mirror of https://github.com/YosysHQ/yosys.git
506 lines
19 KiB
Markdown
506 lines
19 KiB
Markdown
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# The `memory_libmap` pass
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The `memory_libmap` pass is used to map memories to hardware primitives. To work,
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it needs a description of available target memories in a custom format.
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## Basic structure
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A basic library could look like this:
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# A distributed-class RAM called $__RAM16X4SDP_
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ram distributed $__RAM16X4SDP_ {
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# Has 4 address bits (ie. 16 rows).
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abits 4;
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# Has 4 data bits.
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width 4;
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# Cost for the selection heuristic.
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cost 4;
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# Can be initialized to any value on startup.
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init any;
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# Has a synchronous write port called "W"...
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port sw "W" {
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# ... with a positive edge clock.
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clock posedge;
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}
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# Has an asynchronous read port called "R".
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port ar "R" {
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}
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}
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# A block-class RAM called $__RAMB9K_
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ram block $__RAMB9K_ {
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# Has 13 address bits in the base (most narrow) data width.
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abits 13;
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# The available widths are:
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# - 1 (13 address bits)
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# - 2 (12 address bits)
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# - 4 (11 address bits)
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# - 9 (10 address bits)
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# - 18 (9 address bits)
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# The width selection is per-port.
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widths 1 2 4 9 18 per_port;
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# Has a write enable signal with 1 bit for every 9 data bits.
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byte 9;
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cost 64;
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init any;
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# Has two synchronous read+write ports, called "A" and "B".
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port srsw "A" "B" {
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clock posedge;
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# Has a clock enable signal (gates both read and write).
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clken;
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# Has three per-port selectable options for handling read+write behavior:
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portoption "RDWR" "NO_CHANGE" {
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# When port is writing, reading is not done (output register keeps
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# its value).
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rdwr no_change;
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}
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portoption "RDWR" "OLD" {
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# When port is writing, the data read is the old value (before the
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# write).
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rdwr old;
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}
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portoption "RDWR" "NEW" {
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# When port is writing, the data read is the new value.
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rdwr new;
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}
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}
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}
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The pass will automatically select between the two available cells and
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the logic fallback (mapping the whole memory to LUTs+FFs) based on required
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capabilities and cost function. The selected memories will be transformed
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to intermediate `$__RAM16X4SDP_` and `$__RAMB9K_` cells that need to be mapped
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to actual hardware cells by a `techmap` pass, while memories selected for logic
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fallback will be left unmapped and will be later mopped up by `memory_map` pass.
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## RAM definition blocks
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The syntax for a RAM definition is:
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ram <kind: distributed|block|huge> <name> {
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<ram properties>
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<ports>
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}
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The `<name>` is used as the type of the mapped cell that will be passed to `techmap`.
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The memory kind is one of `distributed`, `block`, or `huge`. It describes the general
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class of the memory and can be matched on by manual selection attributes.
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The available ram properties are:
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- `abits <address bits>;`
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- `width <width>;`
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- `widths <width 1> <width 2> ... <width n> <global|per_port>;`
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- `byte <width>;`
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- `cost <cost>;`
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- `widthscale [<factor>];`
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- `resource <name> <count>;`
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- `init <none|zero|any|no_undef>;`
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- `style "<name 1>" "<name 2>" "<name 3>" ...;`
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- `prune_rom;`
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### RAM dimensions
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The memory dimensions are described by `abits` and `width` or `widths` properties.
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For a simple memory cell with a fixed width, use `abits` and `width` like this:
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abits 4;
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width 4;
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This will result in a `2**abits × width` memory cell.
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Multiple-width memories are also possible, and use the `widths` property instead.
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The rules for multiple-width memories are:
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- the widths are given in `widths` property in increasing order
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- the value in the `abits` property corresponds to the most narrow width
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- every width in the list needs to be greater than or equal to twice
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the previous width (ie. `1 2 4 9 18` is valid, `1 2 4 7 14` is not)
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- it is assumed that, for every width in progression, the word in memory
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is made of two smaller words, plus optionally some extra bits (eg. in the above
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list, the 9-bit word is made of two 4-bit words and 1 extra bit), and thus
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each sequential width in the list corresponds to one fewer usable address bit
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- all addresses connected to memory ports are always `abits` bits wide, with const
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zero wired to the unused bits corresponding to wide ports
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When multiple widths are specified, they can be `per_port` or `global`.
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For the `global` version, the pass has to pick one width for the whole cell,
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and it is set on the resulting cell as the `WIDTH` parameter. For the `per_port`
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version, the selection is made on per-port basis, and passed using `PORT_*_WIDTH`
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parameters. When the mode is `per_port`, the width selection can be fine-tuned
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with the port `width` property.
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Specifying dimensions is mandatory.
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### Byte width
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If the memory cell has per-byte write enables, the `byte` property can be used
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to define the byte size (ie. how many data bits correspond to one write enable
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bit).
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The property is optional. If not used, it is assumed that there is a single
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write enable signal for each writable port.
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The rules for this property are as follows:
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- for every available width, the width needs to be a multiple of the byte size,
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or the byte size needs to be larger than the width
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- if the byte size is larger than the width, the byte enable signel is assumed
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to be one bit wide and cover the whole port
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- otherwise, the byte enable signal has one bit for every `byte` bits of the
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data port
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The exact kind of byte enable signal is determined by the presence or absence
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of the per-port `wrbe_separate` property.
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### Cost properties
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The `cost` property is used to estimate the cost of using a given mapping.
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This is the cost of using one cell, and will be scaled as appropriate if
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the mapping requires multiple cells.
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If the `widthscale` property is specified, the mapping is assumed to be flexible,
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with cost scaling with the percentage of data width actually used. The value
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of the `widthscale` property is how much of the cost is scalable as such.
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If the value is omitted, all of the cost is assumed to scale.
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Eg. for the following properties:
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width 14;
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cost 8;
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widthscale 7;
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The cost of a given cell will be assumed to be `(8 - 7) + 7 * (used_bits / 14)`.
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If `widthscale` is used, The pass will attach a `BITS_USED` parameter to mapped
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calls, with a bitmask of which data bits of the memory are actually in use.
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The parameter width will be the widest width in the `widths` property, and
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the bit correspondence is defined accordingly.
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The `cost` property is mandatory.
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### `init` property
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This property describes the state of the memory at initialization time. Can have
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one of the following values:
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- `none`: the memory contents are unpredictable, memories requiring any sort
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of initialization will not be mapped to this cell
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- `zero`: the memory contents are zero, memories can be mapped to this cell iff
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their initialization value is entirely zero or undef
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- `any`: the memory contents can be arbitrarily selected, and the initialization
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will be passes as the `INIT` parameter to the mapped cell
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- `no_undef`: like `any`, but only 0 and 1 bit values are supported (the pass will
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convert any x bits to 0)
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The `INIT` parameter is always constructed as a concatenation of words corresponding
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to the widest available `widths` setting, so that all available memory cell bits
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are covered.
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This property is optional and assumed to be `none` when not present.
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### `style` property
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Provides a name (or names) for this definition that can be passed to the `ram_style`
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or similar attribute to manually select it. Optional and can be used multiple times.
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### `prune_rom` property
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Specifying this property disqualifies the definition from consideration for source
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memories that have no write ports (ie. ROMs). Use this on definitions that have
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an obviously superior read-only alternative (eg. LUTRAMs) to make the pass skip
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them over quickly.
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## Port definition blocks
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The syntax for a port group definition is:
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port <ar|sr|sw|arsw|srsw> "NAME 1" "NAME 2" ... {
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<port properties>
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}
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A port group definition defines a group of ports with identical properties.
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There are as many ports in a group as there are names given.
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Ports come in 5 kinds:
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- `ar`: asynchronous read port
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- `sr`: synchronous read port
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- `sw`: synchronous write port
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- `arsw`: simultanous synchronous write + asynchronous read with common address (commonly found in LUT RAMs)
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- `srsw`: synchronous write + synchronous read with common address
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The port properties available are:
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- `width <tied|mix>;`
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- `width <width 1> <width 2> ...;`
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- `width <tied|mix> <width 1> <width 2> ...;`
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- `width rd <width 1> <width 2> ... wr <width 1> <width 2> ...;`
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- `clock <posedge|negedge|anyedge> ["SHARED_NAME"];`
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- `clken;`
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- `rden;`
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- `wrbe_separate;`
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- `rdwr <undefined|no_change|new|old|new_only>;`
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- `rdinit <none|zero|any|no_undef>;`
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- `rdarst <none|zero|any|no_undef|init>;`
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- `rdsrst <none|zero|any|no_undef|init> <ungated|gatec_clken|gated_rden> [block_wr];`
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- `wrprio "NAME" "NAME" ...;`
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- `wrtrans <"NAME"|all> <old|new>;`
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- `optional;`
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- `optional_rw;`
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The base signals connected to the mapped cell for ports are:
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- `PORT_<name>_ADDR`: the address
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- `PORT_<name>_WR_DATA`: the write data (for `sw`/`arsw`/`srsw` ports only)
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- `PORT_<name>_RD_DATA`: the read data (for `ar`/`sr`/`arsw`/`srsw` ports only)
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- `PORT_<name>_WR_EN`: the write enable or enables (for `sw`/`arsw`/`srsw` ports only)
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The address is always `abits` wide. If a non-narrowest width is used, the appropriate low
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bits will be tied to 0.
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### Port `width` prooperty
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If the RAM has `per_port` widths, the available width selection can be further described
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on per-port basis, by using one of the following properties:
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- `width tied;`: any width from the master `widths` list is acceptable, and
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(for read+write ports) the read and write width has to be the same
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- `width tied <width 1> <width 2> ...;`: like above, but limits the width
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selection to the given list; the list has to be a contiguous sublist of the
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master `widths` list
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- `width <width 1> <width 2> ...;`: alias for the above, to be used for read-only
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or write-only ports
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- `width mix;`: any width from the master `widths` list is acceptable, and
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read width can be different than write width (only usable for read+write ports)
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- `width mix <width 1> <width 2> ...;`: like above, but limits the width
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selection to the given list; the list has to be a contiguous sublist of the
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master `widths` list
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- `width rd <width 1> <width 2> ... wr <width 1> <width 2> ...;`: like above,
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but the limitted selection can be different for read and write widths
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If `per_port` widths are in use and this property is not specified, `width tied;` is assumed.
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The parameters attached to the cell in `per_port` widths mode are:
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- `PORT_<name>_WIDTH`: the selected width (for `tied` ports)
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- `PORT_<name>_RD_WIDTH`: the selected read width (for `mix` ports)
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- `PORT_<name>_WR_WIDTH`: the selected write width (for `mix` ports)
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### `clock` property
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The `clock` property is used with synchronous ports (and synchronous ports only).
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It is mandatory for them and describes the clock polarity and clock sharing.
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`anyedge` means that both polarities are supported.
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If a shared clock name is provided, the port is assumed to have a shared clock signal
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with all other ports using the same shared name. Otherwise, the port is assumed to
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have its own clock signal.
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The port clock is always provided on the memory cell as `PORT_<name>_CLK` signal
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(even if it is also shared). Shared clocks are also provided as `CLK_<shared_name>`
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signals.
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For `anyedge` clocks, the cell gets a `PORT_<name>_CLKPOL` parameter that is set
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to 1 for `posedge` clocks and 0 for `negedge` clocks. If the clock is shared,
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the same information will also be provided as `CLK_<shared_name>_POL` parameter.
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### `clken` and `rden`
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The `clken` property, if present, means that the port has a clock enable signal
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gating both reads and writes. Such signal will be provided to the mapped cell
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as `PORT_<name>_CLK_EN`. It is only applicable to synchronous ports.
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The `rden` property, if present, means that the port has a read clock enable signal.
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Such signal will be provided to the mapped cell as `PORT_<name>_RD_EN`. It is only
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applicable to synchronous read ports (`sr` and `srsw`).
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For `sr` ports, both of these options are effectively equivalent.
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### `wrbe_separate` and the write enables
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The `wrbe_separate` property specifies that the write byte enables are provided
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as a separate signal from the main write enable. It can only be used when the
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RAM-level `byte` property is also specified.
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The rules are as follows:
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If no `byte` is specified:
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- `wrbe_separate` is not allowed
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- `PORT_<name>_WR_EN` signal is single bit
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If `byte` is specified, but `wrbe_separate` is not:
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- `PORT_<name>_WR_EN` signal has one bit for every data byte
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- `PORT_<name>_WR_EN_WIDTH` parameter is the width of the above (only present for multiple-width cells)
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If `byte` is specified and `wrbe_separate` is present:
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- `PORT_<name>_WR_EN` signal is single bit
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- `PORT_<name>_WR_BE` signal has one bit for every data byte
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- `PORT_<name>_WR_BE_WIDTH` parameter is the width of the above (only present for multiple-width cells)
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- a given byte is written iff all of `CLK_EN` (if present), `WR_EN`, and the corresponding `WR_BE` bit are one
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This property can only be used on write ports.
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### `rdwr` property
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This property is allowed only on `srsw` ports and describes read-write interactions.
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The possible values are:
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- `no_change`: if write is being performed (any bit of `WR_EN` is set),
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reading is not performed and the `RD_DATA` keeps its old value
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- `undefined`: all `RD_DATA` bits corresponding to enabled `WR_DATA` bits
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have undefined value, remaining bits read from memory
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- `old`: all `RD_DATA` bits get the previous value in memory
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- `new`: all `RD_DATA` bits get the new value in memory (transparent write)
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- `new_only`: all `RD_DATA` bits corresponding to enabled `WR_DATA` bits
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get the new value, all others are undefined
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If this property is not found on an `srsw` port, `undefined` is assumed.
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### Read data initial value and resets
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The `rdinit`, `rdarst`, and `rdsrst` are applicable only to synchronous read
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ports.
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`rdinit` describes the initial value of the read port data, and can be set to
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one of the following:
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- `none`: initial data is indeterminate
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- `zero`: initial data is all-0
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- `any`: initial data is arbitrarily configurable, and the selected value
|
|||
|
will be attached to the cell as `PORT_<name>_RD_INIT_VALUE` parameter
|
|||
|
- `no_undef`: like `any`, but only 0 and 1 bits are allowed
|
|||
|
|
|||
|
`rdarst` and `rdsrst` describe the asynchronous and synchronous reset capabilities.
|
|||
|
The values are similar to `rdinit`:
|
|||
|
|
|||
|
- `none`: no reset
|
|||
|
- `zero`: reset to all-0 data
|
|||
|
- `any`: reset to arbitrary value, the selected value
|
|||
|
will be attached to the cell as `PORT_<name>_RD_ARST_VALUE` or
|
|||
|
`PORT_<name>_RD_SRST_VALUE` parameter
|
|||
|
- `no_undef`: like `any`, but only 0 and 1 bits are allowed
|
|||
|
- `init`: reset to the initial value, as specified by `rdinit` (which must be `any`
|
|||
|
or `no_undef` itself)
|
|||
|
|
|||
|
If the capability is anything other than `none`, the reset signal
|
|||
|
will be provided as `PORT_<name>_RD_ARST` or `PORT_<name>_RD_SRST`.
|
|||
|
|
|||
|
For `rdsrst`, the priority must be additionally specified, as one of:
|
|||
|
|
|||
|
- `ungated`: `RD_SRST` has priority over both `CLK_EN` and `RD_EN` (if present)
|
|||
|
- `gated_clken`: `CLK_EN` has priority over `RD_SRST`; `RD_SRST` has priority over `RD_EN` if present
|
|||
|
- `gated_rden`: `RD_EN` and `CLK_EN` (if present) both have priority over `RD_SRST`
|
|||
|
|
|||
|
Also, `rdsrst` can optionally have `block_wr` specified, which means that sync reset
|
|||
|
cannot be performed in the same cycle as a write.
|
|||
|
|
|||
|
If not provided, `none` is assumed for all three properties.
|
|||
|
|
|||
|
|
|||
|
### Write priority
|
|||
|
|
|||
|
The `wrprio` property is only allowed on write ports and defines a priority relationship
|
|||
|
between port — when `wrprio "B";` is used in definition of port `"A"`, and both ports
|
|||
|
simultanously write to the same memory cell, the value written by port `"A"` will have
|
|||
|
precedence.
|
|||
|
|
|||
|
This property is optional, and can be used multiple times as necessary. If no relationship
|
|||
|
is described for a pair of write ports, no priority will be assumed.
|
|||
|
|
|||
|
|
|||
|
### Write transparency
|
|||
|
|
|||
|
The `wrtrans` property is only allowed on write ports and defines behavior when
|
|||
|
another synchronous read port reads from the memory cell at the same time as the
|
|||
|
given port writes it. The values are:
|
|||
|
|
|||
|
- `old`: the read port will get the old value of the cell
|
|||
|
- `new`: the read port will get the new value of the cell
|
|||
|
|
|||
|
This property is optional, and can be used multiple times as necessary. If no relationship
|
|||
|
is described for a pair of ports, the value read is assumed to be indeterminate.
|
|||
|
|
|||
|
Note that this property is not used to describe the read value on the port itself for `srsw`
|
|||
|
ports — for that purpose, the `rdwr` property is used instead.
|
|||
|
|
|||
|
|
|||
|
### Optional ports
|
|||
|
|
|||
|
The `optional;` property will make the pass attach a `PORT_<name>_USED` parameter
|
|||
|
with a boolean value specifying whether a given port was meaningfully used in
|
|||
|
mapping a given cell. Likewise, `optional_rw;` will attach `PORT_<name>_RD_USED`
|
|||
|
and `PORT_<name>_WR_USED` the specify whether the read / write part in particular
|
|||
|
was used. These can be useful if the mapping has some meaningful optimization
|
|||
|
to apply for unused ports, but doesn't otherwise influence the selection process.
|
|||
|
|
|||
|
|
|||
|
## Options
|
|||
|
|
|||
|
For highly configurable cells, multiple variants may be described in one cell description.
|
|||
|
All properties and port definitions within a RAM or port definition can be put inside
|
|||
|
an `option` block as follows:
|
|||
|
|
|||
|
option "NAME" <value> {
|
|||
|
<properties, ports, ...>
|
|||
|
}
|
|||
|
|
|||
|
The value and name of an option are arbitrary, and the selected option value
|
|||
|
will be provided to the cell as `OPTION_<name>` parameter. Values can be
|
|||
|
strings or integers.
|
|||
|
|
|||
|
|
|||
|
Likewise, for per-port options, a `portoption` block can be used:
|
|||
|
|
|||
|
portoption "NAME" <value> {
|
|||
|
<properties, ...>
|
|||
|
}
|
|||
|
|
|||
|
These options will be provided as `PORT_<pname>_OPTION_<oname>` parameters.
|
|||
|
|
|||
|
The library parser will simply expand the RAM definition for every possible combination
|
|||
|
of option values mentioned in the RAM body, and likewise for port definitions.
|
|||
|
This can lead to a combinatorial explosion.
|
|||
|
|
|||
|
If some option values cannot be used together, a `forbid` pseudo-property can be used
|
|||
|
to discard a given combination, eg:
|
|||
|
|
|||
|
option "ABC" 1 {
|
|||
|
portoption "DEF" "GHI" {
|
|||
|
forbid;
|
|||
|
}
|
|||
|
}
|
|||
|
|
|||
|
will disallow combining the RAM option `ABC = 2` with port option `DEF = "GHI"`.
|
|||
|
|
|||
|
|
|||
|
## Ifdefs
|
|||
|
|
|||
|
To allow reusing a library for multiple FPGA families with slighly differing
|
|||
|
capabilities, `ifdef` (and `ifndef`) blocks are provided:
|
|||
|
|
|||
|
ifdef IS_FANCY_FPGA_WITH_CONFIGURABLE_ASYNC_RESET {
|
|||
|
rdarst any;
|
|||
|
} else {
|
|||
|
rdarst zero;
|
|||
|
}
|
|||
|
|
|||
|
Such blocks can be enabled by passing the `-D` option to the pass.
|