This is useful for certain cross-compilation workloads, and to cache
rarely changing build products.
To use this functionality, build e.g. as follows:
cmake . -B build-export -DEXPORT_BBA_FILES=../bba-files -DARCH=all
cmake --build build-export -t nextpnr-all-bba
cmake . -B build-import -DIMPORT_BBA_FILES=../bba-files -DARCH=all
cmake --build build-import
Two user-visible changes were made:
* `-DUSE_RUST` is replaced with `-DBUILD_RUST`, by analogy with
`-DBUILD_PYTHON`
* `-DCOVERAGE` was removed as it doesn't work with either modern GCC
or Clang
Primarily, this commit makes both of them use the `BBAsm` functions
to build and compile `.bba` files.
In addition, Himbaechel targets are now aligned with the rest in
how they are configured: instead of having all uarches enabled with
all of the devices disabled (the opposite of the rest of nextpnr),
uarches must be enabled explicitly but they come with all devices
enabled (except for Xilinx, which does not have a list of devices).
Erroneously created wires for specific IOs on the underside of some
chips.
Fixes https://github.com/YosysHQ/nextpnr/issues/1417
Also cosmetic edits.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Add the ability to place registers in IOB
IO blocks have registers: for input, for output and for OutputEnable
signal - IREG, OREG and TREG respectively.
Each of the registers has one implicit non-switched wire, which one
depends on the type of register (IREG has a Q wire, OREG has a D wire).
Although the registers can be activated independently of each other they
share the CLK, ClockEnable and LocalSetReset wires and this places
restrictions on the possible combinations of register types in a single
IO.
Register placement in IO blocks is enabled by specifying the command
line keys --vopt ireg_in_iob, --vopt oreg_in_iob, or --vopt ioreg_in_iob.
It should be noted that specifying these keys leads to attempts to place
registers in IO blocks, but no errors are generated in case of failure.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Registers in IO
Check for unconnected ports.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. IO regs. Verbose warnings.
If an attempt to place an FF in an IO block fails, issue a warning
detailing the reason for the failure, whether it is a register type
conflict, a network requirement violation, or a control signal conflict.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. BUGFIX. Fix FFs compatibility.
Flipflops with a fixed ClockEnable input cannot coexist with flipflops
with a variable one.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. FFs in IO. Changing diagnostic messages.
Placement modes are still specified by the command line keys
ireg_in_iob/oreg_in_iob/ioreg_in_iob, but also introduces more granular
control in the form of attributes at I/O ports:
(* NOIOBFF *) - registers are never placed in this IO,
(* IOBFF *) - registers must be placed in this IO, in case of failure
a warning (not an error) with the reason for nonplacement is issued,
_attribute_absence_ - no diagnostics will be issued: managed to place - good, failed - not bad either.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Registers in IO.
Change the logic for handling command line keys and attributes -
attributes allow routines to be placed in IO regardless of global mode.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Registers in IO. Fix style.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
---------
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
Adds additional restrictions on the first PIP after the clock source -
only connections to SPINEs are allowed. This allowed to correct the
behaviour of DQCEs since the latter can only disable/enable SPINEs.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Add IODELAY.
Input/Output delay (IODELAY) is programmable delay uint in IO block.
This delay line is enabled before/after the IO pad and allows the signal
to be delayed statically or dynamically during 0-127 stages each lasting
from 18 to 30 picoseconds depending on the chip family.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Replacing assertions with log_error.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
---------
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
Add sampling part to IO blocks (input only). This edge detector will
allow to dynamically adjust DDR decoding window in the future.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. FFs placement.
* Allow clusters to be created from FFs and LUTs;
* Immediately create pass-through LUTs from free LUTs adjacent to FF - at the same time ensure alternating use of LUT inputs;
* In case of constant networks, such pass-through LUTs are disconnected from networks altogether;
* Allow FF to be placed directly into SSRAM slides - this is useful when using synchronous reading.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Fix aux name creation
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Use I3 for pass-trough LUTs
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
---------
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Fix the port check for connectivity.
What happens is that it's not enough to check for a network, we also
need to make sure that the network is functional: has src and sinks.
And the style edits - they get automatically when I make sure to run
clang-format10.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Fix the port check for connectivity.
What happens is that it's not enough to check for a network, we also
need to make sure that the network is functional: has src and sinks
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
---------
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Implement the EMCU primitive.
Add support for the GW1NSR-4C's embedded Cortex-M3 processor. Since it
uses flash in its own way, we disable additional flash processing for
this case.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Fix merge.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
---------
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Add DHCEN primitive.
This primitive allows you to dynamically turn off and turn on the
networks of high-speed clocks.
This is done tracking the routes to the sinks and if the route passes
through a special HCLK MUX (this may be the input MUX or the output MUX,
as well as the interbank MUX), then the control signal of this MUX is
used.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Change the DHCEN binding
Use the entire PIP instead of a wire - avoids normalisation and may also
be useful in the future when calculating clock stuff.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
---------
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
Some Clocks PIPS were not created due to a check for the presence of a
delay class, now all wires are attributed to the class so that there is
no longer any need for this check.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Implement the UserFlash primitive
Some Gowin chips have embedded flash memory accessible from the fabric.
Here we add primitives that allow access to this memory.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Gowin. Fix cell creation
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
---------
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Himbaechel Gowin: Add support for CLKDIV and CLKDIV2
* Himbaechel Gowin: Add support for CLKDIV and CLKDIV2
* Gowin Himbaechel: HCLK Bug fixes and corrections
DQCE and DCS primitives are added.
DQCE allows the internal logic to enable or disable the clock network in
the quadrant. When clock network is disabled, all logic drivern by this
clock is no longer toggled, thus reducing the total power consumtion of
the device.
DCS allows you to select one of four sources for two clock wires (6 and 7).
Wires 6 and 7 have not been used up to this point.
Since "hardware" primitives operate strictly in their own quadrants,
user-specified primitives are converted into one or more "hardware"
primitives as needed.
Also:
- minor edits to make the most of helper functions like connectPorts()
- when creating bases, the corresponding constants are assigned to the
VCC and GND wires, but for now huge nodes are used because, for an
unknown reason, the constants mechanism makes large examples
inoperable. So for now we remain on the nodes.
Compatible with older Apicula databases.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
It was not taken into account that there are only 6 ALUs per cell. As a
result, on complex designs where ALUs and LUT-based memory are involved
and there are many LUTs (like in the RISCV emulator), there were
sometimes false positives about placement conflicts.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
The statement in the Gowin documentation that in the reading mode
"READ_MODE=0" the output register is not used and the OCE signal is
ignored is not confirmed by practice - if the OCE was left unconnected
or connected to the constant network, then a change in output data was
observed even with CE=0, as well as the absence of such at CE=1.
Synchronizing CE and OCE helps and the memory works properly in complex
systems such as RISC-V emulation and i8080 emulation (with 32K RAM and
16K BSRAM based ROM), but there is no theoretical basis for this fix, so
it is a hack.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
For pROM(X9) primitives in images generated by Gowin IDE, there is an
interesting recommunication of inputs depending on the data bit depth.
For example, in some cases, a high logical level may be applied to the
Write Enable input, which, let’s say, is not entirely usual for Read
Only memory.
Here we will do similar manipulations.
In addition, several minor bug fixes are included:
- Fixed bit numbering for non-X9 series primitives.
- Fixed decoder generation for BLKSEL - do not assume unused inputs are
connected to GND.
- Use default values for BSRAM parameters - don't assume their
mandatory presence.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
As the board on the GW1N-1 chip becomes a rarity, its replacement is the
Tangnano1k board with the GW1NZ-1 chip. This chip has a unique mechanism
for turning off power to important things such as OSC, PLL, etc.
Here we introduce a primitive that allows energy saving to be controlled
dynamically.
We also bring the names of some functions to uniformity.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
In the images generated by Gowin IDE, the signals for dynamic BSRAM
block selection (BLKSEL[2:0]) are not always connected directly to the
ports - some chips add LUT2, LUT3 or LUT4 to turn these signals into
Clock Enable. Apparently there are chips with an error in the operation
of these ports.
Here we make such a decoder instead of using ports directly.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
It seems that the internal registers on the BSRAM output pins in
READ_MODE=1'b1 (pipeline) mode do not function properly because in the
images generated by Gowin IDE an external register is added to each pin,
and the BSRAM itself switches to READ_MODE=1'b0 (bypass) mode .
This is observed on Tangnano9k and Tangnano20k boards.
Here we repeat this fix.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
Add description of BSRAM harness
In some cases, Gowin IDE adds a number of LUTs and DFFs to the BSRAM. Here we are trying to add similar elements.
More details with pictures: https://github.com/YosysHQ/apicula/blob/master/doc/bsram-fix.md
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
When multiplying 36 bits by 36 bits using four 18x18 multipliers, the
sign bits of the higher 18-bit parts of the multipliers were correctly
switched, but what was incorrect was leaving the sign bits of the lower
parts of the multipliers uninitialized. They now connect to VSS.
Addresses https://github.com/YosysHQ/apicula/issues/242
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
Do not search for pads if the signal source for the PLL is something
other than the IO pin - these are guaranteed to already be placed and
have a bound Bel.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
If the CLKIN input of the PLL is connected to a special pin, then it
makes sense to try to place the PLL so that it uses a direct implicit
non-switched connection to this pin.
The transfer of information about pins for various purposes has been
implemented (clock input signal, feedback, etc), but so far only CLKIN
is used.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
For the following primitives:
- PADD9
- PADD18
- MULT9X9
- MULT18X18
- MULT36X36
- MULTALU18X18
- MULTALU36X18
- MULTADDALU18X18
- ALU54D
packing and processing of fixed wires between macro and between DSP
blocks is implemented.
Clusters of DSP and macro blocks are processed using custom placement of
cluster elements.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
Corrects the situation when it is impossible to use IOBUF with two
IOLOGIC elements at the same time - input and output.
Addresses https://github.com/YosysHQ/nextpnr/issues/1275
This is done by dividing one IOLOGIC Bel into two - input IOLOGIC and
output IOLOGIC plus checking for compatibility of the cells located
there.
At the moment, this check is simple and allows only the combination of
DDR and DDRC primitives.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
A small improvement - do not waste time analyzing already processed
networks in the previous step (and possibly steps).
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
Semi-dual port BSRAM (in Gowin terminology) has the same feature as
Single Port - the CE and OCE signals must be synchronized.
Such a sin has not yet been noticed for Dual Port.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
* Don't stop at the first bad "arc", but use the global network to the
maximum.
* Report partial/full use of global wires for the network.
* In case of complete routing failure, releasing the source - this is
actually a BUGFIX.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
This type setting is not needed here - the packer distinguishes memory
features by the X9 attribute, which will be correct anyway.
Signed-off-by: YRabbit <rabbit@yrabbit.cyou>
