user_count(ctx)) {
return BC_STS_SUCCESS;
}
crystalhd_hw_close(&ctx->hw_ctx);
ctx->state = BC_LINK_INVALID;
return BC_STS_SUCCESS;
}
/**
* crystalhd_setup_cmd_context - Setup Command layer resources.
* @ctx: Command layer contextx.
* @adp: Adapter context
*
* Return:
* status
*
* Called at the time of driver load.
*/
enum BC_STATUS __devinit crystalhd_setup_cmd_context(struct crystalhd_cmd *ctx,
struct crystalhd_adp *adp)
{
int i = 0;
if (!ctx || !adp) {
BCMLOG_ERR("Invalid arg!!\n");
return BC_STS_INV_ARG;
}
if (ctx->adp)
BCMLOG(BCMLOG_DBG, "Resetting Cmd context delete missing..\n");
ctx->adp = adp;
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
ctx->user[i].uid = i;
ctx->user[i].in_use = 0;
ctx->user[i].mode = DTS_MODE_INV;
}
/*Open and Close the Hardware to put it in to sleep state*/
crystalhd_hw_open(&ctx->hw_ctx, ctx->adp);
crystalhd_hw_close(&ctx->hw_ctx);
return BC_STS_SUCCESS;
}
/**
* crystalhd_delete_cmd_context - Release Command layer resources.
* @ctx: Command layer contextx.
*
* Return:
* status
*
* Called at the time of driver un-load.
*/
enum BC_STATUS __devexit crystalhd_delete_cmd_context(struct crystalhd_cmd *ctx)
{
BCMLOG(BCMLOG_DBG, "Deleting Command context..\n");
ctx->adp = NULL;
return BC_STS_SUCCESS;
}
/**
* crystalhd_get_cmd_proc - Cproc table lookup.
* @ctx: Command layer contextx.
* @cmd: IOCTL command code.
* @uc: User ID context.
*
* Return:
* command proc function pointer
*
* This function checks the process context, application's
* mode of operation and returns the function pointer
* from the cproc table.
*/
crystalhd_cmd_proc crystalhd_get_cmd_proc(struct crystalhd_cmd *ctx, uint32_t cmd,
struct crystalhd_user *uc)
{
crystalhd_cmd_proc cproc = NULL;
unsigned int i, tbl_sz;
if (!ctx) {
BCMLOG_ERR("Invalid arg.. Cmd[%d]\n", cmd);
return NULL;
}
if ((cmd != BCM_IOC_GET_DRV_STAT) && (ctx->state & BC_LINK_SUSPEND)) {
BCMLOG_ERR("Invalid State [suspend Set].. Cmd[%d]\n", cmd);
return NULL;
}
tbl_sz = sizeof(g_crystalhd_cproc_tbl) / sizeof(struct crystalhd_cmd_tbl);
for (i = 0; i < tbl_sz; i++) {
if (g_crystalhd_cproc_tbl[i].cmd_id == cmd) {
if ((uc->mode == DTS_MONITOR_MODE) &&
(g_crystalhd_cproc_tbl[i].block_mon)) {
BCMLOG(BCMLOG_INFO, "Blocking cmd %d\n", cmd);
break;
}
cproc = g_crystalhd_cproc_tbl[i].cmd_proc;
break;
}
}
return cproc;
}
/**
* crystalhd_cmd_interrupt - ISR entry point
* @ctx: Command layer contextx.
*
* Return:
* TRUE: If interrupt from bcm70012 device.
*
*
* ISR entry point from OS layer.
*/
bool crystalhd_cmd_interrupt(struct crystalhd_cmd *ctx)
{
if (!ctx) {
BCMLOG_ERR("Invalid arg..\n");
return 0;
}
return crystalhd_hw_interrupt(ctx->adp, &ctx->hw_ctx);
}