/*
* Copyright (c) 2016-2017, NVIDIA CORPORATION. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*/
#include <nvgpu/pmu.h>
#include <nvgpu/pmuif/nvgpu_gpmu_cmdif.h>
#include "gk20a/gk20a.h"
#include "clk.h"
#include "ctrl/ctrlclk.h"
#include "ctrl/ctrlvolt.h"
#include "volt/volt.h"
#define BOOT_GPC2CLK_MHZ 2581
#define BOOT_MCLK_MHZ 3003
struct clkrpc_pmucmdhandler_params {
struct nv_pmu_clk_rpc *prpccall;
u32 success;
};
static void clkrpc_pmucmdhandler(struct gk20a *g, struct pmu_msg *msg,
void *param, u32 handle, u32 status)
{
struct clkrpc_pmucmdhandler_params *phandlerparams =
(struct clkrpc_pmucmdhandler_params *)param;
gk20a_dbg_info("");
if (msg->msg.clk.msg_type != NV_PMU_CLK_MSG_ID_RPC) {
nvgpu_err(g, "unsupported msg for VFE LOAD RPC %x",
msg->msg.clk.msg_type);
return;
}
if (phandlerparams->prpccall->b_supported)
phandlerparams->success = 1;
}
int clk_pmu_freq_controller_load(struct gk20a *g, bool bload)
{
struct pmu_cmd cmd;
struct pmu_msg msg;
struct pmu_payload payload;
u32 status;
u32 seqdesc;
struct nv_pmu_clk_rpc rpccall;
struct clkrpc_pmucmdhandler_params handler;
struct nv_pmu_clk_load *clkload;
struct clk_freq_controllers *pclk_freq_controllers;
struct ctrl_boardobjgrp_mask_e32 *load_mask;
memset(&payload, 0, sizeof(struct pmu_payload));
memset(&rpccall, 0, sizeof(struct nv_pmu_clk_rpc));
memset(&handler, 0, sizeof(struct clkrpc_pmucmdhandler_params));
pclk_freq_controllers = &g->clk_pmu.clk_freq_controllers;
rpccall.function = NV_PMU_CLK_RPC_ID_LOAD;
clkload = &rpccall.params.clk_load;
clkload->feature = NV_NV_PMU_CLK_LOAD_FEATURE_FREQ_CONTROLLER;
clkload->action_mask = bload ?
NV_NV_PMU_CLK_LOAD_ACTION_MASK_FREQ_CONTROLLER_CALLBACK_YES :
NV_NV_PMU_CLK_LOAD_ACTION_MASK_FREQ_CONTROLLER_CALLBACK_NO;
load_mask = &rpccall.params.clk_load.payload.freq_controllers.load_mask;
status = boardobjgrpmask_export(
&pclk_freq_controllers->freq_ctrl_load_mask.super,
pclk_freq_controllers->freq_ctrl_load_mask.super.bitcount,
&load_mask->super);
cmd.hdr.unit_id = PMU_UNIT_CLK;
cmd.hdr.size = (u32)sizeof(struct nv_pmu_clk_cmd) +
(u32)sizeof(struct pmu_hdr);
cmd.cmd.clk.cmd_type = NV_PMU_CLK_CMD_ID_RPC;
msg.hdr.size = sizeof(struct pmu_msg);
payload.in.buf = (u8 *)&rpccall;
payload.in.size = (u32)sizeof(struct nv_pmu_clk_rpc);
payload.in.fb_size = PMU_CMD_SUBMIT_PAYLOAD_PARAMS_FB_SIZE_UNUSED;
payload.in.offset = NV_PMU_CLK_CMD_RPC_ALLOC_OFFSET;
payload.out.buf = (u8 *)&rpccall;
payload.out.size = (u32)sizeof(struct nv_pmu_clk_rpc);
payload.out.fb_size = PMU_CMD_SUBMIT_PAYLOAD_PARAMS_FB_SIZE_UNUSED;
payload.out.offset = NV_PMU_CLK_MSG_RPC_ALLOC_OFFSET;
handler.prpccall = &rpccall;
handler.success = 0;
status = gk20a_pmu_cmd_post(g, &cmd, NULL, &payload,
PMU_COMMAND_QUEUE_LPQ,
clkrpc_pmucmdhandler, (void *)&handler,
&seqdesc, ~0);
if (status) {
nvgpu_err(g, "unable to post clk RPC cmd %x",
cmd.cmd.clk.cmd_type);
goto done;
}
pmu_wait_message_cond(&g->pmu,
gk20a_get_gr_idle_timeout(g),
&handler.success, 1);
if (handler.success == 0) {
nvgpu_err(g, "rpc call to load freq cntlr cal failed");
status = -EINVAL;
}
done:
return status;
}
u32 clk_pmu_vin_load(struct gk20a *g)
{
struct pmu_cmd cmd;
struct pmu_msg msg;
struct pmu_payload payload;
u32 status;
u32 seqdesc;
struct nv_pmu_clk_rpc rpccall;
struct clkrpc_pmucmdhandler_params handler;
struct nv_pmu_clk_load *clkload;
memset(&payload, 0, sizeof(struct pmu_payload));
memset(&rpccall, 0, sizeof(struct nv_pmu_clk_rpc));
memset(&handler, 0, sizeof(struct clkrpc_pmucmdhandler_params));
rpccall.function = NV_PMU_CLK_RPC_ID_LOAD;
clkload = &rpccall.params.clk_load;
clkload->feature = NV_NV_PMU_CLK_LOAD_FEATURE_VIN;
clkload->action_mask = NV_NV_PMU_CLK_LOAD_ACTION_MASK_VIN_HW_CAL_PROGRAM_YES << 4;
cmd.hdr.unit_id = PMU_UNIT_CLK;
cmd.hdr.size = (u32)sizeof(struct nv_pmu_clk_cmd) +
(u32)sizeof(struct pmu_hdr);
cmd.cmd.clk.cmd_type = NV_PMU_CLK_CMD_ID_RPC;
msg.hdr.size = sizeof(struct pmu_msg);
payload.in.buf = (u8 *)&rpccall;
payload.in.size = (u32)sizeof(struct nv_pmu_clk_rpc);
payload.in.fb_size = PMU_CMD_SUBMIT_PAYLOAD_PARAMS_FB_SIZE_UNUSED;
payload.in.offset = NV_PMU_CLK_CMD_RPC_ALLOC_OFFSET;
payload.out.buf = (u8 *)&rpccall;
payload.out.size = (u32)sizeof(struct nv_pmu_clk_rpc);
payload.out.fb_size = PMU_CMD_SUBMIT_PAYLOAD_PARAMS_FB_SIZE_UNUSED;
payload.out.offset = NV_PMU_CLK_MSG_RPC_ALLOC_OFFSET;
handler.prpccall = &rpccall;
handler.success = 0;
status = gk20a_pmu_cmd_post(g, &cmd, NULL, &payload,
PMU_COMMAND_QUEUE_LPQ,
clkrpc_pmucmdhandler, (void *)&handler,
&seqdesc, ~0);
if (status) {
nvgpu_err(g, "unable to post clk RPC cmd %x",
cmd.cmd.clk.cmd_type);
goto done;
}
pmu_wait_message_cond(&g->pmu,
gk20a_get_gr_idle_timeout(g),
&handler.success, 1);
if (handler.success == 0) {
nvgpu_err(g, "rpc call to load vin cal failed");
status = -EINVAL;
}
done:
return status;
}
static u32 clk_pmu_vf_inject(struct gk20a *g, struct set_fll_clk *setfllclk)
{
struct pmu_cmd cmd;
struct pmu_msg msg;
struct pmu_payload payload;
u32 status;
u32 seqdesc;
struct nv_pmu_clk_rpc rpccall;
struct clkrpc_pmucmdhandler_params handler;
struct nv_pmu_clk_vf_change_inject *vfchange;
memset(&payload, 0, sizeof(struct pmu_payload));
memset(&rpccall, 0, sizeof(struct nv_pmu_clk_rpc));
memset(&handler, 0, sizeof(struct clkrpc_pmucmdhandler_params));
if ((setfllclk->gpc2clkmhz == 0) || (setfllclk->xbar2clkmhz == 0) ||
(setfllclk->sys2clkmhz == 0) || (setfllclk->voltuv == 0))
return -EINVAL;
if ((setfllclk->target_regime_id_gpc > CTRL_CLK_FLL_REGIME_ID_FR) ||
(setfllclk->target_regime_id_sys > CTRL_CLK_FLL_REGIME_ID_FR) ||
(setfllclk->target_regime_id_xbar > CTRL_CLK_FLL_REGIME_ID_FR))
return -EINVAL;
rpccall.function = NV_PMU_CLK_RPC_ID_CLK_VF_CHANGE_INJECT;
vfchange = &rpccall.params.clk_vf_change_inject;
vfchange->flags = 0;
vfchange->clk_list.num_domains = 3;
vfchange->clk_list.clk_domains[0].clk_domain = CTRL_CLK_DOMAIN_GPC2CLK;
vfchange->clk_list.clk_domains[0].clk_freq_khz =
setfllclk->gpc2clkmhz * 1000;
vfchange->clk_list.clk_domains[0].clk_flags = 0;
vfchange->clk_list.clk_domains[0].current_regime_id =
setfllclk->current_regime_id_gpc;
vfchange->clk_list.clk_domains[0].target_regime_id =
setfllclk->target_regime_id_gpc;
vfchange->clk_list.clk_domains[1].clk_domain = CTRL_CLK_DOMAIN_XBAR2CLK;
vfchange->clk_list.clk_domains[1].clk_freq_khz =
setfllclk->xbar2clkmhz * 1000;
vfchange->clk_list.clk_domains[1].clk_flags = 0;
vfchange->clk_list.clk_domains[1].current_regime_id =
setfllclk->current_regime_id_xbar;
vfchange->clk_list.clk_domains[1].target_regime_id =
setfllclk->target_regime_id_xbar;
vfchange->clk_list.clk_domains[2].clk_domain = CTRL_CLK_DOMAIN_SYS2CLK;
vfchange->clk_list.clk_domains[2].clk_freq_khz =
setfllclk->sys2clkmhz * 1000;
vfchange->clk_list.clk_domains[2].clk_flags = 0;
vfchange->clk_list.clk_domains[2].current_regime_id =
setfllclk->current_regime_id_sys;
vfchange->clk_list.clk_domains[2].target_regime_id =
setfllclk->target_regime_id_sys;
vfchange->volt_list.num_rails = 1;
vfchange->volt_list.rails[0].volt_domain = CTRL_VOLT_DOMAIN_LOGIC;
vfchange->volt_list.rails[0].voltage_uv = setfllclk->voltuv;
vfchange->volt_list.rails[0].voltage_min_noise_unaware_uv =
setfllclk->voltuv;
cmd.hdr.unit_id = PMU_UNIT_CLK;
cmd.hdr.size = (u32)sizeof(struct nv_pmu_clk_cmd) +
(u32)sizeof(struct pmu_hdr);
cmd.cmd.clk.cmd_type = NV_PMU_CLK_CMD_ID_RPC;
msg.hdr.size = sizeof(struct pmu_msg);
payload.in.buf = (u8 *)&rpccall;
payload.in.size = (u32)sizeof(struct nv_pmu_clk_rpc);
payload.in.fb_size = PMU_CMD_SUBMIT_PAYLOAD_PARAMS_FB_SIZE_UNUSED;
payload.in.offset = NV_PMU_CLK_CMD_RPC_ALLOC_OFFSET;
payload.out.buf = (u8 *)&rpccall;
payload.out.size = (u32)sizeof(struct nv_pmu_clk_rpc);
payload.out.fb_size = PMU_CMD_SUBMIT_PAYLOAD_PARAMS_FB_SIZE_UNUSED;
payload.out.offset = NV_PMU_CLK_MSG_RPC_ALLOC_OFFSET;
handler.prpccall = &rpccall;
handler.success = 0;
status = gk20a_pmu_cmd_post(g, &cmd, NULL, &payload,
PMU_COMMAND_QUEUE_LPQ,
clkrpc_pmucmdhandler, (void *)&handler,
&seqdesc, ~0);
if (status) {
nvgpu_err(g, "unable to post clk RPC cmd %x",
cmd.cmd.clk.cmd_type);
goto done;
}
pmu_wait_message_cond(&g->pmu,
gk20a_get_gr_idle_timeout(g),
&handler.success, 1);
if (handler.success == 0) {
nvgpu_err(g, "rpc call to inject clock failed");
status = -EINVAL;
}
done:
return status;
}
static u32 find_regime_id(struct gk20a *g, u32 domain, u16 clkmhz)
{
struct fll_device *pflldev;
u8 j;
struct clk_pmupstate *pclk = &g->clk_pmu;
BOARDOBJGRP_FOR_EACH(&(pclk->avfs_fllobjs.super.super),
struct fll_device *, pflldev, j) {
if (pflldev->clk_domain == domain) {
if (pflldev->regime_desc.fixed_freq_regime_limit_mhz >=
clkmhz)
return CTRL_CLK_FLL_REGIME_ID_FFR;
else
return CTRL_CLK_FLL_REGIME_ID_FR;
}
}
return CTRL_CLK_FLL_REGIME_ID_INVALID;
}
static int set_regime_id(struct gk20a *g, u32 domain, u32 regimeid)
{
struct fll_device *pflldev;
u8 j;
struct clk_pmupstate *pclk = &g->clk_pmu;
BOARDOBJGRP_FOR_EACH(&(pclk->avfs_fllobjs.super.super),
struct fll_device *, pflldev, j) {
if (pflldev->clk_domain == domain) {
pflldev->regime_desc.regime_id = regimeid;
return 0;
}
}
return -EINVAL;
}
static int get_regime_id(struct gk20a *g, u32 domain, u32 *regimeid)
{
struct fll_device *pflldev;
u8 j;
struct clk_pmupstate *pclk = &g->clk_pmu;
BOARDOBJGRP_FOR_EACH(&(pclk->avfs_fllobjs.super.super),
struct fll_device *, pflldev, j) {
if (pflldev->clk_domain == domain) {
*regimeid = pflldev->regime_desc.regime_id;
return 0;
}
}
return -EINVAL;
}
int clk_set_fll_clks(struct gk20a *g, struct set_fll_clk *setfllclk)
{
int status = -EINVAL;
/*set regime ids */
status = get_regime_id(g, CTRL_CLK_DOMAIN_GPC2CLK,
&setfllclk->current_regime_id_gpc);
if (status)
goto done;
setfllclk->target_regime_id_gpc = find_regime_id(g,
CTRL_CLK_DOMAIN_GPC2CLK, setfllclk->gpc2clkmhz);
status = get_regime_id(g, CTRL_CLK_DOMAIN_SYS2CLK,
&setfllclk->current_regime_id_sys);
if (status)
goto done;
setfllclk->target_regime_id_sys = find_regime_id(g,
CTRL_CLK_DOMAIN_SYS2CLK, setfllclk->sys2clkmhz);
status = get_regime_id(g, CTRL_CLK_DOMAIN_XBAR2CLK,
&setfllclk->current_regime_id_xbar);
if (status)
goto done;
setfllclk->target_regime_id_xbar = find_regime_id(g,
CTRL_CLK_DOMAIN_XBAR2CLK, setfllclk->xbar2clkmhz);
status = clk_pmu_vf_inject(g, setfllclk);
if (status)
nvgpu_err(g, "vf inject to change clk failed");
/* save regime ids */
status = set_regime_id(g, CTRL_CLK_DOMAIN_XBAR2CLK,
setfllclk->target_regime_id_xbar);
if (status)
goto done;
status = set_regime_id(g, CTRL_CLK_DOMAIN_GPC2CLK,
setfllclk->target_regime_id_gpc);
if (status)
goto done;
status = set_regime_id(g, CTRL_CLK_DOMAIN_SYS2CLK,
setfllclk->target_regime_id_sys);
if (status)
goto done;
done:
return status;
}
int clk_get_fll_clks(struct gk20a *g, struct set_fll_clk *setfllclk)
{
int status = -EINVAL;
struct clk_domain *pdomain;
u8 i;
struct clk_pmupstate *pclk = &g->clk_pmu;
u16 clkmhz = 0;
struct clk_domain_3x_master *p3xmaster;
struct clk_domain_3x_slave *p3xslave;
unsigned long slaveidxmask;
if (setfllclk->gpc2clkmhz == 0)
return -EINVAL;
BOARDOBJGRP_FOR_EACH(&(pclk->clk_domainobjs.super.super),
struct clk_domain *, pdomain, i) {
if (pdomain->api_domain == CTRL_CLK_DOMAIN_GPC2CLK) {
if (!pdomain->super.implements(g, &pdomain->super,
CTRL_CLK_CLK_DOMAIN_TYPE_3X_MASTER)) {
status = -EINVAL;
goto done;
}
p3xmaster = (struct clk_domain_3x_master *)pdomain;
slaveidxmask = p3xmaster->slave_idxs_mask;
for_each_set_bit(i, &slaveidxmask, 32) {
p3xslave = (struct clk_domain_3x_slave *)
CLK_CLK_DOMAIN_GET(pclk, i);
if ((p3xslave->super.super.super.api_domain !=
CTRL_CLK_DOMAIN_XBAR2CLK) &&
(p3xslave->super.super.super.api_domain !=
CTRL_CLK_DOMAIN_SYS2CLK))
continue;
clkmhz = 0;
status = p3xslave->clkdomainclkgetslaveclk(g,
pclk,
(struct clk_domain *)p3xslave,
&clkmhz,
setfllclk->gpc2clkmhz);
if (status) {
status = -EINVAL;
goto done;
}
if (p3xslave->super.super.super.api_domain ==
CTRL_CLK_DOMAIN_XBAR2CLK)
setfllclk->xbar2clkmhz = clkmhz;
if (p3xslave->super.super.super.api_domain ==
CTRL_CLK_DOMAIN_SYS2CLK)
setfllclk->sys2clkmhz = clkmhz;
}
}
}
done:
return status;
}
u32 clk_domain_print_vf_table(struct gk20a *g, u32 clkapidomain)
{
u32 status = -EINVAL;
struct clk_domain *pdomain;
u8 i;
struct clk_pmupstate *pclk = &g->clk_pmu;
u16 clkmhz = 0;
u32 volt = 0;
BOARDOBJGRP_FOR_EACH(&(pclk->clk_domainobjs.super.super),
struct clk_domain *, pdomain, i) {
if (pdomain->api_domain == clkapidomain) {
status = pdomain->clkdomainclkvfsearch(g, pclk,
pdomain, &clkmhz, &volt,
CLK_PROG_VFE_ENTRY_LOGIC);
status = pdomain->clkdomainclkvfsearch(g, pclk,
pdomain, &clkmhz, &volt,
CLK_PROG_VFE_ENTRY_SRAM);
}
}
return status;
}
u32 clk_domain_get_f_or_v(
struct gk20a *g,
u32 clkapidomain,
u16 *pclkmhz,
u32 *pvoltuv,
u8 railidx
)
{
u32 status = -EINVAL;
struct clk_domain *pdomain;
u8 i;
struct clk_pmupstate *pclk = &g->clk_pmu;
u8 rail;
if ((pclkmhz == NULL) || (pvoltuv == NULL))
return -EINVAL;
if (railidx == CTRL_VOLT_DOMAIN_LOGIC)
rail = CLK_PROG_VFE_ENTRY_LOGIC;
else if (railidx == CTRL_VOLT_DOMAIN_SRAM)
rail = CLK_PROG_VFE_ENTRY_SRAM;
else
return -EINVAL;
BOARDOBJGRP_FOR_EACH(&(pclk->clk_domainobjs.super.super),
struct clk_domain *, pdomain, i) {
if (pdomain->api_domain == clkapidomain) {
status = pdomain->clkdomainclkvfsearch(g, pclk,
pdomain, pclkmhz, pvoltuv, rail);
return status;
}
}
return status;
}
u32 clk_domain_get_f_points(
struct gk20a *g,
u32 clkapidomain,
u32 *pfpointscount,
u16 *pfreqpointsinmhz
)
{
u32 status = -EINVAL;
struct clk_domain *pdomain;
u8 i;
struct clk_pmupstate *pclk = &g->clk_pmu;
if (pfpointscount == NULL)
return -EINVAL;
if ((pfreqpointsinmhz == NULL) && (*pfpointscount != 0))
return -EINVAL;
BOARDOBJGRP_FOR_EACH(&(pclk->clk_domainobjs.super.super),
struct clk_domain *, pdomain, i) {
if (pdomain->api_domain == clkapidomain) {
status = pdomain->clkdomainclkgetfpoints(g, pclk,
pdomain, pfpointscount,
pfreqpointsinmhz,
CLK_PROG_VFE_ENTRY_LOGIC);
return status;
}
}
return status;
}