Visible to Intel only — GUID: nik1410564893772
Ixiasoft
Visible to Intel only — GUID: nik1410564893772
Ixiasoft
4.5. Reset
Refer to Reset and Clocks for more information about the reset sequence and a block diagram of the reset logic.
Signal |
Direction |
Description |
---|---|---|
npor | Input |
Active low reset signal. In the Intel hardware example designs, npor is the OR of pin_perst and local_rstn coming from the software Application Layer. If you do not drive a soft reset signal from the Application Layer, this signal must be derived from pin_perst. You cannot disable this signal. Resets the entire IP Core and transceiver. Asynchronous. In systems that use the hard reset controller, this signal is edge, not level sensitive; consequently, you cannot use a low value on this signal to hold custom logic in reset. For more information about the hard and soft reset controllers, refer to Reset. |
nreset_status | Output |
Active low reset signal. It is derived from npor or pin_perstn. You can use this signal to reset the Application Layer. |
pin_perst | Input |
Active low reset from the PCIe reset pin of the device. pin_perst resets the datapath and control registers. Configuration over PCI Express (CvP) requires this signal. For more information about CvP refer to Configuration over PCI Express (CvP). Arria® V GZ devices can have up to 4 instances of the Hard IP for PCI Express. Each instance has its own pin_perst signal. You must connect the pin_perst of each Hard IP instance to the corresponding nPERST pin of the device. These pins have the following locations:
For example, if you are using the Hard IP instance in the bottom left corner of the device, you must connect pin_perst to NPERSL0. For maximum use of the Arria® V GZ device, Intel recommends that you use the bottom left Hard IP first. This is the only location that supports CvP over a PCIe link. If your design does not require CvP, you may select other Hard IP blocks. Refer to the appropriate device pinout for correct pin assignment for more detailed information about these pins. The PCI Express Card Electromechanical Specification 2.0 specifies this pin requires 3.3 V. You can drive this 3.3V signal to the nPERST* even if the VVCCPGM of the bank is not 3.3V if the following 2 conditions are met:
|
The following figure illustrates the timing relationship between npor and the LTSSM L0 state.
Signal |
Direction |
Description |
---|---|---|
cfg_par_err | Output |
Indicates that a parity error in a TLP routed to the internal Configuration Space. This error is also logged in the Vendor Specific Extended Capability internal error register. You must reset the Hard IP if this error occurs. |
derr_cor_ext_rcv |
Output |
Indicates a corrected error in the RX buffer. This signal is for debug only. It is not valid until the RX buffer is filled with data. This is a pulse, not a level, signal. Internally, the pulse is generated with the 500 MHz clock. A pulse extender extends the signal so that the FPGA fabric running at 250 MHz can capture it. Because the error was corrected by the IP core, no Application Layer intervention is required. 3 |
derr_cor_ext_rpl |
Output |
Indicates a corrected ECC error in the retry buffer. This signal is for debug only. Because the error was corrected by the IP core, no Application Layer intervention is required. 3 |
derr_rpl |
Output |
Indicates an uncorrectable error in the retry buffer. This signal is for debug only. 3 |
dlup | Output |
When asserted, indicates that the Hard IP block is in the Data Link Control and Management State Machine (DLCMSM) DL_Up state. |
dlup_exit | Output |
This signal is asserted low for one pld_clk cycle when the IP core exits the DLCMSM DL_Up state, indicating that the Data Link Layer has lost communication with the other end of the PCIe link and left the Up state. When this pulse is asserted, the Application Layer should generate an internal reset signal that is asserted for at least 32 cycles. |
ev128ns | Output |
Asserted every 128 ns to create a time base aligned activity. |
ev1us | Output |
Asserted every 1µs to create a time base aligned activity. |
hotrst_exit | Output |
Hot reset exit. This signal is asserted for 1 clock cycle when the LTSSM exits the hot reset state. This signal should cause the Application Layer to be reset. This signal is active low. When this pulse is asserted, the Application Layer should generate an internal reset signal that is asserted for at least 32 cycles. |
int_status[3:0] | Output |
These signals drive legacy interrupts to the Application Layer as follows:
|
ko_cpl_spc_data[11:0] | Output |
The Application Layer can use this signal to build circuitry to prevent RX buffer overflow for completion data. Endpoints must advertise infinite space for completion data; however, RX buffer space is finite. ko_cpl_spc_data is a static signal that reflects the total number of 16 byte completion data units that can be stored in the completion RX buffer. |
ko_cpl_spc_header[7:0] | Output |
The Application Layer can use this signal to build circuitry to prevent RX buffer overflow for completion headers. Endpoints must advertise infinite space for completion headers; however, RX buffer space is finite. ko_cpl_spc_header is a static signal that indicates the total number of completion headers that can be stored in the RX buffer. |
l2_exit | Output |
L2 exit. This signal is active low and otherwise remains high. It is asserted for one cycle (changing value from 1 to 0 and back to 1) after the LTSSM transitions from l2.idle to detect. When this pulse is asserted, the Application Layer should generate an internal reset signal that is asserted for at least 32 cycles. |
lane_act[3:0] |
Output |
Lane Active Mode: This signal indicates the number of lanes that configured during link training. The following encodings are defined:
|
ltssmstate[4:0] | Output |
LTSSM state: The LTSSM state machine encoding defines the following states:
|
rx_par_err | Output |
When asserted for a single cycle, indicates that a parity error was detected in a TLP at the input of the RX buffer. This error is logged as an uncorrectable internal error in the VSEC registers. For more information, refer to Uncorrectable Internal Error Status Register. You must reset the Hard IP if this error occurs because parity errors can leave the Hard IP in an unknown state. |
tx_par_err[1:0] | Output |
When asserted for a single cycle, indicates a parity error during TX TLP transmission. These errors are logged in the VSEC register. The following encodings are defined:
Note that not all simulation models assert the Transaction Layer error bit in conjunction with the Data Link Layer error bit. |