2020-05-21 06:37:51 +02:00
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# LPDDR4x SPD tools README
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Tools for generating SPD files for LPDDR4x memory used in memory down
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configurations on Intel Tiger Lake (TGL) and Jasper Lake (JSL) based
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platforms. These tools generate SPDs following JESD209-4C
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specification and Intel recommendations (doc #616599, #610202) for
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LPDDR4x SPD.
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There are two tools provided that assist TGL and JSL based mainboards
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to generate SPDs and Makefile to integrate these SPDs in coreboot
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build. These tools can also be used to allocate DRAM IDs (configure
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DRAM hardware straps) for any LPDDR4x memory part used by the board.
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* gen_spd.go: Generates de-duplicated SPD files using a global memory
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part list provided by the mainboard in JSON format. Additionally,
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generates a SPD manifest file(in CSV format) with information about
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what memory part from the global list uses which of the generated
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SPD files.
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* gen_part_id.go: Allocates DRAM strap IDs for different LPDDR4x
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memory parts used by the board. Takes as input list of memory parts
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used by the board (with one memory part on each line) and the SPD
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manifest file generated by gen_spd.go. Generates Makefile.inc for
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integrating the generated SPD files in the coreboot build.
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## Tool 1 - gen_spd.go
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This program takes as input:
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* Pointer to directory where the generated SPD files and manifest will
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be placed.
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* JSON file containing a global list of memory parts with their
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attributes as per the datasheet. This is the list of all known
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LPDDR4x memory parts irrespective of their usage on the board.
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* SoC platform name for which the SPDs are being generated. Currently
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supported platform names are `TGL` and `JSL`.
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Input JSON file requires the following two fields for every memory part:
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* `name`: Name of the memory part
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* `attribs`: List of attributes of the memory part as per its
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datasheet. These attributes match the part specifications and are
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independent of any SoC expectations. Tool takes care of translating
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the physical attributes of the memory part to match JEDEC and Intel
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MRC expectations.
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`attribs` field further contains two types of sub-fields:
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* Mandatory: These attributes have to be provided for a memory part.
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* Optional: These attributes can be provided by memory part if it wants
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to override the defaults.
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### Mandatory `attribs`
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* `densityPerChannelGb`: Density in Gb of the physical channel.
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* `banks`: Number of banks per physical channel. This is typically 8
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for LPDDR4x memory parts.
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* `channelsPerDie`: Number of physical channels per die. Valid values:
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`1, 2, 4`. For a part with x16 bit width, number of channels per die
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is 1 or 2. For a part with x8 bit width, number of channels can be
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2 or 4 (4 is basically when two dual-channel byte mode devices are
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combined as shown in Figure 3 in JESD209-4C).
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* `diesPerPackage`: Number of physical dies in each SDRAM
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package. As per JESD209-4C, "Standard LPDDR4 package ballmaps
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allocate one ZQ ball per die." Thus, number of diesPerPackage is the
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number of ZQ balls on the package.
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* `bitWidthPerChannel`: Width of each physical channel. Valid values:
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`8, 16` bits.
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* `ranksPerChannel`: Number of ranks per physical channel. Valid
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values: `1, 2`. If the channels across multiple dies share the same
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DQ/DQS pins but use a separate CS, then ranks is 2 else it is 1.
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* `speedMbps`: Maximum data rate supported by the part in Mbps. Valid
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values: `3200, 3733, 4267` Mbps.
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### Optional `attribs`
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* `trfcabNs`: Minimum Refresh Recovery Delay Time (tRFCab) for all
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banks in nanoseconds. As per JESD209-4C, this is dependent on the
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density per channel. Default values used:
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* 6Gb : 280ns
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* 8Gb : 280ns
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* 12Gb: 380ns
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* 16Gb: 380ns
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* `trfcpbNs`: Minimum Refresh Recovery Delay Time (tRFCab) per
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bank in nanoseconds. As per JESD209-4C, this is dependent on the
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density per channel. Default values used:
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* 6Gb : 140ns
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* 8Gb : 140ns
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* 12Gb: 190ns
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* 16Gb: 190ns
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* `trpabMinNs`: Minimum Row Precharge Delay Time (tRPab) for all banks
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in nanoseconds. As per JESD209-4C, this is max(21ns, 4nck) which
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defaults to `21ns`.
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* `trppbMinNs`: Minimum Row Precharge Delay Time (tRPpb) per bank in
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nanoseconds. As per JESD209-4C, this is max(18ns, 4nck) which
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defaults to `18ns`.
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* `tckMinPs`: SDRAM minimum cycle time (tckMin) value in
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picoseconds. This is typically calculated based on the `speedMbps`
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attribute. `(1 / speedMbps) * 2`. Default values used(taken from
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JESD209-4C):
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* 4267 Mbps: 468ps
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* 3733 Mbps: 535ps
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* 3200 Mbps: 625ps
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* `tckMaxPs`: SDRAM maximum cycle time (tckMax) value in
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picoseconds. Default value used: `31875ps`. As per JESD209-4C,
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TCKmax should be 100ns (100000ps) for all speed grades. But the SPD
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byte to encode this field is only 1 byte. Hence, the maximum value
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that can be encoded is 31875ps.
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* `taaMinPs`: Minimum CAS Latency Time(taaMin) in picoseconds. This
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value defaults to nck * tckMin, where nck is minimum CAS latency.
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* `trcdMinNs`: Minimum RAS# to CAS# Delay Time (tRCDmin) in
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nanoseconds. As per JESD209-4C, this is max(18ns, 4nck) which
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defaults to `18ns`.
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* `casLatencies`: List of CAS latencies supported by the
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part. This is dependent on the attrib `speedMbps`. Default values
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used:
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* 4267: `"6 10 14 20 24 28 32 36"`.
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* 3733: `"6 10 14 20 24 28 32"`.
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* 3200: `"6 10 14 20 24 28"`.
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### Example JSON file
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```
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{
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"parts": [
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{
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"name": "MEMORY_PART_A",
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"attribs": {
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"densityPerChannelGb": 8,
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"banks": 8,
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"channelsPerDie": 2,
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"diesPerPackage": 2,
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"bitWidthPerChannel": 16,
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"ranksPerChannel": 1,
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"speedMbps": 4267
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}
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},
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{
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"name": "MEMORY_PART_B",
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"attribs": {
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"densityPerChannelGb": 8,
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"banks": 8,
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"channelsPerDie": 1,
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"diesPerPackage": 2,
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"bitWidthPerChannel": 16,
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"ranksPerChannel": 1,
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"speedMbps": 3733,
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"casLatencies": "14 20 24 28 32",
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"tckMaxPs": "1250"
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}
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}
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]
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}
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```
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### Output
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This tool generates the following files using the global list of
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memory parts in JSON format as described above:
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* De-duplicated SPDs required for the different memory parts. These
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2020-08-28 00:59:19 +02:00
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SPD files are named (spd_1.bin, spd_2.bin, spd_3.bin and so on)
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2020-05-21 06:37:51 +02:00
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and placed in the directory provided as an input to the tool.
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* CSV file representing which of the deduplicated SPD files is used
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by which memory part. This file is named as
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`spd_manifest.generated.txt` and placed in the directory provided
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as an input to the tool along with the generated SPD
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files. Example CSV file:
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```
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MEMORY_PART_A, spd_1.bin
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MEMORY_PART_B, spd_2.bin
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MEMORY_PART_C, spd_3.bin
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MEMORY_PART_D, spd_2.bin
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MEMORY_PART_E, spd_2.bin
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2020-05-21 06:37:51 +02:00
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```
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## Tool 2 - gen_part_id.go
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This program takes as input:
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* Pointer to directory where the SPD files and the manifest file
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`spd_manifest.generated.txt` (in CSV format) are placed by
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gen_spd.go
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* File containing list of memory parts used by the board. Each line of
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the file is supposed to contain one memory part `name` as present in
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the global list of memory parts provided to gen_spd.go
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* Pointer to directory where the generated Makefile.inc should be
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placed by the tool.
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### Output
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This program provides the following:
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* Prints out the list of DRAM hardware strap IDs that should be
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allocated to each memory part listed in the input file.
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* Makefile.inc is generated in the provided directory to integrate
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SPDs generated by gen_spd.go with the coreboot build for the board.
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* dram_id.generated.txt is generated in the same directory as
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Makefile. This contains the part IDs assigned to the different
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memory parts. (Useful to integrate in board schematics).
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Sample output (dram_id.generated.txt):
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```
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DRAM Part Name ID to assign
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MEMORY_PART_A 0 (0000)
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MEMORY_PART_B 1 (0001)
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MEMORY_PART_C 2 (0010)
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MEMORY_PART_D 1 (0001)
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```
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Sample Makefile.inc:
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```
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## SPDX-License-Identifier: GPL-2.0-or-later
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## This is an auto-generated file. Do not edit!!
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SPD_SOURCES =
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SPD_SOURCES += spd_1.bin # ID = 0(0b0000) Parts = MEMORY_PART_A
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SPD_SOURCES += spd_2.bin # ID = 1(0b0001) Parts = MEMORY_PART_B, MEMORY_PART_D
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SPD_SOURCES += spd_3.bin # ID = 2(0b0010) Parts = MEMORY_PART_C
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```
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### Note of caution
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This program assigns DRAM IDs using the order of DRAM part names
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provided in the input file. Thus, when adding a new memory part to the
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list, it should always go to the end of the input text file. This
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guarantees that the memory parts that were already assigned IDs do not
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change.
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## How to build the tools?
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```
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# go build gen_spd.go
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# go build gen_part_id.go
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```
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## How to use the tools?
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```
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# ./gen_spd <spd_dir> <mem_parts_list_json> <platform>
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# ./gen_part_id <spd_dir> <makefile_dir> <mem_parts_used_file>
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```
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### Need to add a new memory part for a board?
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* If the memory part is not present in the global list of memory
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parts, then add the memory part name and attributes as per the
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datasheet to the file containing the global list.
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* Use `gen_spd.go` with input as the file containing the global list
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of memory parts to generate de-duplicated SPDs.
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* If a new SPD file is generated, use `git add` to add it to the
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tree and push a CL for review.
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* Update the file containing memory parts used by board (variant) to
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add the new memory part name at the end of the file.
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* Use gen_part_id.go providing it pointer to the location where SPD
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files are stored and file containing the list of memory parts used
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by the board(variant).
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* Use `git add` to add `Makefile.inc` and `dram_id.generated.txt`
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with updated changes and push a CL for review.
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