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use crate::core::prelude::*;
#[derive(Clone, Debug, LogicInterface)]
pub struct OpalKellyHostInterface {
pub sig_in: Signal<In, Bits<8>>,
pub sig_out: Signal<Out, Bits<2>>,
pub sig_inout: Signal<InOut, Bits<16>>,
pub sig_aa: Signal<InOut, Bit>,
pub sig_mux: Signal<Out, Bit>,
}
impl OpalKellyHostInterface {
pub fn xem_6010() -> OpalKellyHostInterface {
let mut hi_in = Signal::default();
for (ndx, name) in ["Y12", "AB20", "AB7", "AB8", "AA4", "AB4", "Y3", "AB3"]
.iter()
.enumerate()
{
hi_in.add_location(ndx, name);
hi_in.add_signal_type(ndx, SignalType::LowVoltageCMOS_3v3);
if ndx != 0 {
hi_in.add_constraint(PinConstraint {
index: ndx,
constraint: Constraint::Timing(Timing::InputTiming(InputTimingConstraint {
offset_nanoseconds: 14.3,
valid_duration_nanoseconds: 20.83,
relative: TimingRelative::Before,
edge_sense: TimingRelativeEdge::Rising,
to_signal_id: hi_in.id(),
to_signal_bit: Some(0),
})),
})
} else {
hi_in.add_constraint(PinConstraint {
index: 0,
constraint: Constraint::Timing(Periodic(PeriodicTiming {
net: "okHostClk".into(),
period_nanoseconds: 20.83,
duty_cycle: 50.0,
})),
});
}
}
let mut hi_out = Signal::default();
for (ndx, name) in ["Y19", "AA8"].iter().enumerate() {
hi_out.add_location(ndx, name);
hi_out.add_signal_type(ndx, SignalType::LowVoltageCMOS_3v3);
hi_out.add_constraint(PinConstraint {
index: ndx,
constraint: Constraint::Timing(Timing::OutputTiming(OutputTimingConstraint {
offset_nanoseconds: 11.93,
relative: TimingRelative::After,
edge_sense: TimingRelativeEdge::Rising,
to_signal_id: hi_in.id(),
to_signal_bit: Some(0),
})),
})
}
let mut hi_inout = Signal::default();
for (ndx, name) in [
"AB12", "AA12", "Y13", "AB18", "AA18", "V15", "AB2", "AA2", "Y7", "Y4", "W4", "AB6",
"AA6", "U13", "U14", "AA20",
]
.iter()
.enumerate()
{
hi_inout.add_location(ndx, name);
hi_inout.add_signal_type(ndx, SignalType::LowVoltageCMOS_3v3);
hi_inout.add_constraint(PinConstraint {
index: ndx,
constraint: Constraint::Timing(Timing::OutputTiming(OutputTimingConstraint {
offset_nanoseconds: 11.63,
relative: TimingRelative::After,
edge_sense: TimingRelativeEdge::Rising,
to_signal_id: hi_in.id(),
to_signal_bit: Some(0),
})),
});
hi_inout.add_constraint(PinConstraint {
index: ndx,
constraint: Constraint::Timing(Timing::InputTiming(InputTimingConstraint {
offset_nanoseconds: 9.83,
valid_duration_nanoseconds: 9.83,
relative: TimingRelative::Before,
edge_sense: TimingRelativeEdge::Rising,
to_signal_id: hi_in.id(),
to_signal_bit: Some(0),
})),
})
}
let mut hi_aa = Signal::default();
hi_aa.add_location(0, "W11");
hi_aa.add_signal_type(0, SignalType::LowVoltageCMOS_3v3);
let mut hi_mux = Signal::default();
hi_mux.add_location(0, "AA22");
hi_mux.add_signal_type(0, SignalType::LowVoltageCMOS_3v3);
Self {
sig_in: hi_in,
sig_out: hi_out,
sig_inout: hi_inout,
sig_aa: hi_aa,
sig_mux: hi_mux,
}
}
pub fn xem_7010() -> OpalKellyHostInterface {
let mut hi_in = Signal::default();
for (ndx, name) in ["Y18", "V17", "AA19", "V20", "W17", "AB20", "V19", "AA18"]
.iter()
.enumerate()
{
hi_in.add_location(ndx, name);
hi_in.add_signal_type(ndx, SignalType::LowVoltageCMOS_3v3);
hi_in.add_constraint(PinConstraint {
index: ndx,
constraint: Constraint::Slew(SlewType::Fast),
});
if ndx != 0 {
hi_in.add_constraint(PinConstraint {
index: ndx,
constraint: Constraint::Timing(Timing::VivadoInputTiming(
VivadoInputTimingConstraint {
min_nanoseconds: 0.0,
max_nanoseconds: 6.7,
multicycle: 2,
clock: "okHostClk".to_string(),
},
)),
})
} else {
hi_in.add_constraint(PinConstraint {
index: 0,
constraint: Constraint::Timing(Periodic(PeriodicTiming {
net: "okHostClk".into(),
period_nanoseconds: 20.83,
duty_cycle: 50.0,
})),
});
hi_in.add_constraint(PinConstraint {
index: 0,
constraint: Constraint::Timing(VivadoClockGroup(vec![
vec!["okHostClk".to_string()],
vec!["sys_clock_p".to_string()],
])),
})
}
}
let mut hi_out = Signal::default();
for (ndx, name) in ["Y21", "U20"].iter().enumerate() {
hi_out.add_location(ndx, name);
hi_out.add_signal_type(ndx, SignalType::LowVoltageCMOS_3v3);
hi_out.add_constraint(PinConstraint {
index: ndx,
constraint: Constraint::Timing(VivadoOutputTiming(VivadoOutputTimingConstraint {
delay_nanoseconds: 8.9,
clock: "okHostClk".to_string(),
})),
})
}
let mut hi_inout = Signal::default();
for (ndx, name) in [
"AB22", "AB21", "Y22", "AA21", "AA20", "W22", "W21", "T20", "R19", "P19", "U21", "T21",
"R21", "P21", "R22", "P22",
]
.iter()
.enumerate()
{
hi_inout.add_location(ndx, name);
hi_inout.add_signal_type(ndx, SignalType::LowVoltageCMOS_3v3);
hi_inout.add_constraint(PinConstraint {
index: ndx,
constraint: Constraint::Timing(VivadoInputTiming(VivadoInputTimingConstraint {
min_nanoseconds: 0.0,
max_nanoseconds: 11.0,
multicycle: 2,
clock: "okHostClk".to_string(),
})),
});
hi_inout.add_constraint(PinConstraint {
index: ndx,
constraint: Constraint::Timing(VivadoOutputTiming(VivadoOutputTimingConstraint {
delay_nanoseconds: 9.2,
clock: "okHostClk".to_string(),
})),
});
}
let mut hi_aa = Signal::default();
hi_aa.add_location(0, "V22");
hi_aa.add_signal_type(0, SignalType::LowVoltageCMOS_3v3);
let mut hi_mux = Signal::default();
hi_mux.add_location(0, "P20");
hi_mux.add_signal_type(0, SignalType::LowVoltageCMOS_3v3);
Self {
sig_in: hi_in,
sig_out: hi_out,
sig_inout: hi_inout,
sig_aa: hi_aa,
sig_mux: hi_mux,
}
}
}
