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1. About the External Memory Interfaces Intel® Agilex™ FPGA IP
2. Intel® Agilex™ FPGA EMIF IP – Introduction
3. Intel® Agilex™ FPGA EMIF IP – Product Architecture
4. Intel® Agilex™ FPGA EMIF IP – End-User Signals
5. Intel® Agilex™ FPGA EMIF IP – Simulating Memory IP
6. Intel® Agilex™ FPGA EMIF IP – DDR4 Support
7. Intel® Agilex™ FPGA EMIF IP – QDR-IV Support
8. Intel® Agilex™ FPGA EMIF IP – Timing Closure
9. Intel® Agilex™ FPGA EMIF IP – I/O Timing Closure
10. Intel® Agilex™ FPGA EMIF IP – Controller Optimization
11. Intel® Agilex™ FPGA EMIF IP – Debugging
12. External Memory Interfaces Intel® Agilex™ FPGA IP User Guide Archives
13. Document Revision History for External Memory Interfaces Intel® Agilex™ FPGA IP User Guide
3.1. Intel® Agilex™ EMIF Architecture: Introduction
3.2. Intel® Agilex™ EMIF Sequencer
3.3. Intel® Agilex™ EMIF Calibration
3.4. Intel® Agilex™ EMIF Controller
3.5. User-requested Reset in Intel® Agilex™ EMIF IP
3.6. Intel® Agilex™ EMIF for Hard Processor Subsystem
3.7. Using a Custom Controller with the Hard PHY
3.1.1. Intel® Agilex™ EMIF Architecture: I/O Subsystem
3.1.2. Intel® Agilex™ EMIF Architecture: I/O SSM
3.1.3. Intel® Agilex™ EMIF Architecture: I/O Bank
3.1.4. Intel® Agilex™ EMIF Architecture: I/O Lane
3.1.5. Intel® Agilex™ EMIF Architecture: Input DQS Clock Tree
3.1.6. Intel® Agilex™ EMIF Architecture: PHY Clock Tree
3.1.7. Intel® Agilex™ EMIF Architecture: PLL Reference Clock Networks
3.1.8. Intel® Agilex™ EMIF Architecture: Clock Phase Alignment
3.3.4.3.1. Debugging Calibration Failure Using Information from the Calibration report
3.3.4.3.2. Debugging Address and Command Leveling Calibration Failure
3.3.4.3.3. Debugging Address and Command Deskew Failure
3.3.4.3.4. Debugging DQS Enable Failure
3.3.4.3.5. Debugging Read Deskew Calibration Failure
3.3.4.3.6. Debugging VREFIN Calibration Failure
3.3.4.3.7. Debugging LFIFO Calibration Failure
3.3.4.3.8. Debugging Write Leveling Failure
3.3.4.3.9. Debugging Write Deskew Calibration Failure
3.3.4.3.10. Debugging VREFOUT Calibration Failure
4.1.1.1. local_reset_req for DDR4
4.1.1.2. local_reset_status for DDR4
4.1.1.3. pll_ref_clk for DDR4
4.1.1.4. pll_locked for DDR4
4.1.1.5. ac_parity_err for DDR4
4.1.1.6. oct for DDR4
4.1.1.7. mem for DDR4
4.1.1.8. status for DDR4
4.1.1.9. afi_reset_n for DDR4
4.1.1.10. afi_clk for DDR4
4.1.1.11. afi_half_clk for DDR4
4.1.1.12. afi for DDR4
4.1.1.13. emif_usr_reset_n for DDR4
4.1.1.14. emif_usr_clk for DDR4
4.1.1.15. ctrl_amm for DDR4
4.1.1.16. ctrl_amm_aux for DDR4
4.1.1.17. ctrl_auto_precharge for DDR4
4.1.1.18. ctrl_user_priority for DDR4
4.1.1.19. ctrl_ecc_user_interrupt for DDR4
4.1.1.20. ctrl_ecc_readdataerror for DDR4
4.1.1.21. ctrl_ecc_status for DDR4
4.1.1.22. ctrl_mmr_slave for DDR4
4.1.1.23. hps_emif for DDR4
4.1.1.24. emif_calbus for DDR4
4.1.1.25. emif_calbus_clk for DDR4
4.1.2.1. local_reset_req for QDR-IV
4.1.2.2. local_reset_status for QDR-IV
4.1.2.3. pll_ref_clk for QDR-IV
4.1.2.4. pll_locked for QDR-IV
4.1.2.5. oct for QDR-IV
4.1.2.6. mem for QDR-IV
4.1.2.7. status for QDR-IV
4.1.2.8. afi_reset_n for QDR-IV
4.1.2.9. afi_clk for QDR-IV
4.1.2.10. afi_half_clk for QDR-IV
4.1.2.11. afi for QDR-IV
4.1.2.12. emif_usr_reset_n for QDR-IV
4.1.2.13. emif_usr_clk for QDR-IV
4.1.2.14. ctrl_amm for QDR-IV
4.1.2.15. emif_calbus for QDR-IV
4.1.2.16. emif_calbus_clk for QDR-IV
4.4.1. ctrlcfg0
4.4.2. ctrlcfg1
4.4.3. dramtiming0
4.4.4. sbcfg1
4.4.5. caltiming0
4.4.6. caltiming1
4.4.7. caltiming2
4.4.8. caltiming3
4.4.9. caltiming4
4.4.10. caltiming9
4.4.11. dramaddrw
4.4.12. sideband0
4.4.13. sideband1
4.4.14. sideband4
4.4.15. sideband6
4.4.16. sideband7
4.4.17. sideband9
4.4.18. sideband11
4.4.19. sideband12
4.4.20. sideband13
4.4.21. sideband14
4.4.22. dramsts
4.4.23. niosreserve0
4.4.24. niosreserve1
4.4.25. sideband16
4.4.26. ecc3: ECC Error and Interrupt Configuration
4.4.27. ecc4: Status and Error Information
4.4.28. ecc5: Address of Most Recent SBE/DBE
4.4.29. ecc6: Address of Most Recent Correction Command Dropped
4.4.30. ecc7: Extension for Address of Most Recent SBE/DBE
4.4.31. ecc8: Extension for Address of Most Recent Correction Command Dropped
6.1.1. Intel Agilex EMIF IP DDR4 Parameters: General
6.1.2. Intel Agilex EMIF IP DDR4 Parameters: Memory
6.1.3. Intel Agilex EMIF IP DDR4 Parameters: Mem I/O
6.1.4. Intel Agilex EMIF IP DDR4 Parameters: FPGA I/O
6.1.5. Intel Agilex EMIF IP DDR4 Parameters: Mem Timing
6.1.6. Intel Agilex EMIF IP DDR4 Parameters: Controller
6.1.7. Intel Agilex EMIF IP DDR4 Parameters: Diagnostics
6.1.8. Intel Agilex EMIF IP DDR4 Parameters: Example Designs
6.5.1. Terminations for DDR4 with Intel® Agilex™ Devices
6.5.2. Clamshell Topology
6.5.3. General Layout Routing Guidelines
6.5.4. Reference Stackup
6.5.5. Intel® Agilex™ EMIF-Specific Routing Guidelines for Various DDR4 Topologies
6.5.6. DDR4 Routing Guidelines: Discrete (Component) Topologies
6.5.7. Intel® Agilex™ EMIF Pin Swapping Guidelines
6.5.5.1. One DIMM per Channel (1DPC) for UDIMM, RDIMM, LRDIMM, and SODIMM DDR4 Topologies
6.5.5.2. Two DIMMs per Channel (2DPC) for UDIMM, RDIMM, and LRDIMM DDR4 Topologies
6.5.5.3. Two DIMMs per Channel (2DPC) for SODIMM Topology
6.5.5.4. Skew Matching Guidelines for DIMM Configurations
6.5.5.5. Power Delivery Recommendations for the Memory / DIMM Side
6.5.6.1. Single Rank x 8 Discrete (Component) Topology
6.5.6.2. Single Rank x 16 Discrete (Component) Topology
6.5.6.3. ADDR/CMD Reference Voltage/RESET Signal Routing Guidelines for Single Rank x 8 and R Rank x 16 Discrete (Component) Topologies
6.5.6.4. Skew Matching Guidelines for DDR4 Discrete Configurations
6.5.6.5. Power Delivery Recommendations for DDR4 Discrete Configurations
7.1.1. Intel Agilex EMIF IP QDR-IV Parameters: General
7.1.2. Intel Agilex EMIF IP QDR-IV Parameters: Memory
7.1.3. Intel Agilex EMIF IP QDR-IV Parameters: FPGA I/O
7.1.4. Intel Agilex EMIF IP QDR-IV Parameters: Mem Timing
7.1.5. Intel Agilex EMIF IP QDR-IV Parameters: Controller
7.1.6. Intel Agilex EMIF IP QDR-IV Parameters: Diagnostics
7.1.7. Intel Agilex EMIF IP QDR-IV Parameters: Example Designs
7.3.3.1. Intel® Agilex™ FPGA EMIF IP Banks
7.3.3.2. General Guidelines
7.3.3.3. QDR IV SRAM Commands and Addresses, AP, and AINV Signals
7.3.3.4. QDR IV SRAM Clock Signals
7.3.3.5. QDR IV SRAM Data, DINV, and QVLD Signals
7.3.3.6. Specific Pin Connection Requirements
7.3.3.7. Resource Sharing Guidelines (Multiple Interfaces)
9.1. I/O Timing Closure Overview
9.2. Collateral Generated with Your EMIF IP
9.3. SPICE Decks
9.4. File Organization
9.5. Top-level Parameterization File
9.6. IP-Supplied Parameters that You Might Need to Override
9.7. Understanding the *_ip_parameters.dat File and Making a Mask Polygon
9.8. Multi-Rank Topology
9.9. Pin Parasitics
9.10. Mask Evaluation
10.4.1. Auto-Precharge Commands
10.4.2. Additive Latency
10.4.3. Bank Interleaving
10.4.4. Additive Latency and Bank Interleaving
10.4.5. User-Controlled Refresh
10.4.6. Frequency of Operation
10.4.7. Series of Reads or Writes
10.4.8. Data Reordering
10.4.9. Starvation Control
10.4.10. Command Reordering
10.4.11. Bandwidth
10.4.12. Enable Command Priority Control
10.4.13. Controller Pre-pay and Post-pay Refresh (DDR4 Only)
11.1. Interface Configuration Performance Issues
11.2. Functional Issue Evaluation
11.3. Timing Issue Characteristics
11.4. Verifying Memory IP Using the Signal Tap Logic Analyzer
11.5. Hardware Debugging Guidelines
11.6. Categorizing Hardware Issues
11.7. Debugging with the External Memory Interface Debug Toolkit
11.8. Using the Default Traffic Generator
11.9. Using the Configurable Traffic Generator (TG2)
11.10. EMIF On-Chip Debug Port
11.11. Efficiency Monitor
11.5.1. Create a Simplified Design that Demonstrates the Same Issue
11.5.2. Measure Power Distribution Network
11.5.3. Measure Signal Integrity and Setup and Hold Margin
11.5.4. Vary Voltage
11.5.5. Operate at a Lower Speed
11.5.6. Determine Whether the Issue Exists in Previous Versions of Software
11.5.7. Determine Whether the Issue Exists in the Current Version of Software
11.5.8. Try A Different PCB
11.5.9. Try Other Configurations
11.5.10. Debugging Checklist
11.7.4.3.1. Debugging Calibration Failure Using Information from the Calibration report
11.7.4.3.2. Debugging Address and Command Leveling Calibration Failure
11.7.4.3.3. Debugging Address and Command Deskew Failure
11.7.4.3.4. Debugging DQS Enable Failure
11.7.4.3.5. Debugging Read Deskew Calibration Failure
11.7.4.3.6. Debugging VREFIN Calibration Failure
11.7.4.3.7. Debugging LFIFO Calibration Failure
11.7.4.3.8. Debugging Write Leveling Failure
11.7.4.3.9. Debugging Write Deskew Calibration Failure
11.7.4.3.10. Debugging VREFOUT Calibration Failure
11.9.1. Enabling the Traffic Generator in a Design Example
11.9.2. Traffic Generator Block Description
11.9.3. Default Traffic Pattern
11.9.4. Configuration and Status Registers
11.9.5. User Pattern
11.9.6. Traffic Generator Status
11.9.7. Starting Traffic with the Traffic Generator
11.9.8. Traffic Generator Configuration User Interface
11.9.8.1. Connecting the Traffic Generator
11.9.8.2. Claiming/Releasing the TG Config Interface
11.9.8.3. Configuring the Traffic Generator
11.9.8.4. Traffic Generator Preset Selection
11.9.8.5. Traffic Generator Status Report
11.9.8.6. Examples of Configuring the TG2 Traffic Generator
Example 1: Configuring TG2 to Write and Read from All Memory Locations with Alternating 0x555_5555_5555_5555 and 0xAAA_AAAA_AAAA_AAAA Data Pattern
Example 2: Configuring TG2 to Run with an Infinite Loop
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11.9.8.6. Examples of Configuring the TG2 Traffic Generator
Example 1: Configuring TG2 to Write and Read from All Memory Locations with Alternating 0x555_5555_5555_5555 and 0xAAA_AAAA_AAAA_AAAA Data Pattern
In this example, 227 logical addresses are available on the EMIF controller. This example is a x72 DDR4 interface, configured to use Quarter Rate (QR) user logic.
Figure 244. Address Width for Memory IP
To write to all memory locations for a memory IP, starting from address=0x0 , it is necessary to satisfy the following requirement:
TG_LOOP_COUNT x TG_BURST_LENGTH x TG_WRITE_COUNT = Total Logical Address AvailableFor this example, assume the following:
- TG_BURST_LENGTH = 64 (in decimal) or TG_BURST_LENGTH = 0x40 (in hexadecimal).
- TG_WRITE_COUNT = 1.
You can calculate the required TG_LOOP_COUNT as follows:
TG_LOOP_COUNT = Total Logical Address Available / (TG_WRITE_COUNT x TG_BURST_LENGTH)
= 227/64
= 2097152 (in decimal)
= 0x20_0000 (in hexadecimal)
To configure the TG2 using core logic, follow these steps:
- Write to TG_CLEAR with data=0xF to clear all the failure status registers.
- Configure the registers with the value specified in table 1 below.
- Write to TG_START to start the TG2 using the configuration in step 2. This starts the traffic test in user mode.
- Read from TG_TEST_COMPLETE until the read data =0x1, indicating the traffic test has completed.
- Read from TG_PASS, TG_FAIL, and TG_TIMEOUT to check the test result.
- TG_PASS. A value of 1 indicates that the traffic test passed at the end of all test stages.
- TG_FAIL. A value of 1 indicates that the configured traffic finished running but a failure (read miscompare) was observed. You may read from other relevant registers to get more information about the failure. Refer to the Configuration and Status Registers table for information on the available registers.
- TG_TIMEOUT. A value of 1 indicates that a read response was not received from the interface for one or more read commands.
Address | Register Name | Value | Remarks |
---|---|---|---|
0x8 | TG_LOOP_COUNT | 0x20_0000 | Require 2097152* 64 to cover all memory locations. |
0xC | TG_WRITE_COUNT | 0x1 | |
0x10 | TG_READ_COUNT | 0x1 | |
0x14 | TG_WRITE_REPEAT_COUNT | 0x1 | |
0x18 | TG_READ_REPEAT_COUNT | 0x1 | |
0x1C | TG_BURST_LENGTH | 0x40 | Require 2097152* 64 to cover all memory locations. |
0x38 | TG_RW_GEN_IDLE_COUNT | 0x1 | |
0x3C | TG_RW_GEN_LOOP_IDLE_COUNT | 0x1 | |
0x40 | TG_SEQ_START_ADDR_WR_L | 0x0 | Lower 32-bit of start write address. |
0x44 | TG_SEQ_START_ADDR_WR_H | 0x0 | Upper 32-bit of start write address. |
0x48 | TG_ADDR_MODE_WR | 0x1 | Sequential Addressing. |
0x50 | TG_RETURN_TO_START_ADDR | 0x0 | |
0x74 | TG_SEQ_ADDR_INCR | 0x40 | Must match the burst length in this example. |
0x78 | TG_SEQ_START_ADDR_RD_L | 0x0 | Lower 32-bit of start read address. |
0x7C | TG_SEQ_START_ADDR_RD_H | 0x0 | Upper 32-bit of start read address. |
0x80 | TG_ADDR_MODE_RD | 0x1 | Sequential Addressing. Must match the TG_ADDR_MODE_WR. |
0xB4 | TG_USER_WORM_EN | 0x0 | Disable WORM mode. |
0xE80 | TG_BYTEEN_SEL | 0x0 | Fixed Pattern. |
0xC00 | TG_PPPG_SEL | 0x0 | Fixed Pattern. |
0x400 | TG_DATA_SEED | 0x5555_5555 | For DG0 (DQ0/8/16/24/32/40/48/56/64). |
0x404 | TG_DATA_SEED | 0xAAAA_AAAA | For DG1 (DQ1/9/17/25/33/41/49/57/65). |
0x408 | TG_DATA_SEED | 0x5555_5555 | For DG2 (DQ2/10/18/26/34/42/50/58/66). |
0x40C | TG_DATA_SEED | 0xAAAA_AAAA | For DG3 (DQ3/11/19/27/35/43/51/59/67). |
0x410 | TG_DATA_SEED | 0x5555_5555 | For DG4 (DQ4/12/20/28/36/44/52/60/68). |
0x414 | TG_DATA_SEED | 0xAAAA_AAAA | For DG5 (DQ5/13/21/29/37/45/53/61/69). |
0x418 | TG_DATA_SEED | 0x5555_5555 | For DG6 (DQ6/14/22/20/38/46/54/62/70). |
0x41C | TG_DATA_SEED | 0xAAAA_AAAA | For DG7 (DQ7/15/23/31/39/47/55/63/71). |
0x800 | TG_BYTEEN_SEED | 0xFFFF_FFFF | For Byte 0. |
0x804 | TG_BYTEEN_SEED | 0xFFFF_FFFF | For Byte 1. |
0x808 | TG_BYTEEN_SEED | 0xFFFF_FFFF | For Byte 2. |
0x80C | TG_BYTEEN_SEED | 0xFFFF_FFFF | For Byte 3. |
0x810 | TG_BYTEEN_SEED | 0xFFFF_FFFF | For Byte 4. |
0x814 | TG_BYTEEN_SEED | 0xFFFF_FFFF | For Byte 5. |
0x818 | TG_BYTEEN_SEED | 0xFFFF_FFFF | For Byte 6. |
0x81C | TG_BYTEEN_SEED | 0xFFFF_FFFF | For Byte 7. |
0x820 | TG_BYTEEN_SEED | 0xFFFF_FFFF | For Byte 8. |
Example 2: Configuring TG2 to Run with an Infinite Loop
- Clear all the failure status registers. Write to TG_CLEAR with data=0xF.
- Configure the TG2 with the access and data pattern you want.
- Write to TG_LOOP_COUNT with data=0x0.
- Write to TG_START with a 0 or 1 to start TG2.
- To stop the TG2 while running an infinite loop, write to TG_LOOP_COUNT with data=0x1.