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gfiber / barebox / mindspeed / d3ad9795915ceab55e49c07f909cc7ad28b2b322 / . / diags / test_usb3.c
blob: e863b85786b3510f34a2639a1c70f93123bd5b7b [file] [log] [blame]
//*********************************************************************************//
//Testcase Name:usb3_as_ss_host_on_board1_and_usb3_as_flash_drive_device
//Author: shaikm
//Objective:
//The objective of this test case to configure the usb3 controller
//on board1 in SuperSpeed host mode and perform control transfer handshaking
//(Device Slot,Set Address,Configure Endpoint commands) with connected
//usb3 flash drive device.
//*********************************************************************************//
#include <init.h>
#include <common.h>
#include <asm/io.h>
#include "usb3/DWC_usb3_params.h"
#include "usb3/usb3subsys_registers.h"
#include "usb3/test_defines.h"
#include "usb3subsys_func.h"
#include "usb3_phy_ber_test_defines.h"
#include "common_func.h"
//$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$//
//Global variables:
//
int usb3_i=0;
u32 usb3_total_num_of_bulkout_bytes=0;
int usb3_host_num_of_bulkout_trbs=0;
u32 usb3_host_num_of_bulkout_bytes_per_trb=0;
u32 usb3_total_num_of_bulkin_bytes=0;
int usb3_host_num_of_bulkin_trbs=0;
u32 usb3_host_num_of_bulkin_bytes_per_trb=0;
u32 usb3_step=0;
u32 usb3_read_data=0;
u32 usb3_read_data1=0;
u32 usb3_read_data2=0;
u32 usb3_read_data3=0;
u32 usb3_start_data=0;
u32 usb3_caplength;
u32 usb3_fail=0;
u32 usb3_first=0;
u32 usb3_xHC_data_addr=0;
u32 usb3_xHC_Transfer_TRB_addr=0;
u32 usb3_xHC_Command_TRB_addr=0;
u32 usb3_xHC_Event_TRB_addr=0;
u32 usb3_xHC_register_base=0;
u32 usb3_xHC_DCBAR_addr=0;
u32 usb3_xHC_Device_Context_addr=0;
u32 usb3_xHC_Input_Context_addr=0;
u32 usb3_xHC_Scratch_Pad_Array_addr=0;
u32 usb3_xHC_Scratch_Pad_buf0_addr=0;
u32 usb3_xHC_EventRing_Segment_addr=0;
u32 usb3_xHC_EventRing_Segment_table_addr=0;
u32 usb3_xHC_CommandRing_Segment_addr=0;
u32 usb3_xHC_TransferRing_Segment_addr=0;
u32 usb3_xHC_Data_BulkOut_Buffer_addr=0;
u32 usb3_xHC_Data_BulkIn_Buffer_addr=0;
u32 usb3_Runtime_Base_addr=0;
u32 usb3_Doorbell_Array_Base_addr;
u32 usb3_ERDP=0;
u32 usb3_PortID=0;
u32 usb3_SlotID=0;
u32 usb3_Event_TRBs=0;
u32 usb3_PortSpeed=0;
u32 usb3_CNR=0;
u32 usb3_hst_event_count=0;
u32 usb3_ss_port_number=0;
u32 usb3_ss_port_addr=0;
u32 usb3_hs_port_number=0;
u32 usb3_hs_port_addr=0;
u32 pmu_intr_status=0;
u32 a9_irq_bus_31_0_bits_status=0;
u32 a9_irq_bus_63_32_bits_status=0;
int device_connected_on_ss_port=0;
int device_slots_cmd_pass=0;
int set_addr_cmd_pass=0;
int config_end_point_cmd_pass=0;
//************************************************************************************************************
//This file contains the usb3 host mode functions
#include "usb3/usb3_test_func.h"
//&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&//
int Comcerto_usb3_test (struct diags_test_param *p)
{
u32 debug=0;
//[0.0]::APPLYING THE RESET TO USB3 UTMI,USB3 PHY,USB2 UTMI,USB2 PHY
writel(0x33,0x904B000C);
//[0.1]APLLYING RESET TO USB3 AXI RESET ,USB2 RESET
//[4]Bit-When Set to 1,USB1(USB3) Controller's AXI clock domain is in Reset +
//[3]Bit-When Set to 1, USB0(USB2) Controller's AXI clock domain is in Reset.
writel(0x18,0x904B0058);
//************ USB3 POR SEQUENCE ***********************//
//[1] Initializing the USB3 phy registers
// while usb3 controller and phy are in reset
usb3subsys_phy_init();
//[2]::RELEASING POR TO USB3 PHY
writel(0x23,0x904B000C);
//writel(0x20,0x904B000C);
nop(8000000);//Delay
//[3]::RELEASING UTMI RST TO USB3 CONTROLLER
writel(0x03,0x904B000C);
//writel(0x00,0x904B000C);
nop(1000000);//Delay
//[4]::RELEASING THE USB3 CONTROLLER AXI CLOCK DOMAIN RESET
//Bit[4]-USB3,Bit[3]-USB2
writel(0x08,0x904B0058);
//writel(0x00,0x904B0058);
nop(1000000);//Delay
//Initializing the xHC (USB3 controller & configuring as a Host
//Initializing Global registers
usb3_controller_global_regs_init();
//USB3 constants initialization
usb3_constants_init();
//Wait for xHC controller ready before writing to its register space
usb3_xHC_controller_init();
//Configure xHc controller registers for Host programming.
usb3_xHC_controller_regs_config();
//Initialize xHC Device Context to '0'
usb3_xHC_device_context_init();
//Initialize the xHC Event Ring Segments to '0'
usb3_xHC_event_TRBs_init();
//Initialize CommandRing Segments to 0
usb3_xHC_command_TRBs_init();
//Initialize TransferRing Segments to 0
usb3_xHC_transfer_TRBs_init();
//Initializing the xHC device context data structure
usb3_xHC_device_context_datastructure_init();
//Declaring the xHC scratchpad buffer pointer.
usb3_xHC_scratchpad_buffer_datastructure_init();
//Declaring the xHC Event Ring Segement Table
usb3_xHC_eventring_datastructure_init();
//Initializing the xHC interrupter registers
usb3_xHC_interrupter_regs_init();
//Enabling the RUN bit on xHC-USBCMD register to excecute outstanding commands
usb3_xHC_enable_run_mode();
printf("Waiting for USB3 host controller to drive VBUS to high ");
usb3_wait_untill_phy_vbus_is_high();
printf("...done\n");
printf("USB3 Controller initialization done\n");
nop(1000000);//Delay
printf("Polling for 'Device detection' interrupt from USB3 host controller\n");
#if 0
usb3_read_data=reg_rd((USB3p0_PHY_CFG_BASE_ADDR+0x30));
printf("USB3PHY STATUS REG @ A:%x,RdD:%x\n",(USB3p0_PHY_CFG_BASE_ADDR+0x30),usb3_read_data);
usb3_read_data=reg_rd((USB3p0_CFG_BASE_ADDR+usb3_caplength+0x400));
printf("USB3 HS PORTSC REG @ A:%x,RdD:%x\n",(USB3p0_CFG_BASE_ADDR+usb3_caplength+0x400),usb3_read_data);
usb3_read_data=reg_rd((USB3p0_CFG_BASE_ADDR+usb3_caplength+0x410));
printf("USB3 SS PORTSC REG @ A:%x,RdD:%x\n",(USB3p0_CFG_BASE_ADDR+usb3_caplength+0x410),usb3_read_data);
printf("USB3:WAITING FOR CONNECTION DONE INTERRUPT\n");
#endif
printf("-----------------------------------------------\n");
printf("Connect the USB3 device or Press Ctrl-c to exit\n");
printf("-----------------------------------------------\n");
if(usb3_wait_for_interrupt())
return -1;
#if 0
usb3_read_data=reg_rd((USB3p0_CFG_BASE_ADDR+usb3_caplength+0x400));
printf("USB3 HS PORTSC REG @ A:%x,RdD:%x\n",(USB3p0_CFG_BASE_ADDR+usb3_caplength+0x400),usb3_read_data);
usb3_read_data=reg_rd((USB3p0_CFG_BASE_ADDR+usb3_caplength+0x410));
printf("USB3 SS PORTSC REG @ A:%x,RdD:%x\n",(USB3p0_CFG_BASE_ADDR+usb3_caplength+0x410),usb3_read_data);
#endif
printf("\n\n DEVICE CONNECTION DONE INTERRUPT DETECTED ON USB3 CONTROLLER \n\n");
printf("Waiting for handshaking to complete with the USB3 device...\n\n");
// printf("Check the port status change event(completion code,cycle bit,TRB type) generated from USB3 host controller\n");
//Acknowledge the port status change interrupt;Read Event interrupt type.
if(usb3_xHC_ack_port_status_change_interrupt())
return -1;
//Clear the xHC event interrupts
usb3_xHC_clear_event_interupt();
nop(1000000);//Delay
//Clearing the PMU status register interrupts
gpio_interrupt_status_register_clear();
nop(1000000);
//Check whether xHC is in Enable or Disable state.
usb3_xHC_state_check();
nop(1000000);//Delay
//Enable xHC Device slot
usb3_xHC_enable_device_slot();
nop(1000000);//Delay
//Ring xHC Doorbell with "Host Controller Command"
usb3_xHC_ring_doorbell_with_host_control_cmd();
nop(1000000);//Delay
//Wait for interrupt -for device slot availability
usb3_wait_for_interrupt();
nop(1000000);//Delay
//Check the status of cyclic bit,TRB type,slotID after 'Device enable slot' command completion
usb3_xHC_check_for_device_slot();
nop(1000000);//Delay
//Clear the xHC event interrupts
usb3_xHC_clear_event_interupt();
nop(1000000);//Delay
//Clearing the PMU status register interrupts
gpio_interrupt_status_register_clear();
nop(1000000);//Delay
usb3_host_get_ss_port_status();
nop(1000000);//Delay
//Issue xHC set address device command
usb3_xHC_issue_addr_device_cmd();
nop(1000000);//Delay
//Ring xHC Doorbell with "Host Controller Command"
usb3_xHC_ring_doorbell_with_host_control_cmd();
nop(1000000);//Delay
usb3_host_get_ss_port_status();
//Wait for interrupt-on command Completion Event TRB
usb3_wait_for_interrupt();
nop(1000000);//Delay
//Check the status of cyclic bit,TRB type,slotID after 'set address' command completion
usb3_xHC_check_cmd_completion_status();
nop(1000000);//Delay
//Clear the xHC event interrupts
usb3_xHC_clear_event_interupt();
nop(1000000);//Delay
//Clearing the PMU status register interrupts
gpio_interrupt_status_register_clear();
nop(1000000);//Delay
//Issue xHC configure endpoint command
usb3_xHC_issue_configure_endpoint_cmd();
nop(1000000);//Delay
//Ring xHC Doorbell with "Host Controller Command"
usb3_xHC_ring_doorbell_with_host_control_cmd();
nop(1000000);//Delay
//Wait for event interrupt -on configure end point command completion
usb3_wait_for_interrupt();
nop(1000000);//Delay
//Check the status of cyclic bit,TRB type,slotID after 'configure endpoint' command completion
usb3_xHC_check_cmd_completion_status();
nop(1000000);//Delay
//Clear the xHC event interrupts
usb3_xHC_clear_event_interupt();
nop(1000000);//Delay
//Clearing the PMU status register interrupts
gpio_interrupt_status_register_clear();
nop(100000);
if(check_host_to_device_handshaking_result())
return -1;
return 0;
} //main
int Comcerto_usb3_phy_ber_test (struct diags_test_param *p)
{
int ret = -1;
U32 err_cnt=0;
U32 marker_code=0x900d0000;
U32 read_data=0;
U32 exp_read_data=0;
printf("\nusb3p0_phy_ber_test....\n");
printf("ST:\n");
//------------------------------------------------------------//
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//printf("[1]: $$ Continuing resets on usb3,usb2 controller+phy blocks $$\n");
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//[0.0]::APPLYING THE RESET TO USB3 UTMI,USB3 PHY,USB2 UTMI,USB2 PHY
reg_wr(0x904B000C, 0x33);
printf("USB_RST_CNTRL @ A:%x,WrD:%x\n",0x904B000C,0x33);
printf("USB3_UTMI_RST:ON,USB3_PHY_RST:ON,USB2_UTMI_RST:ON,USB2_PHY_RST:ON\n");
//[0.1]APLLYING RESET TO USB3 AXI RESET ,USB2 RESET
//[4]Bit-When Set to 1,USB1(USB3) Controller's AXI clock domain is in Reset +
//[3]Bit-When Set to 1, USB0(USB2) Controller's AXI clock domain is in Reset.
reg_wr(0x904B0058, 0x18);
printf("AXI_RESET_2 @ A:%x,WrD:%x\n",0x904B0058,0x18);
printf("USB3_AXI_RST:ON,USB2_HRESET:ON\n");
//------------------------------------------------------------//
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//printf("[2.1]: $$ Initializing usb3 phy & controller top level registers while phy &
// controller are in reset $$ \n");
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//[1] Initializing the USB3 phy registers
// while usb3 controller and phy are in reset
//----------------------------------------------------------------
//Configuring the PHY Control Register#0 w.r.t dump.
//(M) reg_wr(USB3p0_PHY_CNTRL_REG0_ADDR, 0xCAD159AA); //For external 24MHz clock
reg_wr(USB3p0_PHY_CNTRL_REG0_ADDR, 0xCAD159A9); //For internal 48MHz clock
printf("A:%x,WrD:%x\n",USB3p0_PHY_CNTRL_REG0_ADDR, 0xCAD159A9); //For internal 48MHz clock
//Configuring the PHY Control Register#1 w.r.t dump.
reg_wr(USB3p0_PHY_CNTRL_REG1_ADDR, 0x95CFBC38);
printf("A:%x,WrD:%x\n",USB3p0_PHY_CNTRL_REG1_ADDR, 0x95CFBC38);
//Configuring the PHY Control Register#2 w.r.t dump.
reg_wr(USB3p0_PHY_CNTRL_REG2_ADDR, 0xA9A15555);
printf("A:%x,WrD:%x\n",USB3p0_PHY_CNTRL_REG2_ADDR, 0xA9A15555);
//Configuring the PHY Control Register#3 w.r.t dump.
reg_wr(USB3p0_PHY_CNTRL_REG3_ADDR, 0x0000A001);
printf("A:%x,WrD:%x\n",USB3p0_PHY_CNTRL_REG3_ADDR, 0x0000A001);
//----------------------------------------------------------------
nop(100000);//Delay
//----------------------------------------------------------------
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//printf("[3]: $$ Releasing the POR (Power on Reset) to usb3 phy $$ \n");
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//[2]::RELEASING POR TO USB3 PHY
reg_wr(0x904B000C, 0x23);
nop(100000);//Delay
//reg_wr(0x904B000C, 0x20);
printf("USB_RST_CNTRL @ A:%x,WrD:%x\n",0x904B000C,0x23);
printf("USB3_UTMI_RST:ON,USB3_PHY_RST:OFF,USB2_UTMI_RST:ON,USB2_PHY_RST:ON\n");
nop(8000000);//Delay
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//printf("[4]: $$ Releasing the UTMI reset to usb3 controller $$ \n");
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//[3]::RELEASING UTMI RST TO USB3 CONTROLLER
reg_wr(0x904B000C, 0x03);
nop(100000);//Delay
//reg_wr(0x904B000C, 0x00);
printf("USB_RST_CNTRL @ A:%x,WrD:%x\n",0x904B000C,0x03);
printf("USB3_UTMI_RST:OFF,USB3_PHY_RST:OFF,USB2_UTMI_RST:ON,USB2_PHY_RST:ON\n");
nop(1000000);//Delay
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//printf("[5]: $$ Releasing the AXI reset to usb3 controller $$ \n");
//printf("$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$\n");
//[4]::RELEASING THE USB3 CONTROLLER AXI CLOCK DOMAIN RESET
//Bit[4]-USB3,Bit[3]-USB2
reg_wr(0x904B0058, 0x08);
printf("AXI_RESET_2 @ A:%x,WrD:%x\n",0x904B0058,0x08);
printf("USB3_AXI_RST:OFF,USB2_HRESET:ON \n");
//nop(1000000);//Delay
nop(100000);//Delay
//------------------------------------------------------------//
set_marker(0x900d0001);
//----------------------------------------------------------------
// Read default values from the PHY CR registers
//----------------------------------------------------------------
// Checking the default of PHY CR IDCODE_LO register
err_cnt = err_cnt + phy_cr_reg_def_val_check(0x0000,0x64CD);
// Checking the default of PHY CR IDCODE_HI register
//(old) err_cnt = err_cnt + phy_cr_reg_def_val_check(0x0001,0x8218);
err_cnt = err_cnt + phy_cr_reg_def_val_check(0x0001,0x9218);
if (err_cnt == 0)
printf("IDCODE CHECK TEST PASS\n");
else
printf("IDCODE CHECK TEST FAIL\n");
//----------------------------------------------------------------
nop(3000);//Delay
//----------------------------------------------------------------
set_marker(0x900d0002);
//$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$//
//+INITIALIZE
//+*************************************************************************
//+This routine does general initialization of the ssp. It is intended that
//+this script be run first before any tests. It will set the clock frequency,
//+turn on the pattern matchers/generators, enable rx, enable tx and invert
//+the channel data where needed.
//+At the end of this script the device will be powered up and sending and
//+receiving lfsr7
//+**************************************************************************
//*************************************************************************
// lbert_mode = mode of the lbert (tx and rx, integer between 0 and 7)
// 0 - disabled
// 1 - lfsr31. X^31 + X^28 + 1
// 2 - lfsr23. X^23 + X^18 + 1
// 3 - lfsr15. X^15 + X^14 + 1
// 4 - lfsr7. X^7 + X^6 + 1
// 5 - fixed word (PAT0)
// 6 - DC balanced word (PAT0, ~PAT0)
// 7 - Fixed pattern: (000, PAT0, 3ff, ~PAT0)
// lbert_pattern = pattern for lbert (optional) (integer representing
// binary pattern of 10 bits, 0 to 1023) used for
// lbert_mode 5, 6, and 7
// tx_lvl = transmit level (integer value between 0 and 127)
// output amplitude is set by vptx*(1+tx_lvl)/128
// tx_boost = transmit boost level (integer value between 0 and 127)
// boost (or EQ or preemphasis) is set by
// tx_eq_ratio = (128 - 2*tx_boost)/128
// tx_eq_dB = -20*log10(tx_eq_ratio)
// for tx_boost = 21, tx_eq_dB is 3.45dB
// rx_eq = eq value for rx (integer value between 0 and 7)
// 0 is lest EQ and 7 is most EQ.
// ssc_ppm = ssc ppm, if 0 ssc is not enabled.
//*************************************************************************
// This will reset the device and power the ssp and hsp as specifiecd in the
// gui. It will override in the digital. It will set the baud rate as what
// is specified in the part_params
//**************************************************************************
//verify the reading writting of registers
//Verify can write register in IP write to 101010101
// [11:3]=341
SSP_CR_LANE0_DIG_RX_SCOPE_CTL_val=((SSP_CR_LANE0_DIG_RX_SCOPE_CTL_val & 0xFFFFF007)|(341<<3));
phy_cr_write(SSP_CR_LANE0_DIG_RX_SCOPE_CTL,SSP_CR_LANE0_DIG_RX_SCOPE_CTL_val);
read_data=phy_cr_read(SSP_CR_LANE0_DIG_RX_SCOPE_CTL);
exp_read_data=0x0aa8;
if(read_data==exp_read_data)
{
printf("Write[1] is Pass\n");
}
else
{
printf("Write[1] is Fail\n");
err_cnt++;
printf("Error:%d\n",err_cnt);
}
//Verify can write register in IP write to 010101010
// [11:3]=170
SSP_CR_LANE0_DIG_RX_SCOPE_CTL_val=((SSP_CR_LANE0_DIG_RX_SCOPE_CTL_val & 0xFFFFF007)|(170<<3));
phy_cr_write(SSP_CR_LANE0_DIG_RX_SCOPE_CTL,SSP_CR_LANE0_DIG_RX_SCOPE_CTL_val);
set_marker(0x900d0003);
read_data=phy_cr_read(SSP_CR_LANE0_DIG_RX_SCOPE_CTL);
exp_read_data=0x0550;
if(read_data==exp_read_data)
{
printf("Write[2] is Pass\n");
}
else
{
printf("Write[2] is Fail\n");
err_cnt++;
printf("Error:%d\n",err_cnt);
}
//-Set ref_clock divider value to 0 (SUP_DIG_ATEOVRD.ref_clkdiv2)
// [0:0]
SSP_CR_SUP_DIG_ATEOVRD_val= ((SSP_CR_SUP_DIG_ATEOVRD_val & 0xFFFFFFFE) | (0x0));
phy_cr_write(SSP_CR_SUP_DIG_ATEOVRD,SSP_CR_SUP_DIG_ATEOVRD_val);
//enable usb ref clock from ssp
//-Enable ref clock to usb(SUP_DIG_ATEOVRD.ref_usb2_en
//[1:1]
SSP_CR_SUP_DIG_ATEOVRD_val = ((SSP_CR_SUP_DIG_ATEOVRD_val & 0xFFFFFFFD) | (0x1<<1));
phy_cr_write(SSP_CR_SUP_DIG_ATEOVRD,SSP_CR_SUP_DIG_ATEOVRD_val);
//-Enable ATEOVRD (SUP_DIG_ATEOVRD.ateovrd_en)
//[2:2]
SSP_CR_SUP_DIG_ATEOVRD_val= ((SSP_CR_SUP_DIG_ATEOVRD_val & 0xFFFFFFFB) | (0x1<<2));
phy_cr_write(SSP_CR_SUP_DIG_ATEOVRD,SSP_CR_SUP_DIG_ATEOVRD_val);
//- Set tx_vboost_lvl
//[15:13]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val & 0xFFFFEFFF)|(0x4<<13));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI,SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val);
//- Set los_bias
//[15:13]
SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val=((SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val & 0xFFFFEFFF)|(0x5<<13));
phy_cr_write(SSP_CR_SUP_DIG_LEVEL_OVRD_IN,SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val);
//- Set los_level
//[4:0]
SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val=((SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val & 0xFFFFFFE0)|(0x9));
phy_cr_write(SSP_CR_SUP_DIG_LEVEL_OVRD_IN,SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val);
set_marker(0x900d0004);
//- Set acjt_level
// [9:5]
SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val=((SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val & 0xFFFFFC1F)|(13<<5));
phy_cr_write(SSP_CR_SUP_DIG_LEVEL_OVRD_IN,SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val);
//- Set enable for tx_vboost_lvl/los_bias/los_level/acjt_level
//[10:10]
SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val=((SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val & 0xFFFFFBFF)|(0x1<<10));
phy_cr_write(SSP_CR_SUP_DIG_LEVEL_OVRD_IN,SSP_CR_SUP_DIG_LEVEL_OVRD_IN_val);
//- Set tx_vboost_en
//[8:8]
SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val & 0xFFFFFEFF)|(0x1<<8));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_HI,SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val);
//[9:9]
SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val & 0xFFFFFDFF)|(0x1<<9));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_HI,SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val);
//-Set Tx Reset Low(LANEX_DIG_TX_OVRD_IN_HI.TX_RESET)
//[6:6]
SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val & 0xFFFFFFDF)|(0x1<<6));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_HI,SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val);
//-Enable override (LANEX_DIG_TX_OVRD_IN_HI.TX_RESET_OVRD)
//[7:7]
SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val & 0xFFFFFF7F)|(0x1<<7));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_HI,SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val);
set_marker(0x900d0005);
//-Set Rx reset low(LANEX_DIG_RX_OVRD_IN_HI.RX_RESET)
//[12:12]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFEFFF)|(0x1<<12));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
//-Enable override (LANEX_DIG_RX_OVRD_IN_HI.RX_RESET_OVRD)
//[13:13]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFDFFF)|(0x1<<13));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
//turn off the mpll while setting it up
//-Disable mpll(SUP_DIG_MPLL_OVRD_IN_LO.MPLL_EN)
//[0:0]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val & 0xFFFFFFFE)|(0x0));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO,SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val);
//-Enable override (SUP_DIG_MPLL_OVRD_IN_LO.MPLL_EN_OVRD)
//[1:1]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val & 0xFFFFFFFD)|(0x1<<1));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO,SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val);
//select to remove the fsel from pins
//-Do not use FSEL override pins for multiplier for ssp (SUP.DIG.MPLL_OVRD_IN_HI.FSEL)
//[8:6]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val & 0xFFFFFE3F)|(0x0));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI,SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val);
//-Enable FSEL override (SUP.DIG.MPLL_OVRD_IN_HI.FSEL_OVRD)
//[9:9]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val & 0xFFFFFDFF)|(0x1<<9));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI,SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val);
//set divide and enable ssp refclk
//-Set multiplier value to %x (SUP_DIG_MPLL_OVRD_IN_LO.MPLL_MULTIPLIER)", div_val);
//[8:2]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val & 0xFFFFFE03)|(0x68<<2));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO,SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val);
set_marker(0x900d0006);
//-Enable override (SUP_DIG_MPLL_OVRD_IN_LO.MPLL_MULTIPLIER_OVRD)
//[9:9]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val & 0xFFFFFDFF)|(0x1<<9));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO,SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val);
//-Write Fraction multipler to: 0x%x (SUP_DIG_SSC_OVRD_IN.SSC_REF_CLK_SEL)", ssc_ref_clk_sel);
//[8:0]
SSP_CR_SUP_DIG_SSC_OVRD_IN_val=((SSP_CR_SUP_DIG_SSC_OVRD_IN_val & 0xFFFFFE00)|(132));
phy_cr_write(SSP_CR_SUP_DIG_SSC_OVRD_IN,SSP_CR_SUP_DIG_SSC_OVRD_IN_val);
//turn on the mpll
//-Enable mpll(SUP_DIG_MPLL_OVRD_IN_LO.MPLL_EN)
//[0:0]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val & 0xFFFFFFFE)|(0x1));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO,SSP_CR_SUP_DIG_MPLL_OVRD_IN_LO_val);
//reset the mpll now that it is up and running
//-Reset MPll. Set bit to 0 (SUP_DIG_MPLL_OVRD_IN_HI.MPLL_RST)
//[10:10]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val & 0xFFFFFBFF)|(0x0));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI,SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val);
//-Reset MPll. Set bit to 1 (SUP_DIG_MPLL_OVRD_IN_HI.MPLL_RST)
//[10:10]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val & 0xFFFFFBFF)|(0x1<<10));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI,SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val);
set_marker(0x900d0007);
//-Reset MPll. Set bit to 0 (SUP_DIG_MPLL_OVRD_IN_HI.MPLL_RST)
//[10:10]
SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val=((SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val & 0xFFFFFBFF)|(0x0));
phy_cr_write(SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI,SSP_CR_SUP_DIG_MPLL_OVRD_IN_HI_val);
//-Disable ssc override (SUP_DIG_SSC_OVRD_IN.SSC_EN)
//[12:12]
SSP_CR_SUP_DIG_SSC_OVRD_IN_val=((SSP_CR_SUP_DIG_SSC_OVRD_IN_val & 0xFFFFEFFF)|(0x0));
phy_cr_write(SSP_CR_SUP_DIG_SSC_OVRD_IN,SSP_CR_SUP_DIG_SSC_OVRD_IN_val);
//-Enable override (SUP_DIG_SSC_OVRD_IN.SSC_OVRD_IN_EN)
//[13:13]
SSP_CR_SUP_DIG_SSC_OVRD_IN_val=((SSP_CR_SUP_DIG_SSC_OVRD_IN_val & 0xFFFFDFFF)|(0x1<<13));
phy_cr_write(SSP_CR_SUP_DIG_SSC_OVRD_IN,SSP_CR_SUP_DIG_SSC_OVRD_IN_val);
//turn on the tx
//-Turn off digital loopback (LANEX.DIG.TX.OVRD_IN_LO.LOOPBK_EN)
//[0:0]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFFFE)|(0x0));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Enable override (LANEX.DIG.TX.OVRD_IN_LO.TX_LOOPBK_EN_OVRD)
//[1:1]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFFFD)|(0x1<<1));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Override tx_term_offset to 0 (LANE0_DIG_TX_OVRD_DRV_HI.TERM_OFFSET)
//[4:0]
SSP_CR_LANEX_DIG_TX_OVRD_DRV_HI_val=((SSP_CR_LANEX_DIG_TX_OVRD_DRV_HI_val & 0xFFFFFFE0)|(0x0));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_DRV_HI,SSP_CR_LANEX_DIG_TX_OVRD_DRV_HI_val);
//-Enable override (LANE0_DIG_TX_OVRD_DRV_HI.EN)
//[5:5]
SSP_CR_LANEX_DIG_TX_OVRD_DRV_HI_val=((SSP_CR_LANEX_DIG_TX_OVRD_DRV_HI_val & 0xFFFFFFDF)|(0x1<<5));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_DRV_HI,SSP_CR_LANEX_DIG_TX_OVRD_DRV_HI_val);
set_marker(0x900d0008);
//-Turn off Beacon Enable (LANEX.DIG.TX.OVRD_IN_LO.TX_BEACON_EN)
//[10:10]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFBFF)|(0x0));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Enable override (LANEX.DIG.TX.OVRD_IN_LO.TX_BEACON_EN_OVRD)
//[11:11]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFF7FF)|(0x1<<11));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Set TX CM Enable (LANEX.DIG.TX.OVRD_IN_LO.TX_CM_EN)
//[8:8]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFEFF)|(0x1<<8));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Enable override (LANEX.DIG.TX.OVRD_IN_LO.TX_CM_EN_OVRD)
//[9:9]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFDFF)|(0x1<<9));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Turn off tx_rx detect (LANEX.DIG.TX.OVRD_IN_LO.TX_DETECT_RX_REQ)
//[12:12]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFEFFF)|(0x0<<12));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Enable override (LANEX.DIG.TX.OVRD_IN_LO.TX_DETECT_RX_REQ_OVRD)
//[13:13]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFDFFF)|(0x1<<13));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Turn off tx invert(LANEX.DIG.TX.OVRD_IN_LO.TX_INVERT)
//[2:2]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFFFB)|(0x0<<2));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Enable override (LANEX.DIG.TX.OVRD_IN_LO.TX_INVERT_OVRD)
//[3:3]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFFF7)|(0x1<<3));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Set the TX amplitude(LANEX_DIG_TX_OVRD_DRV_LO.AMPLITUDE)
//[6:0]
SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO_val & 0xFFFFFF80)|(0x7F));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO,SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO_val);
set_marker(0x900d0009);
//-Set the TX boost(LANEX_DIG_TX_OVRD_DRV_LO.PREEMPH)
//[13:7]
SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO_val & 0xFFFFC07F)|(0x0<<7));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO,SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO_val);
//-Enable override (LANEX_DIG_TX_OVRD_DRV_LO.EN)
//[14:14]
SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO_val & 0xFFFFBFFF)|(0x1<<14));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO,SSP_CR_LANEX_DIG_TX_OVRD_DRV_LO_val);
//-Set Data rate(LANEX_DIG_TX_OVRD_IN_HI.TX_RATE)
//[1:0]
SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val & 0xFFFFFFFC)|(0x0));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_HI,SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val);
//-Enable override (LANEX_DIG_TX_OVRD_IN_HI.TX_RATE_OVRD)
//[2:2]
SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val & 0xFFFFFFFB)|(0x1<<2));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_HI,SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val);
set_marker(0x900d000A);
//have the lberts send out data before turning on
//*************************************************
//-Set pattern generator to send commas not commas(LANEX_DIG_TX_LBERT_CTL.PAT0)
//[14:5]
SSP_CR_LANEX_DIG_TX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_TX_LBERT_CTL_val & 0xFFFF801F)|(31<<5));
phy_cr_write(SSP_CR_LANEX_DIG_TX_LBERT_CTL,SSP_CR_LANEX_DIG_TX_LBERT_CTL_val);
//-Set pattern generator to correct mode(LANEX_DIG_TX_LBERT_CTL.MODE)
//[3:0]
SSP_CR_LANEX_DIG_TX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_TX_LBERT_CTL_val & 0xFFFFFFF0)|(0x6));
phy_cr_write(SSP_CR_LANEX_DIG_TX_LBERT_CTL,SSP_CR_LANEX_DIG_TX_LBERT_CTL_val);
//**************************************************
//-Turn on TX Enable(LANEX.DIG.TX.OVRD_IN_LO.TX_EN)
//[6:6]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFFBF)|(0x0));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Enable override (LANEX.DIG.TX.OVRD_IN_LO.TX_EN_OVRD)
//[7:7]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFF7F)|(0x1<<7));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//do tune to get tx amp and boost to take
//-Set Rtune to TX(SUP.DIG.RTUNE_DEBUG.TYPE)
//[4:3]
SSP_CR_SUP_DIG_RTUNE_DEBUG_val=((SSP_CR_SUP_DIG_RTUNE_DEBUG_val & 0xFFFFFFE7)|(0x2<<3));
phy_cr_write(SSP_CR_SUP_DIG_RTUNE_DEBUG,SSP_CR_SUP_DIG_RTUNE_DEBUG_val);
set_marker(0x900d000B);
//-Force Rtune High(SUP.DIG.RTUNE_DEBUG.MAN_TUNE)
//[1:1]
SSP_CR_SUP_DIG_RTUNE_DEBUG_val=((SSP_CR_SUP_DIG_RTUNE_DEBUG_val & 0xFFFFFFFD)|(0x1<<1));
phy_cr_write(SSP_CR_SUP_DIG_RTUNE_DEBUG,SSP_CR_SUP_DIG_RTUNE_DEBUG_val);
//-Force Rtune Low(SUP.DIG.RTUNE_DEBUG.MAN_TUNE)
//[1:1]
SSP_CR_SUP_DIG_RTUNE_DEBUG_val=((SSP_CR_SUP_DIG_RTUNE_DEBUG_val & 0xFFFFFFFD)|(0x0<<1));
phy_cr_write(SSP_CR_SUP_DIG_RTUNE_DEBUG,SSP_CR_SUP_DIG_RTUNE_DEBUG_val);
//take tx out of reset
//-Set Tx Reset Low(LANEX_DIG_TX_OVRD_IN_HI.TX_RESET)
//[6:6]
SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val & 0xFFFFFFBF)|(0x0<<6));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_HI,SSP_CR_LANEX_DIG_TX_OVRD_IN_HI_val);
//-Set Tx Data Enable Low(LANEX_DIG_TX_OVRD_IN_LO.TX_DATA_EN)
//[4:4]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFFEF)|(0x0<<4));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Enable override (LANEX_DIG_TX_OVRD_IN_LO.TX_DATA_EN_OVRD)
//[5:5]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFFDF)|(0x1<<5));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
//-Set Tx Data Enable High(LANEX_DIG_TX_OVRD_IN_LO.TX_DATA_EN)
//[4:4]
SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val & 0xFFFFFFEF)|(0x1<<4));
phy_cr_write(SSP_CR_LANEX_DIG_TX_OVRD_IN_LO,SSP_CR_LANEX_DIG_TX_OVRD_IN_LO_val);
set_marker(0x900d000C);
//start of receiver testing
//-Set Tx Eq to use register value(LANEX.DIG.RX.OVRD_IN_HI.RX_EQ_EN)
//[6:6]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFFFBF));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
//-Enable override (LANEX.DIG.RX.OVRD_IN_HI.RX_EQ_EN_OVRD)
//[7:7]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFFF7F)|(0x1<<7));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
//-Set Tx Eq register value(LANEX_DIG_RX_OVRD_IN_HI.RX_EQ)
//[10:8]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFF8FF)|(0x0<<8));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
//-Enable override (LANEX_DIG_RX_OVRD_IN_HI.RX_EQ_OVRD)
//[11:11]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFF7FF)|(0x1<<11));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
//force eq value
//-Set Rx Los filer to 0(LANEX.DIG.RX.OVRD_IN_HI.RX_LOS_FILTER)
//[4:3]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFFFE7)|(0x0));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
set_marker(0x900d000D);
//-Enable override (LANEX.DIG.RX.OVRD_IN_HI.RX_LOS_FILTER_OVRD)
//[5:5]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFFFDF)|(0x1<<5));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
//-Set Rx Bit shift to 0(LANEX.DIG.RX.OVRD_IN_LO.RX_BIT_SHIFT)
//[8:8]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFEFF)|(0x0<<8));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Enable override (LANEX.DIG.RX.OVRD_IN_LO.RX_BIT_SHIFT_OVRD)
//[9:9]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFDFF)|(0x1<<9));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Set Rx invert bit to: %x (LANEX.DIG.RX.OVRD_IN_LO.RX_INVERT)", `FLIP_ONE);
//[0:0]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFFFE)|(0x0));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Enable override (LANEX.DIG.RX.OVRD_IN_LO.RX_INVERT_OVRD)
//[1:1]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFFFD)|(0x1<<1));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Enable rx los(LANEX.DIG.RX.OVRD_IN_LO.RX_LOS_EN)
//[12:12]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFEFFF)|(0x1<<12));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Enable override (LANEX.DIG.RX.OVRD_IN_LO.RX_LOS_EN_OVRD)
//[13:13]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFDFFF)|(0x1<<13));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
set_marker(0x900d000E);
//-Set rx datarate to full(LANEX_DIG_RX_OVRD_IN_HI.RX_RATE)
//[1:0]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFFFFC)|(0x0<<0));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
//-Enable override (LANEX_DIG_RX_OVRD_IN_HI.RX_RATE_OVRD)
//[2:2]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFFFFB)|(0x1<<2));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
//-Set Rx Align(LANEX_DIG_RX_OVRD_IN_LO.RX_ALIGN_EN)
//[6:6]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFFBF)|(0x1<<6));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Enable override (LANEX_DIG_RX_OVRD_IN_LO.RX_ALIGN_EN_OVRD)
//[7:7]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFF7F)|(0x1<<7));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Set Term enable(LANEX_DIG_RX_OVRD_IN_LO.RX_TERM_EN)
//[10:10]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFBFF)|(0x1<<10));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Enable override (LANEX_DIG_RX_OVRD_IN_LO.RX_TERM_EN_OVRD)
//[11:11]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFF7FF)|(0x1<<11));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
set_marker(0x900d000F);
//-Enable Rx PLL(LANEX_DIG_RX_OVRD_IN_LO.RX_PLL_EN)
//[2:2]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFFFB)|(0x1<<2));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Enable override (LANEX_DIG_RX_OVRD_IN_LO.RX_PLL_EN_OVRD)
//[3:3]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFFF7)|(0x1<<3));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Enable Rx(LANEX_DIG_RX_OVRD_IN_LO.RX_DATA_EN)
//[4:4]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFFEF)|(0x1<<4));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Enable override (LANEX_DIG_RX_OVRD_IN_LO.RX_DATA_EN_OVRD)
//[5:5]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFFDF)|(0x1<<5));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//take the Rx out of reset
//-Set Rx reset low(LANEX_DIG_RX_OVRD_IN_HI.RX_RESET)
//[12:12]
SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val & 0xFFFFEFFF)|(0x0<<12));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_HI,SSP_CR_LANEX_DIG_RX_OVRD_IN_HI_val);
set_marker(0x900d0010);
//-Pause 1mS
nop(100000);//Delay
set_marker(0x900d0011);
printf("Waiting for RX CDR is lock on LANE0...\n");
//-Check to see if RX CDR is locked on LANE0
//Verify CDR has locked
read_data=phy_cr_read(SSP_CR_LANE0_DIG_RX_CDR_CDR_FSM_DEBUG);
exp_read_data = (read_data | 0x0008); // Checking to see if LANE0_DIG_RX_CDR_CDR_FSM_DEBUG.ALIGNED is 1
while(read_data != exp_read_data)
{
read_data=phy_cr_read(SSP_CR_LANE0_DIG_RX_CDR_CDR_FSM_DEBUG);
exp_read_data = (read_data | 0x0008); // Checking to see if LANE0_DIG_RX_CDR_CDR_FSM_DEBUG.ALIGNED is 1
}
//if(read_data == exp_read_data)
//{
printf("RX CDR is locked on LANE0\n");
//}
//else
//{
// printf("RX CDR is not-locked on LANE0\n");
// err_cnt++;
// printf("Error:%d\n",err_cnt);
//}
//set bert back to normal mode
//-Turn off data alignment(LANEX_DIG_RX_OVRD_IN_LO.RX_ALIGN_EN)");
//[6:6]
SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val=((SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val & 0xFFFFFFBF)|(0x0<<6));
phy_cr_write(SSP_CR_LANEX_DIG_RX_OVRD_IN_LO,SSP_CR_LANEX_DIG_RX_OVRD_IN_LO_val);
//-Set patten generator to selected pattern(LANEX_DIG_TX_LBERT_CTL.PAT0)
//[14:5]
SSP_CR_LANEX_DIG_TX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_TX_LBERT_CTL_val & 0xFFFF801F)|(302<<5));
phy_cr_write(SSP_CR_LANEX_DIG_TX_LBERT_CTL,SSP_CR_LANEX_DIG_TX_LBERT_CTL_val);
//-Set patten generator to selected mode(LANEX_DIG_TX_LBERT_CTL.MODE)
//[3:0]
SSP_CR_LANEX_DIG_TX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_TX_LBERT_CTL_val & 0xFFFFFFF0)|(0x4));
phy_cr_write(SSP_CR_LANEX_DIG_TX_LBERT_CTL,SSP_CR_LANEX_DIG_TX_LBERT_CTL_val);
set_marker(0x900d0012);
//-Set patten matcher to selected mode(LANEX_DIG_RX_LBERT_CTL.MODE)
//[3:0]
SSP_CR_LANEX_DIG_RX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_RX_LBERT_CTL_val & 0xFFFFFFF0)|(0x4));
phy_cr_write(SSP_CR_LANEX_DIG_RX_LBERT_CTL,SSP_CR_LANEX_DIG_RX_LBERT_CTL_val);
//-Sync pattern matcher low(LANEX_DIG_RX_LBERT_CTL.SYNC)
//[4:4]
SSP_CR_LANEX_DIG_RX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_RX_LBERT_CTL_val & 0xFFFFFFEF)|(0x0<<4));
phy_cr_write(SSP_CR_LANEX_DIG_RX_LBERT_CTL,SSP_CR_LANEX_DIG_RX_LBERT_CTL_val);
//-Sync pattern matcher high(LANEX_DIG_RX_LBERT_CTL.SYNC)
//[4:4]
SSP_CR_LANEX_DIG_RX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_RX_LBERT_CTL_val & 0xFFFFFFEF)|(0x1<<4));
phy_cr_write(SSP_CR_LANEX_DIG_RX_LBERT_CTL,SSP_CR_LANEX_DIG_RX_LBERT_CTL_val);
//-Sync pattern matcher low(LANEX_DIG_RX_LBERT_CTL.SYNC)
//[4:4]
SSP_CR_LANEX_DIG_RX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_RX_LBERT_CTL_val & 0xFFFFFFEF)|(0x0<<4));
phy_cr_write(SSP_CR_LANEX_DIG_RX_LBERT_CTL,SSP_CR_LANEX_DIG_RX_LBERT_CTL_val);
set_marker(0x900d0013);
//$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$//
//while(1)
//{
//@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@//
// BERT_TEST
//*************************************************************************
// Functional test to verify that the device is operational and
// the BERTS are functioning. The device is set-up in external loopback.
// The berts are tested that they can match lfsr7 and that they can count
// errors
//
// DETAILED PROGRAM STEPS
// Assume device is in set-up mode
// Sync pattern matchers
// Wait 5ms
// Check for errors
// Generate 1 error in pattern generator
// Wait 5mS
// Check for 1 error at patten matchers
//*************************************************************************
//sync pattern matchers
//-Sync the patten matchers high (LANEX.DIG.RX.LBERT_CTL.SYNC)
// set sync bit
//[4:4]
SSP_CR_LANEX_DIG_RX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_RX_LBERT_CTL_val & 0xFFFFFFEF)|(0x1<<4));
phy_cr_write(SSP_CR_LANEX_DIG_RX_LBERT_CTL,SSP_CR_LANEX_DIG_RX_LBERT_CTL_val);
//-Sync the pattern matchers low (LANEX.DIG.RX.LBERT_CTL.SYNC)
// clear sync bit
//[4:4]
SSP_CR_LANEX_DIG_RX_LBERT_CTL_val=(( SSP_CR_LANEX_DIG_RX_LBERT_CTL_val & 0xFFFFFFEF)|(0x0<<4));
phy_cr_write(SSP_CR_LANEX_DIG_RX_LBERT_CTL,SSP_CR_LANEX_DIG_RX_LBERT_CTL_val);
set_marker(0x900d0014);
//wait 5ms to check if errors are generated
//-Pause 5mS
nop(50000);//Delay
set_marker(0x900d0015);
//verify no errors on pattern matcher
//-Check for 0 errors on channel0 .DIG.RX.LBERT_ERR.COUNT)
//Bert errors on channel0 expect 0 errors
read_data=phy_cr_read(SSP_CR_LANE0_DIG_RX_LBERT_ERR);
exp_read_data=0x0000;//(read_data & 0x8000);
if(read_data == exp_read_data)
{
printf("NO BIST ERRORS\n");
}
else
{
printf("%d BIST ERRORS\n",read_data);
err_cnt++;
printf("Error:%d\n",err_cnt);
}
//insert 1 error on all channels
//-Insert 1 error on the pattern generator high (LANEX.DIG.TX.LBERT_CTL.TRIGGER_ERR)
//[4:4]
SSP_CR_LANEX_DIG_TX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_TX_LBERT_CTL_val & 0xFFFFFFEF)|(0x1<<4));
phy_cr_write(SSP_CR_LANEX_DIG_TX_LBERT_CTL,SSP_CR_LANEX_DIG_TX_LBERT_CTL_val);
//-Insert 1 error on the pattern generator low (LANEX.DIG.TX.LBERT_CTL.TRIGGER_ERR)
//[4:4]
SSP_CR_LANEX_DIG_TX_LBERT_CTL_val=((SSP_CR_LANEX_DIG_TX_LBERT_CTL_val & 0xFFFFFFEF)|(0x0<<4));
phy_cr_write(SSP_CR_LANEX_DIG_TX_LBERT_CTL,SSP_CR_LANEX_DIG_TX_LBERT_CTL_val);
set_marker(0x900d0016);
//wait 5ms to check if errors are generated
//-Wait 5mS
nop(50000);//Delay
set_marker(0x900d0017);
//verify 1 error on pattern matcher
//-Check for 1 error on channel0 .DIG.RX.LBERT_ERR.COUNT
//Bert errors on channel0 expect 1 error
read_data = phy_cr_read(SSP_CR_LANE0_DIG_RX_LBERT_ERR);
exp_read_data = 0x0001;//(read_data & 0x8001);
if(read_data == exp_read_data)
{
printf("BIST ERRORS MATCHED\n");
}
else
{
printf("%d BIST ERRORS\n",read_data);
err_cnt++;
printf("Error:%d\n",err_cnt);
}
//@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@//
if(err_cnt==0)
{
printf(">>BER TEST PASS<<\n");
set_marker(0x900D900D);
ret = 0;
}
else
{
printf(">>BER TEST FAIL<<\n");
set_marker(0xBAADBAAD);
}
nop(50);
return ret;
}