Stratix® 10 Embedded Memory User Guide

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ID 683423
Date 7/24/2025
Public
Document Table of Contents
Document Table of Contents x
1. Stratix® 10 Embedded Memory Overview 2. Stratix® 10 Embedded Memory Architecture and Features 3. Stratix® 10 Embedded Memory Design Considerations 4. Stratix® 10 Embedded Memory IP References 5. Stratix 10 Embedded Memory Design Example 6. Stratix® 10 Embedded Memory User Guide Archives 7. Document Revision History for the Stratix® 10 Embedded Memory User Guide
1. Stratix® 10 Embedded Memory Overview x
1.1. Stratix® 10 Embedded Memory Features
2. Stratix® 10 Embedded Memory Architecture and Features x
2.1. Byte Enable in Stratix® 10 Embedded Memory Blocks 2.2. Address Clock Enable Support 2.3. Asynchronous Clear and Synchronous Clear 2.4. Memory Blocks Error Correction Code (ECC) Support 2.5. Force-to-Zero 2.6. Coherent Read Memory 2.7. Freeze Logic 2.8. True Dual Port Dual Clock Emulator 2.9. 'X' Propagation Support in Simulation 2.10. Stratix® 10 Supported Embedded Memory IPs 2.11. Stratix® 10 Embedded Memory Clocking Modes 2.12. Stratix® 10 Embedded Memory Configurations 2.13. Initial Value of Read and Write Address Registers
2.1. Byte Enable in Stratix® 10 Embedded Memory Blocks x
2.1.1. Byte Enable Controls 2.1.2. Data Byte Output 2.1.3. Byte Enable Behavior
2.4. Memory Blocks Error Correction Code (ECC) Support x
2.4.1. Parity Bit 2.4.2. ECC Parity Flip 2.4.3. ECC Read-During-Write Behavior 2.4.4. Error Correction Code Truth Table
2.6. Coherent Read Memory x
2.6.1. Forwarding Logic
2.8. True Dual Port Dual Clock Emulator x
2.8.1. Reducing the DCFIFO Depth 2.8.2. True Dual-Port Mixed Port Read During Write New Data Emulation
2.11. Stratix® 10 Embedded Memory Clocking Modes x
2.11.1. Single Clock Mode 2.11.2. Read/Write Clock Mode 2.11.3. Input/Output Clock Mode 2.11.4. Asynchronous/Synchronous Clears in Clocking Modes 2.11.5. Output Read Data in Simultaneous Read/Write 2.11.6. Independent Clock Enables in Clocking Modes
2.12. Stratix® 10 Embedded Memory Configurations x
2.12.1. Mixed-Width Port Configurations
3. Stratix® 10 Embedded Memory Design Considerations x
3.1. Consider the Memory Block Selection 3.2. Consider the Concurrent Read Behavior 3.3. Read-During-Write (RDW) 3.4. Consider Power-Up State and Memory Initialization 3.5. Reduce Power Consumption 3.6. Avoid Providing Non-Deterministic Input 3.7. Avoid Changing Clock Signals and Other Control Signals Simultaneously 3.8. Including the Reset Release FPGA IP in Your Design 3.9. Resource and Timing Optimization Feature in MLAB Blocks 3.10. Consider the Memory Depth Setting 3.11. Consider Registering the Memory Output
3.3. Read-During-Write (RDW) x
3.3.1. Customize Read-During-Write Behavior
3.3.1. Customize Read-During-Write Behavior x
3.3.1.1. Same-Port Read-During-Write Mode 3.3.1.2. Mixed-Port Read-During-Write Mode
4. Stratix® 10 Embedded Memory IP References x
4.1. On Chip Memory RAM and ROM FPGA IPs 4.2. eSRAM FPGA IP 4.3. FIFO IP 4.4. FIFO2 IP 4.5. Shift Register (RAM-based) FPGA IP
4.1. On Chip Memory RAM and ROM FPGA IPs x
4.1.1. Release Information for RAM and ROM IPs 4.1.2. RAM: 1-PORT FPGA IP Parameters 4.1.3. RAM: 2-PORT FPGA IP Parameters 4.1.4. RAM: 4-PORT FPGA IP Parameters 4.1.5. ROM: 1-PORT FPGA IP Parameters 4.1.6. ROM: 2-PORT FPGA IP Parameters 4.1.7. RAM and ROM Interface Signals 4.1.8. Changing Parameter Settings Manually
4.1.8. Changing Parameter Settings Manually x
4.1.8.1. RAM and ROM Parameter Settings
4.2. eSRAM FPGA IP x
4.2.1. Release Information for eSRAM FPGA IP 4.2.2. eSRAM System Features 4.2.3. eSRAM FPGA IP Parameters 4.2.4. eSRAM FPGA IP Interface Signals 4.2.5. eSRAM FPGA IP Simulation Walk-Through 4.2.6. eSRAM Timing Diagrams
4.2.2. eSRAM System Features x
4.2.2.1. eSRAM Specifications 4.2.2.2. eSRAM Usage Model
4.3. FIFO IP x
4.3.1. Release Information for FIFO FPGA IP 4.3.2. Configuration Methods 4.3.3. Specifications 4.3.4. FIFO Functional Timing Requirements 4.3.5. SCFIFO ALMOST_EMPTY Functional Timing 4.3.6. FIFO Output Status Flag and Latency 4.3.7. FIFO Metastability Protection and Related Options 4.3.8. FIFO Synchronous Clear and Asynchronous Clear Effect 4.3.9. SCFIFO and DCFIFO Show-Ahead Mode 4.3.10. Different Input and Output Width 4.3.11. DCFIFO Timing Constraint Setting 4.3.12. Coding Example for Manual Instantiation 4.3.13. Design Example 4.3.14. Gray-Code Counter Transfer at the Clock Domain Crossing 4.3.15. Guidelines for Embedded Memory ECC Feature 4.3.16. FIFO IP Parameters 4.3.17. Reset Scheme
4.3.3. Specifications x
4.3.3.1. Verilog HDL Prototype 4.3.3.2. VHDL Component Declaration 4.3.3.3. VHDL LIBRARY-USE Declaration 4.3.3.4. FIFO Signals 4.3.3.5. FIFO Parameter Settings
4.3.8. FIFO Synchronous Clear and Asynchronous Clear Effect x
4.3.8.1. Recovery and Removal Timing Violation Warnings when Compiling a DCFIFO
4.3.11. DCFIFO Timing Constraint Setting x
4.3.11.1. Embedded Timing Constraint 4.3.11.2. User Configurable Timing Constraint
4.3.11.2. User Configurable Timing Constraint x
4.3.11.2.1. SDC Commands
4.4. FIFO2 IP x
4.4.1. Release Information for FIFO2 IP 4.4.2. Configuration Methods 4.4.3. Fmax Target Measuring Methodology 4.4.4. Performance Considerations 4.4.5. FIFO2 IP Features 4.4.6. FIFO2 IP Parameters 4.4.7. FIFO2 IP Interface Signals 4.4.8. Reset and Clock Schemes
4.4.5. FIFO2 IP Features x
4.4.5.1. FIFO2 Specifications
4.4.6. FIFO2 IP Parameters x
4.4.6.1. FIFO2 Parameter Settings
4.4.7. FIFO2 IP Interface Signals x
4.4.7.1. SCFIFO Signals 4.4.7.2. DCFIFO Signals
4.4.8. Reset and Clock Schemes x
4.4.8.1. Clock Domains 4.4.8.2. Reset
4.4.8.2. Reset x
4.4.8.2.1. FIFO2 IP Reset Guidelines
4.5. Shift Register (RAM-based) FPGA IP x
4.5.1. Release Information for Shift Register (RAM-based) FPGA IP 4.5.2. Shift Register (RAM-based) FPGA IP Features 4.5.3. Shift Register (RAM-based) FPGA IP General Description 4.5.4. Shift Register (RAM-based) FPGA IP Parameter Settings 4.5.5. Shift Register Ports and Parameters Setting
5. Stratix 10 Embedded Memory Design Example x
5.1. FIFO and FIFO2 Design Example
5.1. FIFO and FIFO2 Design Example x
5.1.1. Generating the Design Example 5.1.2. Simulating the Design Example
5.1.2. Simulating the Design Example x
5.1.2.1. Simulation Results
1. Stratix® 10 Embedded Memory Overview
2. Stratix® 10 Embedded Memory Architecture and Features
3. Stratix® 10 Embedded Memory Design Considerations
4. Stratix® 10 Embedded Memory IP References
5. Stratix 10 Embedded Memory Design Example
6. Stratix® 10 Embedded Memory User Guide Archives
7. Document Revision History for the Stratix® 10 Embedded Memory User Guide

4.1.2. RAM: 1-PORT Intel® FPGA IP Parameters

This table lists the parameters for the RAM: 1-PORT Intel® FPGA IP.
Table 23.  RAM: 1-PORT Intel® FPGA IP Parameters Description
Parameter Legal Values Description
Parameter Settings: Widths/Blk Type/Clks
How wide should the ‘q’ output bus be? Specifies the width of the ‘q’ output bus.
How many words of memory? Specifies the number of bit words.
What should the memory block type be?
  • Auto
  • MLAB
  • M20K
  • LCs
Specifies the memory block type. The types of memory block that are available for selection depends on your target device.
Set the maximum block depth to
  • Auto: Auto, 32, 64, 128, 256, 512, 1024, 2048, or 4096
  • MLAB: Auto or 32
  • M20K: Auto, 512, 1024, or 2048
  • LCs: Auto
Specifies the maximum block depth in words.
How should the memory be implemented?
  • Use default logic cell style
Specifies the logic cell implementation method.
  • Select Use default logic cell style if you prefer smaller and faster memory capacity.
Which clocking method would you like to use?
  • Single clock
  • Dual clock: use separate ‘input’ and ‘output’ clocks
Specifies the clocking method to use.
  • Single clock—A single clock and a clock enable controls all registers of the memory block.
  • Dual clock: use separate ‘input’ and ‘output’ clocks—An input clock controls all registers related to the data input to the embedded memory block including data, address, byte enables, read enables, and write enables. An output clock controls the data output registers.
Parameter Settings: Regs/Clken/Byte Enable/Aclrs
Which ports should be registered?
The following options are available:
  • ‘data’ and ‘wren’ input ports
  • ‘address’ input port
  • ‘q’ output port
 On/Off Specifies whether to register the input and output ports.
Create one clock enable signal for each clock signal.
Note: All registered ports are controlled by the enable signal(s).
On/Off Specifies whether to turn on the option to create one clock enable signal for each clock signal.
More Options Use clock enable for port A input registers On/Off Specifies whether to use clock enable for port A input registers.
Use clock enable for port A output registers On/Off Specifies whether to use clock enable for port A output registers.
Create an ‘addressstall_a’ input port. On/Off Specifies whether to create an addressstall_a input port. You can create this port to act as an extra active low clock enable input for the address registers.
Create byte enable for port A On/Off Specifies whether to create a byte enable for port A. Turn on this option if you want to mask the input data so that only specific bytes, nibbles, or bits of data are written.

To enable byte enable for port A and port B, the data width ratio has to be 1 or 2 for the RAM: 1-PORT and RAM: 2-PORT Intel® FPGA IPs.

What is the width of a byte for byte enables?
  • MLAB: 5 , 8, 9, or 10
  • Other memory block types: 8 or 9
  • M20K: 8, 9, or 10
Specifies the byte width of the byte enable port. The width of the data input port must be divisible by the byte size.
Create an ‘aclr’ asynchronous clear for the registered ports.

‘q’ port

 On/Off Specifies whether the registered ports are affected by an asynchronous clear port.
Create an ‘sclr’ synchronous clear for the registered ports.

‘q’ port

On/Off Specifies whether the registered ports are affected by a synchronous clear port.
Create a ‘rden’ read enable signal On/Off Turn on if you want to create a read enable signal.
Parameter Settings: Read During Write Option
What should the ‘q’ output be when reading from a memory location being written to?
  • Don’t Care
  • Old Data
Specifies the output behavior when read-during-write occurs.

Don’t Care—The RAM outputs “don't care” or “unknown” values for read-during-write operation.

Old Data—The RAM outputs reflect the old data at that address before the write operation proceeds.

Get x’s for write masked bytes instead of old data when byte enable is used On/Off Turn on this option to obtain ‘X’ on the masked byte.
Parameter Settings: Mem Init
Do you want to specify the initial content of the memory?
  • No, leave it blank
  • Yes, use this file for the memory content data
Specifies the initial content of the memory.

To initialize the memory to zero, select No, leave it blank.

To use a memory initialization file (.mif) or a hexadecimal (Altera-format) file (.hex), select Yes, use this file for the memory content data.

Initialize memory content data to XX..X on power-up in simulation On/Off
Implement clock-enable circuitry for use in a partial reconfiguration region On/Off Specifies whether to implement clock-enable circuitry for use in a partial reconfiguration region.
Allow In-System Memory Content Editor to capture and update content independently of the system clock On/Off Specifies whether to allow In-System Memory Content Editor to capture and update content independently of the system clock.
The ‘Instance ID’ of this RAM is NONE Specifies the RAM ID.
Parameter Settings: Performance Optimization
Enable Force To Zero On/Off Specifies whether to set the output to zero when you deassert the read enable signal.

Enabling this feature helps improve the glue logic performance when the selected memory depth is larger than a single memory block.

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