#include "mtk-phy.h" #ifdef CONFIG_PROJECT_7621 #include "mtk-phy-7621.h" //not used on SoC PHY_INT32 phy_init(struct u3phy_info *info){ return PHY_TRUE; } //not used on SoC PHY_INT32 phy_change_pipe_phase(struct u3phy_info *info, PHY_INT32 phy_drv, PHY_INT32 pipe_phase){ return PHY_TRUE; } //-------------------------------------------------------- // Function : fgEyeScanHelper_CheckPtInRegion() // Description : Check if the test point is in a rectangle region. // If it is in the rectangle, also check if this point // is on the multiple of deltaX and deltaY. // Parameter : strucScanRegion * prEye - the region // BYTE bX // BYTE bY // Return : BYTE - TRUE : This point needs to be tested // FALSE: This point will be omitted // Note : First check within the rectangle. // Secondly, use modulous to check if the point will be tested. //-------------------------------------------------------- static PHY_INT8 fgEyeScanHelper_CheckPtInRegion(struct strucScanRegion * prEye, PHY_INT8 bX, PHY_INT8 bY) { PHY_INT8 fgValid = true; /// Be careful, the axis origin is on the TOP-LEFT corner. /// Therefore the top-left point has the minimum X and Y /// Botton-right point is the maximum X and Y if ( (prEye->bX_tl <= bX) && (bX <= prEye->bX_br) && (prEye->bY_tl <= bY) && (bY <= prEye->bX_br)) { // With the region, now check whether or not the input test point is // on the multiples of X and Y // Do not have to worry about negative value, because we have already // check the input bX, and bY is within the region. if ( ((bX - prEye->bX_tl) % (prEye->bDeltaX)) || ((bY - prEye->bY_tl) % (prEye->bDeltaY)) ) { // if the division will have remainder, that means // the input test point is on the multiples of X and Y fgValid = false; } else { } } else { fgValid = false; } return fgValid; } //-------------------------------------------------------- // Function : EyeScanHelper_RunTest() // Description : Enable the test, and wait til it is completed // Parameter : None // Return : None // Note : None //-------------------------------------------------------- static void EyeScanHelper_RunTest(struct u3phy_info *info) { DRV_UDELAY(100); // Disable the test U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE_CNT_EN_OFST, RG_SSUSB_EQ_EYE_CNT_EN, 0); //RG_SSUSB_RX_EYE_CNT_EN = 0 DRV_UDELAY(100); // Run the test U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE_CNT_EN_OFST, RG_SSUSB_EQ_EYE_CNT_EN, 1); //RG_SSUSB_RX_EYE_CNT_EN = 1 DRV_UDELAY(100); // Wait til it's done //RGS_SSUSB_RX_EYE_CNT_RDY while(!U3PhyReadField32(((PHY_UINT32)&info->u3phyd_regs->phya_rx_mon5) , RGS_SSUSB_EQ_EYE_CNT_RDY_OFST, RGS_SSUSB_EQ_EYE_CNT_RDY)); } //-------------------------------------------------------- // Function : fgEyeScanHelper_CalNextPoint() // Description : Calcualte the test point for the measurement // Parameter : None // Return : BOOL - TRUE : the next point is within the // boundaryof HW limit // FALSE: the next point is out of the HW limit // Note : The next point is obtained by calculating // from the bottom left of the region rectangle // and then scanning up until it reaches the upper // limit. At this time, the x will increment, and // start scanning downwards until the y hits the // zero. //-------------------------------------------------------- static PHY_INT8 fgEyeScanHelper_CalNextPoint(void) { if ( ((_bYcurr == MAX_Y) && (_eScanDir == SCAN_DN)) || ((_bYcurr == MIN_Y) && (_eScanDir == SCAN_UP)) ) { /// Reaches the limit of Y axis /// Increment X _bXcurr++; _fgXChged = true; _eScanDir = (_eScanDir == SCAN_UP) ? SCAN_DN : SCAN_UP; if (_bXcurr > MAX_X) { return false; } } else { _bYcurr = (_eScanDir == SCAN_DN) ? _bYcurr + 1 : _bYcurr - 1; _fgXChged = false; } return PHY_TRUE; } PHY_INT32 eyescan_init(struct u3phy_info *info){ //initial PHY setting U3PhyWriteField32(((PHY_UINT32)&info->u3phya_regs->rega) , RG_SSUSB_CDR_EPEN_OFST, RG_SSUSB_CDR_EPEN, 1); U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->phyd_mix3) , RG_SSUSB_FORCE_CDR_PI_PWD_OFST, RG_SSUSB_FORCE_CDR_PI_PWD, 1); U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_bank2_regs->b2_phyd_misc0) , RG_SSUSB_RX_PI_CAL_EN_SEL_OFST, RG_SSUSB_RX_PI_CAL_EN_SEL, 1); //RG_SSUSB_RX_PI_CAL_MANUAL_SEL = 1 U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_bank2_regs->b2_phyd_misc0) , RG_SSUSB_RX_PI_CAL_EN_OFST, RG_SSUSB_RX_PI_CAL_EN, 1); //RG_SSUSB_RX_PI_CAL_MANUAL_EN = 1 return PHY_TRUE; } PHY_INT32 phy_eyescan(struct u3phy_info *info, PHY_INT32 x_t1, PHY_INT32 y_t1, PHY_INT32 x_br, PHY_INT32 y_br, PHY_INT32 delta_x, PHY_INT32 delta_y , PHY_INT32 eye_cnt, PHY_INT32 num_cnt, PHY_INT32 PI_cal_en, PHY_INT32 num_ignore_cnt){ PHY_INT32 cOfst = 0; PHY_UINT8 bIdxX = 0; PHY_UINT8 bIdxY = 0; //PHY_INT8 bCnt = 0; PHY_UINT8 bIdxCycCnt = 0; PHY_INT8 fgValid; PHY_INT8 cX; PHY_INT8 cY; PHY_UINT8 bExtendCnt; PHY_INT8 isContinue; //PHY_INT8 isBreak; PHY_UINT32 wErr0 = 0, wErr1 = 0; //PHY_UINT32 temp; PHY_UINT32 pwErrCnt0[CYCLE_COUNT_MAX][ERRCNT_MAX][ERRCNT_MAX]; PHY_UINT32 pwErrCnt1[CYCLE_COUNT_MAX][ERRCNT_MAX][ERRCNT_MAX]; _rEye1.bX_tl = x_t1; _rEye1.bY_tl = y_t1; _rEye1.bX_br = x_br; _rEye1.bY_br = y_br; _rEye1.bDeltaX = delta_x; _rEye1.bDeltaY = delta_y; _rEye2.bX_tl = x_t1; _rEye2.bY_tl = y_t1; _rEye2.bX_br = x_br; _rEye2.bY_br = y_br; _rEye2.bDeltaX = delta_x; _rEye2.bDeltaY = delta_y; _rTestCycle.wEyeCnt = eye_cnt; _rTestCycle.bNumOfEyeCnt = num_cnt; _rTestCycle.bNumOfIgnoreCnt = num_ignore_cnt; _rTestCycle.bPICalEn = PI_cal_en; _bXcurr = 0; _bYcurr = 0; _eScanDir = SCAN_DN; _fgXChged = false; printk("x_t1: %x, y_t1: %x, x_br: %x, y_br: %x, delta_x: %x, delta_y: %x, \ eye_cnt: %x, num_cnt: %x, PI_cal_en: %x, num_ignore_cnt: %x\n", \ x_t1, y_t1, x_br, y_br, delta_x, delta_y, eye_cnt, num_cnt, PI_cal_en, num_ignore_cnt); //force SIGDET to OFF U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_bank2_regs->b2_phyd_misc0) , RG_SSUSB_RX_SIGDET_EN_SEL_OFST, RG_SSUSB_RX_SIGDET_EN_SEL, 1); //RG_SSUSB_RX_SIGDET_SEL = 1 U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_bank2_regs->b2_phyd_misc0) , RG_SSUSB_RX_SIGDET_EN_OFST, RG_SSUSB_RX_SIGDET_EN, 0); //RG_SSUSB_RX_SIGDET_EN = 0 U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye1) , RG_SSUSB_EQ_SIGDET_OFST, RG_SSUSB_EQ_SIGDET, 0); //RG_SSUSB_RX_SIGDET = 0 // RX_TRI_DET_EN to Disable U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq3) , RG_SSUSB_EQ_TRI_DET_EN_OFST, RG_SSUSB_EQ_TRI_DET_EN, 0); //RG_SSUSB_RX_TRI_DET_EN = 0 U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE_MON_EN_OFST, RG_SSUSB_EQ_EYE_MON_EN, 1); //RG_SSUSB_EYE_MON_EN = 1 U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE_XOFFSET_OFST, RG_SSUSB_EQ_EYE_XOFFSET, 0); //RG_SSUSB_RX_EYE_XOFFSET = 0 U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE0_Y_OFST, RG_SSUSB_EQ_EYE0_Y, 0); //RG_SSUSB_RX_EYE0_Y = 0 U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE1_Y_OFST, RG_SSUSB_EQ_EYE1_Y, 0); //RG_SSUSB_RX_EYE1_Y = 0 if (PI_cal_en){ // PI Calibration U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_bank2_regs->b2_phyd_misc0) , RG_SSUSB_RX_PI_CAL_EN_SEL_OFST, RG_SSUSB_RX_PI_CAL_EN_SEL, 1); //RG_SSUSB_RX_PI_CAL_MANUAL_SEL = 1 U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_bank2_regs->b2_phyd_misc0) , RG_SSUSB_RX_PI_CAL_EN_OFST, RG_SSUSB_RX_PI_CAL_EN, 0); //RG_SSUSB_RX_PI_CAL_MANUAL_EN = 0 U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_bank2_regs->b2_phyd_misc0) , RG_SSUSB_RX_PI_CAL_EN_OFST, RG_SSUSB_RX_PI_CAL_EN, 1); //RG_SSUSB_RX_PI_CAL_MANUAL_EN = 1 DRV_UDELAY(20); U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_bank2_regs->b2_phyd_misc0) , RG_SSUSB_RX_PI_CAL_EN_OFST, RG_SSUSB_RX_PI_CAL_EN, 0); //RG_SSUSB_RX_PI_CAL_MANUAL_EN = 0 _bPIResult = U3PhyReadField32(((PHY_UINT32)&info->u3phyd_regs->phya_rx_mon5) , RGS_SSUSB_EQ_PILPO_OFST, RGS_SSUSB_EQ_PILPO); //read RGS_SSUSB_RX_PILPO printk(KERN_ERR "PI result: %d\n", _bPIResult); } // Read Initial DAC // Set CYCLE U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye3) ,RG_SSUSB_EQ_EYE_CNT_OFST, RG_SSUSB_EQ_EYE_CNT, eye_cnt); //RG_SSUSB_RX_EYE_CNT // Eye Monitor Feature U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye1) , RG_SSUSB_EQ_EYE_MASK_OFST, RG_SSUSB_EQ_EYE_MASK, 0x3ff); //RG_SSUSB_RX_EYE_MASK = 0x3ff U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE_MON_EN_OFST, RG_SSUSB_EQ_EYE_MON_EN, 1); //RG_SSUSB_EYE_MON_EN = 1 // Move X,Y to the top-left corner for (cOfst = 0; cOfst >= -64; cOfst--) { U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) ,RG_SSUSB_EQ_EYE_XOFFSET_OFST, RG_SSUSB_EQ_EYE_XOFFSET, cOfst); //RG_SSUSB_RX_EYE_XOFFSET } for (cOfst = 0; cOfst < 64; cOfst++) { U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE0_Y_OFST, RG_SSUSB_EQ_EYE0_Y, cOfst); //RG_SSUSB_RX_EYE0_Y U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE1_Y_OFST, RG_SSUSB_EQ_EYE1_Y, cOfst); //RG_SSUSB_RX_EYE1_Y } //ClearErrorResult for(bIdxCycCnt = 0; bIdxCycCnt < CYCLE_COUNT_MAX; bIdxCycCnt++){ for(bIdxX = 0; bIdxX < ERRCNT_MAX; bIdxX++) { for(bIdxY = 0; bIdxY < ERRCNT_MAX; bIdxY++){ pwErrCnt0[bIdxCycCnt][bIdxX][bIdxY] = 0; pwErrCnt1[bIdxCycCnt][bIdxX][bIdxY] = 0; } } } isContinue = true; while(isContinue){ //printk(KERN_ERR "_bXcurr: %d, _bYcurr: %d\n", _bXcurr, _bYcurr); // The point is within the boundary, then let's check if it is within // the testing region. // The point is only test-able if one of the eye region // includes this point. fgValid = fgEyeScanHelper_CheckPtInRegion(&_rEye1, _bXcurr, _bYcurr) || fgEyeScanHelper_CheckPtInRegion(&_rEye2, _bXcurr, _bYcurr); // Translate bX and bY to 2's complement from where the origin was on the // top left corner. // 0x40 and 0x3F needs a bit of thinking!!!! >"< cX = (_bXcurr ^ 0x40); cY = (_bYcurr ^ 0x3F); // Set X if necessary if (_fgXChged == true) { U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE_XOFFSET_OFST, RG_SSUSB_EQ_EYE_XOFFSET, cX); //RG_SSUSB_RX_EYE_XOFFSET } // Set Y U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE0_Y_OFST, RG_SSUSB_EQ_EYE0_Y, cY); //RG_SSUSB_RX_EYE0_Y U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE1_Y_OFST, RG_SSUSB_EQ_EYE1_Y, cY); //RG_SSUSB_RX_EYE1_Y /// Test this point! if (fgValid){ for (bExtendCnt = 0; bExtendCnt < num_ignore_cnt; bExtendCnt++) { //run test EyeScanHelper_RunTest(info); } for (bExtendCnt = 0; bExtendCnt < num_cnt; bExtendCnt++) { EyeScanHelper_RunTest(info); wErr0 = U3PhyReadField32(((PHY_UINT32)&info->u3phyd_regs->phya_rx_mon3) , RGS_SSUSB_EQ_EYE_MONITOR_ERRCNT_0_OFST, RGS_SSUSB_EQ_EYE_MONITOR_ERRCNT_0); wErr1 = U3PhyReadField32(((PHY_UINT32)&info->u3phyd_regs->phya_rx_mon4) , RGS_SSUSB_EQ_EYE_MONITOR_ERRCNT_1_OFST, RGS_SSUSB_EQ_EYE_MONITOR_ERRCNT_1); pwErrCnt0[bExtendCnt][_bXcurr][_bYcurr] = wErr0; pwErrCnt1[bExtendCnt][_bXcurr][_bYcurr] = wErr1; //EyeScanHelper_GetResult(&_rRes.pwErrCnt0[bCnt], &_rRes.pwErrCnt1[bCnt]); // printk(KERN_ERR "cnt[%d] cur_x,y [0x%x][0x%x], cX,cY [0x%x][0x%x], ErrCnt[%d][%d]\n" // , bExtendCnt, _bXcurr, _bYcurr, cX, cY, pwErrCnt0[bExtendCnt][_bXcurr][_bYcurr], pwErrCnt1[bExtendCnt][_bXcurr][_bYcurr]); } //printk(KERN_ERR "cur_x,y [0x%x][0x%x], cX,cY [0x%x][0x%x], ErrCnt[%d][%d]\n", _bXcurr, _bYcurr, cX, cY, pwErrCnt0[0][_bXcurr][_bYcurr], pwErrCnt1[0][_bXcurr][_bYcurr]); } else{ } if (fgEyeScanHelper_CalNextPoint() == false){ #if 0 printk(KERN_ERR "Xcurr [0x%x] Ycurr [0x%x]\n", _bXcurr, _bYcurr); printk(KERN_ERR "XcurrREG [0x%x] YcurrREG [0x%x]\n", cX, cY); #endif printk(KERN_ERR "end of eye scan\n"); isContinue = false; } } printk(KERN_ERR "CurX [0x%x] CurY [0x%x]\n" , U3PhyReadField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0), RG_SSUSB_EQ_EYE_XOFFSET_OFST, RG_SSUSB_EQ_EYE_XOFFSET) , U3PhyReadField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0), RG_SSUSB_EQ_EYE0_Y_OFST, RG_SSUSB_EQ_EYE0_Y)); // Move X,Y to the top-left corner for (cOfst = 63; cOfst >= 0; cOfst--) { U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE_XOFFSET_OFST, RG_SSUSB_EQ_EYE_XOFFSET, cOfst); //RG_SSUSB_RX_EYE_XOFFSET } for (cOfst = 63; cOfst >= 0; cOfst--) { U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE0_Y_OFST, RG_SSUSB_EQ_EYE0_Y, cOfst); U3PhyWriteField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0) , RG_SSUSB_EQ_EYE1_Y_OFST, RG_SSUSB_EQ_EYE1_Y, cOfst); } printk(KERN_ERR "CurX [0x%x] CurY [0x%x]\n" , U3PhyReadField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0), RG_SSUSB_EQ_EYE_XOFFSET_OFST, RG_SSUSB_EQ_EYE_XOFFSET) , U3PhyReadField32(((PHY_UINT32)&info->u3phyd_regs->eq_eye0), RG_SSUSB_EQ_EYE0_Y_OFST, RG_SSUSB_EQ_EYE0_Y)); printk(KERN_ERR "PI result: %d\n", _bPIResult); printk(KERN_ERR "pwErrCnt0 addr: 0x%x\n", (PHY_UINT32)pwErrCnt0); printk(KERN_ERR "pwErrCnt1 addr: 0x%x\n", (PHY_UINT32)pwErrCnt1); return PHY_TRUE; } //not used on SoC PHY_INT32 u2_save_cur_en(struct u3phy_info *info){ return PHY_TRUE; } //not used on SoC PHY_INT32 u2_save_cur_re(struct u3phy_info *info){ return PHY_TRUE; } PHY_INT32 u2_slew_rate_calibration(struct u3phy_info *info){ PHY_INT32 i=0; //PHY_INT32 j=0; //PHY_INT8 u1SrCalVal = 0; //PHY_INT8 u1Reg_addr_HSTX_SRCAL_EN; PHY_INT32 fgRet = 0; PHY_INT32 u4FmOut = 0; PHY_INT32 u4Tmp = 0; //PHY_INT32 temp; // => RG_USB20_HSTX_SRCAL_EN = 1 // enable HS TX SR calibration U3PhyWriteField32(((PHY_UINT32)&info->u2phy_regs->u2phyacr0) , RG_USB20_HSTX_SRCAL_EN_OFST, RG_USB20_HSTX_SRCAL_EN, 0x1); DRV_MSLEEP(1); // => RG_FRCK_EN = 1 // Enable free run clock U3PhyWriteField32(((PHY_UINT32)&info->sifslv_fm_regs->fmmonr1) , RG_FRCK_EN_OFST, RG_FRCK_EN, 1); // MT6290 HS signal quality patch // => RG_CYCLECNT = 400 // Setting cyclecnt =400 U3PhyWriteField32(((PHY_UINT32)&info->sifslv_fm_regs->fmcr0) , RG_CYCLECNT_OFST, RG_CYCLECNT, 0x400); // => RG_FREQDET_EN = 1 // Enable frequency meter U3PhyWriteField32(((PHY_UINT32)&info->sifslv_fm_regs->fmcr0) , RG_FREQDET_EN_OFST, RG_FREQDET_EN, 0x1); // wait for FM detection done, set 10ms timeout for(i=0; i<10; i++){ // => u4FmOut = USB_FM_OUT // read FM_OUT u4FmOut = U3PhyReadReg32(((PHY_UINT32)&info->sifslv_fm_regs->fmmonr0)); printk("FM_OUT value: u4FmOut = %d(0x%08X)\n", u4FmOut, u4FmOut); // check if FM detection done if (u4FmOut != 0) { fgRet = 0; printk("FM detection done! loop = %d\n", i); break; } fgRet = 1; DRV_MSLEEP(1); } // => RG_FREQDET_EN = 0 // disable frequency meter U3PhyWriteField32(((PHY_UINT32)&info->sifslv_fm_regs->fmcr0) , RG_FREQDET_EN_OFST, RG_FREQDET_EN, 0); // => RG_FRCK_EN = 0 // disable free run clock U3PhyWriteField32(((PHY_UINT32)&info->sifslv_fm_regs->fmmonr1) , RG_FRCK_EN_OFST, RG_FRCK_EN, 0); // => RG_USB20_HSTX_SRCAL_EN = 0 // disable HS TX SR calibration U3PhyWriteField32(((PHY_UINT32)&info->u2phy_regs->u2phyacr0) , RG_USB20_HSTX_SRCAL_EN_OFST, RG_USB20_HSTX_SRCAL_EN, 0); DRV_MSLEEP(1); if(u4FmOut == 0){ U3PhyWriteField32(((PHY_UINT32)&info->u2phy_regs->u2phyacr0) , RG_USB20_HSTX_SRCTRL_OFST, RG_USB20_HSTX_SRCTRL, 0x4); fgRet = 1; } else{ // set reg = (1024/FM_OUT) * 25 * 0.028 (round to the nearest digits) u4Tmp = (((1024 * 25 * U2_SR_COEF_7621) / u4FmOut) + 500) / 1000; printk("SR calibration value u1SrCalVal = %d\n", (PHY_UINT8)u4Tmp); U3PhyWriteField32(((PHY_UINT32)&info->u2phy_regs->u2phyacr0) , RG_USB20_HSTX_SRCTRL_OFST, RG_USB20_HSTX_SRCTRL, u4Tmp); } return fgRet; } #endif