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Verilog

3 years ago
// © IBM Corp. 2020
// Licensed under the Apache License, Version 2.0 (the "License"), as modified by
// the terms below; you may not use the files in this repository except in
// compliance with the License as modified.
// You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0
//
// Modified Terms:
//
// 1) For the purpose of the patent license granted to you in Section 3 of the
// License, the "Work" hereby includes implementations of the work of authorship
// in physical form.
//
// 2) Notwithstanding any terms to the contrary in the License, any licenses
// necessary for implementation of the Work that are available from OpenPOWER
// via the Power ISA End User License Agreement (EULA) are explicitly excluded
// hereunder, and may be obtained from OpenPOWER under the terms and conditions
// of the EULA.
//
// Unless required by applicable law or agreed to in writing, the reference design
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License
// for the specific language governing permissions and limitations under the License.
//
// Additional rights, including the ability to physically implement a softcore that
// is compliant with the required sections of the Power ISA Specification, are
// available at no cost under the terms of the OpenPOWER Power ISA EULA, which can be
// obtained (along with the Power ISA) here: https://openpowerfoundation.org.
//
// Description: Pervasive Core Thread Controls
//
//*****************************************************************************
`timescale 1 ns / 1 ns
`include "tri_a2o.vh"
module pcq_ctrl(
// Include model build parameters
`include "tri_a2o.vh"
inout vdd,
inout gnd,
input [0:`NCLK_WIDTH-1] nclk,
input scan_dis_dc_b,
input lcb_clkoff_dc_b,
input lcb_mpw1_dc_b,
input lcb_mpw2_dc_b,
input lcb_delay_lclkr_dc,
input lcb_act_dis_dc,
input pc_pc_func_slp_sl_thold_0,
input pc_pc_sg_0,
input func_scan_in,
output func_scan_out,
// Reset Related
output pc_lq_init_reset,
output pc_iu_init_reset,
output ct_rg_hold_during_init,
// Power Management
output [0:`THREADS-1] ct_rg_power_managed,
output ac_an_power_managed,
output ac_an_rvwinkle_mode,
output pc_xu_pm_hold_thread,
output ct_ck_pm_ccflush_disable,
output ct_ck_pm_raise_tholds,
input rg_ct_dis_pwr_savings,
input [0:1] xu_pc_spr_ccr0_pme,
input [0:`THREADS-1] xu_pc_spr_ccr0_we,
// Trace/Trigger Signals
output [0:14] dbg_ctrls
);
//=====================================================================
// Signal Declarations
//=====================================================================
parameter INITACTIVE_SIZE = 1;
parameter HOLDCNTR_SIZE = 3;
parameter INITCNTR_SIZE = 9;
parameter INITERAT_SIZE = 1;
parameter PMCTRLS_T0_SIZE = 15;
parameter PMCTRLS_T1_SIZE = 2 * (`THREADS - 1);
parameter SPARECTRL_SIZE = 6;
//---------------------------------------------------------------------
// Scan Ring Ordering:
// start of func scan chain ordering
parameter INITACTIVE_OFFSET = 0;
parameter HOLDCNTR_OFFSET = INITACTIVE_OFFSET + INITACTIVE_SIZE;
parameter INITCNTR_OFFSET = HOLDCNTR_OFFSET + HOLDCNTR_SIZE;
parameter INITERAT_OFFSET = INITCNTR_OFFSET + INITCNTR_SIZE;
parameter PMCTRLS_T0_OFFSET = INITERAT_OFFSET + INITERAT_SIZE;
parameter PMCTRLS_T1_OFFSET = PMCTRLS_T0_OFFSET + PMCTRLS_T0_SIZE;
parameter SPARECTRL_OFFSET = PMCTRLS_T1_OFFSET + PMCTRLS_T1_SIZE;
parameter FUNC_RIGHT = SPARECTRL_OFFSET + SPARECTRL_SIZE - 1;
// end of func scan chain ordering
//---------------------------------------------------------------------
// Array Initialization Controls:
parameter HOLDCNT_IDLE = 0;
parameter HOLDCNT_DONE = 7;
parameter INITCNT_START = 15+(`INIT_BHT*496); // sets INITCNTR to 15 or 511
parameter INITCNT_DONE = 0;
//---------------------------------------------------------------------
// Basic/Misc signals
wire tiup;
wire [0:FUNC_RIGHT] func_siv;
wire [0:FUNC_RIGHT] func_sov;
wire pc_pc_func_slp_sl_thold_0_b;
wire force_funcslp;
// Reset Signals
wire initcntr_enabled;
// Power management Signals
wire [0:1] spr_ccr0_pme_q;
wire [0:`THREADS-1] spr_ccr0_we_q;
wire pm_sleep_enable;
wire pm_rvw_enable;
wire [0:`THREADS-1] thread_stopped;
wire pmstate_q_anded;
// Latch definitions begin
wire [0:HOLDCNTR_SIZE-1] holdcntr_d;
wire [0:HOLDCNTR_SIZE-1] holdcntr_q;
wire [0:INITCNTR_SIZE-1] initcntr_d;
wire [0:INITCNTR_SIZE-1] initcntr_q;
wire init_active_d;
wire init_active_q;
wire initerat_d;
wire initerat_q;
wire pmstate_enab;
wire [0:`THREADS-1] pmstate_d;
wire [0:`THREADS-1] pmstate_q;
wire pmstate_all_d;
wire pmstate_all_q;
wire [0:7] pmclkctrl_dly_d;
wire [0:7] pmclkctrl_dly_q;
wire power_managed_d;
wire power_managed_q;
wire rvwinkled_d;
wire rvwinkled_q;
wire pm_ccflush_disable_int;
wire pm_raise_tholds_int;
wire [0:SPARECTRL_SIZE-1] spare_ctrl_wrapped_q;
//!! Bugspray Include: pcq_ctrl;
assign tiup = 1'b1;
//=====================================================================
// Reset State Machine
//=====================================================================
// HOLDCNTR: Delays start of array initialization for 7 cycles. Provides some time
// after clock start to ensure clock controls have propagated to LCBs. .
assign holdcntr_d = init_active_q == 1'b0 ? HOLDCNT_IDLE :
holdcntr_q == HOLDCNT_DONE ? HOLDCNT_DONE :
holdcntr_q + 3'b001;
// Latch ACT control: Goes inactive once array initialization is over.
assign initcntr_enabled = init_active_q | (|holdcntr_q);
// INITCNTR: Initialized to a value; counts down while array init signal held active.
// Default time is 16 cycles, which is long enough for the ERATs to initialize.
// To initialize the BHT, the array init signal is kept active for 512 cycles.
// Controlled by `INIT_BHT (0=16 cycles; 1=512 cycles)
assign initcntr_d = holdcntr_q != HOLDCNT_DONE ? initcntr_q :
initcntr_q == INITCNT_DONE ? INITCNT_DONE :
initcntr_q - 9'b000000001;
// INITERAT: The initerat latch controls the init_reset signals to IU and XU.
// Goes active when HOLDCNTR=7, and shuts off when INITCNTR counts down to 0.
assign initerat_d = ( holdcntr_q < HOLDCNT_DONE-1) ? 1'b0 :
(|initcntr_q);
// INIT_ACTIVE: init_active_q initializes to '1'; cleared after INITCNTR counts down to 0.
assign init_active_d = (initcntr_q == INITCNT_DONE) ? 1'b0 :
init_active_q;
//=====================================================================
// Power Management Latches
//=====================================================================
// XU signals indicate when power-savings is enabled (sleep or rvw modes), and which
// THREADS are stopped.
// The pmstate latch tracks which THREADS are stopped when either power-savings mode
// is enabled. The rvwinkled latch only when pm_rvw_enable is set.
// If all THREADS are stopped when power-savings is enabled, then signals to the
// clock control macro will initiate power savings actions. These controls force
// ccflush_dc inactive to ensure all PLATs are clocking. After a delay period, the
// run tholds will be raised to stop clocks.
// When coming out of power-savings, the tholds will be disabled prior to deactivating
// ccflush_dc.
assign pm_sleep_enable = (~spr_ccr0_pme_q[0]) & spr_ccr0_pme_q[1];
assign pm_rvw_enable = spr_ccr0_pme_q[0] & (~spr_ccr0_pme_q[1]);
assign thread_stopped = spr_ccr0_we_q;
assign pmstate_enab = (pm_sleep_enable | pm_rvw_enable) & (~initcntr_enabled);
assign pmstate_d = {`THREADS{pmstate_enab}} & thread_stopped[0:`THREADS - 1];
// Once all CCR0[WE] bits are set, pmstate_all_q is held active until pmclkctrl_dly_q(7).
// Forces an orderly sequence through PM controls, even if one thread wakes-up right away.
assign pmstate_q_anded = (&pmstate_q);
assign pmstate_all_d = ((~pmclkctrl_dly_q[7]) & (pmstate_q_anded | pmstate_all_q)) |
(pmstate_q_anded & pmstate_all_q);
assign power_managed_d = pmstate_all_d | pmclkctrl_dly_q[6];
assign rvwinkled_d = (pmstate_all_d | pmclkctrl_dly_q[6]) & pm_rvw_enable;
assign pmclkctrl_dly_d[0:7] = {pmstate_all_q, pmclkctrl_dly_q[0:6]};
//=====================================================================
// Outputs
//=====================================================================
// Used as part of thread stop signal to XU.
// Keeps THREADS stopped until after the Reset SM completes count.
assign ct_rg_hold_during_init = init_active_q;
// Init pulse to IU and XU to force initialization of IERAT, DERAT and BHT.
// IU also holds instruction fetch until init signal released.
assign pc_iu_init_reset = initerat_q;
assign pc_lq_init_reset = initerat_q;
// To THRCTL[Tx_PM]; indicates core power-managed via software actions.
assign ct_rg_power_managed = pmstate_q[0:`THREADS - 1];
// Core in rvwinkle power-savings state. L2 can prepare for Chiplet power-down.
assign ac_an_rvwinkle_mode = rvwinkled_q;
// Core in power-savings state due to any combination of power-savings instructions
assign ac_an_power_managed = power_managed_q;
assign pc_xu_pm_hold_thread = power_managed_q;
// Goes to clock controls to disable plat flush controls
assign pm_ccflush_disable_int = pmstate_all_q | pmclkctrl_dly_q[7];
assign ct_ck_pm_ccflush_disable = pm_ccflush_disable_int & (~rg_ct_dis_pwr_savings);
// Goes to clock controls to activate run tholds
assign pm_raise_tholds_int = pmstate_all_q & pmclkctrl_dly_q[7];
assign ct_ck_pm_raise_tholds = pm_raise_tholds_int & (~rg_ct_dis_pwr_savings);
//=====================================================================
// Trace/Trigger Signals
//=====================================================================
assign dbg_ctrls = { pmstate_q_anded, // 0
pmstate_all_q, // 1
power_managed_q, // 2
rvwinkled_q, // 3
pmclkctrl_dly_q[0:7], // 4:11
rg_ct_dis_pwr_savings, // 12
pm_ccflush_disable_int, // 13
pm_raise_tholds_int // 14
};
//=====================================================================
// Latches
//=====================================================================
// func ring registers start
tri_rlmlatch_p #(.INIT(1)) initactive(
.vd(vdd),
.gd(gnd),
.nclk(nclk),
.act(tiup),
.thold_b(pc_pc_func_slp_sl_thold_0_b),
.sg(pc_pc_sg_0),
.force_t(force_funcslp),
.delay_lclkr(lcb_delay_lclkr_dc),
.mpw1_b(lcb_mpw1_dc_b),
.mpw2_b(lcb_mpw2_dc_b),
.scin(func_siv[ INITACTIVE_OFFSET]),
.scout(func_sov[INITACTIVE_OFFSET]),
.din(init_active_d),
.dout(init_active_q)
);
tri_rlmreg_p #(.WIDTH(HOLDCNTR_SIZE), .INIT(0)) holdcntr(
.vd(vdd),
.gd(gnd),
.nclk(nclk),
.act(initcntr_enabled),
.thold_b(pc_pc_func_slp_sl_thold_0_b),
.sg(pc_pc_sg_0),
.force_t(force_funcslp),
.delay_lclkr(lcb_delay_lclkr_dc),
.mpw1_b(lcb_mpw1_dc_b),
.mpw2_b(lcb_mpw2_dc_b),
.scin(func_siv[ HOLDCNTR_OFFSET:HOLDCNTR_OFFSET + HOLDCNTR_SIZE - 1]),
.scout(func_sov[HOLDCNTR_OFFSET:HOLDCNTR_OFFSET + HOLDCNTR_SIZE - 1]),
.din(holdcntr_d),
.dout(holdcntr_q)
);
tri_rlmreg_p #(.WIDTH(INITCNTR_SIZE), .INIT(INITCNT_START)) initcntr(
.vd(vdd),
.gd(gnd),
.nclk(nclk),
.act(initcntr_enabled),
.thold_b(pc_pc_func_slp_sl_thold_0_b),
.sg(pc_pc_sg_0),
.force_t(force_funcslp),
.delay_lclkr(lcb_delay_lclkr_dc),
.mpw1_b(lcb_mpw1_dc_b),
.mpw2_b(lcb_mpw2_dc_b),
.scin(func_siv[ INITCNTR_OFFSET:INITCNTR_OFFSET + INITCNTR_SIZE - 1]),
.scout(func_sov[INITCNTR_OFFSET:INITCNTR_OFFSET + INITCNTR_SIZE - 1]),
.din(initcntr_d),
.dout(initcntr_q)
);
tri_rlmlatch_p #(.INIT(0)) initerat(
.vd(vdd),
.gd(gnd),
.nclk(nclk),
.act(initcntr_enabled),
.thold_b(pc_pc_func_slp_sl_thold_0_b),
.sg(pc_pc_sg_0),
.force_t(force_funcslp),
.delay_lclkr(lcb_delay_lclkr_dc),
.mpw1_b(lcb_mpw1_dc_b),
.mpw2_b(lcb_mpw2_dc_b),
.scin(func_siv[ INITERAT_OFFSET]),
.scout(func_sov[INITERAT_OFFSET]),
.din(initerat_d),
.dout(initerat_q)
);
tri_rlmreg_p #(.WIDTH(PMCTRLS_T0_SIZE), .INIT(0)) pmctrls_t0(
.vd(vdd),
.gd(gnd),
.nclk(nclk),
.act(tiup),
.thold_b(pc_pc_func_slp_sl_thold_0_b),
.sg(pc_pc_sg_0),
.force_t(force_funcslp),
.delay_lclkr(lcb_delay_lclkr_dc),
.mpw1_b(lcb_mpw1_dc_b),
.mpw2_b(lcb_mpw2_dc_b),
.scin(func_siv[ PMCTRLS_T0_OFFSET:PMCTRLS_T0_OFFSET + PMCTRLS_T0_SIZE - 1]),
.scout(func_sov[PMCTRLS_T0_OFFSET:PMCTRLS_T0_OFFSET + PMCTRLS_T0_SIZE - 1]),
.din( {pmclkctrl_dly_d, xu_pc_spr_ccr0_pme, xu_pc_spr_ccr0_we[0], pmstate_d[0],
pmstate_all_d, rvwinkled_d, power_managed_d}),
.dout({pmclkctrl_dly_q, spr_ccr0_pme_q, spr_ccr0_we_q[0], pmstate_q[0],
pmstate_all_q, rvwinkled_q, power_managed_q})
);
generate
if (`THREADS > 1)
begin : T1_pmctrls
tri_rlmreg_p #(.WIDTH(PMCTRLS_T1_SIZE), .INIT(0)) pmctrls_t1(
.vd(vdd),
.gd(gnd),
.nclk(nclk),
.act(tiup),
.thold_b(pc_pc_func_slp_sl_thold_0_b),
.sg(pc_pc_sg_0),
.force_t(force_funcslp),
.delay_lclkr(lcb_delay_lclkr_dc),
.mpw1_b(lcb_mpw1_dc_b),
.mpw2_b(lcb_mpw2_dc_b),
.scin(func_siv[ PMCTRLS_T1_OFFSET:PMCTRLS_T1_OFFSET + PMCTRLS_T1_SIZE - 1]),
.scout(func_sov[PMCTRLS_T1_OFFSET:PMCTRLS_T1_OFFSET + PMCTRLS_T1_SIZE - 1]),
.din({xu_pc_spr_ccr0_we[1], pmstate_d[1]}),
.dout({spr_ccr0_we_q[1], pmstate_q[1]})
);
end
endgenerate
tri_rlmreg_p #(.WIDTH(SPARECTRL_SIZE), .INIT(0)) sparectrl(
.vd(vdd),
.gd(gnd),
.nclk(nclk),
.act(tiup),
.thold_b(pc_pc_func_slp_sl_thold_0_b),
.sg(pc_pc_sg_0),
.force_t(force_funcslp),
.delay_lclkr(lcb_delay_lclkr_dc),
.mpw1_b(lcb_mpw1_dc_b),
.mpw2_b(lcb_mpw2_dc_b),
.scin(func_siv[ SPARECTRL_OFFSET:SPARECTRL_OFFSET + SPARECTRL_SIZE - 1]),
.scout(func_sov[SPARECTRL_OFFSET:SPARECTRL_OFFSET + SPARECTRL_SIZE - 1]),
.din(spare_ctrl_wrapped_q),
.dout(spare_ctrl_wrapped_q)
);
// func ring registers end
//=====================================================================
// Thold/SG Staging
//=====================================================================
// func_slp lcbor
tri_lcbor lcbor_funcslp(
.clkoff_b(lcb_clkoff_dc_b),
.thold(pc_pc_func_slp_sl_thold_0),
.sg(pc_pc_sg_0),
.act_dis(lcb_act_dis_dc),
.force_t(force_funcslp),
.thold_b(pc_pc_func_slp_sl_thold_0_b)
);
//=====================================================================
// Scan Connections
//=====================================================================
// Func ring
assign func_siv[0:FUNC_RIGHT] = {func_scan_in, func_sov[0:FUNC_RIGHT - 1]};
assign func_scan_out = func_sov[FUNC_RIGHT] & scan_dis_dc_b;
endmodule