UInt32 IntelBacklightHandler::getBacklightLevel()
{
if (!_baseAddr)
return -1;
// read backlight level
UInt32 result = -1;
switch (_fbtype)
{
case kFBTypeHaswellBroadwell:
result = REG32_READ(LEVX) & 0xFFFF;
break;
case kFBTypeIvySandy:
result = REG32_READ(LEVL);
break;
}
// adjust result to be within limits set by XRGL and XRGH
if (result > _params._xrgh)
result = _params._xrgh;
if (result && result < _params._xrgl)
result = _params._xrgl;
return result;
}
/*!
* タイマ動作中か検査する関数
* index : タイマ資源番号
* (返却値)TRUE : タイマ動作中
* (返却値)FALSE : タイマ未動作
*/
static BOOL is_running_timer(int index)
{
if (REG32_READ(gpt_tier[index]) && OVF_IT_BIT) {
return TRUE;
}
else {
return FALSE;
}
}
/*!
* 周期タイマスタート
* index : タイマ資源番号
* タイマの割込みイベントは以下がある
* ・コンペアマッチ
* ・オーバーフロー
* ・キャプチャ
* ここでは,オーバーフローとする
*/
void start_cycle_timer(int index, int usec)
{
/* タイマ初期設定 */
REG32_WRITE(gpt_tclr[index], REG32_READ(gpt_tclr[index]) & ~0x20); /* プリスケーラ(分周器)の無効化 */
REG32_WRITE(gpt_tclr[index], REG32_READ(gpt_tclr[index]) | 0x2); /* 周期タイマとして使用する事を設定 */
/*
* TLDRレジスタに初期値を書き込み,TTGRレジスタに任意の値(1)を書きこむ.
* この方式だと,タイマーが満了した時に,TLDRの値が自動的にTCRRレジスタにコピーされる
*/
REG32_WRITE(gpt_tldr[index], 0xFFFFFFFF - 13 * usec); /* タイマ値のセット */
REG32_WRITE(gpt_ttgr[index], 0x1); /* TCRRレジスタにTLDRレジスタがコピーされる */
REG32_WRITE(gpt_tisr[index], OVF_IT_BIT); /* 念のため,割込みを無効化しておく */
REG32_WRITE(gpt_tier[index], OVF_IT_BIT); /* タイマのイベントをオーバーフロー割込みを有効化 */
REG32_WRITE(gpt_tclr[index], REG32_READ(gpt_tclr[index]) | 0x1); /* タイマカウントスタート */
}
/*!
* タイマの現在値を取得する関数
* index : タイマ資源番号
* (返却値)usec : タイマの現在値
* (返却値)E_NG : タイマは動作してない
*/
ER_VLE get_timervalue(int index)
{
int usec;
usec = (0xFFFFFFFF - REG32_READ(gpt_tcrr[index])) / 13; /* 逆算 */
if (is_running_timer(index)) {
return (ER_VLE)usec;
}
else {
return E_NG;
}
}
void IntelBacklightHandler::setBacklightLevel(UInt32 level)
{
if (!_baseAddr)
return;
// adjust level to within limits set by XRGL and XRGH
if (level > _params._xrgh)
level = _params._xrgh;
if (level && level < _params._xrgl)
level = _params._xrgl;
// write backlight level
switch (_fbtype)
{
case kFBTypeHaswellBroadwell:
{
// store new backlight level and restore max
REG32_WRITE(LEVX, (_params._lmax<<16) | level);
break;
}
case kFBTypeIvySandy:
{
// initialize for consistent backlight level before/after sleep\n
if (_params._kpch != -1 && REG32_READ(PCHL) != _params._kpch)
REG32_WRITE(PCHL, _params._kpch);
if (REG32_READ(LEVW) != 0x80000000)
REG32_WRITE(LEVW, 0x80000000);
if (REG32_READ(LEVX) != _params._klvx)
REG32_WRITE(LEVX, _params._klvx);
// store new backlight level
if (REG32_READ(LEV2) != 0x80000000)
REG32_WRITE(LEV2, 0x80000000);
REG32_WRITE(LEVL, level);
break;
}
}
}
/*!
* タイマの停止(一度止めたタイマ資源はstart_timer()で再度起動できる)
* index : タイマ資源番号
*/
void stop_timer(int index)
{
REG32_WRITE(gpt_tclr[index], REG32_READ(gpt_tclr[index]) & ~0x01);
}
/*!
* ワンショットタイマ割込み満了処理
* index : タイマ資源番号
*/
void expire_oneshot_timer(int index)
{
REG32_WRITE(gpt_tisr[index], REG32_READ(gpt_tisr[index]));
}
/*******************************************************************************
* Function: dspmod_ioctl
*******************************************************************************
* DESCRIPTION: ioctl implementation for dspmod.
*
******************************************************************************/
static long dspmod_ioctl(struct file *file,
unsigned int ioctl_num,
unsigned long ioctl_param)
{
/*
* Sanity check.
*/
if ((_IOC_TYPE(ioctl_num) != DSPMOD_IOCTL_MAGIC)
|| (_IOC_NR(ioctl_num) > DSPMOD_DEV_IOC_MAXNR)) return -ENOTTY;
switch (ioctl_num)
{
case DSPMOD_IOCTL_QUERY_DSP_TYPE:
{
#if defined(CONFIG_MACH_PUMA6)
return put_user((unsigned long)GG_DSP_PUMA6, (unsigned long __user *)ioctl_param);
#elif defined(CONFIG_MACH_PUMA5)
return put_user((unsigned long)GG_DSP_PUMA5, (unsigned long __user *)ioctl_param);
#endif
}
case DSPMOD_IOCTL_QUERY_DSP_NUM:
{
return put_user((unsigned long)GG_NUM_DSPS, (unsigned long __user *)ioctl_param);
}
case DSPMOD_IOCTL_DSP_HALT:
{
unsigned short dsp_num;
if(get_user(dsp_num, (unsigned short __user *)ioctl_param))
{
return -EFAULT;
}
hwu_lin_puma_dsp_halt(dsp_num);
break;
}
case DSPMOD_IOCTL_DSP_RESET:
{
GW_DSPMOD_PARAM_T data;
if(get_user(data.v, (unsigned long __user *)ioctl_param))
{
return -EFAULT;
}
hwu_lin_puma_dsp_reset(data.u.dsp_num, (data.u.bool_value) ? TRUE : FALSE);
break;
}
case DSPMOD_IOCTL_QUERY_DSP_ADDR:
{
unsigned long start_addr;
#if defined(CONFIG_MACH_PUMA6)
if ( avalanche_alloc_no_OperSys_memory(eNO_OperSys_VDSP, PUMA6_DSP_EXTERNAL_MEM_SIZE, (unsigned int *)&start_addr) != 0)
{
printk("DSPMOD query DSP address syscall: Alloc API failed!\n");
return put_user((unsigned long)0, (unsigned long __user *)ioctl_param);
}
else
{
printk("DSPMOD query DSP address syscall: DSP Start address = 0x%08X\n", (unsigned int)start_addr);
/* Set DSP base address */
/* First one is C55_CFG1 in BootCfg. It can be used when the DSP is in reset and will override the default internal DSP register */
PAL_sysBootCfgCtrl_ReadModifyWriteReg(C55_CFG1_OFFSET, C55_CFG1_BA_MASK, ((start_addr&0xFF000000) >> 8)); /* Configure DSP external address */
/* Bring TDM IN Reset */
hwu_lin_puma_reset_tdm(0, FALSE);
return put_user((unsigned long)start_addr, (unsigned long __user *)ioctl_param);
}
#elif defined(CONFIG_MACH_PUMA5)
/* Make sure the DSP-SS is out of RESET */
REG32_WRITE(0x08621a08, 0x03);
REG32_WRITE(0x08621120, 0x1);
/* Take DSP CPPI Proxy out of reset */
REG32_WRITE(0x08621a8c, 0x103);
REG32_WRITE(0x08621120 , 0x01);
if ( avalanche_alloc_no_OperSys_memory(eNO_OperSys_VDSP, PUMAV_DSP_EXTERNAL_MEM_SIZE, (unsigned int *)&start_addr) != 0)
{
printk("DSPMOD query DSP address syscall: Alloc API failed!\n");
/* Default 32 MB start_addr = 0x81E00000; */
return put_user((unsigned long)0, (unsigned long __user *)ioctl_param);
}
else
{
printk("DSPMOD query DSP address syscall: DSP Start address = 0x%08X\n", (unsigned int)start_addr);
REG32_WRITE(PUMAV_EXT_ADDR_CFG_REG, start_addr&0xff000000); /* Configure DSP external address */
printk("HW_DSP DSP External Config Register set to: 0x%08X, Start: 0x%08X\n",
(unsigned int)REG32_DATA(PUMAV_EXT_ADDR_CFG_REG), (unsigned int)start_addr);
return put_user((unsigned long)start_addr, (unsigned long __user *)ioctl_param);
}
#endif
}
case DSPMOD_IOCTL_DSP_NMI:
{
GW_DSPMOD_PARAM_T data;
if(get_user(data.v, (unsigned long __user *)ioctl_param))
{
return -EFAULT;
}
hwu_lin_puma_dsp_nmi(data.u.dsp_num, (data.u.bool_value) ? TRUE : FALSE);
break;
}
case DSPMOD_IOCTL_DSP_PWR:
{
GW_DSPMOD_PARAM_T data;
if(get_user(data.v, (unsigned long __user *)ioctl_param))
{
return -EFAULT;
}
#if defined(CONFIG_MACH_PUMA5)
hwu_lin_pumav_dsp_power_control(data.u.dsp_num, (data.u.bool_value) ? TRUE : FALSE);
#endif
break;
}
case DSPMOD_IOCTL_RESET_TDM:
{
GW_DSPMOD_PARAM_T data;
if(get_user(data.v, (unsigned long __user *)ioctl_param))
{
return -EFAULT;
}
hwu_lin_puma_reset_tdm(data.u.dsp_num, (data.u.bool_value) ? TRUE : FALSE);
break;
}
case DSPMOD_IOCTL_REG_READ:
{
unsigned long register_val = 0, register_addr = 0;
if(get_user(register_addr, (unsigned long __user *)ioctl_param))
{
return -EFAULT;
}
REG32_READ(register_addr, register_val);
return put_user(register_val, (unsigned long __user *)ioctl_param);
}
default:
{
printk("Unknown ioctl (0x%x) called: Type=%d\n", ioctl_num, _IOC_TYPE(ioctl_num));
return -EINVAL;
}
} /* switch (ioctl_num) */
return 0;
}
