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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. Intel 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
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
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 Intel® 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
4.1.1. Release Information for RAM and ROM Intel® FPGA IPs
4.1.2. RAM: 1-PORT Intel® FPGA IP Parameters
4.1.3. RAM: 2-PORT Intel® FPGA IP Parameters
4.1.4. RAM: 4-PORT Intel® FPGA IP Parameters
4.1.5. ROM: 1-PORT Intel® FPGA IP Parameters
4.1.6. ROM: 2-PORT Intel® FPGA IP Parameters
4.1.7. RAM and ROM Interface Signals
4.1.8. Changing Parameter Settings Manually
4.3.1. Release Information for FIFO Intel® 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 Intel® FPGA IP Parameters
4.3.17. Reset Scheme
4.4.1. Release Information for FIFO2 Intel® FPGA IP
4.4.2. Configuration Methods
4.4.3. Fmax Target Measuring Methodology
4.4.4. Performance Considerations
4.4.5. FIFO2 Intel® FPGA IP Features
4.4.6. FIFO2 Intel® FPGA IP Parameters
4.4.7. FIFO2 Intel® FPGA IP Interface Signals
4.4.8. Reset and Clock Schemes
4.5.1. Release Information for Shift Register (RAM-based) Intel® FPGA IP
4.5.2. Shift Register (RAM-based) Intel® FPGA IP Features
4.5.3. Shift Register (RAM-based) Intel® FPGA IP General Description
4.5.4. Shift Register (RAM-based) Intel® FPGA IP Parameter Settings
4.5.5. Shift Register Ports and Parameters Setting
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4.3.8. FIFO Synchronous Clear and Asynchronous Clear Effect
The FIFO Intel® FPGA IP core supports the synchronous clear (sclr) and asynchronous clear (aclr) signals, depending on the FIFO modes.
The effects of these signals are varied for different FIFO configurations. The SCFIFO supports both synchronous and asynchronous clear signals while the DCFIFO support asynchronous clear signal and asynchronous clear signal that synchronized with the write and read clocks.
Note: You must assert either aclr or sclr upon power-up to guarantee correct functionality.
Mode | Synchronous Clear (sclr) 31 | Asynchronous Clear (aclr) |
---|---|---|
Effects on status ports | Deasserts the full and almost_full signals. | |
Asserts the empty and almost_empty signals. | ||
Resets the usedw flag. | ||
Commencement of effects upon assertion | At the rising edge of the clock. | Immediate (except for the q output) |
Effects on the q output for normal output modes | The read pointer is reset and points to the first data location. If the q output is not registered, the output shows the first data word of the SCFIFO; otherwise, the q output remains at its previous value. | The q output remains at its previous value. |
Effects on the q output for show-ahead output modes | The read pointer is reset and points to the first data location. If the q output is not registered, the output remains at its previous value for only one clock cycle and shows the first data word of the SCFIFO at the next rising clock edge. 32 Otherwise, the q output remains at its previous value. |
If the q output is not registered, the output shows the first data word of the SCFIFO starting at the first rising clock edge. Otherwise, the q output remains its previous value. |
Mode | Asynchronous Clear (aclr) | aclr (synchronize with write clock) 33 34 | aclr (synchronize with read clock) 35 36 |
---|---|---|---|
Effects on status ports | Deasserts the wrfull signal. | The wrfull signal is asserted while the write domain is clearing which nominally takes three cycles of the write clock after the asynchronous release of the aclr input. | The rdempty signal is asserted while the read domain is clearing which nominally takes three cycles of the read clock after the asynchronous release of the aclr input. |
Deasserts the rdfull signal. | |||
Asserts the wrempty and rdempty signals. | |||
Resets the wrusedw and rdusedw flags. | |||
Commencement of effects upon assertion | Immediate. | ||
Effects on the q output for normal output modes 37 | The output remains unchanged if it is not registered. If the port is registered, it is cleared. | ||
Effects on the q output for show-ahead output modes | The output shows 'X' if it is not registered. If the port is registered, it is cleared. |
31 The read and write pointers reset to zero upon assertion of either the sclr or aclr signal.
32 The first data word shown after the reset is not a valid Show-ahead data. It reflects the data where the read pointer is pointing to because the q output is not registered. To obtain a valid Show-ahead data, perform a valid write after the reset.
33 The wrreq signal must be low when the DCFIFO comes out of reset (the instant when the aclr signal is deasserted) at the rising edge of the write clock to avoid a race condition between write and reset. If this condition cannot be guaranteed in your design, the aclr signal needs to be synchronized with the write clock. This can be done by setting the Add circuit to synchronize 'aclr' input with 'wrclk' option from the FIFO parameter editor, or setting the WRITE_ACLR_SYNCH parameter to ON.
34 Even though the aclr signal is synchronized with the write clock, asserting the aclr signal still affects all the status flags asynchronously.
35 A race condition between the aclr signal and the rising edge of the read clock must be avoided. If this condition cannot be guaranteed in your design, the aclr signal needs to be synchronized with the read clock. This can be done by setting the Add circuit to synchronize 'aclr' input with 'rdclk' option from the FIFO parameter editor, or setting the READ_ACLR_SYNCH parameter to ON.
36 Even though the aclr signal is synchronized with the read clock, asserting the aclr signal affects all the status flags asynchronously.
37 The DCFIFO only supports registered q output in Normal mode, and unregistered q output in Show-ahead mode.