/*
* Copyright 2008-2012 Freescale Semiconductor Inc.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of Freescale Semiconductor nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
*
* ALTERNATIVELY, this software may be distributed under the terms of the
* GNU General Public License ("GPL") as published by the Free Software
* Foundation, either version 2 of that License or (at your option) any
* later version.
*
* THIS SOFTWARE IS PROVIDED BY Freescale Semiconductor ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL Freescale Semiconductor BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <linux/math64.h>
#include "fsl_fman.h"
#include "dpaa_integration_ext.h"
uint32_t fman_get_bmi_err_event(struct fman_bmi_regs *bmi_rg)
{
uint32_t event, mask, force;
event = ioread32be(&bmi_rg->fmbm_ievr);
mask = ioread32be(&bmi_rg->fmbm_ier);
event &= mask;
/* clear the forced events */
force = ioread32be(&bmi_rg->fmbm_ifr);
if (force & event)
iowrite32be(force & ~event, &bmi_rg->fmbm_ifr);
/* clear the acknowledged events */
iowrite32be(event, &bmi_rg->fmbm_ievr);
return event;
}
uint32_t fman_get_qmi_err_event(struct fman_qmi_regs *qmi_rg)
{
uint32_t event, mask, force;
event = ioread32be(&qmi_rg->fmqm_eie);
mask = ioread32be(&qmi_rg->fmqm_eien);
event &= mask;
/* clear the forced events */
force = ioread32be(&qmi_rg->fmqm_eif);
if (force & event)
iowrite32be(force & ~event, &qmi_rg->fmqm_eif);
/* clear the acknowledged events */
iowrite32be(event, &qmi_rg->fmqm_eie);
return event;
}
uint32_t fman_get_dma_com_id(struct fman_dma_regs *dma_rg)
{
return ioread32be(&dma_rg->fmdmtcid);
}
uint64_t fman_get_dma_addr(struct fman_dma_regs *dma_rg)
{
uint64_t addr;
addr = (uint64_t)ioread32be(&dma_rg->fmdmtal);
addr |= ((uint64_t)(ioread32be(&dma_rg->fmdmtah)) << 32);
return addr;
}
uint32_t fman_get_dma_err_event(struct fman_dma_regs *dma_rg)
{
uint32_t status, mask;
status = ioread32be(&dma_rg->fmdmsr);
mask = ioread32be(&dma_rg->fmdmmr);
/* clear DMA_STATUS_BUS_ERR if mask has no DMA_MODE_BER */
if ((mask & DMA_MODE_BER) != DMA_MODE_BER)
status &= ~DMA_STATUS_BUS_ERR;
/* clear relevant bits if mask has no DMA_MODE_ECC */
if ((mask & DMA_MODE_ECC) != DMA_MODE_ECC)
status &= ~(DMA_STATUS_FM_SPDAT_ECC |
DMA_STATUS_READ_ECC |
DMA_STATUS_SYSTEM_WRITE_ECC |
DMA_STATUS_FM_WRITE_ECC);
/* clear set events */
iowrite32be(status, &dma_rg->fmdmsr);
return status;
}
uint32_t fman_get_fpm_err_event(struct fman_fpm_regs *fpm_rg)
{
uint32_t event;
event = ioread32be(&fpm_rg->fmfp_ee);
/* clear the all occurred events */
iowrite32be(event, &fpm_rg->fmfp_ee);
return event;
}
uint32_t fman_get_muram_err_event(struct fman_fpm_regs *fpm_rg)
{
uint32_t event, mask;
event = ioread32be(&fpm_rg->fm_rcr);
mask = ioread32be(&fpm_rg->fm_rie);
/* clear MURAM event bit (do not clear IRAM event) */
iowrite32be(event & ~FPM_RAM_IRAM_ECC, &fpm_rg->fm_rcr);
if ((mask & FPM_MURAM_ECC_ERR_EX_EN))
return event;
else
return 0;
}
uint32_t fman_get_iram_err_event(struct fman_fpm_regs *fpm_rg)
{
uint32_t event, mask;
event = ioread32be(&fpm_rg->fm_rcr) ;
mask = ioread32be(&fpm_rg->fm_rie);
/* clear IRAM event bit (do not clear MURAM event) */
iowrite32be(event & ~FPM_RAM_MURAM_ECC,
&fpm_rg->fm_rcr);
if ((mask & FPM_IRAM_ECC_ERR_EX_EN))
return event;
else
return 0;
}
uint32_t fman_get_qmi_event(struct fman_qmi_regs *qmi_rg)
{
uint32_t event, mask, force;
event = ioread32be(&qmi_rg->fmqm_ie);
mask = ioread32be(&qmi_rg->fmqm_ien);
event &= mask;
/* clear the forced events */
force = ioread32be(&qmi_rg->fmqm_if);
if (force & event)
iowrite32be(force & ~event, &qmi_rg->fmqm_if);
/* clear the acknowledged events */
iowrite32be(event, &qmi_rg->fmqm_ie);
return event;
}
void fman_enable_time_stamp(struct fman_fpm_regs *fpm_rg,
uint8_t count1ubit,
uint16_t fm_clk_freq)
{
uint32_t tmp;
uint64_t frac;
uint32_t intgr;
uint32_t ts_freq = (uint32_t)(1 << count1ubit); /* in Mhz */
/* configure timestamp so that bit 8 will count 1 microsecond
* Find effective count rate at TIMESTAMP least significant bits:
* Effective_Count_Rate = 1MHz x 2^8 = 256MHz
* Find frequency ratio between effective count rate and the clock:
* Effective_Count_Rate / CLK e.g. for 600 MHz clock:
* 256/600 = 0.4266666... */
intgr = ts_freq / fm_clk_freq;
/* we multiply by 2^16 to keep the fraction of the division
* we do not div back, since we write this value as a fraction
* see spec */
frac = ((uint64_t)ts_freq << 16) - ((uint64_t)intgr << 16) * fm_clk_freq;
/* we check remainder of the division in order to round up if not int */
if (do_div(frac, fm_clk_freq))
frac++;
tmp = (intgr << FPM_TS_INT_SHIFT) | (uint16_t)frac;
iowrite32be(tmp, &fpm_rg->fmfp_tsc2);
/* enable timestamp with original clock */
iowrite32be(FPM_TS_CTL_EN, &fpm_rg->fmfp_tsc1);
}
uint32_t fman_get_fpm_error_interrupts(struct fman_fpm_regs *fpm_rg)
{
return ioread32be(&fpm_rg->fm_epi);
}
int fman_set_erratum_10gmac_a004_wa(struct fman_fpm_regs *fpm_rg)
{
int timeout = 100;
iowrite32be(0x40000000, &fpm_rg->fmfp_extc);
while ((ioread32be(&fpm_rg->fmfp_extc) & 0x40000000) && --timeout)
DELAY(10);
if (!timeout)
return -EBUSY;
return 0;
}
void fman_set_ctrl_intr(struct fman_fpm_regs *fpm_rg,
uint8_t event_reg_id,
uint32_t enable_events)
{
iowrite32be(enable_events, &fpm_rg->fmfp_cee[event_reg_id]);
}
uint32_t fman_get_ctrl_intr(struct fman_fpm_regs *fpm_rg, uint8_t event_reg_id)
{
return ioread32be(&fpm_rg->fmfp_cee[event_reg_id]);
}
void fman_set_num_of_riscs_per_port(struct fman_fpm_regs *fpm_rg,
uint8_t port_id,
uint8_t num_fman_ctrls,
uint32_t or_fman_ctrl)
{
uint32_t tmp = 0;
tmp = (uint32_t)(port_id << FPM_PORT_FM_CTL_PORTID_SHIFT);
/*TODO - maybe to put CTL# according to another criteria*/
if (num_fman_ctrls == 2)
tmp = FPM_PRT_FM_CTL2 | FPM_PRT_FM_CTL1;
/* order restoration */
tmp |= (or_fman_ctrl << FPM_PRC_ORA_FM_CTL_SEL_SHIFT) | or_fman_ctrl;
iowrite32be(tmp, &fpm_rg->fmfp_prc);
}
void fman_set_order_restoration_per_port(struct fman_fpm_regs *fpm_rg,
uint8_t port_id,
bool independent_mode,
bool is_rx_port)
{
uint32_t tmp = 0;
tmp = (uint32_t)(port_id << FPM_PORT_FM_CTL_PORTID_SHIFT);
if (independent_mode) {
if (is_rx_port)
tmp |= (FPM_PRT_FM_CTL1 <<
FPM_PRC_ORA_FM_CTL_SEL_SHIFT) | FPM_PRT_FM_CTL1;
else
tmp |= (FPM_PRT_FM_CTL2 <<
FPM_PRC_ORA_FM_CTL_SEL_SHIFT) | FPM_PRT_FM_CTL2;
} else {
tmp |= (FPM_PRT_FM_CTL2|FPM_PRT_FM_CTL1);
/* order restoration */
if (port_id % 2)
tmp |= (FPM_PRT_FM_CTL1 <<
FPM_PRC_ORA_FM_CTL_SEL_SHIFT);
else
tmp |= (FPM_PRT_FM_CTL2 <<
FPM_PRC_ORA_FM_CTL_SEL_SHIFT);
}
iowrite32be(tmp, &fpm_rg->fmfp_prc);
}
uint8_t fman_get_qmi_deq_th(struct fman_qmi_regs *qmi_rg)
{
return (uint8_t)ioread32be(&qmi_rg->fmqm_gc);
}
uint8_t fman_get_qmi_enq_th(struct fman_qmi_regs *qmi_rg)
{
return (uint8_t)(ioread32be(&qmi_rg->fmqm_gc) >> 8);
}
void fman_set_qmi_enq_th(struct fman_qmi_regs *qmi_rg, uint8_t val)
{
uint32_t tmp_reg;
tmp_reg = ioread32be(&qmi_rg->fmqm_gc);
tmp_reg &= ~QMI_CFG_ENQ_MASK;
tmp_reg |= ((uint32_t)val << 8);
iowrite32be(tmp_reg, &qmi_rg->fmqm_gc);
}
void fman_set_qmi_deq_th(struct fman_qmi_regs *qmi_rg, uint8_t val)
{
uint32_t tmp_reg;
tmp_reg = ioread32be(&qmi_rg->fmqm_gc);
tmp_reg &= ~QMI_CFG_DEQ_MASK;
tmp_reg |= (uint32_t)val;
iowrite32be(tmp_reg, &qmi_rg->fmqm_gc);
}
void fman_qmi_disable_dispatch_limit(struct fman_fpm_regs *fpm_rg)
{
iowrite32be(0, &fpm_rg->fmfp_mxd);
}
void fman_set_liodn_per_port(struct fman_rg *fman_rg, uint8_t port_id,
uint16_t liodn_base,
uint16_t liodn_ofst)
{
uint32_t tmp;
if ((port_id > 63) || (port_id < 1))
return;
/* set LIODN base for this port */
tmp = ioread32be(&fman_rg->dma_rg->fmdmplr[port_id / 2]);
if (port_id % 2) {
tmp &= ~FM_LIODN_BASE_MASK;
tmp |= (uint32_t)liodn_base;
} else {
tmp &= ~(FM_LIODN_BASE_MASK << DMA_LIODN_SHIFT);
tmp |= (uint32_t)liodn_base << DMA_LIODN_SHIFT;
}
iowrite32be(tmp, &fman_rg->dma_rg->fmdmplr[port_id / 2]);
iowrite32be((uint32_t)liodn_ofst,
&fman_rg->bmi_rg->fmbm_spliodn[port_id - 1]);
}
bool fman_is_port_stalled(struct fman_fpm_regs *fpm_rg, uint8_t port_id)
{
return (bool)!!(ioread32be(&fpm_rg->fmfp_ps[port_id]) & FPM_PS_STALLED);
}
void fman_resume_stalled_port(struct fman_fpm_regs *fpm_rg, uint8_t port_id)
{
uint32_t tmp;
tmp = (uint32_t)((port_id << FPM_PORT_FM_CTL_PORTID_SHIFT) |
FPM_PRC_REALSE_STALLED);
iowrite32be(tmp, &fpm_rg->fmfp_prc);
}
int fman_reset_mac(struct fman_fpm_regs *fpm_rg, uint8_t mac_id, bool is_10g)
{
uint32_t msk, timeout = 100;
/* Get the relevant bit mask */
if (is_10g) {
switch (mac_id) {
case(0):
msk = FPM_RSTC_10G0_RESET;
break;
case(1):
msk = FPM_RSTC_10G1_RESET;
break;
default:
return -EINVAL;
}
} else {
switch (mac_id) {
case(0):
msk = FPM_RSTC_1G0_RESET;
break;
case(1):
msk = FPM_RSTC_1G1_RESET;
break;
case(2):
msk = FPM_RSTC_1G2_RESET;
break;
case(3):
msk = FPM_RSTC_1G3_RESET;
break;
case(4):
msk = FPM_RSTC_1G4_RESET;
break;
case (5):
msk = FPM_RSTC_1G5_RESET;
break;
case (6):
msk = FPM_RSTC_1G6_RESET;
break;
case (7):
msk = FPM_RSTC_1G7_RESET;
break;
default:
return -EINVAL;
}
}
/* reset */
iowrite32be(msk, &fpm_rg->fm_rstc);
while ((ioread32be(&fpm_rg->fm_rstc) & msk) && --timeout)
DELAY(10);
if (!timeout)
return -EBUSY;
return 0;
}
uint16_t fman_get_size_of_fifo(struct fman_bmi_regs *bmi_rg, uint8_t port_id)
{
uint32_t tmp_reg;
if ((port_id > 63) || (port_id < 1))
return 0;
tmp_reg = ioread32be(&bmi_rg->fmbm_pfs[port_id - 1]);
return (uint16_t)((tmp_reg & BMI_FIFO_SIZE_MASK) + 1);
}
uint32_t fman_get_total_fifo_size(struct fman_bmi_regs *bmi_rg)
{
uint32_t reg, res;
reg = ioread32be(&bmi_rg->fmbm_cfg1);
res = (reg >> BMI_CFG1_FIFO_SIZE_SHIFT) & 0x3ff;
return res * FMAN_BMI_FIFO_UNITS;
}
uint16_t fman_get_size_of_extra_fifo(struct fman_bmi_regs *bmi_rg,
uint8_t port_id)
{
uint32_t tmp_reg;
if ((port_id > 63) || (port_id < 1))
return 0;
tmp_reg = ioread32be(&bmi_rg->fmbm_pfs[port_id-1]);
return (uint16_t)((tmp_reg & BMI_EXTRA_FIFO_SIZE_MASK) >>
BMI_EXTRA_FIFO_SIZE_SHIFT);
}
void fman_set_size_of_fifo(struct fman_bmi_regs *bmi_rg,
uint8_t port_id,
uint32_t sz_fifo,
uint32_t extra_sz_fifo)
{
uint32_t tmp;
if ((port_id > 63) || (port_id < 1))
return;
/* calculate reg */
tmp = (uint32_t)((sz_fifo / FMAN_BMI_FIFO_UNITS - 1) |
((extra_sz_fifo / FMAN_BMI_FIFO_UNITS) <<
BMI_EXTRA_FIFO_SIZE_SHIFT));
iowrite32be(tmp, &bmi_rg->fmbm_pfs[port_id - 1]);
}
uint8_t fman_get_num_of_tasks(struct fman_bmi_regs *bmi_rg, uint8_t port_id)
{
uint32_t tmp;
if ((port_id > 63) || (port_id < 1))
return 0;
tmp = ioread32be(&bmi_rg->fmbm_pp[port_id - 1]);
return (uint8_t)(((tmp & BMI_NUM_OF_TASKS_MASK) >>
BMI_NUM_OF_TASKS_SHIFT) + 1);
}
uint8_t fman_get_num_extra_tasks(struct fman_bmi_regs *bmi_rg, uint8_t port_id)
{
uint32_t tmp;
if ((port_id > 63) || (port_id < 1))
return 0;
tmp = ioread32be(&bmi_rg->fmbm_pp[port_id - 1]);
return (uint8_t)((tmp & BMI_NUM_OF_EXTRA_TASKS_MASK) >>
BMI_EXTRA_NUM_OF_TASKS_SHIFT);
}
void fman_set_num_of_tasks(struct fman_bmi_regs *bmi_rg,
uint8_t port_id,
uint8_t num_tasks,
uint8_t num_extra_tasks)
{
uint32_t tmp;
if ((port_id > 63) || (port_id < 1))
return;
/* calculate reg */
tmp = ioread32be(&bmi_rg->fmbm_pp[port_id - 1]) &
~(BMI_NUM_OF_TASKS_MASK | BMI_NUM_OF_EXTRA_TASKS_MASK);
tmp |= (uint32_t)(((num_tasks - 1) << BMI_NUM_OF_TASKS_SHIFT) |
(num_extra_tasks << BMI_EXTRA_NUM_OF_TASKS_SHIFT));
iowrite32be(tmp, &bmi_rg->fmbm_pp[port_id - 1]);
}
uint8_t fman_get_num_of_dmas(struct fman_bmi_regs *bmi_rg, uint8_t port_id)
{
uint32_t tmp;
if ((port_id > 63) || (port_id < 1))
return 0;
tmp = ioread32be(&bmi_rg->fmbm_pp[port_id - 1]);
return (uint8_t)(((tmp & BMI_NUM_OF_DMAS_MASK) >>
BMI_NUM_OF_DMAS_SHIFT) + 1);
}
uint8_t fman_get_num_extra_dmas(struct fman_bmi_regs *bmi_rg, uint8_t port_id)
{
uint32_t tmp;
if ((port_id > 63) || (port_id < 1))
return 0;
tmp = ioread32be(&bmi_rg->fmbm_pp[port_id - 1]);
return (uint8_t)((tmp & BMI_NUM_OF_EXTRA_DMAS_MASK) >>
BMI_EXTRA_NUM_OF_DMAS_SHIFT);
}
void fman_set_num_of_open_dmas(struct fman_bmi_regs *bmi_rg,
uint8_t port_id,
uint8_t num_open_dmas,
uint8_t num_extra_open_dmas,
uint8_t total_num_dmas)
{
uint32_t tmp = 0;
if ((port_id > 63) || (port_id < 1))
return;
/* calculate reg */
tmp = ioread32be(&bmi_rg->fmbm_pp[port_id - 1]) &
~(BMI_NUM_OF_DMAS_MASK | BMI_NUM_OF_EXTRA_DMAS_MASK);
tmp |= (uint32_t)(((num_open_dmas-1) << BMI_NUM_OF_DMAS_SHIFT) |
(num_extra_open_dmas << BMI_EXTRA_NUM_OF_DMAS_SHIFT));
iowrite32be(tmp, &bmi_rg->fmbm_pp[port_id - 1]);
/* update total num of DMA's with committed number of open DMAS,
* and max uncommitted pool. */
if (total_num_dmas)
{
tmp = ioread32be(&bmi_rg->fmbm_cfg2) & ~BMI_CFG2_DMAS_MASK;
tmp |= (uint32_t)(total_num_dmas - 1) << BMI_CFG2_DMAS_SHIFT;
iowrite32be(tmp, &bmi_rg->fmbm_cfg2);
}
}
void fman_set_vsp_window(struct fman_bmi_regs *bmi_rg,
uint8_t port_id,
uint8_t base_storage_profile,
uint8_t log2_num_of_profiles)
{
uint32_t tmp = 0;
if ((port_id > 63) || (port_id < 1))
return;
tmp = ioread32be(&bmi_rg->fmbm_spliodn[port_id-1]);
tmp |= (uint32_t)((uint32_t)base_storage_profile & 0x3f) << 16;
tmp |= (uint32_t)log2_num_of_profiles << 28;
iowrite32be(tmp, &bmi_rg->fmbm_spliodn[port_id-1]);
}
void fman_set_congestion_group_pfc_priority(uint32_t *cpg_rg,
uint32_t congestion_group_id,
uint8_t priority_bit_map,
uint32_t reg_num)
{
uint32_t offset, tmp = 0;
offset = (congestion_group_id%4)*8;
tmp = ioread32be(&cpg_rg[reg_num]);
tmp &= ~(0xFF<<offset);
tmp |= (uint32_t)priority_bit_map << offset;
iowrite32be(tmp,&cpg_rg[reg_num]);
}
/*****************************************************************************/
/* API Init unit functions */
/*****************************************************************************/
void fman_defconfig(struct fman_cfg *cfg, bool is_master)
{
memset(cfg, 0, sizeof(struct fman_cfg));
cfg->catastrophic_err = DEFAULT_CATASTROPHIC_ERR;
cfg->dma_err = DEFAULT_DMA_ERR;
cfg->halt_on_external_activ = DEFAULT_HALT_ON_EXTERNAL_ACTIVATION;
cfg->halt_on_unrecov_ecc_err = DEFAULT_HALT_ON_UNRECOVERABLE_ECC_ERROR;
cfg->en_iram_test_mode = FALSE;
cfg->en_muram_test_mode = FALSE;
cfg->external_ecc_rams_enable = DEFAULT_EXTERNAL_ECC_RAMS_ENABLE;
if (!is_master)
return;
cfg->dma_aid_override = DEFAULT_AID_OVERRIDE;
cfg->dma_aid_mode = DEFAULT_AID_MODE;
cfg->dma_comm_qtsh_clr_emer = DEFAULT_DMA_COMM_Q_LOW;
cfg->dma_comm_qtsh_asrt_emer = DEFAULT_DMA_COMM_Q_HIGH;
cfg->dma_cache_override = DEFAULT_CACHE_OVERRIDE;
cfg->dma_cam_num_of_entries = DEFAULT_DMA_CAM_NUM_OF_ENTRIES;
cfg->dma_dbg_cnt_mode = DEFAULT_DMA_DBG_CNT_MODE;
cfg->dma_en_emergency = DEFAULT_DMA_EN_EMERGENCY;
cfg->dma_sos_emergency = DEFAULT_DMA_SOS_EMERGENCY;
cfg->dma_watchdog = DEFAULT_DMA_WATCHDOG;
cfg->dma_en_emergency_smoother = DEFAULT_DMA_EN_EMERGENCY_SMOOTHER;
cfg->dma_emergency_switch_counter = DEFAULT_DMA_EMERGENCY_SWITCH_COUNTER;
cfg->disp_limit_tsh = DEFAULT_DISP_LIMIT;
cfg->prs_disp_tsh = DEFAULT_PRS_DISP_TH;
cfg->plcr_disp_tsh = DEFAULT_PLCR_DISP_TH;
cfg->kg_disp_tsh = DEFAULT_KG_DISP_TH;
cfg->bmi_disp_tsh = DEFAULT_BMI_DISP_TH;
cfg->qmi_enq_disp_tsh = DEFAULT_QMI_ENQ_DISP_TH;
cfg->qmi_deq_disp_tsh = DEFAULT_QMI_DEQ_DISP_TH;
cfg->fm_ctl1_disp_tsh = DEFAULT_FM_CTL1_DISP_TH;
cfg->fm_ctl2_disp_tsh = DEFAULT_FM_CTL2_DISP_TH;
cfg->pedantic_dma = FALSE;
cfg->tnum_aging_period = DEFAULT_TNUM_AGING_PERIOD;
cfg->dma_stop_on_bus_error = FALSE;
cfg->qmi_deq_option_support = FALSE;
}
void fman_regconfig(struct fman_rg *fman_rg, struct fman_cfg *cfg)
{
uint32_t tmp_reg;
/* read the values from the registers as they are initialized by the HW with
* the required values.
*/
tmp_reg = ioread32be(&fman_rg->bmi_rg->fmbm_cfg1);
cfg->total_fifo_size =
(((tmp_reg & BMI_TOTAL_FIFO_SIZE_MASK) >> BMI_CFG1_FIFO_SIZE_SHIFT) + 1) * FMAN_BMI_FIFO_UNITS;
tmp_reg = ioread32be(&fman_rg->bmi_rg->fmbm_cfg2);
cfg->total_num_of_tasks =
(uint8_t)(((tmp_reg & BMI_TOTAL_NUM_OF_TASKS_MASK) >> BMI_CFG2_TASKS_SHIFT) + 1);
tmp_reg = ioread32be(&fman_rg->dma_rg->fmdmtr);
cfg->dma_comm_qtsh_asrt_emer = (uint8_t)(tmp_reg >> DMA_THRESH_COMMQ_SHIFT);
tmp_reg = ioread32be(&fman_rg->dma_rg->fmdmhy);
cfg->dma_comm_qtsh_clr_emer = (uint8_t)(tmp_reg >> DMA_THRESH_COMMQ_SHIFT);
tmp_reg = ioread32be(&fman_rg->dma_rg->fmdmmr);
cfg->dma_cache_override = (enum fman_dma_cache_override)((tmp_reg & DMA_MODE_CACHE_OR_MASK) >> DMA_MODE_CACHE_OR_SHIFT);
cfg->dma_cam_num_of_entries = (uint8_t)((((tmp_reg & DMA_MODE_CEN_MASK) >> DMA_MODE_CEN_SHIFT) +1)*DMA_CAM_UNITS);
cfg->dma_aid_override = (bool)((tmp_reg & DMA_MODE_AID_OR)? TRUE:FALSE);
cfg->dma_dbg_cnt_mode = (enum fman_dma_dbg_cnt_mode)((tmp_reg & DMA_MODE_DBG_MASK) >> DMA_MODE_DBG_SHIFT);
cfg->dma_en_emergency = (bool)((tmp_reg & DMA_MODE_EB)? TRUE : FALSE);
tmp_reg = ioread32be(&fman_rg->fpm_rg->fmfp_mxd);
cfg->disp_limit_tsh = (uint8_t)((tmp_reg & FPM_DISP_LIMIT_MASK) >> FPM_DISP_LIMIT_SHIFT);
tmp_reg = ioread32be(&fman_rg->fpm_rg->fmfp_dist1);
cfg->prs_disp_tsh = (uint8_t)((tmp_reg & FPM_THR1_PRS_MASK ) >> FPM_THR1_PRS_SHIFT);
cfg->plcr_disp_tsh = (uint8_t)((tmp_reg & FPM_THR1_KG_MASK ) >> FPM_THR1_KG_SHIFT);
cfg->kg_disp_tsh = (uint8_t)((tmp_reg & FPM_THR1_PLCR_MASK ) >> FPM_THR1_PLCR_SHIFT);
cfg->bmi_disp_tsh = (uint8_t)((tmp_reg & FPM_THR1_BMI_MASK ) >> FPM_THR1_BMI_SHIFT);
tmp_reg = ioread32be(&fman_rg->fpm_rg->fmfp_dist2);
cfg->qmi_enq_disp_tsh = (uint8_t)((tmp_reg & FPM_THR2_QMI_ENQ_MASK ) >> FPM_THR2_QMI_ENQ_SHIFT);
cfg->qmi_deq_disp_tsh = (uint8_t)((tmp_reg & FPM_THR2_QMI_DEQ_MASK ) >> FPM_THR2_QMI_DEQ_SHIFT);
cfg->fm_ctl1_disp_tsh = (uint8_t)((tmp_reg & FPM_THR2_FM_CTL1_MASK ) >> FPM_THR2_FM_CTL1_SHIFT);
cfg->fm_ctl2_disp_tsh = (uint8_t)((tmp_reg & FPM_THR2_FM_CTL2_MASK ) >> FPM_THR2_FM_CTL2_SHIFT);
tmp_reg = ioread32be(&fman_rg->dma_rg->fmdmsetr);
cfg->dma_sos_emergency = tmp_reg;
tmp_reg = ioread32be(&fman_rg->dma_rg->fmdmwcr);
cfg->dma_watchdog = tmp_reg/cfg->clk_freq;
tmp_reg = ioread32be(&fman_rg->dma_rg->fmdmemsr);
cfg->dma_en_emergency_smoother = (bool)((tmp_reg & DMA_EMSR_EMSTR_MASK)? TRUE : FALSE);
cfg->dma_emergency_switch_counter = (tmp_reg & DMA_EMSR_EMSTR_MASK);
}
void fman_reset(struct fman_fpm_regs *fpm_rg)
{
iowrite32be(FPM_RSTC_FM_RESET, &fpm_rg->fm_rstc);
}
/**************************************************************************//**
@Function FM_Init
@Description Initializes the FM module
@Param[in] h_Fm - FM module descriptor
@Return E_OK on success; Error code otherwise.
*//***************************************************************************/
int fman_dma_init(struct fman_dma_regs *dma_rg, struct fman_cfg *cfg)
{
uint32_t tmp_reg;
/**********************/
/* Init DMA Registers */
/**********************/
/* clear status reg events */
/* oren - check!!! */
tmp_reg = (DMA_STATUS_BUS_ERR | DMA_STATUS_READ_ECC |
DMA_STATUS_SYSTEM_WRITE_ECC | DMA_STATUS_FM_WRITE_ECC);
iowrite32be(ioread32be(&dma_rg->fmdmsr) | tmp_reg,
&dma_rg->fmdmsr);
/* configure mode register */
tmp_reg = 0;
tmp_reg |= cfg->dma_cache_override << DMA_MODE_CACHE_OR_SHIFT;
if (cfg->dma_aid_override)
tmp_reg |= DMA_MODE_AID_OR;
if (cfg->exceptions & FMAN_EX_DMA_BUS_ERROR)
tmp_reg |= DMA_MODE_BER;
if ((cfg->exceptions & FMAN_EX_DMA_SYSTEM_WRITE_ECC) |
(cfg->exceptions & FMAN_EX_DMA_READ_ECC) |
(cfg->exceptions & FMAN_EX_DMA_FM_WRITE_ECC))
tmp_reg |= DMA_MODE_ECC;
if (cfg->dma_stop_on_bus_error)
tmp_reg |= DMA_MODE_SBER;
if(cfg->dma_axi_dbg_num_of_beats)
tmp_reg |= (uint32_t)(DMA_MODE_AXI_DBG_MASK &
((cfg->dma_axi_dbg_num_of_beats - 1) << DMA_MODE_AXI_DBG_SHIFT));
if (cfg->dma_en_emergency) {
tmp_reg |= cfg->dma_emergency_bus_select;
tmp_reg |= cfg->dma_emergency_level << DMA_MODE_EMER_LVL_SHIFT;
if (cfg->dma_en_emergency_smoother)
iowrite32be(cfg->dma_emergency_switch_counter,
&dma_rg->fmdmemsr);
}
tmp_reg |= ((cfg->dma_cam_num_of_entries / DMA_CAM_UNITS) - 1) <<
DMA_MODE_CEN_SHIFT;
tmp_reg |= DMA_MODE_SECURE_PROT;
tmp_reg |= cfg->dma_dbg_cnt_mode << DMA_MODE_DBG_SHIFT;
tmp_reg |= cfg->dma_aid_mode << DMA_MODE_AID_MODE_SHIFT;
if (cfg->pedantic_dma)
tmp_reg |= DMA_MODE_EMER_READ;
iowrite32be(tmp_reg, &dma_rg->fmdmmr);
/* configure thresholds register */
tmp_reg = ((uint32_t)cfg->dma_comm_qtsh_asrt_emer <<
DMA_THRESH_COMMQ_SHIFT) |
((uint32_t)cfg->dma_read_buf_tsh_asrt_emer <<
DMA_THRESH_READ_INT_BUF_SHIFT) |
((uint32_t)cfg->dma_write_buf_tsh_asrt_emer);
iowrite32be(tmp_reg, &dma_rg->fmdmtr);
/* configure hysteresis register */
tmp_reg = ((uint32_t)cfg->dma_comm_qtsh_clr_emer <<
DMA_THRESH_COMMQ_SHIFT) |
((uint32_t)cfg->dma_read_buf_tsh_clr_emer <<
DMA_THRESH_READ_INT_BUF_SHIFT) |
((uint32_t)cfg->dma_write_buf_tsh_clr_emer);
iowrite32be(tmp_reg, &dma_rg->fmdmhy);
/* configure emergency threshold */
iowrite32be(cfg->dma_sos_emergency, &dma_rg->fmdmsetr);
/* configure Watchdog */
iowrite32be((cfg->dma_watchdog * cfg->clk_freq),
&dma_rg->fmdmwcr);
iowrite32be(cfg->cam_base_addr, &dma_rg->fmdmebcr);
return 0;
}
int fman_fpm_init(struct fman_fpm_regs *fpm_rg, struct fman_cfg *cfg)
{
uint32_t tmp_reg;
int i;
/**********************/
/* Init FPM Registers */
/**********************/
tmp_reg = (uint32_t)(cfg->disp_limit_tsh << FPM_DISP_LIMIT_SHIFT);
iowrite32be(tmp_reg, &fpm_rg->fmfp_mxd);
tmp_reg = (((uint32_t)cfg->prs_disp_tsh << FPM_THR1_PRS_SHIFT) |
((uint32_t)cfg->kg_disp_tsh << FPM_THR1_KG_SHIFT) |
((uint32_t)cfg->plcr_disp_tsh << FPM_THR1_PLCR_SHIFT) |
((uint32_t)cfg->bmi_disp_tsh << FPM_THR1_BMI_SHIFT));
iowrite32be(tmp_reg, &fpm_rg->fmfp_dist1);
tmp_reg = (((uint32_t)cfg->qmi_enq_disp_tsh << FPM_THR2_QMI_ENQ_SHIFT) |
((uint32_t)cfg->qmi_deq_disp_tsh << FPM_THR2_QMI_DEQ_SHIFT) |
((uint32_t)cfg->fm_ctl1_disp_tsh << FPM_THR2_FM_CTL1_SHIFT) |
((uint32_t)cfg->fm_ctl2_disp_tsh << FPM_THR2_FM_CTL2_SHIFT));
iowrite32be(tmp_reg, &fpm_rg->fmfp_dist2);
/* define exceptions and error behavior */
tmp_reg = 0;
/* Clear events */
tmp_reg |= (FPM_EV_MASK_STALL | FPM_EV_MASK_DOUBLE_ECC |
FPM_EV_MASK_SINGLE_ECC);
/* enable interrupts */
if (cfg->exceptions & FMAN_EX_FPM_STALL_ON_TASKS)
tmp_reg |= FPM_EV_MASK_STALL_EN;
if (cfg->exceptions & FMAN_EX_FPM_SINGLE_ECC)
tmp_reg |= FPM_EV_MASK_SINGLE_ECC_EN;
if (cfg->exceptions & FMAN_EX_FPM_DOUBLE_ECC)
tmp_reg |= FPM_EV_MASK_DOUBLE_ECC_EN;
tmp_reg |= (cfg->catastrophic_err << FPM_EV_MASK_CAT_ERR_SHIFT);
tmp_reg |= (cfg->dma_err << FPM_EV_MASK_DMA_ERR_SHIFT);
if (!cfg->halt_on_external_activ)
tmp_reg |= FPM_EV_MASK_EXTERNAL_HALT;
if (!cfg->halt_on_unrecov_ecc_err)
tmp_reg |= FPM_EV_MASK_ECC_ERR_HALT;
iowrite32be(tmp_reg, &fpm_rg->fmfp_ee);
/* clear all fmCtls event registers */
for (i = 0; i < cfg->num_of_fman_ctrl_evnt_regs; i++)
iowrite32be(0xFFFFFFFF, &fpm_rg->fmfp_cev[i]);
/* RAM ECC - enable and clear events*/
/* first we need to clear all parser memory,
* as it is uninitialized and may cause ECC errors */
/* event bits */
tmp_reg = (FPM_RAM_MURAM_ECC | FPM_RAM_IRAM_ECC);
/* Rams enable not effected by RCR bit, but by a COP configuration */
if (cfg->external_ecc_rams_enable)
tmp_reg |= FPM_RAM_RAMS_ECC_EN_SRC_SEL;
/* enable test mode */
if (cfg->en_muram_test_mode)
tmp_reg |= FPM_RAM_MURAM_TEST_ECC;
if (cfg->en_iram_test_mode)
tmp_reg |= FPM_RAM_IRAM_TEST_ECC;
iowrite32be(tmp_reg, &fpm_rg->fm_rcr);
tmp_reg = 0;
if (cfg->exceptions & FMAN_EX_IRAM_ECC) {
tmp_reg |= FPM_IRAM_ECC_ERR_EX_EN;
fman_enable_rams_ecc(fpm_rg);
}
if (cfg->exceptions & FMAN_EX_NURAM_ECC) {
tmp_reg |= FPM_MURAM_ECC_ERR_EX_EN;
fman_enable_rams_ecc(fpm_rg);
}
iowrite32be(tmp_reg, &fpm_rg->fm_rie);
return 0;
}
int fman_bmi_init(struct fman_bmi_regs *bmi_rg, struct fman_cfg *cfg)
{
uint32_t tmp_reg;
/**********************/
/* Init BMI Registers */
/**********************/
/* define common resources */
tmp_reg = cfg->fifo_base_addr;
tmp_reg = tmp_reg / BMI_FIFO_ALIGN;
tmp_reg |= ((cfg->total_fifo_size / FMAN_BMI_FIFO_UNITS - 1) <<
BMI_CFG1_FIFO_SIZE_SHIFT);
iowrite32be(tmp_reg, &bmi_rg->fmbm_cfg1);
tmp_reg = ((uint32_t)(cfg->total_num_of_tasks - 1) <<
BMI_CFG2_TASKS_SHIFT);
/* num of DMA's will be dynamically updated when each port is set */
iowrite32be(tmp_reg, &bmi_rg->fmbm_cfg2);
/* define unmaskable exceptions, enable and clear events */
tmp_reg = 0;
iowrite32be(BMI_ERR_INTR_EN_LIST_RAM_ECC |
BMI_ERR_INTR_EN_STORAGE_PROFILE_ECC |
BMI_ERR_INTR_EN_STATISTICS_RAM_ECC |
BMI_ERR_INTR_EN_DISPATCH_RAM_ECC,
&bmi_rg->fmbm_ievr);
if (cfg->exceptions & FMAN_EX_BMI_LIST_RAM_ECC)
tmp_reg |= BMI_ERR_INTR_EN_LIST_RAM_ECC;
if (cfg->exceptions & FMAN_EX_BMI_PIPELINE_ECC)
tmp_reg |= BMI_ERR_INTR_EN_STORAGE_PROFILE_ECC;
if (cfg->exceptions & FMAN_EX_BMI_STATISTICS_RAM_ECC)
tmp_reg |= BMI_ERR_INTR_EN_STATISTICS_RAM_ECC;
if (cfg->exceptions & FMAN_EX_BMI_DISPATCH_RAM_ECC)
tmp_reg |= BMI_ERR_INTR_EN_DISPATCH_RAM_ECC;
iowrite32be(tmp_reg, &bmi_rg->fmbm_ier);
return 0;
}
int fman_qmi_init(struct fman_qmi_regs *qmi_rg, struct fman_cfg *cfg)
{
uint32_t tmp_reg;
uint16_t period_in_fm_clocks;
uint8_t remainder;
/**********************/
/* Init QMI Registers */
/**********************/
/* Clear error interrupt events */
iowrite32be(QMI_ERR_INTR_EN_DOUBLE_ECC | QMI_ERR_INTR_EN_DEQ_FROM_DEF,
&qmi_rg->fmqm_eie);
tmp_reg = 0;
if (cfg->exceptions & FMAN_EX_QMI_DEQ_FROM_UNKNOWN_PORTID)
tmp_reg |= QMI_ERR_INTR_EN_DEQ_FROM_DEF;
if (cfg->exceptions & FMAN_EX_QMI_DOUBLE_ECC)
tmp_reg |= QMI_ERR_INTR_EN_DOUBLE_ECC;
/* enable events */
iowrite32be(tmp_reg, &qmi_rg->fmqm_eien);
if (cfg->tnum_aging_period) {
/* tnum_aging_period is in units of usec, p_FmClockFreq in Mhz */
period_in_fm_clocks = (uint16_t)
(cfg->tnum_aging_period * cfg->clk_freq);
/* period_in_fm_clocks must be a 64 multiply */
remainder = (uint8_t)(period_in_fm_clocks % 64);
if (remainder)
tmp_reg = (uint32_t)((period_in_fm_clocks / 64) + 1);
else{
tmp_reg = (uint32_t)(period_in_fm_clocks / 64);
if (!tmp_reg)
tmp_reg = 1;
}
tmp_reg <<= QMI_TAPC_TAP;
iowrite32be(tmp_reg, &qmi_rg->fmqm_tapc);
}
tmp_reg = 0;
/* Clear interrupt events */
iowrite32be(QMI_INTR_EN_SINGLE_ECC, &qmi_rg->fmqm_ie);
if (cfg->exceptions & FMAN_EX_QMI_SINGLE_ECC)
tmp_reg |= QMI_INTR_EN_SINGLE_ECC;
/* enable events */
iowrite32be(tmp_reg, &qmi_rg->fmqm_ien);
return 0;
}
int fman_enable(struct fman_rg *fman_rg, struct fman_cfg *cfg)
{
uint32_t cfg_reg = 0;
/**********************/
/* Enable all modules */
/**********************/
/* clear & enable global counters - calculate reg and save for later,
because it's the same reg for QMI enable */
cfg_reg = QMI_CFG_EN_COUNTERS;
if (cfg->qmi_deq_option_support)
cfg_reg |= (uint32_t)(((cfg->qmi_def_tnums_thresh) << 8) |
(uint32_t)cfg->qmi_def_tnums_thresh);
iowrite32be(BMI_INIT_START, &fman_rg->bmi_rg->fmbm_init);
iowrite32be(cfg_reg | QMI_CFG_ENQ_EN | QMI_CFG_DEQ_EN,
&fman_rg->qmi_rg->fmqm_gc);
return 0;
}
void fman_free_resources(struct fman_rg *fman_rg)
{
/* disable BMI and QMI */
iowrite32be(0, &fman_rg->bmi_rg->fmbm_init);
iowrite32be(0, &fman_rg->qmi_rg->fmqm_gc);
/* release BMI resources */
iowrite32be(0, &fman_rg->bmi_rg->fmbm_cfg2);
iowrite32be(0, &fman_rg->bmi_rg->fmbm_cfg1);
/* disable ECC */
iowrite32be(0, &fman_rg->fpm_rg->fm_rcr);
}
/****************************************************/
/* API Run-time Control uint functions */
/****************************************************/
uint32_t fman_get_normal_pending(struct fman_fpm_regs *fpm_rg)
{
return ioread32be(&fpm_rg->fm_npi);
}
uint32_t fman_get_controller_event(struct fman_fpm_regs *fpm_rg, uint8_t reg_id)
{
uint32_t event;
event = ioread32be(&fpm_rg->fmfp_fcev[reg_id]) &
ioread32be(&fpm_rg->fmfp_cee[reg_id]);
iowrite32be(event, &fpm_rg->fmfp_cev[reg_id]);
return event;
}
uint32_t fman_get_error_pending(struct fman_fpm_regs *fpm_rg)
{
return ioread32be(&fpm_rg->fm_epi);
}
void fman_set_ports_bandwidth(struct fman_bmi_regs *bmi_rg, uint8_t *weights)
{
int i;
uint8_t shift;
uint32_t tmp = 0;
for (i = 0; i < 64; i++) {
if (weights[i] > 1) { /* no need to write 1 since it is 0 */
/* Add this port to tmp_reg */
/* (each 8 ports result in one register)*/
shift = (uint8_t)(32 - 4 * ((i % 8) + 1));
tmp |= ((weights[i] - 1) << shift);
}
if (i % 8 == 7) { /* last in this set */
iowrite32be(tmp, &bmi_rg->fmbm_arb[i / 8]);
tmp = 0;
}
}
}
void fman_enable_rams_ecc(struct fman_fpm_regs *fpm_rg)
{
uint32_t tmp;
tmp = ioread32be(&fpm_rg->fm_rcr);
if (tmp & FPM_RAM_RAMS_ECC_EN_SRC_SEL)
iowrite32be(tmp | FPM_RAM_IRAM_ECC_EN,
&fpm_rg->fm_rcr);
else
iowrite32be(tmp | FPM_RAM_RAMS_ECC_EN |
FPM_RAM_IRAM_ECC_EN,
&fpm_rg->fm_rcr);
}
void fman_disable_rams_ecc(struct fman_fpm_regs *fpm_rg)
{
uint32_t tmp;
tmp = ioread32be(&fpm_rg->fm_rcr);
if (tmp & FPM_RAM_RAMS_ECC_EN_SRC_SEL)
iowrite32be(tmp & ~FPM_RAM_IRAM_ECC_EN,
&fpm_rg->fm_rcr);
else
iowrite32be(tmp & ~(FPM_RAM_RAMS_ECC_EN | FPM_RAM_IRAM_ECC_EN),
&fpm_rg->fm_rcr);
}
int fman_set_exception(struct fman_rg *fman_rg,
enum fman_exceptions exception,
bool enable)
{
uint32_t tmp;
switch (exception) {
case(E_FMAN_EX_DMA_BUS_ERROR):
tmp = ioread32be(&fman_rg->dma_rg->fmdmmr);
if (enable)
tmp |= DMA_MODE_BER;
else
tmp &= ~DMA_MODE_BER;
/* disable bus error */
iowrite32be(tmp, &fman_rg->dma_rg->fmdmmr);
break;
case(E_FMAN_EX_DMA_READ_ECC):
case(E_FMAN_EX_DMA_SYSTEM_WRITE_ECC):
case(E_FMAN_EX_DMA_FM_WRITE_ECC):
tmp = ioread32be(&fman_rg->dma_rg->fmdmmr);
if (enable)
tmp |= DMA_MODE_ECC;
else
tmp &= ~DMA_MODE_ECC;
iowrite32be(tmp, &fman_rg->dma_rg->fmdmmr);
break;
case(E_FMAN_EX_FPM_STALL_ON_TASKS):
tmp = ioread32be(&fman_rg->fpm_rg->fmfp_ee);
if (enable)
tmp |= FPM_EV_MASK_STALL_EN;
else
tmp &= ~FPM_EV_MASK_STALL_EN;
iowrite32be(tmp, &fman_rg->fpm_rg->fmfp_ee);
break;
case(E_FMAN_EX_FPM_SINGLE_ECC):
tmp = ioread32be(&fman_rg->fpm_rg->fmfp_ee);
if (enable)
tmp |= FPM_EV_MASK_SINGLE_ECC_EN;
else
tmp &= ~FPM_EV_MASK_SINGLE_ECC_EN;
iowrite32be(tmp, &fman_rg->fpm_rg->fmfp_ee);
break;
case(E_FMAN_EX_FPM_DOUBLE_ECC):
tmp = ioread32be(&fman_rg->fpm_rg->fmfp_ee);
if (enable)
tmp |= FPM_EV_MASK_DOUBLE_ECC_EN;
else
tmp &= ~FPM_EV_MASK_DOUBLE_ECC_EN;
iowrite32be(tmp, &fman_rg->fpm_rg->fmfp_ee);
break;
case(E_FMAN_EX_QMI_SINGLE_ECC):
tmp = ioread32be(&fman_rg->qmi_rg->fmqm_ien);
if (enable)
tmp |= QMI_INTR_EN_SINGLE_ECC;
else
tmp &= ~QMI_INTR_EN_SINGLE_ECC;
iowrite32be(tmp, &fman_rg->qmi_rg->fmqm_ien);
break;
case(E_FMAN_EX_QMI_DOUBLE_ECC):
tmp = ioread32be(&fman_rg->qmi_rg->fmqm_eien);
if (enable)
tmp |= QMI_ERR_INTR_EN_DOUBLE_ECC;
else
tmp &= ~QMI_ERR_INTR_EN_DOUBLE_ECC;
iowrite32be(tmp, &fman_rg->qmi_rg->fmqm_eien);
break;
case(E_FMAN_EX_QMI_DEQ_FROM_UNKNOWN_PORTID):
tmp = ioread32be(&fman_rg->qmi_rg->fmqm_eien);
if (enable)
tmp |= QMI_ERR_INTR_EN_DEQ_FROM_DEF;
else
tmp &= ~QMI_ERR_INTR_EN_DEQ_FROM_DEF;
iowrite32be(tmp, &fman_rg->qmi_rg->fmqm_eien);
break;
case(E_FMAN_EX_BMI_LIST_RAM_ECC):
tmp = ioread32be(&fman_rg->bmi_rg->fmbm_ier);
if (enable)
tmp |= BMI_ERR_INTR_EN_LIST_RAM_ECC;
else
tmp &= ~BMI_ERR_INTR_EN_LIST_RAM_ECC;
iowrite32be(tmp, &fman_rg->bmi_rg->fmbm_ier);
break;
case(E_FMAN_EX_BMI_STORAGE_PROFILE_ECC):
tmp = ioread32be(&fman_rg->bmi_rg->fmbm_ier);
if (enable)
tmp |= BMI_ERR_INTR_EN_STORAGE_PROFILE_ECC;
else
tmp &= ~BMI_ERR_INTR_EN_STORAGE_PROFILE_ECC;
iowrite32be(tmp, &fman_rg->bmi_rg->fmbm_ier);
break;
case(E_FMAN_EX_BMI_STATISTICS_RAM_ECC):
tmp = ioread32be(&fman_rg->bmi_rg->fmbm_ier);
if (enable)
tmp |= BMI_ERR_INTR_EN_STATISTICS_RAM_ECC;
else
tmp &= ~BMI_ERR_INTR_EN_STATISTICS_RAM_ECC;
iowrite32be(tmp, &fman_rg->bmi_rg->fmbm_ier);
break;
case(E_FMAN_EX_BMI_DISPATCH_RAM_ECC):
tmp = ioread32be(&fman_rg->bmi_rg->fmbm_ier);
if (enable)
tmp |= BMI_ERR_INTR_EN_DISPATCH_RAM_ECC;
else
tmp &= ~BMI_ERR_INTR_EN_DISPATCH_RAM_ECC;
iowrite32be(tmp, &fman_rg->bmi_rg->fmbm_ier);
break;
case(E_FMAN_EX_IRAM_ECC):
tmp = ioread32be(&fman_rg->fpm_rg->fm_rie);
if (enable) {
/* enable ECC if not enabled */
fman_enable_rams_ecc(fman_rg->fpm_rg);
/* enable ECC interrupts */
tmp |= FPM_IRAM_ECC_ERR_EX_EN;
} else {
/* ECC mechanism may be disabled,
* depending on driver status */
fman_disable_rams_ecc(fman_rg->fpm_rg);
tmp &= ~FPM_IRAM_ECC_ERR_EX_EN;
}
iowrite32be(tmp, &fman_rg->fpm_rg->fm_rie);
break;
case(E_FMAN_EX_MURAM_ECC):
tmp = ioread32be(&fman_rg->fpm_rg->fm_rie);
if (enable) {
/* enable ECC if not enabled */
fman_enable_rams_ecc(fman_rg->fpm_rg);
/* enable ECC interrupts */
tmp |= FPM_MURAM_ECC_ERR_EX_EN;
} else {
/* ECC mechanism may be disabled,
* depending on driver status */
fman_disable_rams_ecc(fman_rg->fpm_rg);
tmp &= ~FPM_MURAM_ECC_ERR_EX_EN;
}
iowrite32be(tmp, &fman_rg->fpm_rg->fm_rie);
break;
default:
return -EINVAL;
}
return 0;
}
void fman_get_revision(struct fman_fpm_regs *fpm_rg,
uint8_t *major,
uint8_t *minor)
{
uint32_t tmp;
tmp = ioread32be(&fpm_rg->fm_ip_rev_1);
*major = (uint8_t)((tmp & FPM_REV1_MAJOR_MASK) >> FPM_REV1_MAJOR_SHIFT);
*minor = (uint8_t)((tmp & FPM_REV1_MINOR_MASK) >> FPM_REV1_MINOR_SHIFT);
}
uint32_t fman_get_counter(struct fman_rg *fman_rg,
enum fman_counters reg_name)
{
uint32_t ret_val;
switch (reg_name) {
case(E_FMAN_COUNTERS_ENQ_TOTAL_FRAME):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_etfc);
break;
case(E_FMAN_COUNTERS_DEQ_TOTAL_FRAME):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_dtfc);
break;
case(E_FMAN_COUNTERS_DEQ_0):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_dc0);
break;
case(E_FMAN_COUNTERS_DEQ_1):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_dc1);
break;
case(E_FMAN_COUNTERS_DEQ_2):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_dc2);
break;
case(E_FMAN_COUNTERS_DEQ_3):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_dc3);
break;
case(E_FMAN_COUNTERS_DEQ_FROM_DEFAULT):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_dfdc);
break;
case(E_FMAN_COUNTERS_DEQ_FROM_CONTEXT):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_dfcc);
break;
case(E_FMAN_COUNTERS_DEQ_FROM_FD):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_dffc);
break;
case(E_FMAN_COUNTERS_DEQ_CONFIRM):
ret_val = ioread32be(&fman_rg->qmi_rg->fmqm_dcc);
break;
default:
ret_val = 0;
}
return ret_val;
}
int fman_modify_counter(struct fman_rg *fman_rg,
enum fman_counters reg_name,
uint32_t val)
{
/* When applicable (when there is an 'enable counters' bit,
* check that counters are enabled */
switch (reg_name) {
case(E_FMAN_COUNTERS_ENQ_TOTAL_FRAME):
case(E_FMAN_COUNTERS_DEQ_TOTAL_FRAME):
case(E_FMAN_COUNTERS_DEQ_0):
case(E_FMAN_COUNTERS_DEQ_1):
case(E_FMAN_COUNTERS_DEQ_2):
case(E_FMAN_COUNTERS_DEQ_3):
case(E_FMAN_COUNTERS_DEQ_FROM_DEFAULT):
case(E_FMAN_COUNTERS_DEQ_FROM_CONTEXT):
case(E_FMAN_COUNTERS_DEQ_FROM_FD):
case(E_FMAN_COUNTERS_DEQ_CONFIRM):
if (!(ioread32be(&fman_rg->qmi_rg->fmqm_gc) &
QMI_CFG_EN_COUNTERS))
return -EINVAL;
break;
default:
break;
}
/* Set counter */
switch (reg_name) {
case(E_FMAN_COUNTERS_ENQ_TOTAL_FRAME):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_etfc);
break;
case(E_FMAN_COUNTERS_DEQ_TOTAL_FRAME):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_dtfc);
break;
case(E_FMAN_COUNTERS_DEQ_0):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_dc0);
break;
case(E_FMAN_COUNTERS_DEQ_1):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_dc1);
break;
case(E_FMAN_COUNTERS_DEQ_2):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_dc2);
break;
case(E_FMAN_COUNTERS_DEQ_3):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_dc3);
break;
case(E_FMAN_COUNTERS_DEQ_FROM_DEFAULT):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_dfdc);
break;
case(E_FMAN_COUNTERS_DEQ_FROM_CONTEXT):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_dfcc);
break;
case(E_FMAN_COUNTERS_DEQ_FROM_FD):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_dffc);
break;
case(E_FMAN_COUNTERS_DEQ_CONFIRM):
iowrite32be(val, &fman_rg->qmi_rg->fmqm_dcc);
break;
case(E_FMAN_COUNTERS_SEMAPHOR_ENTRY_FULL_REJECT):
iowrite32be(val, &fman_rg->dma_rg->fmdmsefrc);
break;
case(E_FMAN_COUNTERS_SEMAPHOR_QUEUE_FULL_REJECT):
iowrite32be(val, &fman_rg->dma_rg->fmdmsqfrc);
break;
case(E_FMAN_COUNTERS_SEMAPHOR_SYNC_REJECT):
iowrite32be(val, &fman_rg->dma_rg->fmdmssrc);
break;
default:
break;
}
return 0;
}
void fman_set_dma_emergency(struct fman_dma_regs *dma_rg,
bool is_write,
bool enable)
{
uint32_t msk;
msk = (uint32_t)(is_write ? DMA_MODE_EMER_WRITE : DMA_MODE_EMER_READ);
if (enable)
iowrite32be(ioread32be(&dma_rg->fmdmmr) | msk,
&dma_rg->fmdmmr);
else /* disable */
iowrite32be(ioread32be(&dma_rg->fmdmmr) & ~msk,
&dma_rg->fmdmmr);
}
void fman_set_dma_ext_bus_pri(struct fman_dma_regs *dma_rg, uint32_t pri)
{
uint32_t tmp;
tmp = ioread32be(&dma_rg->fmdmmr) |
(pri << DMA_MODE_BUS_PRI_SHIFT);
iowrite32be(tmp, &dma_rg->fmdmmr);
}
uint32_t fman_get_dma_status(struct fman_dma_regs *dma_rg)
{
return ioread32be(&dma_rg->fmdmsr);
}
void fman_force_intr(struct fman_rg *fman_rg,
enum fman_exceptions exception)
{
switch (exception) {
case E_FMAN_EX_QMI_DEQ_FROM_UNKNOWN_PORTID:
iowrite32be(QMI_ERR_INTR_EN_DEQ_FROM_DEF,
&fman_rg->qmi_rg->fmqm_eif);
break;
case E_FMAN_EX_QMI_SINGLE_ECC:
iowrite32be(QMI_INTR_EN_SINGLE_ECC,
&fman_rg->qmi_rg->fmqm_if);
break;
case E_FMAN_EX_QMI_DOUBLE_ECC:
iowrite32be(QMI_ERR_INTR_EN_DOUBLE_ECC,
&fman_rg->qmi_rg->fmqm_eif);
break;
case E_FMAN_EX_BMI_LIST_RAM_ECC:
iowrite32be(BMI_ERR_INTR_EN_LIST_RAM_ECC,
&fman_rg->bmi_rg->fmbm_ifr);
break;
case E_FMAN_EX_BMI_STORAGE_PROFILE_ECC:
iowrite32be(BMI_ERR_INTR_EN_STORAGE_PROFILE_ECC,
&fman_rg->bmi_rg->fmbm_ifr);
break;
case E_FMAN_EX_BMI_STATISTICS_RAM_ECC:
iowrite32be(BMI_ERR_INTR_EN_STATISTICS_RAM_ECC,
&fman_rg->bmi_rg->fmbm_ifr);
break;
case E_FMAN_EX_BMI_DISPATCH_RAM_ECC:
iowrite32be(BMI_ERR_INTR_EN_DISPATCH_RAM_ECC,
&fman_rg->bmi_rg->fmbm_ifr);
break;
default:
break;
}
}
bool fman_is_qmi_halt_not_busy_state(struct fman_qmi_regs *qmi_rg)
{
return (bool)!!(ioread32be(&qmi_rg->fmqm_gs) & QMI_GS_HALT_NOT_BUSY);
}
void fman_resume(struct fman_fpm_regs *fpm_rg)
{
uint32_t tmp;
tmp = ioread32be(&fpm_rg->fmfp_ee);
/* clear tmp_reg event bits in order not to clear standing events */
tmp &= ~(FPM_EV_MASK_DOUBLE_ECC |
FPM_EV_MASK_STALL |
FPM_EV_MASK_SINGLE_ECC);
tmp |= FPM_EV_MASK_RELEASE_FM;
iowrite32be(tmp, &fpm_rg->fmfp_ee);
}