blob: 84f11791c4f9663d2cf5fe0b1d60a1ff626a6339 [file] [log] [blame]
/* ==========================================================================
* $File: //dwh/usb_iip/dev/software/otg/linux/drivers/dwc_otg_cil.c $
* $Revision: #189 $
* $Date: 2011/10/24 $
* $Change: 1871160 $
*
* Synopsys HS OTG Linux Software Driver and documentation (hereinafter,
* "Software") is an Unsupported proprietary work of Synopsys, Inc. unless
* otherwise expressly agreed to in writing between Synopsys and you.
*
* The Software IS NOT an item of Licensed Software or Licensed Product under
* any End User Software License Agreement or Agreement for Licensed Product
* with Synopsys or any supplement thereto. You are permitted to use and
* redistribute this Software in source and binary forms, with or without
* modification, provided that redistributions of source code must retain this
* notice. You may not view, use, disclose, copy or distribute this file or
* any information contained herein except pursuant to this license grant from
* Synopsys. If you do not agree with this notice, including the disclaimer
* below, then you are not authorized to use the Software.
*
* THIS SOFTWARE IS BEING DISTRIBUTED BY SYNOPSYS SOLELY ON AN "AS IS" BASIS
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE HEREBY DISCLAIMED. IN NO EVENT SHALL SYNOPSYS 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.
* ========================================================================== */
/** @file
*
* The Core Interface Layer provides basic services for accessing and
* managing the DWC_otg hardware. These services are used by both the
* Host Controller Driver and the Peripheral Controller Driver.
*
* The CIL manages the memory map for the core so that the HCD and PCD
* don't have to do this separately. It also handles basic tasks like
* reading/writing the registers and data FIFOs in the controller.
* Some of the data access functions provide encapsulation of several
* operations required to perform a task, such as writing multiple
* registers to start a transfer. Finally, the CIL performs basic
* services that are not specific to either the host or device modes
* of operation. These services include management of the OTG Host
* Negotiation Protocol (HNP) and Session Request Protocol (SRP). A
* Diagnostic API is also provided to allow testing of the controller
* hardware.
*
* The Core Interface Layer has the following requirements:
* - Provides basic controller operations.
* - Minimal use of OS services.
* - The OS services used will be abstracted by using inline functions
* or macros.
*
*/
#include "dwc_os.h"
#include "dwc_otg_regs.h"
#include "dwc_otg_cil.h"
static int dwc_otg_setup_params(dwc_otg_core_if_t * core_if);
/**
* This function is called to initialize the DWC_otg CSR data
* structures. The register addresses in the device and host
* structures are initialized from the base address supplied by the
* caller. The calling function must make the OS calls to get the
* base address of the DWC_otg controller registers. The core_params
* argument holds the parameters that specify how the core should be
* configured.
*
* @param reg_base_addr Base address of DWC_otg core registers
*
*/
dwc_otg_core_if_t *dwc_otg_cil_init(const uint32_t * reg_base_addr)
{
dwc_otg_core_if_t *core_if = 0;
dwc_otg_dev_if_t *dev_if = 0;
dwc_otg_host_if_t *host_if = 0;
uint8_t *reg_base = (uint8_t *) reg_base_addr;
int i = 0;
DWC_DEBUGPL(DBG_CILV, "%s(%p)\n", __func__, reg_base_addr);
core_if = DWC_ALLOC(sizeof(dwc_otg_core_if_t));
if (core_if == NULL) {
DWC_DEBUGPL(DBG_CIL,
"Allocation of dwc_otg_core_if_t failed\n");
return 0;
}
core_if->core_global_regs = (dwc_otg_core_global_regs_t *) reg_base;
/*
* Allocate the Device Mode structures.
*/
dev_if = DWC_ALLOC(sizeof(dwc_otg_dev_if_t));
if (dev_if == NULL) {
DWC_DEBUGPL(DBG_CIL, "Allocation of dwc_otg_dev_if_t failed\n");
DWC_FREE(core_if);
return 0;
}
dev_if->dev_global_regs =
(dwc_otg_device_global_regs_t *) (reg_base +
DWC_DEV_GLOBAL_REG_OFFSET);
for (i = 0; i < MAX_EPS_CHANNELS; i++) {
dev_if->in_ep_regs[i] = (dwc_otg_dev_in_ep_regs_t *)
(reg_base + DWC_DEV_IN_EP_REG_OFFSET +
(i * DWC_EP_REG_OFFSET));
dev_if->out_ep_regs[i] = (dwc_otg_dev_out_ep_regs_t *)
(reg_base + DWC_DEV_OUT_EP_REG_OFFSET +
(i * DWC_EP_REG_OFFSET));
DWC_DEBUGPL(DBG_CILV, "in_ep_regs[%d]->diepctl=%p\n",
i, &dev_if->in_ep_regs[i]->diepctl);
DWC_DEBUGPL(DBG_CILV, "out_ep_regs[%d]->doepctl=%p\n",
i, &dev_if->out_ep_regs[i]->doepctl);
}
dev_if->speed = 0; // unknown
core_if->dev_if = dev_if;
/*
* Allocate the Host Mode structures.
*/
host_if = DWC_ALLOC(sizeof(dwc_otg_host_if_t));
if (host_if == NULL) {
DWC_DEBUGPL(DBG_CIL,
"Allocation of dwc_otg_host_if_t failed\n");
DWC_FREE(dev_if);
DWC_FREE(core_if);
return 0;
}
host_if->host_global_regs = (dwc_otg_host_global_regs_t *)
(reg_base + DWC_OTG_HOST_GLOBAL_REG_OFFSET);
host_if->hprt0 =
(uint32_t *) (reg_base + DWC_OTG_HOST_PORT_REGS_OFFSET);
for (i = 0; i < MAX_EPS_CHANNELS; i++) {
host_if->hc_regs[i] = (dwc_otg_hc_regs_t *)
(reg_base + DWC_OTG_HOST_CHAN_REGS_OFFSET +
(i * DWC_OTG_CHAN_REGS_OFFSET));
DWC_DEBUGPL(DBG_CILV, "hc_reg[%d]->hcchar=%p\n",
i, &host_if->hc_regs[i]->hcchar);
}
host_if->num_host_channels = MAX_EPS_CHANNELS;
core_if->host_if = host_if;
for (i = 0; i < MAX_EPS_CHANNELS; i++) {
core_if->data_fifo[i] =
(uint32_t *) (reg_base + DWC_OTG_DATA_FIFO_OFFSET +
(i * DWC_OTG_DATA_FIFO_SIZE));
DWC_DEBUGPL(DBG_CILV, "data_fifo[%d]=0x%08lx\n",
i, (unsigned long)core_if->data_fifo[i]);
}
core_if->pcgcctl = (uint32_t *) (reg_base + DWC_OTG_PCGCCTL_OFFSET);
/* Initiate lx_state to L3 disconnected state */
core_if->lx_state = DWC_OTG_L3;
/*
* Store the contents of the hardware configuration registers here for
* easy access later.
*/
core_if->hwcfg1.d32 =
DWC_READ_REG32(&core_if->core_global_regs->ghwcfg1);
core_if->hwcfg2.d32 =
DWC_READ_REG32(&core_if->core_global_regs->ghwcfg2);
core_if->hwcfg3.d32 =
DWC_READ_REG32(&core_if->core_global_regs->ghwcfg3);
core_if->hwcfg4.d32 =
DWC_READ_REG32(&core_if->core_global_regs->ghwcfg4);
/* Force host mode to get HPTXFSIZ exact power on value */
{
gusbcfg_data_t gusbcfg = {.d32 = 0 };
gusbcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->gusbcfg);
gusbcfg.b.force_host_mode = 1;
DWC_WRITE_REG32(&core_if->core_global_regs->gusbcfg, gusbcfg.d32);
dwc_mdelay(100);
core_if->hptxfsiz.d32 =
DWC_READ_REG32(&core_if->core_global_regs->hptxfsiz);
gusbcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->gusbcfg);
gusbcfg.b.force_host_mode = 0;
DWC_WRITE_REG32(&core_if->core_global_regs->gusbcfg, gusbcfg.d32);
dwc_mdelay(100);
}
DWC_DEBUGPL(DBG_CILV, "hwcfg1=%08x\n", core_if->hwcfg1.d32);
DWC_DEBUGPL(DBG_CILV, "hwcfg2=%08x\n", core_if->hwcfg2.d32);
DWC_DEBUGPL(DBG_CILV, "hwcfg3=%08x\n", core_if->hwcfg3.d32);
DWC_DEBUGPL(DBG_CILV, "hwcfg4=%08x\n", core_if->hwcfg4.d32);
core_if->hcfg.d32 =
DWC_READ_REG32(&core_if->host_if->host_global_regs->hcfg);
core_if->dcfg.d32 =
DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dcfg);
DWC_DEBUGPL(DBG_CILV, "hcfg=%08x\n", core_if->hcfg.d32);
DWC_DEBUGPL(DBG_CILV, "dcfg=%08x\n", core_if->dcfg.d32);
DWC_DEBUGPL(DBG_CILV, "op_mode=%0x\n", core_if->hwcfg2.b.op_mode);
DWC_DEBUGPL(DBG_CILV, "arch=%0x\n", core_if->hwcfg2.b.architecture);
DWC_DEBUGPL(DBG_CILV, "num_dev_ep=%d\n", core_if->hwcfg2.b.num_dev_ep);
DWC_DEBUGPL(DBG_CILV, "num_host_chan=%d\n",
core_if->hwcfg2.b.num_host_chan);
DWC_DEBUGPL(DBG_CILV, "nonperio_tx_q_depth=0x%0x\n",
core_if->hwcfg2.b.nonperio_tx_q_depth);
DWC_DEBUGPL(DBG_CILV, "host_perio_tx_q_depth=0x%0x\n",
core_if->hwcfg2.b.host_perio_tx_q_depth);
DWC_DEBUGPL(DBG_CILV, "dev_token_q_depth=0x%0x\n",
core_if->hwcfg2.b.dev_token_q_depth);
DWC_DEBUGPL(DBG_CILV, "Total FIFO SZ=%d\n",
core_if->hwcfg3.b.dfifo_depth);
DWC_DEBUGPL(DBG_CILV, "xfer_size_cntr_width=%0x\n",
core_if->hwcfg3.b.xfer_size_cntr_width);
/*
* Set the SRP sucess bit for FS-I2c
*/
core_if->srp_success = 0;
core_if->srp_timer_started = 0;
/*
* Create new workqueue and init works
*/
core_if->wq_otg = DWC_WORKQ_ALLOC("dwc_otg");
if (core_if->wq_otg == 0) {
DWC_WARN("DWC_WORKQ_ALLOC failed\n");
DWC_FREE(host_if);
DWC_FREE(dev_if);
DWC_FREE(core_if);
return 0;
}
core_if->snpsid = DWC_READ_REG32(&core_if->core_global_regs->gsnpsid);
DWC_PRINTF("Core Release: %x.%x%x%x\n",
(core_if->snpsid >> 12 & 0xF),
(core_if->snpsid >> 8 & 0xF),
(core_if->snpsid >> 4 & 0xF), (core_if->snpsid & 0xF));
core_if->wkp_timer = DWC_TIMER_ALLOC("Wake Up Timer",
w_wakeup_detected, core_if);
if (core_if->wkp_timer == 0) {
DWC_WARN("DWC_TIMER_ALLOC failed\n");
DWC_FREE(host_if);
DWC_FREE(dev_if);
DWC_WORKQ_FREE(core_if->wq_otg);
DWC_FREE(core_if);
return 0;
}
if (dwc_otg_setup_params(core_if)) {
DWC_WARN("Error while setting core params\n");
}
core_if->hibernation_suspend = 0;
/** ADP initialization */
dwc_otg_adp_init(core_if);
return core_if;
}
/**
* This function frees the structures allocated by dwc_otg_cil_init().
*
* @param core_if The core interface pointer returned from
* dwc_otg_cil_init().
*
*/
void dwc_otg_cil_remove(dwc_otg_core_if_t * core_if)
{
/* Disable all interrupts */
DWC_MODIFY_REG32(&core_if->core_global_regs->gahbcfg, 1, 0);
DWC_WRITE_REG32(&core_if->core_global_regs->gintmsk, 0);
if (core_if->wq_otg) {
DWC_WORKQ_WAIT_WORK_DONE(core_if->wq_otg, 500);
DWC_WORKQ_FREE(core_if->wq_otg);
}
if (core_if->dev_if) {
DWC_FREE(core_if->dev_if);
}
if (core_if->host_if) {
DWC_FREE(core_if->host_if);
}
/** Remove ADP Stuff */
dwc_otg_adp_remove(core_if);
if (core_if->core_params) {
DWC_FREE(core_if->core_params);
}
if (core_if->wkp_timer) {
DWC_TIMER_FREE(core_if->wkp_timer);
}
if (core_if->srp_timer) {
DWC_TIMER_FREE(core_if->srp_timer);
}
DWC_FREE(core_if);
}
/**
* This function enables the controller's Global Interrupt in the AHB Config
* register.
*
* @param core_if Programming view of DWC_otg controller.
*/
void dwc_otg_enable_global_interrupts(dwc_otg_core_if_t * core_if)
{
gahbcfg_data_t ahbcfg = {.d32 = 0 };
ahbcfg.b.glblintrmsk = 1; /* Enable interrupts */
DWC_MODIFY_REG32(&core_if->core_global_regs->gahbcfg, 0, ahbcfg.d32);
}
/**
* This function disables the controller's Global Interrupt in the AHB Config
* register.
*
* @param core_if Programming view of DWC_otg controller.
*/
void dwc_otg_disable_global_interrupts(dwc_otg_core_if_t * core_if)
{
gahbcfg_data_t ahbcfg = {.d32 = 0 };
ahbcfg.b.glblintrmsk = 1; /* Disable interrupts */
DWC_MODIFY_REG32(&core_if->core_global_regs->gahbcfg, ahbcfg.d32, 0);
}
/**
* This function initializes the commmon interrupts, used in both
* device and host modes.
*
* @param core_if Programming view of the DWC_otg controller
*
*/
static void dwc_otg_enable_common_interrupts(dwc_otg_core_if_t * core_if)
{
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
gintmsk_data_t intr_mask = {.d32 = 0 };
/* Clear any pending OTG Interrupts */
DWC_WRITE_REG32(&global_regs->gotgint, 0xFFFFFFFF);
/* Clear any pending interrupts */
DWC_WRITE_REG32(&global_regs->gintsts, 0xFFFFFFFF);
/*
* Enable the interrupts in the GINTMSK.
*/
intr_mask.b.modemismatch = 1;
intr_mask.b.otgintr = 1;
if (!core_if->dma_enable) {
intr_mask.b.rxstsqlvl = 1;
}
intr_mask.b.conidstschng = 1;
intr_mask.b.wkupintr = 1;
intr_mask.b.disconnect = 0;
intr_mask.b.usbsuspend = 1;
intr_mask.b.sessreqintr = 1;
#ifdef CONFIG_USB_DWC_OTG_LPM
if (core_if->core_params->lpm_enable) {
intr_mask.b.lpmtranrcvd = 1;
}
#endif
DWC_WRITE_REG32(&global_regs->gintmsk, intr_mask.d32);
}
/*
* The restore operation is modified to support Synopsys Emulated Powerdown and
* Hibernation. This function is for exiting from Device mode hibernation by
* Host Initiated Resume/Reset and Device Initiated Remote-Wakeup.
* @param core_if Programming view of DWC_otg controller.
* @param rem_wakeup - indicates whether resume is initiated by Device or Host.
* @param reset - indicates whether resume is initiated by Reset.
*/
int dwc_otg_device_hibernation_restore(dwc_otg_core_if_t * core_if,
int rem_wakeup, int reset)
{
gpwrdn_data_t gpwrdn = {.d32 = 0 };
pcgcctl_data_t pcgcctl = {.d32 = 0 };
dctl_data_t dctl = {.d32 = 0 };
int timeout = 2000;
if (!core_if->hibernation_suspend) {
DWC_PRINTF("Already exited from Hibernation\n");
return 1;
}
DWC_DEBUGPL(DBG_PCD, "%s called\n", __FUNCTION__);
/* Switch-on voltage to the core */
gpwrdn.b.pwrdnswtch = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
dwc_udelay(10);
/* Reset core */
gpwrdn.d32 = 0;
gpwrdn.b.pwrdnrstn = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
dwc_udelay(10);
/* Assert Restore signal */
gpwrdn.d32 = 0;
gpwrdn.b.restore = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, 0, gpwrdn.d32);
dwc_udelay(10);
/* Disable power clamps */
gpwrdn.d32 = 0;
gpwrdn.b.pwrdnclmp = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
if (rem_wakeup) {
dwc_udelay(70);
}
/* Deassert Reset core */
gpwrdn.d32 = 0;
gpwrdn.b.pwrdnrstn = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, 0, gpwrdn.d32);
dwc_udelay(10);
/* Disable PMU interrupt */
gpwrdn.d32 = 0;
gpwrdn.b.pmuintsel = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
/* Mask interrupts from gpwrdn */
gpwrdn.d32 = 0;
gpwrdn.b.connect_det_msk = 1;
gpwrdn.b.srp_det_msk = 1;
gpwrdn.b.disconn_det_msk = 1;
gpwrdn.b.rst_det_msk = 1;
gpwrdn.b.lnstchng_msk = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
/* Indicates that we are going out from hibernation */
core_if->hibernation_suspend = 0;
/*
* Set Restore Essential Regs bit in PCGCCTL register, restore_mode = 1
* indicates restore from remote_wakeup
*/
restore_essential_regs(core_if, rem_wakeup, 0);
/*
* Wait a little for seeing new value of variable hibernation_suspend if
* Restore done interrupt received before polling
*/
dwc_udelay(10);
if (core_if->hibernation_suspend == 0) {
/*
* Wait For Restore_done Interrupt. This mechanism of polling the
* interrupt is introduced to avoid any possible race conditions
*/
do {
gintsts_data_t gintsts;
gintsts.d32 =
DWC_READ_REG32(&core_if->core_global_regs->gintsts);
if (gintsts.b.restoredone) {
gintsts.d32 = 0;
gintsts.b.restoredone = 1;
DWC_WRITE_REG32(&core_if->core_global_regs->
gintsts, gintsts.d32);
DWC_PRINTF("Restore Done Interrupt seen\n");
break;
}
dwc_udelay(10);
} while (--timeout);
if (!timeout) {
DWC_PRINTF("Restore Done interrupt wasn't generated here\n");
}
}
/* Clear all pending interupts */
DWC_WRITE_REG32(&core_if->core_global_regs->gintsts, 0xFFFFFFFF);
/* De-assert Restore */
gpwrdn.d32 = 0;
gpwrdn.b.restore = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
dwc_udelay(10);
if (!rem_wakeup) {
pcgcctl.d32 = 0;
pcgcctl.b.rstpdwnmodule = 1;
DWC_MODIFY_REG32(core_if->pcgcctl, pcgcctl.d32, 0);
}
/* Restore GUSBCFG and DCFG */
DWC_WRITE_REG32(&core_if->core_global_regs->gusbcfg,
core_if->gr_backup->gusbcfg_local);
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->dcfg,
core_if->dr_backup->dcfg);
/* De-assert Wakeup Logic */
gpwrdn.d32 = 0;
gpwrdn.b.pmuactv = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
dwc_udelay(10);
if (!rem_wakeup) {
/* Set Device programming done bit */
dctl.b.pwronprgdone = 1;
DWC_MODIFY_REG32(&core_if->dev_if->dev_global_regs->dctl, 0, dctl.d32);
} else {
/* Start Remote Wakeup Signaling */
dctl.d32 = core_if->dr_backup->dctl;
dctl.b.rmtwkupsig = 1;
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->dctl, dctl.d32);
}
dwc_mdelay(2);
/* Clear all pending interupts */
DWC_WRITE_REG32(&core_if->core_global_regs->gintsts, 0xFFFFFFFF);
/* Restore global registers */
dwc_otg_restore_global_regs(core_if);
/* Restore device global registers */
dwc_otg_restore_dev_regs(core_if, rem_wakeup);
if (rem_wakeup) {
dwc_mdelay(7);
dctl.d32 = 0;
dctl.b.rmtwkupsig = 1;
DWC_MODIFY_REG32(&core_if->dev_if->dev_global_regs->dctl, dctl.d32, 0);
}
core_if->hibernation_suspend = 0;
/* The core will be in ON STATE */
core_if->lx_state = DWC_OTG_L0;
DWC_PRINTF("Hibernation recovery completes here\n");
return 1;
}
/*
* The restore operation is modified to support Synopsys Emulated Powerdown and
* Hibernation. This function is for exiting from Host mode hibernation by
* Host Initiated Resume/Reset and Device Initiated Remote-Wakeup.
* @param core_if Programming view of DWC_otg controller.
* @param rem_wakeup - indicates whether resume is initiated by Device or Host.
* @param reset - indicates whether resume is initiated by Reset.
*/
int dwc_otg_host_hibernation_restore(dwc_otg_core_if_t * core_if,
int rem_wakeup, int reset)
{
gpwrdn_data_t gpwrdn = {.d32 = 0 };
hprt0_data_t hprt0 = {.d32 = 0 };
int timeout = 2000;
DWC_DEBUGPL(DBG_HCD, "%s called\n", __FUNCTION__);
/* Switch-on voltage to the core */
gpwrdn.b.pwrdnswtch = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
dwc_udelay(10);
/* Reset core */
gpwrdn.d32 = 0;
gpwrdn.b.pwrdnrstn = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
dwc_udelay(10);
/* Assert Restore signal */
gpwrdn.d32 = 0;
gpwrdn.b.restore = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, 0, gpwrdn.d32);
dwc_udelay(10);
/* Disable power clamps */
gpwrdn.d32 = 0;
gpwrdn.b.pwrdnclmp = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
if (!rem_wakeup) {
dwc_udelay(50);
}
/* Deassert Reset core */
gpwrdn.d32 = 0;
gpwrdn.b.pwrdnrstn = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, 0, gpwrdn.d32);
dwc_udelay(10);
/* Disable PMU interrupt */
gpwrdn.d32 = 0;
gpwrdn.b.pmuintsel = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
gpwrdn.d32 = 0;
gpwrdn.b.connect_det_msk = 1;
gpwrdn.b.srp_det_msk = 1;
gpwrdn.b.disconn_det_msk = 1;
gpwrdn.b.rst_det_msk = 1;
gpwrdn.b.lnstchng_msk = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
/* Indicates that we are going out from hibernation */
core_if->hibernation_suspend = 0;
/* Set Restore Essential Regs bit in PCGCCTL register */
restore_essential_regs(core_if, rem_wakeup, 1);
/* Wait a little for seeing new value of variable hibernation_suspend if
* Restore done interrupt received before polling */
dwc_udelay(10);
if (core_if->hibernation_suspend == 0) {
/* Wait For Restore_done Interrupt. This mechanism of polling the
* interrupt is introduced to avoid any possible race conditions
*/
do {
gintsts_data_t gintsts;
gintsts.d32 = DWC_READ_REG32(&core_if->core_global_regs->gintsts);
if (gintsts.b.restoredone) {
gintsts.d32 = 0;
gintsts.b.restoredone = 1;
DWC_WRITE_REG32(&core_if->core_global_regs->gintsts, gintsts.d32);
DWC_DEBUGPL(DBG_HCD,"Restore Done Interrupt seen\n");
break;
}
dwc_udelay(10);
} while (--timeout);
if (!timeout) {
DWC_WARN("Restore Done interrupt wasn't generated\n");
}
}
/* Set the flag's value to 0 again after receiving restore done interrupt */
core_if->hibernation_suspend = 0;
/* This step is not described in functional spec but if not wait for this
* delay, mismatch interrupts occurred because just after restore core is
* in Device mode(gintsts.curmode == 0) */
dwc_mdelay(100);
/* Clear all pending interrupts */
DWC_WRITE_REG32(&core_if->core_global_regs->gintsts, 0xFFFFFFFF);
/* De-assert Restore */
gpwrdn.d32 = 0;
gpwrdn.b.restore = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
dwc_udelay(10);
/* Restore GUSBCFG and HCFG */
DWC_WRITE_REG32(&core_if->core_global_regs->gusbcfg,
core_if->gr_backup->gusbcfg_local);
DWC_WRITE_REG32(&core_if->host_if->host_global_regs->hcfg,
core_if->hr_backup->hcfg_local);
/* De-assert Wakeup Logic */
gpwrdn.d32 = 0;
gpwrdn.b.pmuactv = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gpwrdn, gpwrdn.d32, 0);
dwc_udelay(10);
/* Start the Resume operation by programming HPRT0 */
hprt0.d32 = core_if->hr_backup->hprt0_local;
hprt0.b.prtpwr = 1;
hprt0.b.prtena = 0;
hprt0.b.prtsusp = 0;
DWC_WRITE_REG32(core_if->host_if->hprt0, hprt0.d32);
DWC_PRINTF("Resume Starts Now\n");
if (!reset) { // Indicates it is Resume Operation
hprt0.d32 = core_if->hr_backup->hprt0_local;
hprt0.b.prtres = 1;
hprt0.b.prtpwr = 1;
hprt0.b.prtena = 0;
hprt0.b.prtsusp = 0;
DWC_WRITE_REG32(core_if->host_if->hprt0, hprt0.d32);
if (!rem_wakeup)
hprt0.b.prtres = 0;
/* Wait for Resume time and then program HPRT again */
dwc_mdelay(100);
DWC_WRITE_REG32(core_if->host_if->hprt0, hprt0.d32);
} else { // Indicates it is Reset Operation
hprt0.d32 = core_if->hr_backup->hprt0_local;
hprt0.b.prtrst = 1;
hprt0.b.prtpwr = 1;
hprt0.b.prtena = 0;
hprt0.b.prtsusp = 0;
DWC_WRITE_REG32(core_if->host_if->hprt0, hprt0.d32);
/* Wait for Reset time and then program HPRT again */
dwc_mdelay(60);
hprt0.b.prtrst = 0;
DWC_WRITE_REG32(core_if->host_if->hprt0, hprt0.d32);
}
/* Clear all interrupt status */
hprt0.d32 = dwc_otg_read_hprt0(core_if);
hprt0.b.prtconndet = 1;
hprt0.b.prtenchng = 1;
DWC_WRITE_REG32(core_if->host_if->hprt0, hprt0.d32);
/* Clear all pending interupts */
DWC_WRITE_REG32(&core_if->core_global_regs->gintsts, 0xFFFFFFFF);
/* Restore global registers */
dwc_otg_restore_global_regs(core_if);
/* Restore host global registers */
dwc_otg_restore_host_regs(core_if, reset);
/* The core will be in ON STATE */
core_if->lx_state = DWC_OTG_L0;
DWC_PRINTF("Hibernation recovery is complete here\n");
return 0;
}
/** Saves some register values into system memory. */
int dwc_otg_save_global_regs(dwc_otg_core_if_t * core_if)
{
struct dwc_otg_global_regs_backup *gr;
int i;
gr = core_if->gr_backup;
if (!gr) {
gr = DWC_ALLOC(sizeof(*gr));
if (!gr) {
return -DWC_E_NO_MEMORY;
}
core_if->gr_backup = gr;
}
gr->gotgctl_local = DWC_READ_REG32(&core_if->core_global_regs->gotgctl);
gr->gintmsk_local = DWC_READ_REG32(&core_if->core_global_regs->gintmsk);
gr->gahbcfg_local = DWC_READ_REG32(&core_if->core_global_regs->gahbcfg);
gr->gusbcfg_local = DWC_READ_REG32(&core_if->core_global_regs->gusbcfg);
gr->grxfsiz_local = DWC_READ_REG32(&core_if->core_global_regs->grxfsiz);
gr->gnptxfsiz_local = DWC_READ_REG32(&core_if->core_global_regs->gnptxfsiz);
gr->hptxfsiz_local = DWC_READ_REG32(&core_if->core_global_regs->hptxfsiz);
#ifdef CONFIG_USB_DWC_OTG_LPM
gr->glpmcfg_local = DWC_READ_REG32(&core_if->core_global_regs->glpmcfg);
#endif
gr->gi2cctl_local = DWC_READ_REG32(&core_if->core_global_regs->gi2cctl);
gr->pcgcctl_local = DWC_READ_REG32(core_if->pcgcctl);
gr->gdfifocfg_local =
DWC_READ_REG32(&core_if->core_global_regs->gdfifocfg);
for (i = 0; i < MAX_EPS_CHANNELS; i++) {
gr->dtxfsiz_local[i] =
DWC_READ_REG32(&(core_if->core_global_regs->dtxfsiz[i]));
}
DWC_DEBUGPL(DBG_ANY, "===========Backing Global registers==========\n");
DWC_DEBUGPL(DBG_ANY, "Backed up gotgctl = %08x\n", gr->gotgctl_local);
DWC_DEBUGPL(DBG_ANY, "Backed up gintmsk = %08x\n", gr->gintmsk_local);
DWC_DEBUGPL(DBG_ANY, "Backed up gahbcfg = %08x\n", gr->gahbcfg_local);
DWC_DEBUGPL(DBG_ANY, "Backed up gusbcfg = %08x\n", gr->gusbcfg_local);
DWC_DEBUGPL(DBG_ANY, "Backed up grxfsiz = %08x\n", gr->grxfsiz_local);
DWC_DEBUGPL(DBG_ANY, "Backed up gnptxfsiz = %08x\n",
gr->gnptxfsiz_local);
DWC_DEBUGPL(DBG_ANY, "Backed up hptxfsiz = %08x\n",
gr->hptxfsiz_local);
#ifdef CONFIG_USB_DWC_OTG_LPM
DWC_DEBUGPL(DBG_ANY, "Backed up glpmcfg = %08x\n", gr->glpmcfg_local);
#endif
DWC_DEBUGPL(DBG_ANY, "Backed up gi2cctl = %08x\n", gr->gi2cctl_local);
DWC_DEBUGPL(DBG_ANY, "Backed up pcgcctl = %08x\n", gr->pcgcctl_local);
DWC_DEBUGPL(DBG_ANY,"Backed up gdfifocfg = %08x\n",gr->gdfifocfg_local);
return 0;
}
/** Saves GINTMSK register before setting the msk bits. */
int dwc_otg_save_gintmsk_reg(dwc_otg_core_if_t * core_if)
{
struct dwc_otg_global_regs_backup *gr;
gr = core_if->gr_backup;
if (!gr) {
gr = DWC_ALLOC(sizeof(*gr));
if (!gr) {
return -DWC_E_NO_MEMORY;
}
core_if->gr_backup = gr;
}
gr->gintmsk_local = DWC_READ_REG32(&core_if->core_global_regs->gintmsk);
DWC_DEBUGPL(DBG_ANY,"=============Backing GINTMSK registers============\n");
DWC_DEBUGPL(DBG_ANY, "Backed up gintmsk = %08x\n", gr->gintmsk_local);
return 0;
}
int dwc_otg_save_dev_regs(dwc_otg_core_if_t * core_if)
{
struct dwc_otg_dev_regs_backup *dr;
int i;
dr = core_if->dr_backup;
if (!dr) {
dr = DWC_ALLOC(sizeof(*dr));
if (!dr) {
return -DWC_E_NO_MEMORY;
}
core_if->dr_backup = dr;
}
dr->dcfg = DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dcfg);
dr->dctl = DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dctl);
dr->daintmsk =
DWC_READ_REG32(&core_if->dev_if->dev_global_regs->daintmsk);
dr->diepmsk =
DWC_READ_REG32(&core_if->dev_if->dev_global_regs->diepmsk);
dr->doepmsk =
DWC_READ_REG32(&core_if->dev_if->dev_global_regs->doepmsk);
for (i = 0; i < core_if->dev_if->num_in_eps; ++i) {
dr->diepctl[i] =
DWC_READ_REG32(&core_if->dev_if->in_ep_regs[i]->diepctl);
dr->dieptsiz[i] =
DWC_READ_REG32(&core_if->dev_if->in_ep_regs[i]->dieptsiz);
dr->diepdma[i] =
DWC_READ_REG32(&core_if->dev_if->in_ep_regs[i]->diepdma);
}
DWC_DEBUGPL(DBG_ANY,
"=============Backing Host registers==============\n");
DWC_DEBUGPL(DBG_ANY, "Backed up dcfg = %08x\n", dr->dcfg);
DWC_DEBUGPL(DBG_ANY, "Backed up dctl = %08x\n", dr->dctl);
DWC_DEBUGPL(DBG_ANY, "Backed up daintmsk = %08x\n",
dr->daintmsk);
DWC_DEBUGPL(DBG_ANY, "Backed up diepmsk = %08x\n", dr->diepmsk);
DWC_DEBUGPL(DBG_ANY, "Backed up doepmsk = %08x\n", dr->doepmsk);
for (i = 0; i < core_if->dev_if->num_in_eps; ++i) {
DWC_DEBUGPL(DBG_ANY, "Backed up diepctl[%d] = %08x\n", i,
dr->diepctl[i]);
DWC_DEBUGPL(DBG_ANY, "Backed up dieptsiz[%d] = %08x\n",
i, dr->dieptsiz[i]);
DWC_DEBUGPL(DBG_ANY, "Backed up diepdma[%d] = %08x\n", i,
dr->diepdma[i]);
}
return 0;
}
int dwc_otg_save_host_regs(dwc_otg_core_if_t * core_if)
{
struct dwc_otg_host_regs_backup *hr;
int i;
hr = core_if->hr_backup;
if (!hr) {
hr = DWC_ALLOC(sizeof(*hr));
if (!hr) {
return -DWC_E_NO_MEMORY;
}
core_if->hr_backup = hr;
}
hr->hcfg_local =
DWC_READ_REG32(&core_if->host_if->host_global_regs->hcfg);
hr->haintmsk_local =
DWC_READ_REG32(&core_if->host_if->host_global_regs->haintmsk);
for (i = 0; i < dwc_otg_get_param_host_channels(core_if); ++i) {
hr->hcintmsk_local[i] =
DWC_READ_REG32(&core_if->host_if->hc_regs[i]->hcintmsk);
}
hr->hprt0_local = DWC_READ_REG32(core_if->host_if->hprt0);
hr->hfir_local =
DWC_READ_REG32(&core_if->host_if->host_global_regs->hfir);
DWC_DEBUGPL(DBG_ANY,
"=============Backing Host registers===============\n");
DWC_DEBUGPL(DBG_ANY, "Backed up hcfg = %08x\n",
hr->hcfg_local);
DWC_DEBUGPL(DBG_ANY, "Backed up haintmsk = %08x\n", hr->haintmsk_local);
for (i = 0; i < dwc_otg_get_param_host_channels(core_if); ++i) {
DWC_DEBUGPL(DBG_ANY, "Backed up hcintmsk[%02d]=%08x\n", i,
hr->hcintmsk_local[i]);
}
DWC_DEBUGPL(DBG_ANY, "Backed up hprt0 = %08x\n",
hr->hprt0_local);
DWC_DEBUGPL(DBG_ANY, "Backed up hfir = %08x\n",
hr->hfir_local);
return 0;
}
int dwc_otg_restore_global_regs(dwc_otg_core_if_t *core_if)
{
struct dwc_otg_global_regs_backup *gr;
int i;
gr = core_if->gr_backup;
if (!gr) {
return -DWC_E_INVALID;
}
DWC_WRITE_REG32(&core_if->core_global_regs->gotgctl, gr->gotgctl_local);
DWC_WRITE_REG32(&core_if->core_global_regs->gintmsk, gr->gintmsk_local);
DWC_WRITE_REG32(&core_if->core_global_regs->gusbcfg, gr->gusbcfg_local);
DWC_WRITE_REG32(&core_if->core_global_regs->gahbcfg, gr->gahbcfg_local);
DWC_WRITE_REG32(&core_if->core_global_regs->grxfsiz, gr->grxfsiz_local);
DWC_WRITE_REG32(&core_if->core_global_regs->gnptxfsiz,
gr->gnptxfsiz_local);
DWC_WRITE_REG32(&core_if->core_global_regs->hptxfsiz,
gr->hptxfsiz_local);
DWC_WRITE_REG32(&core_if->core_global_regs->gdfifocfg,
gr->gdfifocfg_local);
for (i = 0; i < MAX_EPS_CHANNELS; i++) {
DWC_WRITE_REG32(&core_if->core_global_regs->dtxfsiz[i],
gr->dtxfsiz_local[i]);
}
DWC_WRITE_REG32(&core_if->core_global_regs->gintsts, 0xFFFFFFFF);
DWC_WRITE_REG32(core_if->host_if->hprt0, 0x0000100A);
DWC_WRITE_REG32(&core_if->core_global_regs->gahbcfg,
(gr->gahbcfg_local));
return 0;
}
int dwc_otg_restore_dev_regs(dwc_otg_core_if_t * core_if, int rem_wakeup)
{
struct dwc_otg_dev_regs_backup *dr;
int i;
dr = core_if->dr_backup;
if (!dr) {
return -DWC_E_INVALID;
}
if (!rem_wakeup)
{
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->dctl, dr->dctl);
}
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->daintmsk, dr->daintmsk);
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->diepmsk, dr->diepmsk);
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->doepmsk, dr->doepmsk);
for (i = 0; i < core_if->dev_if->num_in_eps; ++i) {
DWC_WRITE_REG32(&core_if->dev_if->in_ep_regs[i]->diepctl, dr->diepctl[i]);
DWC_WRITE_REG32(&core_if->dev_if->in_ep_regs[i]->dieptsiz, dr->dieptsiz[i]);
DWC_WRITE_REG32(&core_if->dev_if->in_ep_regs[i]->diepdma, dr->diepdma[i]);
}
return 0;
}
int dwc_otg_restore_host_regs(dwc_otg_core_if_t * core_if, int reset)
{
struct dwc_otg_host_regs_backup *hr;
int i;
hr = core_if->hr_backup;
if (!hr) {
return -DWC_E_INVALID;
}
DWC_WRITE_REG32(&core_if->host_if->host_global_regs->hcfg, hr->hcfg_local);
//if (!reset)
//{
// DWC_WRITE_REG32(&core_if->host_if->host_global_regs->hfir, hr->hfir_local);
//}
DWC_WRITE_REG32(&core_if->host_if->host_global_regs->haintmsk,
hr->haintmsk_local);
for (i = 0; i < dwc_otg_get_param_host_channels(core_if); ++i) {
DWC_WRITE_REG32(&core_if->host_if->hc_regs[i]->hcintmsk,
hr->hcintmsk_local[i]);
}
return 0;
}
int restore_lpm_i2c_regs(dwc_otg_core_if_t * core_if)
{
struct dwc_otg_global_regs_backup *gr;
gr = core_if->gr_backup;
/* Restore values for LPM and I2C */
#ifdef CONFIG_USB_DWC_OTG_LPM
DWC_WRITE_REG32(&core_if->core_global_regs->glpmcfg, gr->glpmcfg_local);
#endif
DWC_WRITE_REG32(&core_if->core_global_regs->gi2cctl, gr->gi2cctl_local);
return 0;
}
int restore_essential_regs(dwc_otg_core_if_t * core_if, int rmode, int is_host)
{
struct dwc_otg_global_regs_backup *gr;
pcgcctl_data_t pcgcctl = {.d32 = 0 };
gahbcfg_data_t gahbcfg = {.d32 = 0 };
gusbcfg_data_t gusbcfg = {.d32 = 0 };
gintmsk_data_t gintmsk = {.d32 = 0 };
/* Restore LPM and I2C registers */
restore_lpm_i2c_regs(core_if);
/* Set PCGCCTL to 0 */
DWC_WRITE_REG32(core_if->pcgcctl, 0x00000000);
gr = core_if->gr_backup;
/* Load restore values for [31:14] bits */
DWC_WRITE_REG32(core_if->pcgcctl,
((gr->pcgcctl_local & 0xffffc000) | 0x00020000));
/* Umnask global Interrupt in GAHBCFG and restore it */
gahbcfg.d32 = gr->gahbcfg_local;
gahbcfg.b.glblintrmsk = 1;
DWC_WRITE_REG32(&core_if->core_global_regs->gahbcfg, gahbcfg.d32);
/* Clear all pending interupts */
DWC_WRITE_REG32(&core_if->core_global_regs->gintsts, 0xFFFFFFFF);
/* Unmask restore done interrupt */
gintmsk.b.restoredone = 1;
DWC_WRITE_REG32(&core_if->core_global_regs->gintmsk, gintmsk.d32);
/* Restore GUSBCFG and HCFG/DCFG */
gusbcfg.d32 = core_if->gr_backup->gusbcfg_local;
DWC_WRITE_REG32(&core_if->core_global_regs->gusbcfg, gusbcfg.d32);
if (is_host) {
hcfg_data_t hcfg = {.d32 = 0 };
hcfg.d32 = core_if->hr_backup->hcfg_local;
DWC_WRITE_REG32(&core_if->host_if->host_global_regs->hcfg,
hcfg.d32);
/* Load restore values for [31:14] bits */
pcgcctl.d32 = gr->pcgcctl_local & 0xffffc000;
pcgcctl.d32 = gr->pcgcctl_local | 0x00020000;
if (rmode)
pcgcctl.b.restoremode = 1;
DWC_WRITE_REG32(core_if->pcgcctl, pcgcctl.d32);
dwc_udelay(10);
/* Load restore values for [31:14] bits and set EssRegRestored bit */
pcgcctl.d32 = gr->pcgcctl_local | 0xffffc000;
pcgcctl.d32 = gr->pcgcctl_local & 0xffffc000;
pcgcctl.b.ess_reg_restored = 1;
if (rmode)
pcgcctl.b.restoremode = 1;
DWC_WRITE_REG32(core_if->pcgcctl, pcgcctl.d32);
} else {
dcfg_data_t dcfg = {.d32 = 0 };
dcfg.d32 = core_if->dr_backup->dcfg;
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->dcfg, dcfg.d32);
/* Load restore values for [31:14] bits */
pcgcctl.d32 = gr->pcgcctl_local & 0xffffc000;
pcgcctl.d32 = gr->pcgcctl_local | 0x00020000;
if (!rmode) {
pcgcctl.d32 |= 0x208;
}
DWC_WRITE_REG32(core_if->pcgcctl, pcgcctl.d32);
dwc_udelay(10);
/* Load restore values for [31:14] bits */
pcgcctl.d32 = gr->pcgcctl_local & 0xffffc000;
pcgcctl.d32 = gr->pcgcctl_local | 0x00020000;
pcgcctl.b.ess_reg_restored = 1;
if (!rmode)
pcgcctl.d32 |= 0x208;
DWC_WRITE_REG32(core_if->pcgcctl, pcgcctl.d32);
}
return 0;
}
/**
* Initializes the FSLSPClkSel field of the HCFG register depending on the PHY
* type.
*/
static void init_fslspclksel(dwc_otg_core_if_t * core_if)
{
uint32_t val;
hcfg_data_t hcfg;
if (((core_if->hwcfg2.b.hs_phy_type == 2) &&
(core_if->hwcfg2.b.fs_phy_type == 1) &&
(core_if->core_params->ulpi_fs_ls)) ||
(core_if->core_params->phy_type == DWC_PHY_TYPE_PARAM_FS)) {
/* Full speed PHY */
val = DWC_HCFG_48_MHZ;
} else {
/* High speed PHY running at full speed or high speed */
val = DWC_HCFG_30_60_MHZ;
}
DWC_DEBUGPL(DBG_CIL, "Initializing HCFG.FSLSPClkSel to 0x%1x\n", val);
hcfg.d32 = DWC_READ_REG32(&core_if->host_if->host_global_regs->hcfg);
hcfg.b.fslspclksel = val;
DWC_WRITE_REG32(&core_if->host_if->host_global_regs->hcfg, hcfg.d32);
}
/**
* Initializes the DevSpd field of the DCFG register depending on the PHY type
* and the enumeration speed of the device.
*/
static void init_devspd(dwc_otg_core_if_t * core_if)
{
uint32_t val;
dcfg_data_t dcfg;
if (((core_if->hwcfg2.b.hs_phy_type == 2) &&
(core_if->hwcfg2.b.fs_phy_type == 1) &&
(core_if->core_params->ulpi_fs_ls)) ||
(core_if->core_params->phy_type == DWC_PHY_TYPE_PARAM_FS)) {
/* Full speed PHY */
val = 0x3;
} else if (core_if->core_params->speed == DWC_SPEED_PARAM_FULL) {
/* High speed PHY running at full speed */
val = 0x1;
} else {
/* High speed PHY running at high speed */
val = 0x0;
}
DWC_DEBUGPL(DBG_CIL, "Initializing DCFG.DevSpd to 0x%1x\n", val);
dcfg.d32 = DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dcfg);
dcfg.b.devspd = val;
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->dcfg, dcfg.d32);
}
/**
* This function calculates the number of IN EPS
* using GHWCFG1 and GHWCFG2 registers values
*
* @param core_if Programming view of the DWC_otg controller
*/
static uint32_t calc_num_in_eps(dwc_otg_core_if_t * core_if)
{
uint32_t num_in_eps = 0;
uint32_t num_eps = core_if->hwcfg2.b.num_dev_ep;
uint32_t hwcfg1 = core_if->hwcfg1.d32 >> 3;
uint32_t num_tx_fifos = core_if->hwcfg4.b.num_in_eps;
int i;
for (i = 0; i < num_eps; ++i) {
if (!(hwcfg1 & 0x1))
num_in_eps++;
hwcfg1 >>= 2;
}
if (core_if->hwcfg4.b.ded_fifo_en) {
num_in_eps =
(num_in_eps > num_tx_fifos) ? num_tx_fifos : num_in_eps;
}
return num_in_eps;
}
/**
* This function calculates the number of OUT EPS
* using GHWCFG1 and GHWCFG2 registers values
*
* @param core_if Programming view of the DWC_otg controller
*/
static uint32_t calc_num_out_eps(dwc_otg_core_if_t * core_if)
{
uint32_t num_out_eps = 0;
uint32_t num_eps = core_if->hwcfg2.b.num_dev_ep;
uint32_t hwcfg1 = core_if->hwcfg1.d32 >> 2;
int i;
for (i = 0; i < num_eps; ++i) {
if (!(hwcfg1 & 0x1))
num_out_eps++;
hwcfg1 >>= 2;
}
return num_out_eps;
}
/**
* This function initializes the DWC_otg controller registers and
* prepares the core for device mode or host mode operation.
*
* @param core_if Programming view of the DWC_otg controller
*
*/
void dwc_otg_core_init(dwc_otg_core_if_t * core_if)
{
int i = 0;
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
dwc_otg_dev_if_t *dev_if = core_if->dev_if;
gahbcfg_data_t ahbcfg = {.d32 = 0 };
gusbcfg_data_t usbcfg = {.d32 = 0 };
gi2cctl_data_t i2cctl = {.d32 = 0 };
DWC_DEBUGPL(DBG_CILV, "dwc_otg_core_init(%p)\n", core_if);
/* Common Initialization */
usbcfg.d32 = DWC_READ_REG32(&global_regs->gusbcfg);
/* Program the ULPI External VBUS bit if needed */
usbcfg.b.ulpi_ext_vbus_drv =
(core_if->core_params->phy_ulpi_ext_vbus ==
DWC_PHY_ULPI_EXTERNAL_VBUS) ? 1 : 0;
/* Set external TS Dline pulsing */
usbcfg.b.term_sel_dl_pulse =
(core_if->core_params->ts_dline == 1) ? 1 : 0;
DWC_WRITE_REG32(&global_regs->gusbcfg, usbcfg.d32);
/* Reset the Controller */
dwc_otg_core_reset(core_if);
core_if->adp_enable = core_if->core_params->adp_supp_enable;
core_if->power_down = core_if->core_params->power_down;
core_if->otg_sts = 0;
/* Initialize parameters from Hardware configuration registers. */
dev_if->num_in_eps = calc_num_in_eps(core_if);
dev_if->num_out_eps = calc_num_out_eps(core_if);
DWC_DEBUGPL(DBG_CIL, "num_dev_perio_in_ep=%d\n",
core_if->hwcfg4.b.num_dev_perio_in_ep);
for (i = 0; i < core_if->hwcfg4.b.num_dev_perio_in_ep; i++) {
dev_if->perio_tx_fifo_size[i] =
DWC_READ_REG32(&global_regs->dtxfsiz[i]) >> 16;
DWC_DEBUGPL(DBG_CIL, "Periodic Tx FIFO SZ #%d=0x%0x\n",
i, dev_if->perio_tx_fifo_size[i]);
}
for (i = 0; i < core_if->hwcfg4.b.num_in_eps; i++) {
dev_if->tx_fifo_size[i] =
DWC_READ_REG32(&global_regs->dtxfsiz[i]) >> 16;
DWC_DEBUGPL(DBG_CIL, "Tx FIFO SZ #%d=0x%0x\n",
i, dev_if->tx_fifo_size[i]);
}
core_if->total_fifo_size = core_if->hwcfg3.b.dfifo_depth;
core_if->rx_fifo_size = DWC_READ_REG32(&global_regs->grxfsiz);
core_if->nperio_tx_fifo_size =
DWC_READ_REG32(&global_regs->gnptxfsiz) >> 16;
DWC_DEBUGPL(DBG_CIL, "Total FIFO SZ=%d\n", core_if->total_fifo_size);
DWC_DEBUGPL(DBG_CIL, "Rx FIFO SZ=%d\n", core_if->rx_fifo_size);
DWC_DEBUGPL(DBG_CIL, "NP Tx FIFO SZ=%d\n",
core_if->nperio_tx_fifo_size);
/* This programming sequence needs to happen in FS mode before any other
* programming occurs */
if ((core_if->core_params->speed == DWC_SPEED_PARAM_FULL) &&
(core_if->core_params->phy_type == DWC_PHY_TYPE_PARAM_FS)) {
/* If FS mode with FS PHY */
/* core_init() is now called on every switch so only call the
* following for the first time through. */
if (!core_if->phy_init_done) {
core_if->phy_init_done = 1;
DWC_DEBUGPL(DBG_CIL, "FS_PHY detected\n");
usbcfg.d32 = DWC_READ_REG32(&global_regs->gusbcfg);
usbcfg.b.physel = 1;
DWC_WRITE_REG32(&global_regs->gusbcfg, usbcfg.d32);
/* Reset after a PHY select */
dwc_otg_core_reset(core_if);
}
/* Program DCFG.DevSpd or HCFG.FSLSPclkSel to 48Mhz in FS. Also
* do this on HNP Dev/Host mode switches (done in dev_init and
* host_init). */
if (dwc_otg_is_host_mode(core_if)) {
init_fslspclksel(core_if);
} else {
init_devspd(core_if);
}
if (core_if->core_params->i2c_enable) {
DWC_DEBUGPL(DBG_CIL, "FS_PHY Enabling I2c\n");
/* Program GUSBCFG.OtgUtmifsSel to I2C */
usbcfg.d32 = DWC_READ_REG32(&global_regs->gusbcfg);
usbcfg.b.otgutmifssel = 1;
DWC_WRITE_REG32(&global_regs->gusbcfg, usbcfg.d32);
/* Program GI2CCTL.I2CEn */
i2cctl.d32 = DWC_READ_REG32(&global_regs->gi2cctl);
i2cctl.b.i2cdevaddr = 1;
i2cctl.b.i2cen = 0;
DWC_WRITE_REG32(&global_regs->gi2cctl, i2cctl.d32);
i2cctl.b.i2cen = 1;
DWC_WRITE_REG32(&global_regs->gi2cctl, i2cctl.d32);
}
} /* endif speed == DWC_SPEED_PARAM_FULL */
else {
/* High speed PHY. */
if (!core_if->phy_init_done) {
core_if->phy_init_done = 1;
/* HS PHY parameters. These parameters are preserved
* during soft reset so only program the first time. Do
* a soft reset immediately after setting phyif. */
if (core_if->core_params->phy_type == 2) {
/* ULPI interface */
usbcfg.b.ulpi_utmi_sel = 1;
usbcfg.b.phyif = 0;
usbcfg.b.ddrsel =
core_if->core_params->phy_ulpi_ddr;
} else if (core_if->core_params->phy_type == 1) {
/* UTMI+ interface */
usbcfg.b.ulpi_utmi_sel = 0;
if (core_if->core_params->phy_utmi_width == 16) {
usbcfg.b.phyif = 1;
} else {
usbcfg.b.phyif = 0;
}
} else {
DWC_ERROR("FS PHY TYPE\n");
}
DWC_WRITE_REG32(&global_regs->gusbcfg, usbcfg.d32);
/* Reset after setting the PHY parameters */
dwc_otg_core_reset(core_if);
}
}
if ((core_if->hwcfg2.b.hs_phy_type == 2) &&
(core_if->hwcfg2.b.fs_phy_type == 1) &&
(core_if->core_params->ulpi_fs_ls)) {
DWC_DEBUGPL(DBG_CIL, "Setting ULPI FSLS\n");
usbcfg.d32 = DWC_READ_REG32(&global_regs->gusbcfg);
usbcfg.b.ulpi_fsls = 1;
usbcfg.b.ulpi_clk_sus_m = 1;
DWC_WRITE_REG32(&global_regs->gusbcfg, usbcfg.d32);
} else {
usbcfg.d32 = DWC_READ_REG32(&global_regs->gusbcfg);
usbcfg.b.ulpi_fsls = 0;
usbcfg.b.ulpi_clk_sus_m = 0;
DWC_WRITE_REG32(&global_regs->gusbcfg, usbcfg.d32);
}
/* Program the GAHBCFG Register. */
switch (core_if->hwcfg2.b.architecture) {
case DWC_SLAVE_ONLY_ARCH:
DWC_DEBUGPL(DBG_CIL, "Slave Only Mode\n");
ahbcfg.b.nptxfemplvl_txfemplvl =
DWC_GAHBCFG_TXFEMPTYLVL_HALFEMPTY;
ahbcfg.b.ptxfemplvl = DWC_GAHBCFG_TXFEMPTYLVL_HALFEMPTY;
core_if->dma_enable = 0;
core_if->dma_desc_enable = 0;
break;
case DWC_EXT_DMA_ARCH:
DWC_DEBUGPL(DBG_CIL, "External DMA Mode\n");
{
uint8_t brst_sz = core_if->core_params->dma_burst_size;
ahbcfg.b.hburstlen = 0;
while (brst_sz > 1) {
ahbcfg.b.hburstlen++;
brst_sz >>= 1;
}
}
core_if->dma_enable = (core_if->core_params->dma_enable != 0);
core_if->dma_desc_enable =
(core_if->core_params->dma_desc_enable != 0);
break;
case DWC_INT_DMA_ARCH:
DWC_DEBUGPL(DBG_CIL, "Internal DMA Mode\n");
/* Old value was DWC_GAHBCFG_INT_DMA_BURST_INCR - done for
Host mode ISOC in issue fix - vahrama */
ahbcfg.b.hburstlen = DWC_GAHBCFG_INT_DMA_BURST_INCR16;
core_if->dma_enable = (core_if->core_params->dma_enable != 0);
core_if->dma_desc_enable =
(core_if->core_params->dma_desc_enable != 0);
break;
}
if (core_if->dma_enable) {
if (core_if->dma_desc_enable) {
DWC_PRINTF("Using Descriptor DMA mode\n");
} else {
DWC_PRINTF("Using Buffer DMA mode\n");
}
} else {
DWC_PRINTF("Using Slave mode\n");
core_if->dma_desc_enable = 0;
}
if (core_if->core_params->ahb_single) {
ahbcfg.b.ahbsingle = 1;
}
ahbcfg.b.dmaenable = core_if->dma_enable;
DWC_WRITE_REG32(&global_regs->gahbcfg, ahbcfg.d32);
core_if->en_multiple_tx_fifo = core_if->hwcfg4.b.ded_fifo_en;
core_if->pti_enh_enable = core_if->core_params->pti_enable != 0;
core_if->multiproc_int_enable = core_if->core_params->mpi_enable;
DWC_PRINTF("Periodic Transfer Interrupt Enhancement - %s\n",
((core_if->pti_enh_enable) ? "enabled" : "disabled"));
DWC_PRINTF("Multiprocessor Interrupt Enhancement - %s\n",
((core_if->multiproc_int_enable) ? "enabled" : "disabled"));
/*
* Program the GUSBCFG register.
*/
usbcfg.d32 = DWC_READ_REG32(&global_regs->gusbcfg);
switch (core_if->hwcfg2.b.op_mode) {
case DWC_MODE_HNP_SRP_CAPABLE:
usbcfg.b.hnpcap = (core_if->core_params->otg_cap ==
DWC_OTG_CAP_PARAM_HNP_SRP_CAPABLE);
usbcfg.b.srpcap = (core_if->core_params->otg_cap !=
DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE);
break;
case DWC_MODE_SRP_ONLY_CAPABLE:
usbcfg.b.hnpcap = 0;
usbcfg.b.srpcap = (core_if->core_params->otg_cap !=
DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE);
break;
case DWC_MODE_NO_HNP_SRP_CAPABLE:
usbcfg.b.hnpcap = 0;
usbcfg.b.srpcap = 0;
break;
case DWC_MODE_SRP_CAPABLE_DEVICE:
usbcfg.b.hnpcap = 0;
usbcfg.b.srpcap = (core_if->core_params->otg_cap !=
DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE);
break;
case DWC_MODE_NO_SRP_CAPABLE_DEVICE:
usbcfg.b.hnpcap = 0;
usbcfg.b.srpcap = 0;
break;
case DWC_MODE_SRP_CAPABLE_HOST:
usbcfg.b.hnpcap = 0;
usbcfg.b.srpcap = (core_if->core_params->otg_cap !=
DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE);
break;
case DWC_MODE_NO_SRP_CAPABLE_HOST:
usbcfg.b.hnpcap = 0;
usbcfg.b.srpcap = 0;
break;
}
DWC_WRITE_REG32(&global_regs->gusbcfg, usbcfg.d32);
#ifdef CONFIG_USB_DWC_OTG_LPM
if (core_if->core_params->lpm_enable) {
glpmcfg_data_t lpmcfg = {.d32 = 0 };
/* To enable LPM support set lpm_cap_en bit */
lpmcfg.b.lpm_cap_en = 1;
/* Make AppL1Res ACK */
lpmcfg.b.appl_resp = 1;
/* Retry 3 times */
lpmcfg.b.retry_count = 3;
DWC_MODIFY_REG32(&core_if->core_global_regs->glpmcfg,
0, lpmcfg.d32);
}
#endif
if (core_if->core_params->ic_usb_cap) {
gusbcfg_data_t gusbcfg = {.d32 = 0 };
gusbcfg.b.ic_usb_cap = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gusbcfg,
0, gusbcfg.d32);
}
{
gotgctl_data_t gotgctl = {.d32 = 0 };
gotgctl.b.otgver = core_if->core_params->otg_ver;
DWC_MODIFY_REG32(&core_if->core_global_regs->gotgctl, 0,
gotgctl.d32);
/* Set OTG version supported */
core_if->otg_ver = core_if->core_params->otg_ver;
DWC_PRINTF("OTG VER PARAM: %d, OTG VER FLAG: %d\n",
core_if->core_params->otg_ver, core_if->otg_ver);
}
/* Enable common interrupts */
dwc_otg_enable_common_interrupts(core_if);
/* Do device or host intialization based on mode during PCD
* and HCD initialization */
if (dwc_otg_is_host_mode(core_if)) {
DWC_DEBUGPL(DBG_ANY, "Host Mode\n");
core_if->op_state = A_HOST;
} else {
DWC_DEBUGPL(DBG_ANY, "Device Mode\n");
core_if->op_state = B_PERIPHERAL;
#ifdef DWC_DEVICE_ONLY
dwc_otg_core_dev_init(core_if);
#endif
}
}
/**
* This function enables the Device mode interrupts.
*
* @param core_if Programming view of DWC_otg controller
*/
void dwc_otg_enable_device_interrupts(dwc_otg_core_if_t * core_if)
{
gintmsk_data_t intr_mask = {.d32 = 0 };
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
DWC_DEBUGPL(DBG_CIL, "%s()\n", __func__);
/* Disable all interrupts. */
DWC_WRITE_REG32(&global_regs->gintmsk, 0);
/* Clear any pending interrupts */
DWC_WRITE_REG32(&global_regs->gintsts, 0xFFFFFFFF);
/* Enable the common interrupts */
dwc_otg_enable_common_interrupts(core_if);
/* Enable interrupts */
intr_mask.b.usbreset = 1;
intr_mask.b.enumdone = 1;
/* Disable Disconnect interrupt in Device mode */
intr_mask.b.disconnect = 0;
if (!core_if->multiproc_int_enable) {
intr_mask.b.inepintr = 1;
intr_mask.b.outepintr = 1;
}
intr_mask.b.erlysuspend = 1;
if (core_if->en_multiple_tx_fifo == 0) {
intr_mask.b.epmismatch = 1;
}
//intr_mask.b.incomplisoout = 1;
intr_mask.b.incomplisoin = 1;
/* Enable the ignore frame number for ISOC xfers - MAS */
/* Disable to support high bandwith ISOC transfers - manukz */
#if 0
#ifdef DWC_UTE_PER_IO
if (core_if->dma_enable) {
if (core_if->dma_desc_enable) {
dctl_data_t dctl1 = {.d32 = 0 };
dctl1.b.ifrmnum = 1;
DWC_MODIFY_REG32(&core_if->dev_if->dev_global_regs->
dctl, 0, dctl1.d32);
DWC_DEBUG("----Enabled Ignore frame number (0x%08x)",
DWC_READ_REG32(&core_if->dev_if->
dev_global_regs->dctl));
}
}
#endif
#endif
#ifdef DWC_EN_ISOC
if (core_if->dma_enable) {
if (core_if->dma_desc_enable == 0) {
if (core_if->pti_enh_enable) {
dctl_data_t dctl = {.d32 = 0 };
dctl.b.ifrmnum = 1;
DWC_MODIFY_REG32(&core_if->
dev_if->dev_global_regs->dctl,
0, dctl.d32);
} else {
intr_mask.b.incomplisoin = 1;
intr_mask.b.incomplisoout = 1;
}
}
} else {
intr_mask.b.incomplisoin = 1;
intr_mask.b.incomplisoout = 1;
}
#endif /* DWC_EN_ISOC */
/** @todo NGS: Should this be a module parameter? */
#ifdef USE_PERIODIC_EP
intr_mask.b.isooutdrop = 1;
intr_mask.b.eopframe = 1;
intr_mask.b.incomplisoin = 1;
intr_mask.b.incomplisoout = 1;
#endif
DWC_MODIFY_REG32(&global_regs->gintmsk, intr_mask.d32, intr_mask.d32);
DWC_DEBUGPL(DBG_CIL, "%s() gintmsk=%0x\n", __func__,
DWC_READ_REG32(&global_regs->gintmsk));
}
/**
* This function initializes the DWC_otg controller registers for
* device mode.
*
* @param core_if Programming view of DWC_otg controller
*
*/
void dwc_otg_core_dev_init(dwc_otg_core_if_t * core_if)
{
int i;
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
dwc_otg_dev_if_t *dev_if = core_if->dev_if;
dwc_otg_core_params_t *params = core_if->core_params;
dcfg_data_t dcfg = {.d32 = 0 };
depctl_data_t diepctl = {.d32 = 0 };
grstctl_t resetctl = {.d32 = 0 };
uint32_t rx_fifo_size;
fifosize_data_t nptxfifosize;
fifosize_data_t txfifosize;
dthrctl_data_t dthrctl;
fifosize_data_t ptxfifosize;
uint16_t rxfsiz, nptxfsiz;
gdfifocfg_data_t gdfifocfg = {.d32 = 0 };
hwcfg3_data_t hwcfg3 = {.d32 = 0 };
/* Restart the Phy Clock */
DWC_WRITE_REG32(core_if->pcgcctl, 0);
/* Device configuration register */
init_devspd(core_if);
dcfg.d32 = DWC_READ_REG32(&dev_if->dev_global_regs->dcfg);
dcfg.b.descdma = (core_if->dma_desc_enable) ? 1 : 0;
dcfg.b.perfrint = DWC_DCFG_FRAME_INTERVAL_80;
/* Enable Device OUT NAK in case of DDMA mode*/
if (core_if->core_params->dev_out_nak) {
dcfg.b.endevoutnak = 1;
}
if (core_if->core_params->cont_on_bna) {
dctl_data_t dctl = {.d32 = 0 };
dctl.b.encontonbna = 1;
DWC_MODIFY_REG32(&dev_if->dev_global_regs->dctl, 0, dctl.d32);
}
DWC_WRITE_REG32(&dev_if->dev_global_regs->dcfg, dcfg.d32);
/* Configure data FIFO sizes */
if (core_if->hwcfg2.b.dynamic_fifo && params->enable_dynamic_fifo) {
DWC_DEBUGPL(DBG_CIL, "Total FIFO Size=%d\n",
core_if->total_fifo_size);
DWC_DEBUGPL(DBG_CIL, "Rx FIFO Size=%d\n",
params->dev_rx_fifo_size);
DWC_DEBUGPL(DBG_CIL, "NP Tx FIFO Size=%d\n",
params->dev_nperio_tx_fifo_size);
/* Rx FIFO */
DWC_DEBUGPL(DBG_CIL, "initial grxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->grxfsiz));
#ifdef DWC_UTE_CFI
core_if->pwron_rxfsiz = DWC_READ_REG32(&global_regs->grxfsiz);
core_if->init_rxfsiz = params->dev_rx_fifo_size;
#endif
rx_fifo_size = params->dev_rx_fifo_size;
DWC_WRITE_REG32(&global_regs->grxfsiz, rx_fifo_size);
DWC_DEBUGPL(DBG_CIL, "new grxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->grxfsiz));
/** Set Periodic Tx FIFO Mask all bits 0 */
core_if->p_tx_msk = 0;
/** Set Tx FIFO Mask all bits 0 */
core_if->tx_msk = 0;
if (core_if->en_multiple_tx_fifo == 0) {
/* Non-periodic Tx FIFO */
DWC_DEBUGPL(DBG_CIL, "initial gnptxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->gnptxfsiz));
nptxfifosize.b.depth = params->dev_nperio_tx_fifo_size;
nptxfifosize.b.startaddr = 0x400;
DWC_WRITE_REG32(&global_regs->gnptxfsiz,
nptxfifosize.d32);
DWC_DEBUGPL(DBG_CIL, "new gnptxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->gnptxfsiz));
/**@todo NGS: Fix Periodic FIFO Sizing! */
/*
* Periodic Tx FIFOs These FIFOs are numbered from 1 to 15.
* Indexes of the FIFO size module parameters in the
* dev_perio_tx_fifo_size array and the FIFO size registers in
* the dptxfsiz array run from 0 to 14.
*/
/** @todo Finish debug of this */
ptxfifosize.b.startaddr =
nptxfifosize.b.startaddr + nptxfifosize.b.depth;
for (i = 0; i < core_if->hwcfg4.b.num_dev_perio_in_ep; i++) {
ptxfifosize.b.depth =
params->dev_perio_tx_fifo_size[i];
DWC_DEBUGPL(DBG_CIL,
"initial dtxfsiz[%d]=%08x\n", i,
DWC_READ_REG32(&global_regs->dtxfsiz
[i]));
DWC_WRITE_REG32(&global_regs->dtxfsiz[i],
ptxfifosize.d32);
DWC_DEBUGPL(DBG_CIL, "new dtxfsiz[%d]=%08x\n",
i,
DWC_READ_REG32(&global_regs->dtxfsiz
[i]));
ptxfifosize.b.startaddr += ptxfifosize.b.depth;
}
} else {
/*
* Tx FIFOs These FIFOs are numbered from 1 to 15.
* Indexes of the FIFO size module parameters in the
* dev_tx_fifo_size array and the FIFO size registers in
* the dtxfsiz array run from 0 to 14.
*/
/* Non-periodic Tx FIFO */
DWC_DEBUGPL(DBG_CIL, "initial gnptxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->gnptxfsiz));
#ifdef DWC_UTE_CFI
core_if->pwron_gnptxfsiz =
(DWC_READ_REG32(&global_regs->gnptxfsiz) >> 16);
core_if->init_gnptxfsiz =
params->dev_nperio_tx_fifo_size;
#endif
nptxfifosize.b.depth = params->dev_nperio_tx_fifo_size;
nptxfifosize.b.startaddr = 0x400;
DWC_WRITE_REG32(&global_regs->gnptxfsiz,
nptxfifosize.d32);
DWC_DEBUGPL(DBG_CIL, "new gnptxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->gnptxfsiz));
txfifosize.b.startaddr =
nptxfifosize.b.startaddr + nptxfifosize.b.depth;
for (i = 0; i < core_if->hwcfg4.b.num_in_eps; i++) {
txfifosize.b.depth =
params->dev_tx_fifo_size[i];
DWC_DEBUGPL(DBG_CIL,
"initial dtxfsiz[%d]=%08x\n",
i,
DWC_READ_REG32(&global_regs->dtxfsiz
[i]));
#ifdef DWC_UTE_CFI
core_if->pwron_txfsiz[i] =
(DWC_READ_REG32
(&global_regs->dtxfsiz[i]) >> 16);
core_if->init_txfsiz[i] =
params->dev_tx_fifo_size[i];
#endif
DWC_WRITE_REG32(&global_regs->dtxfsiz[i],
txfifosize.d32);
DWC_DEBUGPL(DBG_CIL,
"new dtxfsiz[%d]=%08x\n",
i,
DWC_READ_REG32(&global_regs->dtxfsiz
[i]));
txfifosize.b.startaddr += txfifosize.b.depth;
}
/* Calculating DFIFOCFG for Device mode to include RxFIFO and NPTXFIFO */
gdfifocfg.d32 = DWC_READ_REG32(&global_regs->gdfifocfg);
hwcfg3.d32 = DWC_READ_REG32(&global_regs->ghwcfg3);
gdfifocfg.b.gdfifocfg = (DWC_READ_REG32(&global_regs->ghwcfg3) >> 16);
DWC_WRITE_REG32(&global_regs->gdfifocfg, gdfifocfg.d32);
rxfsiz = (DWC_READ_REG32(&global_regs->grxfsiz) & 0x0000ffff);
nptxfsiz = (DWC_READ_REG32(&global_regs->gnptxfsiz) >> 16);
gdfifocfg.b.epinfobase = rxfsiz + nptxfsiz;
DWC_WRITE_REG32(&global_regs->gdfifocfg, gdfifocfg.d32);
}
}
/* Flush the FIFOs */
dwc_otg_flush_tx_fifo(core_if, 0x10); /* all Tx FIFOs */
dwc_otg_flush_rx_fifo(core_if);
/* Flush the Learning Queue. */
resetctl.b.intknqflsh = 1;
DWC_WRITE_REG32(&core_if->core_global_regs->grstctl, resetctl.d32);
if (!core_if->core_params->en_multiple_tx_fifo && core_if->dma_enable) {
core_if->start_predict = 0;
for (i = 0; i<= core_if->dev_if->num_in_eps; ++i) {
core_if->nextep_seq[i] = 0xff; // 0xff - EP not active
}
core_if->nextep_seq[0] = 0;
core_if->first_in_nextep_seq = 0;
diepctl.d32 = DWC_READ_REG32(&dev_if->in_ep_regs[0]->diepctl);
diepctl.b.nextep = 0;
DWC_WRITE_REG32(&dev_if->in_ep_regs[0]->diepctl, diepctl.d32);
/* Update IN Endpoint Mismatch Count by active IN NP EP count + 1 */
dcfg.d32 = DWC_READ_REG32(&dev_if->dev_global_regs->dcfg);
dcfg.b.epmscnt = 2;
DWC_WRITE_REG32(&dev_if->dev_global_regs->dcfg, dcfg.d32);
DWC_DEBUGPL(DBG_CILV,"%s first_in_nextep_seq= %2d; nextep_seq[]:\n",
__func__, core_if->first_in_nextep_seq);
for (i=0; i <= core_if->dev_if->num_in_eps; i++) {
DWC_DEBUGPL(DBG_CILV, "%2d ", core_if->nextep_seq[i]);
}
DWC_DEBUGPL(DBG_CILV,"\n");
}
/* Clear all pending Device Interrupts */
/** @todo - if the condition needed to be checked
* or in any case all pending interrutps should be cleared?
*/
if (core_if->multiproc_int_enable) {
for (i = 0; i < core_if->dev_if->num_in_eps; ++i) {
DWC_WRITE_REG32(&dev_if->
dev_global_regs->diepeachintmsk[i], 0);
}
for (i = 0; i < core_if->dev_if->num_out_eps; ++i) {
DWC_WRITE_REG32(&dev_if->
dev_global_regs->doepeachintmsk[i], 0);
}
DWC_WRITE_REG32(&dev_if->dev_global_regs->deachint, 0xFFFFFFFF);
DWC_WRITE_REG32(&dev_if->dev_global_regs->deachintmsk, 0);
} else {
DWC_WRITE_REG32(&dev_if->dev_global_regs->diepmsk, 0);
DWC_WRITE_REG32(&dev_if->dev_global_regs->doepmsk, 0);
DWC_WRITE_REG32(&dev_if->dev_global_regs->daint, 0xFFFFFFFF);
DWC_WRITE_REG32(&dev_if->dev_global_regs->daintmsk, 0);
}
for (i = 0; i <= dev_if->num_in_eps; i++) {
depctl_data_t depctl;
depctl.d32 = DWC_READ_REG32(&dev_if->in_ep_regs[i]->diepctl);
if (depctl.b.epena) {
depctl.d32 = 0;
depctl.b.epdis = 1;
depctl.b.snak = 1;
} else {
depctl.d32 = 0;
}
DWC_WRITE_REG32(&dev_if->in_ep_regs[i]->diepctl, depctl.d32);
DWC_WRITE_REG32(&dev_if->in_ep_regs[i]->dieptsiz, 0);
DWC_WRITE_REG32(&dev_if->in_ep_regs[i]->diepdma, 0);
DWC_WRITE_REG32(&dev_if->in_ep_regs[i]->diepint, 0xFF);
}
for (i = 0; i <= dev_if->num_out_eps; i++) {
depctl_data_t depctl;
depctl.d32 = DWC_READ_REG32(&dev_if->out_ep_regs[i]->doepctl);
if (depctl.b.epena) {
depctl.d32 = 0;
depctl.b.epdis = 1;
depctl.b.snak = 1;
} else {
depctl.d32 = 0;
}
DWC_WRITE_REG32(&dev_if->out_ep_regs[i]->doepctl, depctl.d32);
DWC_WRITE_REG32(&dev_if->out_ep_regs[i]->doeptsiz, 0);
DWC_WRITE_REG32(&dev_if->out_ep_regs[i]->doepdma, 0);
DWC_WRITE_REG32(&dev_if->out_ep_regs[i]->doepint, 0xFF);
}
if (core_if->en_multiple_tx_fifo && core_if->dma_enable) {
dev_if->non_iso_tx_thr_en = params->thr_ctl & 0x1;
dev_if->iso_tx_thr_en = (params->thr_ctl >> 1) & 0x1;
dev_if->rx_thr_en = (params->thr_ctl >> 2) & 0x1;
dev_if->rx_thr_length = params->rx_thr_length;
dev_if->tx_thr_length = params->tx_thr_length;
dev_if->setup_desc_index = 0;
dthrctl.d32 = 0;
dthrctl.b.non_iso_thr_en = dev_if->non_iso_tx_thr_en;
dthrctl.b.iso_thr_en = dev_if->iso_tx_thr_en;
dthrctl.b.tx_thr_len = dev_if->tx_thr_length;
dthrctl.b.rx_thr_en = dev_if->rx_thr_en;
dthrctl.b.rx_thr_len = dev_if->rx_thr_length;
dthrctl.b.ahb_thr_ratio = params->ahb_thr_ratio;
DWC_WRITE_REG32(&dev_if->dev_global_regs->dtknqr3_dthrctl,
dthrctl.d32);
DWC_DEBUGPL(DBG_CIL,
"Non ISO Tx Thr - %d\nISO Tx Thr - %d\nRx Thr - %d\nTx Thr Len - %d\nRx Thr Len - %d\n",
dthrctl.b.non_iso_thr_en, dthrctl.b.iso_thr_en,
dthrctl.b.rx_thr_en, dthrctl.b.tx_thr_len,
dthrctl.b.rx_thr_len);
}
dwc_otg_enable_device_interrupts(core_if);
{
diepmsk_data_t msk = {.d32 = 0 };
msk.b.txfifoundrn = 1;
if (core_if->multiproc_int_enable) {
DWC_MODIFY_REG32(&dev_if->
dev_global_regs->diepeachintmsk[0],
msk.d32, msk.d32);
} else {
DWC_MODIFY_REG32(&dev_if->dev_global_regs->diepmsk,
msk.d32, msk.d32);
}
}
if (core_if->multiproc_int_enable) {
/* Set NAK on Babble */
dctl_data_t dctl = {.d32 = 0 };
dctl.b.nakonbble = 1;
DWC_MODIFY_REG32(&dev_if->dev_global_regs->dctl, 0, dctl.d32);
}
if (core_if->snpsid >= OTG_CORE_REV_2_94a) {
dctl_data_t dctl = {.d32 = 0 };
dctl.d32 = DWC_READ_REG32(&dev_if->dev_global_regs->dctl);
dctl.b.sftdiscon = 0;
DWC_WRITE_REG32(&dev_if->dev_global_regs->dctl, dctl.d32);
}
}
/**
* This function enables the Host mode interrupts.
*
* @param core_if Programming view of DWC_otg controller
*/
void dwc_otg_enable_host_interrupts(dwc_otg_core_if_t * core_if)
{
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
gintmsk_data_t intr_mask = {.d32 = 0 };
DWC_DEBUGPL(DBG_CIL, "%s()\n", __func__);
/* Disable all interrupts. */
DWC_WRITE_REG32(&global_regs->gintmsk, 0);
/* Clear any pending interrupts. */
DWC_WRITE_REG32(&global_regs->gintsts, 0xFFFFFFFF);
/* Enable the common interrupts */
dwc_otg_enable_common_interrupts(core_if);
/*
* Enable host mode interrupts without disturbing common
* interrupts.
*/
intr_mask.b.disconnect = 1;
intr_mask.b.portintr = 1;
intr_mask.b.hcintr = 1;
DWC_MODIFY_REG32(&global_regs->gintmsk, intr_mask.d32, intr_mask.d32);
}
/**
* This function disables the Host Mode interrupts.
*
* @param core_if Programming view of DWC_otg controller
*/
void dwc_otg_disable_host_interrupts(dwc_otg_core_if_t * core_if)
{
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
gintmsk_data_t intr_mask = {.d32 = 0 };
DWC_DEBUGPL(DBG_CILV, "%s()\n", __func__);
/*
* Disable host mode interrupts without disturbing common
* interrupts.
*/
intr_mask.b.sofintr = 1;
intr_mask.b.portintr = 1;
intr_mask.b.hcintr = 1;
intr_mask.b.ptxfempty = 1;
intr_mask.b.nptxfempty = 1;
DWC_MODIFY_REG32(&global_regs->gintmsk, intr_mask.d32, 0);
}
/**
* This function initializes the DWC_otg controller registers for
* host mode.
*
* This function flushes the Tx and Rx FIFOs and it flushes any entries in the
* request queues. Host channels are reset to ensure that they are ready for
* performing transfers.
*
* @param core_if Programming view of DWC_otg controller
*
*/
void dwc_otg_core_host_init(dwc_otg_core_if_t * core_if)
{
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
dwc_otg_host_if_t *host_if = core_if->host_if;
dwc_otg_core_params_t *params = core_if->core_params;
hprt0_data_t hprt0 = {.d32 = 0 };
fifosize_data_t nptxfifosize;
fifosize_data_t ptxfifosize;
uint16_t rxfsiz, nptxfsiz, hptxfsiz;
gdfifocfg_data_t gdfifocfg = {.d32 = 0 };
int i;
hcchar_data_t hcchar;
hcfg_data_t hcfg;
hfir_data_t hfir;
dwc_otg_hc_regs_t *hc_regs;
int num_channels;
gotgctl_data_t gotgctl = {.d32 = 0 };
DWC_DEBUGPL(DBG_CILV, "%s(%p)\n", __func__, core_if);
/* Restart the Phy Clock */
DWC_WRITE_REG32(core_if->pcgcctl, 0);
/* Initialize Host Configuration Register */
init_fslspclksel(core_if);
if (core_if->core_params->speed == DWC_SPEED_PARAM_FULL) {
hcfg.d32 = DWC_READ_REG32(&host_if->host_global_regs->hcfg);
hcfg.b.fslssupp = 1;
DWC_WRITE_REG32(&host_if->host_global_regs->hcfg, hcfg.d32);
}
/* This bit allows dynamic reloading of the HFIR register
* during runtime. This bit needs to be programmed during
* initial configuration and its value must not be changed
* during runtime.*/
if (core_if->core_params->reload_ctl == 1) {
hfir.d32 = DWC_READ_REG32(&host_if->host_global_regs->hfir);
hfir.b.hfirrldctrl = 1;
DWC_WRITE_REG32(&host_if->host_global_regs->hfir, hfir.d32);
}
if (core_if->core_params->dma_desc_enable) {
uint8_t op_mode = core_if->hwcfg2.b.op_mode;
if (!
(core_if->hwcfg4.b.desc_dma
&& (core_if->snpsid >= OTG_CORE_REV_2_90a)
&& ((op_mode == DWC_HWCFG2_OP_MODE_HNP_SRP_CAPABLE_OTG)
|| (op_mode == DWC_HWCFG2_OP_MODE_SRP_ONLY_CAPABLE_OTG)
|| (op_mode ==
DWC_HWCFG2_OP_MODE_NO_HNP_SRP_CAPABLE_OTG)
|| (op_mode == DWC_HWCFG2_OP_MODE_SRP_CAPABLE_HOST)
|| (op_mode ==
DWC_HWCFG2_OP_MODE_NO_SRP_CAPABLE_HOST)))) {
DWC_ERROR("Host can't operate in Descriptor DMA mode.\n"
"Either core version is below 2.90a or "
"GHWCFG2, GHWCFG4 registers' values do not allow Descriptor DMA in host mode.\n"
"To run the driver in Buffer DMA host mode set dma_desc_enable "
"module parameter to 0.\n");
return;
}
hcfg.d32 = DWC_READ_REG32(&host_if->host_global_regs->hcfg);
hcfg.b.descdma = 1;
DWC_WRITE_REG32(&host_if->host_global_regs->hcfg, hcfg.d32);
}
/* Configure data FIFO sizes */
if (core_if->hwcfg2.b.dynamic_fifo && params->enable_dynamic_fifo) {
DWC_DEBUGPL(DBG_CIL, "Total FIFO Size=%d\n",
core_if->total_fifo_size);
DWC_DEBUGPL(DBG_CIL, "Rx FIFO Size=%d\n",
params->host_rx_fifo_size);
DWC_DEBUGPL(DBG_CIL, "NP Tx FIFO Size=%d\n",
params->host_nperio_tx_fifo_size);
DWC_DEBUGPL(DBG_CIL, "P Tx FIFO Size=%d\n",
params->host_perio_tx_fifo_size);
/* Rx FIFO */
DWC_DEBUGPL(DBG_CIL, "initial grxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->grxfsiz));
DWC_WRITE_REG32(&global_regs->grxfsiz,
params->host_rx_fifo_size);
DWC_DEBUGPL(DBG_CIL, "new grxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->grxfsiz));
/* Non-periodic Tx FIFO */
DWC_DEBUGPL(DBG_CIL, "initial gnptxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->gnptxfsiz));
nptxfifosize.b.depth = params->host_nperio_tx_fifo_size;
nptxfifosize.b.startaddr = 0x400;
DWC_WRITE_REG32(&global_regs->gnptxfsiz, nptxfifosize.d32);
DWC_DEBUGPL(DBG_CIL, "new gnptxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->gnptxfsiz));
/* Periodic Tx FIFO */
DWC_DEBUGPL(DBG_CIL, "initial hptxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->hptxfsiz));
ptxfifosize.b.depth = params->host_perio_tx_fifo_size;
ptxfifosize.b.startaddr = 0xC00;
DWC_WRITE_REG32(&global_regs->hptxfsiz, ptxfifosize.d32);
DWC_DEBUGPL(DBG_CIL, "new hptxfsiz=%08x\n",
DWC_READ_REG32(&global_regs->hptxfsiz));
if (core_if->en_multiple_tx_fifo) {
/* Global DFIFOCFG calculation for Host mode - include RxFIFO, NPTXFIFO and HPTXFIFO */
gdfifocfg.d32 = DWC_READ_REG32(&global_regs->gdfifocfg);
rxfsiz = (DWC_READ_REG32(&global_regs->grxfsiz) & 0x0000ffff);
nptxfsiz = (DWC_READ_REG32(&global_regs->gnptxfsiz) >> 16);
hptxfsiz = (DWC_READ_REG32(&global_regs->hptxfsiz) >> 16);
gdfifocfg.b.epinfobase = rxfsiz + nptxfsiz + hptxfsiz;
DWC_WRITE_REG32(&global_regs->gdfifocfg, gdfifocfg.d32);
}
}
/* TODO - check this */
/* Clear Host Set HNP Enable in the OTG Control Register */
gotgctl.b.hstsethnpen = 1;
DWC_MODIFY_REG32(&global_regs->gotgctl, gotgctl.d32, 0);
/* Make sure the FIFOs are flushed. */
dwc_otg_flush_tx_fifo(core_if, 0x10 /* all TX FIFOs */ );
dwc_otg_flush_rx_fifo(core_if);
/* Clear Host Set HNP Enable in the OTG Control Register */
gotgctl.b.hstsethnpen = 1;
DWC_MODIFY_REG32(&global_regs->gotgctl, gotgctl.d32, 0);
if (!core_if->core_params->dma_desc_enable) {
/* Flush out any leftover queued requests. */
num_channels = core_if->core_params->host_channels;
for (i = 0; i < num_channels; i++) {
hc_regs = core_if->host_if->hc_regs[i];
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
hcchar.b.chen = 0;
hcchar.b.chdis = 1;
hcchar.b.epdir = 0;
DWC_WRITE_REG32(&hc_regs->hcchar, hcchar.d32);
}
/* Halt all channels to put them into a known state. */
for (i = 0; i < num_channels; i++) {
int count = 0;
hc_regs = core_if->host_if->hc_regs[i];
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
hcchar.b.chen = 1;
hcchar.b.chdis = 1;
hcchar.b.epdir = 0;
DWC_WRITE_REG32(&hc_regs->hcchar, hcchar.d32);
DWC_DEBUGPL(DBG_HCDV, "%s: Halt channel %d\n", __func__, i);
do {
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
if (++count > 1000) {
DWC_ERROR
("%s: Unable to clear halt on channel %d\n",
__func__, i);
break;
}
dwc_udelay(1);
} while (hcchar.b.chen);
}
}
/* Turn on the vbus power. */
DWC_PRINTF("Init: Port Power? op_state=%d\n", core_if->op_state);
if (core_if->op_state == A_HOST) {
hprt0.d32 = dwc_otg_read_hprt0(core_if);
DWC_PRINTF("Init: Power Port (%d)\n", hprt0.b.prtpwr);
if (hprt0.b.prtpwr == 0) {
hprt0.b.prtpwr = 1;
DWC_WRITE_REG32(host_if->hprt0, hprt0.d32);
}
}
dwc_otg_enable_host_interrupts(core_if);
}
/**
* Prepares a host channel for transferring packets to/from a specific
* endpoint. The HCCHARn register is set up with the characteristics specified
* in _hc. Host channel interrupts that may need to be serviced while this
* transfer is in progress are enabled.
*
* @param core_if Programming view of DWC_otg controller
* @param hc Information needed to initialize the host channel
*/
void dwc_otg_hc_init(dwc_otg_core_if_t * core_if, dwc_hc_t * hc)
{
uint32_t intr_enable;
hcintmsk_data_t hc_intr_mask;
gintmsk_data_t gintmsk = {.d32 = 0 };
hcchar_data_t hcchar;
hcsplt_data_t hcsplt;
uint8_t hc_num = hc->hc_num;
dwc_otg_host_if_t *host_if = core_if->host_if;
dwc_otg_hc_regs_t *hc_regs = host_if->hc_regs[hc_num];
/* Clear old interrupt conditions for this host channel. */
hc_intr_mask.d32 = 0xFFFFFFFF;
hc_intr_mask.b.reserved14_31 = 0;
DWC_WRITE_REG32(&hc_regs->hcint, hc_intr_mask.d32);
/* Enable channel interrupts required for this transfer. */
hc_intr_mask.d32 = 0;
hc_intr_mask.b.chhltd = 1;
if (core_if->dma_enable) {
/* For Descriptor DMA mode core halts the channel on AHB error. Interrupt is not required */
if (!core_if->dma_desc_enable)
hc_intr_mask.b.ahberr = 1;
else {
if (hc->ep_type == DWC_OTG_EP_TYPE_ISOC)
hc_intr_mask.b.xfercompl = 1;
}
if (hc->error_state && !hc->do_split &&
hc->ep_type != DWC_OTG_EP_TYPE_ISOC) {
hc_intr_mask.b.ack = 1;
if (hc->ep_is_in) {
hc_intr_mask.b.datatglerr = 1;
if (hc->ep_type != DWC_OTG_EP_TYPE_INTR) {
hc_intr_mask.b.nak = 1;
}
}
}
} else {
switch (hc->ep_type) {
case DWC_OTG_EP_TYPE_CONTROL:
case DWC_OTG_EP_TYPE_BULK:
hc_intr_mask.b.xfercompl = 1;
hc_intr_mask.b.stall = 1;
hc_intr_mask.b.xacterr = 1;
hc_intr_mask.b.datatglerr = 1;
if (hc->ep_is_in) {
hc_intr_mask.b.bblerr = 1;
} else {
hc_intr_mask.b.nak = 1;
hc_intr_mask.b.nyet = 1;
if (hc->do_ping) {
hc_intr_mask.b.ack = 1;
}
}
if (hc->do_split) {
hc_intr_mask.b.nak = 1;
if (hc->complete_split) {
hc_intr_mask.b.nyet = 1;
} else {
hc_intr_mask.b.ack = 1;
}
}
if (hc->error_state) {
hc_intr_mask.b.ack = 1;
}
break;
case DWC_OTG_EP_TYPE_INTR:
hc_intr_mask.b.xfercompl = 1;
hc_intr_mask.b.nak = 1;
hc_intr_mask.b.stall = 1;
hc_intr_mask.b.xacterr = 1;
hc_intr_mask.b.datatglerr = 1;
hc_intr_mask.b.frmovrun = 1;
if (hc->ep_is_in) {
hc_intr_mask.b.bblerr = 1;
}
if (hc->error_state) {
hc_intr_mask.b.ack = 1;
}
if (hc->do_split) {
if (hc->complete_split) {
hc_intr_mask.b.nyet = 1;
} else {
hc_intr_mask.b.ack = 1;
}
}
break;
case DWC_OTG_EP_TYPE_ISOC:
hc_intr_mask.b.xfercompl = 1;
hc_intr_mask.b.frmovrun = 1;
hc_intr_mask.b.ack = 1;
if (hc->ep_is_in) {
hc_intr_mask.b.xacterr = 1;
hc_intr_mask.b.bblerr = 1;
}
break;
}
}
DWC_WRITE_REG32(&hc_regs->hcintmsk, hc_intr_mask.d32);
/* Enable the top level host channel interrupt. */
intr_enable = (1 << hc_num);
DWC_MODIFY_REG32(&host_if->host_global_regs->haintmsk, 0, intr_enable);
/* Make sure host channel interrupts are enabled. */
gintmsk.b.hcintr = 1;
DWC_MODIFY_REG32(&core_if->core_global_regs->gintmsk, 0, gintmsk.d32);
/*
* Program the HCCHARn register with the endpoint characteristics for
* the current transfer.
*/
hcchar.d32 = 0;
hcchar.b.devaddr = hc->dev_addr;
hcchar.b.epnum = hc->ep_num;
hcchar.b.epdir = hc->ep_is_in;
hcchar.b.lspddev = (hc->speed == DWC_OTG_EP_SPEED_LOW);
hcchar.b.eptype = hc->ep_type;
hcchar.b.mps = hc->max_packet;
DWC_WRITE_REG32(&host_if->hc_regs[hc_num]->hcchar, hcchar.d32);
DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, hc->hc_num);
DWC_DEBUGPL(DBG_HCDV, " Dev Addr: %d\n", hcchar.b.devaddr);
DWC_DEBUGPL(DBG_HCDV, " Ep Num: %d\n", hcchar.b.epnum);
DWC_DEBUGPL(DBG_HCDV, " Is In: %d\n", hcchar.b.epdir);
DWC_DEBUGPL(DBG_HCDV, " Is Low Speed: %d\n", hcchar.b.lspddev);
DWC_DEBUGPL(DBG_HCDV, " Ep Type: %d\n", hcchar.b.eptype);
DWC_DEBUGPL(DBG_HCDV, " Max Pkt: %d\n", hcchar.b.mps);
DWC_DEBUGPL(DBG_HCDV, " Multi Cnt: %d\n", hcchar.b.multicnt);
/*
* Program the HCSPLIT register for SPLITs
*/
hcsplt.d32 = 0;
if (hc->do_split) {
DWC_DEBUGPL(DBG_HCDV, "Programming HC %d with split --> %s\n",
hc->hc_num,
hc->complete_split ? "CSPLIT" : "SSPLIT");
hcsplt.b.compsplt = hc->complete_split;
hcsplt.b.xactpos = hc->xact_pos;
hcsplt.b.hubaddr = hc->hub_addr;
hcsplt.b.prtaddr = hc->port_addr;
DWC_DEBUGPL(DBG_HCDV, " comp split %d\n", hc->complete_split);
DWC_DEBUGPL(DBG_HCDV, " xact pos %d\n", hc->xact_pos);
DWC_DEBUGPL(DBG_HCDV, " hub addr %d\n", hc->hub_addr);
DWC_DEBUGPL(DBG_HCDV, " port addr %d\n", hc->port_addr);
DWC_DEBUGPL(DBG_HCDV, " is_in %d\n", hc->ep_is_in);
DWC_DEBUGPL(DBG_HCDV, " Max Pkt: %d\n", hcchar.b.mps);
DWC_DEBUGPL(DBG_HCDV, " xferlen: %d\n", hc->xfer_len);
}
DWC_WRITE_REG32(&host_if->hc_regs[hc_num]->hcsplt, hcsplt.d32);
}
/**
* Attempts to halt a host channel. This function should only be called in
* Slave mode or to abort a transfer in either Slave mode or DMA mode. Under
* normal circumstances in DMA mode, the controller halts the channel when the
* transfer is complete or a condition occurs that requires application
* intervention.
*
* In slave mode, checks for a free request queue entry, then sets the Channel
* Enable and Channel Disable bits of the Host Channel Characteristics
* register of the specified channel to intiate the halt. If there is no free
* request queue entry, sets only the Channel Disable bit of the HCCHARn
* register to flush requests for this channel. In the latter case, sets a
* flag to indicate that the host channel needs to be halted when a request
* queue slot is open.
*
* In DMA mode, always sets the Channel Enable and Channel Disable bits of the
* HCCHARn register. The controller ensures there is space in the request
* queue before submitting the halt request.
*
* Some time may elapse before the core flushes any posted requests for this
* host channel and halts. The Channel Halted interrupt handler completes the
* deactivation of the host channel.
*
* @param core_if Controller register interface.
* @param hc Host channel to halt.
* @param halt_status Reason for halting the channel.
*/
void dwc_otg_hc_halt(dwc_otg_core_if_t * core_if,
dwc_hc_t * hc, dwc_otg_halt_status_e halt_status)
{
gnptxsts_data_t nptxsts;
hptxsts_data_t hptxsts;
hcchar_data_t hcchar;
dwc_otg_hc_regs_t *hc_regs;
dwc_otg_core_global_regs_t *global_regs;
dwc_otg_host_global_regs_t *host_global_regs;
hc_regs = core_if->host_if->hc_regs[hc->hc_num];
global_regs = core_if->core_global_regs;
host_global_regs = core_if->host_if->host_global_regs;
DWC_ASSERT(!(halt_status == DWC_OTG_HC_XFER_NO_HALT_STATUS),
"halt_status = %d\n", halt_status);
if (halt_status == DWC_OTG_HC_XFER_URB_DEQUEUE ||
halt_status == DWC_OTG_HC_XFER_AHB_ERR) {
/*
* Disable all channel interrupts except Ch Halted. The QTD
* and QH state associated with this transfer has been cleared
* (in the case of URB_DEQUEUE), so the channel needs to be
* shut down carefully to prevent crashes.
*/
hcintmsk_data_t hcintmsk;
hcintmsk.d32 = 0;
hcintmsk.b.chhltd = 1;
DWC_WRITE_REG32(&hc_regs->hcintmsk, hcintmsk.d32);
/*
* Make sure no other interrupts besides halt are currently
* pending. Handling another interrupt could cause a crash due
* to the QTD and QH state.
*/
DWC_WRITE_REG32(&hc_regs->hcint, ~hcintmsk.d32);
/*
* Make sure the halt status is set to URB_DEQUEUE or AHB_ERR
* even if the channel was already halted for some other
* reason.
*/
hc->halt_status = halt_status;
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
if (hcchar.b.chen == 0) {
/*
* The channel is either already halted or it hasn't
* started yet. In DMA mode, the transfer may halt if
* it finishes normally or a condition occurs that
* requires driver intervention. Don't want to halt
* the channel again. In either Slave or DMA mode,
* it's possible that the transfer has been assigned
* to a channel, but not started yet when an URB is
* dequeued. Don't want to halt a channel that hasn't
* started yet.
*/
return;
}
}
if (hc->halt_pending) {
/*
* A halt has already been issued for this channel. This might
* happen when a transfer is aborted by a higher level in
* the stack.
*/
#ifdef DEBUG
DWC_PRINTF
("*** %s: Channel %d, _hc->halt_pending already set ***\n",
__func__, hc->hc_num);
#endif
return;
}
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
/* No need to set the bit in DDMA for disabling the channel */
//TODO check it everywhere channel is disabled
if (!core_if->core_params->dma_desc_enable)
hcchar.b.chen = 1;
hcchar.b.chdis = 1;
if (!core_if->dma_enable) {
/* Check for space in the request queue to issue the halt. */
if (hc->ep_type == DWC_OTG_EP_TYPE_CONTROL ||
hc->ep_type == DWC_OTG_EP_TYPE_BULK) {
nptxsts.d32 = DWC_READ_REG32(&global_regs->gnptxsts);
if (nptxsts.b.nptxqspcavail == 0) {
hcchar.b.chen = 0;
}
} else {
hptxsts.d32 =
DWC_READ_REG32(&host_global_regs->hptxsts);
if ((hptxsts.b.ptxqspcavail == 0)
|| (core_if->queuing_high_bandwidth)) {
hcchar.b.chen = 0;
}
}
}
DWC_WRITE_REG32(&hc_regs->hcchar, hcchar.d32);
hc->halt_status = halt_status;
if (hcchar.b.chen) {
hc->halt_pending = 1;
hc->halt_on_queue = 0;
} else {
hc->halt_on_queue = 1;
}
DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, hc->hc_num);
DWC_DEBUGPL(DBG_HCDV, " hcchar: 0x%08x\n", hcchar.d32);
DWC_DEBUGPL(DBG_HCDV, " halt_pending: %d\n", hc->halt_pending);
DWC_DEBUGPL(DBG_HCDV, " halt_on_queue: %d\n", hc->halt_on_queue);
DWC_DEBUGPL(DBG_HCDV, " halt_status: %d\n", hc->halt_status);
return;
}
/**
* Clears the transfer state for a host channel. This function is normally
* called after a transfer is done and the host channel is being released.
*
* @param core_if Programming view of DWC_otg controller.
* @param hc Identifies the host channel to clean up.
*/
void dwc_otg_hc_cleanup(dwc_otg_core_if_t * core_if, dwc_hc_t * hc)
{
dwc_otg_hc_regs_t *hc_regs;
hc->xfer_started = 0;
/*
* Clear channel interrupt enables and any unhandled channel interrupt
* conditions.
*/
hc_regs = core_if->host_if->hc_regs[hc->hc_num];
DWC_WRITE_REG32(&hc_regs->hcintmsk, 0);
DWC_WRITE_REG32(&hc_regs->hcint, 0xFFFFFFFF);
#ifdef DEBUG
DWC_TIMER_CANCEL(core_if->hc_xfer_timer[hc->hc_num]);
#endif
}
/**
* Sets the channel property that indicates in which frame a periodic transfer
* should occur. This is always set to the _next_ frame. This function has no
* effect on non-periodic transfers.
*
* @param core_if Programming view of DWC_otg controller.
* @param hc Identifies the host channel to set up and its properties.
* @param hcchar Current value of the HCCHAR register for the specified host
* channel.
*/
static inline void hc_set_even_odd_frame(dwc_otg_core_if_t * core_if,
dwc_hc_t * hc, hcchar_data_t * hcchar)
{
if (hc->ep_type == DWC_OTG_EP_TYPE_INTR ||
hc->ep_type == DWC_OTG_EP_TYPE_ISOC) {
hfnum_data_t hfnum;
hfnum.d32 =
DWC_READ_REG32(&core_if->host_if->host_global_regs->hfnum);
/* 1 if _next_ frame is odd, 0 if it's even */
hcchar->b.oddfrm = (hfnum.b.frnum & 0x1) ? 0 : 1;
#ifdef DEBUG
if (hc->ep_type == DWC_OTG_EP_TYPE_INTR && hc->do_split
&& !hc->complete_split) {
switch (hfnum.b.frnum & 0x7) {
case 7:
core_if->hfnum_7_samples++;
core_if->hfnum_7_frrem_accum += hfnum.b.frrem;
break;
case 0:
core_if->hfnum_0_samples++;
core_if->hfnum_0_frrem_accum += hfnum.b.frrem;
break;
default:
core_if->hfnum_other_samples++;
core_if->hfnum_other_frrem_accum +=
hfnum.b.frrem;
break;
}
}
#endif
}
}
#ifdef DEBUG
void hc_xfer_timeout(void *ptr)
{
hc_xfer_info_t *xfer_info = NULL;
int hc_num = 0;
if (ptr)
xfer_info = (hc_xfer_info_t *) ptr;
if (!xfer_info->hc) {
DWC_ERROR("xfer_info->hc = %p\n", xfer_info->hc);
return;
}
hc_num = xfer_info->hc->hc_num;
DWC_WARN("%s: timeout on channel %d\n", __func__, hc_num);
DWC_WARN(" start_hcchar_val 0x%08x\n",
xfer_info->core_if->start_hcchar_val[hc_num]);
}
#endif
void ep_xfer_timeout(void *ptr)
{
ep_xfer_info_t *xfer_info = NULL;
int ep_num = 0;
dctl_data_t dctl = {.d32 = 0 };
gintsts_data_t gintsts = {.d32 = 0 };
gintmsk_data_t gintmsk = {.d32 = 0 };
if (ptr)
xfer_info = (ep_xfer_info_t *) ptr;
if (!xfer_info->ep) {
DWC_ERROR("xfer_info->ep = %p\n", xfer_info->ep);
return;
}
ep_num = xfer_info->ep->num;
DWC_WARN("%s: timeout on endpoit %d\n", __func__, ep_num);
/* Put the sate to 2 as it was time outed */
xfer_info->state = 2;
dctl.d32 = DWC_READ_REG32(&xfer_info->core_if->
dev_if->dev_global_regs->dctl);
gintsts.d32 = DWC_READ_REG32(&xfer_info->core_if->
core_global_regs->gintsts);
gintmsk.d32 = DWC_READ_REG32(&xfer_info->core_if->
core_global_regs->gintmsk);
if (!gintmsk.b.goutnakeff) {
/* Unmask it */
gintmsk.b.goutnakeff = 1;
DWC_WRITE_REG32(&xfer_info->core_if->
core_global_regs->gintmsk, gintmsk.d32);
}
if (!gintsts.b.goutnakeff) {
dctl.b.sgoutnak = 1;
}
DWC_WRITE_REG32(&xfer_info->core_if->dev_if->
dev_global_regs->dctl, dctl.d32);
}
void set_pid_isoc(dwc_hc_t * hc)
{
/* Set up the initial PID for the transfer. */
if (hc->speed == DWC_OTG_EP_SPEED_HIGH) {
if (hc->ep_is_in) {
if (hc->multi_count == 1) {
hc->data_pid_start = DWC_OTG_HC_PID_DATA0;
} else if (hc->multi_count == 2) {
hc->data_pid_start = DWC_OTG_HC_PID_DATA1;
} else {
hc->data_pid_start = DWC_OTG_HC_PID_DATA2;
}
} else {
if (hc->multi_count == 1) {
hc->data_pid_start = DWC_OTG_HC_PID_DATA0;
} else {
hc->data_pid_start = DWC_OTG_HC_PID_MDATA;
}
}
} else {
hc->data_pid_start = DWC_OTG_HC_PID_DATA0;
}
}
/**
* This function does the setup for a data transfer for a host channel and
* starts the transfer. May be called in either Slave mode or DMA mode. In
* Slave mode, the caller must ensure that there is sufficient space in the
* request queue and Tx Data FIFO.
*
* For an OUT transfer in Slave mode, it loads a data packet into the
* appropriate FIFO. If necessary, additional data packets will be loaded in
* the Host ISR.
*
* For an IN transfer in Slave mode, a data packet is requested. The data
* packets are unloaded from the Rx FIFO in the Host ISR. If necessary,
* additional data packets are requested in the Host ISR.
*
* For a PING transfer in Slave mode, the Do Ping bit is set in the HCTSIZ
* register along with a packet count of 1 and the channel is enabled. This
* causes a single PING transaction to occur. Other fields in HCTSIZ are
* simply set to 0 since no data transfer occurs in this case.
*
* For a PING transfer in DMA mode, the HCTSIZ register is initialized with
* all the information required to perform the subsequent data transfer. In
* addition, the Do Ping bit is set in the HCTSIZ register. In this case, the
* controller performs the entire PING protocol, then starts the data
* transfer.
*
* @param core_if Programming view of DWC_otg controller.
* @param hc Information needed to initialize the host channel. The xfer_len
* value may be reduced to accommodate the max widths of the XferSize and
* PktCnt fields in the HCTSIZn register. The multi_count value may be changed
* to reflect the final xfer_len value.
*/
void dwc_otg_hc_start_transfer(dwc_otg_core_if_t * core_if, dwc_hc_t * hc)
{
hcchar_data_t hcchar;
hctsiz_data_t hctsiz;
uint16_t num_packets;
uint32_t max_hc_xfer_size = core_if->core_params->max_transfer_size;
uint16_t max_hc_pkt_count = core_if->core_params->max_packet_count;
dwc_otg_hc_regs_t *hc_regs = core_if->host_if->hc_regs[hc->hc_num];
hctsiz.d32 = 0;
if (hc->do_ping) {
if (!core_if->dma_enable) {
dwc_otg_hc_do_ping(core_if, hc);
hc->xfer_started = 1;
return;
} else {
hctsiz.b.dopng = 1;
}
}
if (hc->do_split) {
num_packets = 1;
if (hc->complete_split && !hc->ep_is_in) {
/* For CSPLIT OUT Transfer, set the size to 0 so the
* core doesn't expect any data written to the FIFO */
hc->xfer_len = 0;
} else if (hc->ep_is_in || (hc->xfer_len > hc->max_packet)) {
hc->xfer_len = hc->max_packet;
} else if (!hc->ep_is_in && (hc->xfer_len > 188)) {
hc->xfer_len = 188;
}
hctsiz.b.xfersize = hc->xfer_len;
} else {
/*
* Ensure that the transfer length and packet count will fit
* in the widths allocated for them in the HCTSIZn register.
*/
if (hc->ep_type == DWC_OTG_EP_TYPE_INTR ||
hc->ep_type == DWC_OTG_EP_TYPE_ISOC) {
/*
* Make sure the transfer size is no larger than one
* (micro)frame's worth of data. (A check was done
* when the periodic transfer was accepted to ensure
* that a (micro)frame's worth of data can be
* programmed into a channel.)
*/
uint32_t max_periodic_len =
hc->multi_count * hc->max_packet;
if (hc->xfer_len > max_periodic_len) {
hc->xfer_len = max_periodic_len;
} else {
}
} else if (hc->xfer_len > max_hc_xfer_size) {
/* Make sure that xfer_len is a multiple of max packet size. */
hc->xfer_len = max_hc_xfer_size - hc->max_packet + 1;
}
if (hc->xfer_len > 0) {
num_packets =
(hc->xfer_len + hc->max_packet -
1) / hc->max_packet;
if (num_packets > max_hc_pkt_count) {
num_packets = max_hc_pkt_count;
hc->xfer_len = num_packets * hc->max_packet;
}
} else {
/* Need 1 packet for transfer length of 0. */
num_packets = 1;
}
if (hc->ep_is_in) {
/* Always program an integral # of max packets for IN transfers. */
hc->xfer_len = num_packets * hc->max_packet;
}
if (hc->ep_type == DWC_OTG_EP_TYPE_INTR ||
hc->ep_type == DWC_OTG_EP_TYPE_ISOC) {
/*
* Make sure that the multi_count field matches the
* actual transfer length.
*/
hc->multi_count = num_packets;
}
if (hc->ep_type == DWC_OTG_EP_TYPE_ISOC)
set_pid_isoc(hc);
hctsiz.b.xfersize = hc->xfer_len;
}
hc->start_pkt_count = num_packets;
hctsiz.b.pktcnt = num_packets;
hctsiz.b.pid = hc->data_pid_start;
DWC_WRITE_REG32(&hc_regs->hctsiz, hctsiz.d32);
DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, hc->hc_num);
DWC_DEBUGPL(DBG_HCDV, " Xfer Size: %d\n", hctsiz.b.xfersize);
DWC_DEBUGPL(DBG_HCDV, " Num Pkts: %d\n", hctsiz.b.pktcnt);
DWC_DEBUGPL(DBG_HCDV, " Start PID: %d\n", hctsiz.b.pid);
if (core_if->dma_enable) {
dwc_dma_t dma_addr;
if (hc->align_buff) {
dma_addr = hc->align_buff;
} else {
dma_addr = ((unsigned long)hc->xfer_buff & 0xffffffff);
}
DWC_WRITE_REG32(&hc_regs->hcdma, dma_addr);
}
/* Start the split */
if (hc->do_split) {
hcsplt_data_t hcsplt;
hcsplt.d32 = DWC_READ_REG32(&hc_regs->hcsplt);
hcsplt.b.spltena = 1;
DWC_WRITE_REG32(&hc_regs->hcsplt, hcsplt.d32);
}
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
hcchar.b.multicnt = hc->multi_count;
hc_set_even_odd_frame(core_if, hc, &hcchar);
#ifdef DEBUG
core_if->start_hcchar_val[hc->hc_num] = hcchar.d32;
if (hcchar.b.chdis) {
DWC_WARN("%s: chdis set, channel %d, hcchar 0x%08x\n",
__func__, hc->hc_num, hcchar.d32);
}
#endif
/* Set host channel enable after all other setup is complete. */
hcchar.b.chen = 1;
hcchar.b.chdis = 0;
DWC_WRITE_REG32(&hc_regs->hcchar, hcchar.d32);
hc->xfer_started = 1;
hc->requests++;
if (!core_if->dma_enable && !hc->ep_is_in && hc->xfer_len > 0) {
/* Load OUT packet into the appropriate Tx FIFO. */
dwc_otg_hc_write_packet(core_if, hc);
}
#ifdef DEBUG
if (hc->ep_type != DWC_OTG_EP_TYPE_INTR) {
core_if->hc_xfer_info[hc->hc_num].core_if = core_if;
core_if->hc_xfer_info[hc->hc_num].hc = hc;
/* Start a timer for this transfer. */
DWC_TIMER_SCHEDULE(core_if->hc_xfer_timer[hc->hc_num], 10000);
}
#endif
}
/**
* This function does the setup for a data transfer for a host channel
* and starts the transfer in Descriptor DMA mode.
*
* Initializes HCTSIZ register. For a PING transfer the Do Ping bit is set.
* Sets PID and NTD values. For periodic transfers
* initializes SCHED_INFO field with micro-frame bitmap.
*
* Initializes HCDMA register with descriptor list address and CTD value
* then starts the transfer via enabling the channel.
*
* @param core_if Programming view of DWC_otg controller.
* @param hc Information needed to initialize the host channel.
*/
void dwc_otg_hc_start_transfer_ddma(dwc_otg_core_if_t * core_if, dwc_hc_t * hc)
{
dwc_otg_hc_regs_t *hc_regs = core_if->host_if->hc_regs[hc->hc_num];
hcchar_data_t hcchar;
hctsiz_data_t hctsiz;
hcdma_data_t hcdma;
hctsiz.d32 = 0;
if (hc->do_ping)
hctsiz.b_ddma.dopng = 1;
if (hc->ep_type == DWC_OTG_EP_TYPE_ISOC)
set_pid_isoc(hc);
/* Packet Count and Xfer Size are not used in Descriptor DMA mode */
hctsiz.b_ddma.pid = hc->data_pid_start;
hctsiz.b_ddma.ntd = hc->ntd - 1; /* 0 - 1 descriptor, 1 - 2 descriptors, etc. */
hctsiz.b_ddma.schinfo = hc->schinfo; /* Non-zero only for high-speed interrupt endpoints */
DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, hc->hc_num);
DWC_DEBUGPL(DBG_HCDV, " Start PID: %d\n", hctsiz.b.pid);
DWC_DEBUGPL(DBG_HCDV, " NTD: %d\n", hctsiz.b_ddma.ntd);
DWC_WRITE_REG32(&hc_regs->hctsiz, hctsiz.d32);
hcdma.d32 = 0;
hcdma.b.dma_addr = ((uint32_t) hc->desc_list_addr) >> 11;
/* Always start from first descriptor. */
hcdma.b.ctd = 0;
DWC_WRITE_REG32(&hc_regs->hcdma, hcdma.d32);
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
hcchar.b.multicnt = hc->multi_count;
#ifdef DEBUG
core_if->start_hcchar_val[hc->hc_num] = hcchar.d32;
if (hcchar.b.chdis) {
DWC_WARN("%s: chdis set, channel %d, hcchar 0x%08x\n",
__func__, hc->hc_num, hcchar.d32);
}
#endif
/* Set host channel enable after all other setup is complete. */
hcchar.b.chen = 1;
hcchar.b.chdis = 0;
DWC_WRITE_REG32(&hc_regs->hcchar, hcchar.d32);
hc->xfer_started = 1;
hc->requests++;
#ifdef DEBUG
if ((hc->ep_type != DWC_OTG_EP_TYPE_INTR)
&& (hc->ep_type != DWC_OTG_EP_TYPE_ISOC)) {
core_if->hc_xfer_info[hc->hc_num].core_if = core_if;
core_if->hc_xfer_info[hc->hc_num].hc = hc;
/* Start a timer for this transfer. */
DWC_TIMER_SCHEDULE(core_if->hc_xfer_timer[hc->hc_num], 10000);
}
#endif
}
/**
* This function continues a data transfer that was started by previous call
* to <code>dwc_otg_hc_start_transfer</code>. The caller must ensure there is
* sufficient space in the request queue and Tx Data FIFO. This function
* should only be called in Slave mode. In DMA mode, the controller acts
* autonomously to complete transfers programmed to a host channel.
*
* For an OUT transfer, a new data packet is loaded into the appropriate FIFO
* if there is any data remaining to be queued. For an IN transfer, another
* data packet is always requested. For the SETUP phase of a control transfer,
* this function does nothing.
*
* @return 1 if a new request is queued, 0 if no more requests are required
* for this transfer.
*/
int dwc_otg_hc_continue_transfer(dwc_otg_core_if_t * core_if, dwc_hc_t * hc)
{
DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, hc->hc_num);
if (hc->do_split) {
/* SPLITs always queue just once per channel */
return 0;
} else if (hc->data_pid_start == DWC_OTG_HC_PID_SETUP) {
/* SETUPs are queued only once since they can't be NAKed. */
return 0;
} else if (hc->ep_is_in) {
/*
* Always queue another request for other IN transfers. If
* back-to-back INs are issued and NAKs are received for both,
* the driver may still be processing the first NAK when the
* second NAK is received. When the interrupt handler clears
* the NAK interrupt for the first NAK, the second NAK will
* not be seen. So we can't depend on the NAK interrupt
* handler to requeue a NAKed request. Instead, IN requests
* are issued each time this function is called. When the
* transfer completes, the extra requests for the channel will
* be flushed.
*/
hcchar_data_t hcchar;
dwc_otg_hc_regs_t *hc_regs =
core_if->host_if->hc_regs[hc->hc_num];
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
hc_set_even_odd_frame(core_if, hc, &hcchar);
hcchar.b.chen = 1;
hcchar.b.chdis = 0;
DWC_DEBUGPL(DBG_HCDV, " IN xfer: hcchar = 0x%08x\n",
hcchar.d32);
DWC_WRITE_REG32(&hc_regs->hcchar, hcchar.d32);
hc->requests++;
return 1;
} else {
/* OUT transfers. */
if (hc->xfer_count < hc->xfer_len) {
if (hc->ep_type == DWC_OTG_EP_TYPE_INTR ||
hc->ep_type == DWC_OTG_EP_TYPE_ISOC) {
hcchar_data_t hcchar;
dwc_otg_hc_regs_t *hc_regs;
hc_regs = core_if->host_if->hc_regs[hc->hc_num];
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
hc_set_even_odd_frame(core_if, hc, &hcchar);
}
/* Load OUT packet into the appropriate Tx FIFO. */
dwc_otg_hc_write_packet(core_if, hc);
hc->requests++;
return 1;
} else {
return 0;
}
}
}
/**
* Starts a PING transfer. This function should only be called in Slave mode.
* The Do Ping bit is set in the HCTSIZ register, then the channel is enabled.
*/
void dwc_otg_hc_do_ping(dwc_otg_core_if_t * core_if, dwc_hc_t * hc)
{
hcchar_data_t hcchar;
hctsiz_data_t hctsiz;
dwc_otg_hc_regs_t *hc_regs = core_if->host_if->hc_regs[hc->hc_num];
DWC_DEBUGPL(DBG_HCDV, "%s: Channel %d\n", __func__, hc->hc_num);
hctsiz.d32 = 0;
hctsiz.b.dopng = 1;
hctsiz.b.pktcnt = 1;
DWC_WRITE_REG32(&hc_regs->hctsiz, hctsiz.d32);
hcchar.d32 = DWC_READ_REG32(&hc_regs->hcchar);
hcchar.b.chen = 1;
hcchar.b.chdis = 0;
DWC_WRITE_REG32(&hc_regs->hcchar, hcchar.d32);
}
/*
* This function writes a packet into the Tx FIFO associated with the Host
* Channel. For a channel associated with a non-periodic EP, the non-periodic
* Tx FIFO is written. For a channel associated with a periodic EP, the
* periodic Tx FIFO is written. This function should only be called in Slave
* mode.
*
* Upon return the xfer_buff and xfer_count fields in _hc are incremented by
* then number of bytes written to the Tx FIFO.
*/
void dwc_otg_hc_write_packet(dwc_otg_core_if_t * core_if, dwc_hc_t * hc)
{
uint32_t i;
uint32_t remaining_count;
uint32_t byte_count;
uint32_t dword_count;
uint32_t *data_buff = (uint32_t *) (hc->xfer_buff);
uint32_t *data_fifo = core_if->data_fifo[hc->hc_num];
remaining_count = hc->xfer_len - hc->xfer_count;
if (remaining_count > hc->max_packet) {
byte_count = hc->max_packet;
} else {
byte_count = remaining_count;
}
dword_count = (byte_count + 3) / 4;
if ((((unsigned long)data_buff) & 0x3) == 0) {
/* xfer_buff is DWORD aligned. */
for (i = 0; i < dword_count; i++, data_buff++) {
DWC_WRITE_REG32(data_fifo, *data_buff);
}
} else {
/* xfer_buff is not DWORD aligned. */
for (i = 0; i < dword_count; i++, data_buff++) {
uint32_t data;
data =
(data_buff[0] | data_buff[1] << 8 | data_buff[2] <<
16 | data_buff[3] << 24);
DWC_WRITE_REG32(data_fifo, data);
}
}
hc->xfer_count += byte_count;
hc->xfer_buff += byte_count;
}
/**
* Gets the current USB frame number. This is the frame number from the last
* SOF packet.
*/
uint32_t dwc_otg_get_frame_number(dwc_otg_core_if_t * core_if)
{
dsts_data_t dsts;
dsts.d32 = DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dsts);
/* read current frame/microframe number from DSTS register */
return dsts.b.soffn;
}
/**
* Calculates and gets the frame Interval value of HFIR register according PHY
* type and speed.The application can modify a value of HFIR register only after
* the Port Enable bit of the Host Port Control and Status register
* (HPRT.PrtEnaPort) has been set.
*/
uint32_t calc_frame_interval(dwc_otg_core_if_t * core_if)
{
gusbcfg_data_t usbcfg;
hwcfg2_data_t hwcfg2;
hprt0_data_t hprt0;
int clock = 60; // default value
usbcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->gusbcfg);
hwcfg2.d32 = DWC_READ_REG32(&core_if->core_global_regs->ghwcfg2);
hprt0.d32 = DWC_READ_REG32(core_if->host_if->hprt0);
if (!usbcfg.b.physel && usbcfg.b.ulpi_utmi_sel && !usbcfg.b.phyif)
clock = 60;
if (usbcfg.b.physel && hwcfg2.b.fs_phy_type == 3)
clock = 48;
if (!usbcfg.b.phylpwrclksel && !usbcfg.b.physel &&
!usbcfg.b.ulpi_utmi_sel && usbcfg.b.phyif)
clock = 30;
if (!usbcfg.b.phylpwrclksel && !usbcfg.b.physel &&
!usbcfg.b.ulpi_utmi_sel && !usbcfg.b.phyif)
clock = 60;
if (usbcfg.b.phylpwrclksel && !usbcfg.b.physel &&
!usbcfg.b.ulpi_utmi_sel && usbcfg.b.phyif)
clock = 48;
if (usbcfg.b.physel && !usbcfg.b.phyif && hwcfg2.b.fs_phy_type == 2)
clock = 48;
if (usbcfg.b.physel && hwcfg2.b.fs_phy_type == 1)
clock = 48;
if (hprt0.b.prtspd == 0)
/* High speed case */
return 125 * clock;
else
/* FS/LS case */
return 1000 * clock;
}
/**
* This function reads a setup packet from the Rx FIFO into the destination
* buffer. This function is called from the Rx Status Queue Level (RxStsQLvl)
* Interrupt routine when a SETUP packet has been received in Slave mode.
*
* @param core_if Programming view of DWC_otg controller.
* @param dest Destination buffer for packet data.
*/
void dwc_otg_read_setup_packet(dwc_otg_core_if_t * core_if, uint32_t * dest)
{
/* Get the 8 bytes of a setup transaction data */
/* Pop 2 DWORDS off the receive data FIFO into memory */
dest[0] = DWC_READ_REG32(core_if->data_fifo[0]);
dest[1] = DWC_READ_REG32(core_if->data_fifo[0]);
}
/**
* This function enables EP0 OUT to receive SETUP packets and configures EP0
* IN for transmitting packets. It is normally called when the
* "Enumeration Done" interrupt occurs.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP0 data.
*/
void dwc_otg_ep0_activate(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
dwc_otg_dev_if_t *dev_if = core_if->dev_if;
dsts_data_t dsts;
depctl_data_t diepctl;
depctl_data_t doepctl;
dctl_data_t dctl = {.d32 = 0 };
/* Read the Device Status and Endpoint 0 Control registers */
dsts.d32 = DWC_READ_REG32(&dev_if->dev_global_regs->dsts);
diepctl.d32 = DWC_READ_REG32(&dev_if->in_ep_regs[0]->diepctl);
doepctl.d32 = DWC_READ_REG32(&dev_if->out_ep_regs[0]->doepctl);
/* Set the MPS of the IN EP based on the enumeration speed */
switch (dsts.b.enumspd) {
case DWC_DSTS_ENUMSPD_HS_PHY_30MHZ_OR_60MHZ:
case DWC_DSTS_ENUMSPD_FS_PHY_30MHZ_OR_60MHZ:
case DWC_DSTS_ENUMSPD_FS_PHY_48MHZ:
diepctl.b.mps = DWC_DEP0CTL_MPS_64;
break;
case DWC_DSTS_ENUMSPD_LS_PHY_6MHZ:
diepctl.b.mps = DWC_DEP0CTL_MPS_8;
break;
}
DWC_WRITE_REG32(&dev_if->in_ep_regs[0]->diepctl, diepctl.d32);
/* Enable OUT EP for receive */
doepctl.b.epena = 1;
DWC_WRITE_REG32(&dev_if->out_ep_regs[0]->doepctl, doepctl.d32);
#ifdef VERBOSE
DWC_DEBUGPL(DBG_PCDV, "doepctl0=%0x\n",
DWC_READ_REG32(&dev_if->out_ep_regs[0]->doepctl));
DWC_DEBUGPL(DBG_PCDV, "diepctl0=%0x\n",
DWC_READ_REG32(&dev_if->in_ep_regs[0]->diepctl));
#endif
dctl.b.cgnpinnak = 1;
DWC_MODIFY_REG32(&dev_if->dev_global_regs->dctl, dctl.d32, dctl.d32);
DWC_DEBUGPL(DBG_PCDV, "dctl=%0x\n",
DWC_READ_REG32(&dev_if->dev_global_regs->dctl));
}
/**
* This function activates an EP. The Device EP control register for
* the EP is configured as defined in the ep structure. Note: This
* function is not used for EP0.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to activate.
*/
void dwc_otg_ep_activate(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
dwc_otg_dev_if_t *dev_if = core_if->dev_if;
depctl_data_t depctl;
volatile uint32_t *addr;
daint_data_t daintmsk = {.d32 = 0 };
dcfg_data_t dcfg;
uint8_t i;
DWC_DEBUGPL(DBG_PCDV, "%s() EP%d-%s\n", __func__, ep->num,
(ep->is_in ? "IN" : "OUT"));
#ifdef DWC_UTE_PER_IO
ep->xiso_frame_num = 0xFFFFFFFF;
ep->xiso_active_xfers = 0;
ep->xiso_queued_xfers = 0;
#endif
/* Read DEPCTLn register */
if (ep->is_in == 1) {
addr = &dev_if->in_ep_regs[ep->num]->diepctl;
daintmsk.ep.in = 1 << ep->num;
} else {
addr = &dev_if->out_ep_regs[ep->num]->doepctl;
daintmsk.ep.out = 1 << ep->num;
}
/* If the EP is already active don't change the EP Control
* register. */
depctl.d32 = DWC_READ_REG32(addr);
if (!depctl.b.usbactep) {
depctl.b.mps = ep->maxpacket;
depctl.b.eptype = ep->type;
depctl.b.txfnum = ep->tx_fifo_num;
if (ep->type == DWC_OTG_EP_TYPE_ISOC) {
depctl.b.setd0pid = 1; // ???
} else {
depctl.b.setd0pid = 1;
}
depctl.b.usbactep = 1;
/* Update nextep_seq array and EPMSCNT in DCFG*/
if (!(depctl.b.eptype & 1) && (ep->is_in == 1)) { // NP IN EP
for (i = 0; i <= core_if->dev_if->num_in_eps; i++) {
if (core_if->nextep_seq[i] == core_if->first_in_nextep_seq)
break;
}
core_if->nextep_seq[i] = ep->num;
core_if->nextep_seq[ep->num] = core_if->first_in_nextep_seq;
depctl.b.nextep = core_if->nextep_seq[ep->num];
dcfg.d32 = DWC_READ_REG32(&dev_if->dev_global_regs->dcfg);
dcfg.b.epmscnt++;
DWC_WRITE_REG32(&dev_if->dev_global_regs->dcfg, dcfg.d32);
DWC_DEBUGPL(DBG_PCDV,"%s first_in_nextep_seq= %2d; nextep_seq[]:\n",
__func__, core_if->first_in_nextep_seq);
for (i=0; i <= core_if->dev_if->num_in_eps; i++) {
DWC_DEBUGPL(DBG_PCDV, "%2d\n", core_if->nextep_seq[i]);
}
}
DWC_WRITE_REG32(addr, depctl.d32);
DWC_DEBUGPL(DBG_PCDV, "DEPCTL=%08x\n", DWC_READ_REG32(addr));
}
/* Enable the Interrupt for this EP */
if (core_if->multiproc_int_enable) {
if (ep->is_in == 1) {
diepmsk_data_t diepmsk = {.d32 = 0 };
diepmsk.b.xfercompl = 1;
diepmsk.b.timeout = 1;
diepmsk.b.epdisabled = 1;
diepmsk.b.ahberr = 1;
diepmsk.b.intknepmis = 1;
if (!core_if->en_multiple_tx_fifo && core_if->dma_enable)
diepmsk.b.intknepmis = 0;
diepmsk.b.txfifoundrn = 1; //?????
if (ep->type == DWC_OTG_EP_TYPE_ISOC) {
diepmsk.b.nak = 1;
}
/*
if (core_if->dma_desc_enable) {
diepmsk.b.bna = 1;
}
*/
/*
if (core_if->dma_enable) {
doepmsk.b.nak = 1;
}
*/
DWC_WRITE_REG32(&dev_if->dev_global_regs->
diepeachintmsk[ep->num], diepmsk.d32);
} else {
doepmsk_data_t doepmsk = {.d32 = 0 };
doepmsk.b.xfercompl = 1;
doepmsk.b.ahberr = 1;
doepmsk.b.epdisabled = 1;
if (ep->type == DWC_OTG_EP_TYPE_ISOC)
doepmsk.b.outtknepdis = 1;
/*
if (core_if->dma_desc_enable) {
doepmsk.b.bna = 1;
}
*/
/*
doepmsk.b.babble = 1;
doepmsk.b.nyet = 1;
doepmsk.b.nak = 1;
*/
DWC_WRITE_REG32(&dev_if->dev_global_regs->
doepeachintmsk[ep->num], doepmsk.d32);
}
DWC_MODIFY_REG32(&dev_if->dev_global_regs->deachintmsk,
0, daintmsk.d32);
} else {
if (ep->type == DWC_OTG_EP_TYPE_ISOC) {
if (ep->is_in)
{
diepmsk_data_t diepmsk = {.d32 = 0 };
diepmsk.b.nak = 1;
DWC_MODIFY_REG32(&dev_if->dev_global_regs->diepmsk, 0, diepmsk.d32);
} else {
doepmsk_data_t doepmsk = {.d32 = 0 };
doepmsk.b.outtknepdis = 1;
DWC_MODIFY_REG32(&dev_if->dev_global_regs->doepmsk, 0, doepmsk.d32);
}
}
DWC_MODIFY_REG32(&dev_if->dev_global_regs->daintmsk,
0, daintmsk.d32);
}
DWC_DEBUGPL(DBG_PCDV, "DAINTMSK=%0x\n",
DWC_READ_REG32(&dev_if->dev_global_regs->daintmsk));
ep->stall_clear_flag = 0;
return;
}
/**
* This function deactivates an EP. This is done by clearing the USB Active
* EP bit in the Device EP control register. Note: This function is not used
* for EP0. EP0 cannot be deactivated.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to deactivate.
*/
void dwc_otg_ep_deactivate(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
depctl_data_t depctl = {.d32 = 0 };
volatile uint32_t *addr;
daint_data_t daintmsk = {.d32 = 0 };
dcfg_data_t dcfg;
uint8_t i = 0;
#ifdef DWC_UTE_PER_IO
ep->xiso_frame_num = 0xFFFFFFFF;
ep->xiso_active_xfers = 0;
ep->xiso_queued_xfers = 0;
#endif
/* Read DEPCTLn register */
if (ep->is_in == 1) {
addr = &core_if->dev_if->in_ep_regs[ep->num]->diepctl;
daintmsk.ep.in = 1 << ep->num;
} else {
addr = &core_if->dev_if->out_ep_regs[ep->num]->doepctl;
daintmsk.ep.out = 1 << ep->num;
}
depctl.d32 = DWC_READ_REG32(addr);
depctl.b.usbactep = 0;
/* Update nextep_seq array and EPMSCNT in DCFG*/
if (!(depctl.b.eptype & 1) && ep->is_in == 1) { // NP EP IN
for (i = 0; i <= core_if->dev_if->num_in_eps; i++) {
if (core_if->nextep_seq[i] == ep->num)
break;
}
core_if->nextep_seq[i] = core_if->nextep_seq[ep->num];
if (core_if->first_in_nextep_seq == ep->num)
core_if->first_in_nextep_seq = i;
core_if->nextep_seq[ep->num] = 0xff;
depctl.b.nextep = 0;
dcfg.d32 = DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dcfg);
dcfg.b.epmscnt--;
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->dcfg, dcfg.d32);
DWC_DEBUGPL(DBG_PCDV,"%s first_in_nextep_seq= %2d; nextep_seq[]:\n",
__func__, core_if->first_in_nextep_seq);
for (i=0; i <= core_if->dev_if->num_in_eps; i++) {
DWC_DEBUGPL(DBG_PCDV, "%2d\n", core_if->nextep_seq[i]);
}
}
if (ep->is_in == 1)
depctl.b.txfnum = 0;
if (core_if->dma_desc_enable)
depctl.b.epdis = 1;
DWC_WRITE_REG32(addr, depctl.d32);
depctl.d32 = DWC_READ_REG32(addr);
if (core_if->dma_enable && ep->type == DWC_OTG_EP_TYPE_ISOC && depctl.b.epena)
{
depctl_data_t depctl = {.d32 = 0};
if (ep->is_in)
{
diepint_data_t diepint = {.d32 = 0};
depctl.b.snak = 1;
DWC_WRITE_REG32(&core_if->dev_if->in_ep_regs[ep->num]->diepctl, depctl.d32);
do
{
dwc_udelay(10);
diepint.d32 = DWC_READ_REG32(&core_if->dev_if->
in_ep_regs[ep->num]->diepint);
} while (!diepint.b.inepnakeff);
diepint.b.inepnakeff = 1;
DWC_WRITE_REG32(&core_if->dev_if->
in_ep_regs[ep->num]->diepint, diepint.d32);
depctl.d32 = 0;
depctl.b.epdis = 1;
DWC_WRITE_REG32(&core_if->dev_if->in_ep_regs[ep->num]->diepctl, depctl.d32);
do
{
dwc_udelay(10);
diepint.d32 = DWC_READ_REG32(&core_if->dev_if->
in_ep_regs[ep->num]->diepint);
} while (!diepint.b.epdisabled);
diepint.b.epdisabled = 1;
DWC_WRITE_REG32(&core_if->dev_if->in_ep_regs[ep->num]->diepint, diepint.d32);
} else {
dctl_data_t dctl = {.d32 = 0};
gintmsk_data_t gintsts = {.d32 = 0};
doepint_data_t doepint = {.d32 = 0};
dctl.b.sgoutnak = 1;
DWC_MODIFY_REG32(&core_if->dev_if->dev_global_regs->dctl, 0, dctl.d32);
do
{
dwc_udelay(10);
gintsts.d32 = DWC_READ_REG32(&core_if->core_global_regs->gintsts);
} while (!gintsts.b.goutnakeff);
gintsts.d32 = 0;
gintsts.b.goutnakeff = 1;
DWC_WRITE_REG32(&core_if->core_global_regs->gintsts, gintsts.d32);
depctl.d32 = 0;
depctl.b.epdis = 1;
depctl.b.snak = 1;
DWC_WRITE_REG32(&core_if->dev_if->out_ep_regs[ep->num]->doepctl, depctl.d32);
do
{
dwc_udelay(10);
doepint.d32 = DWC_READ_REG32(&core_if->dev_if->
out_ep_regs[ep->num]->doepint);
} while (!doepint.b.epdisabled);
doepint.b.epdisabled = 1;
DWC_WRITE_REG32(&core_if->dev_if->out_ep_regs[ep->num]->doepint, doepint.d32);
dctl.d32 = 0;
dctl.b.cgoutnak = 1;
DWC_MODIFY_REG32(&core_if->dev_if->dev_global_regs->dctl, 0, dctl.d32);
}
}
/* Disable the Interrupt for this EP */
if (core_if->multiproc_int_enable) {
DWC_MODIFY_REG32(&core_if->dev_if->dev_global_regs->deachintmsk,
daintmsk.d32, 0);
if (ep->is_in == 1) {
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->
diepeachintmsk[ep->num], 0);
} else {
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->
doepeachintmsk[ep->num], 0);
}
} else {
DWC_MODIFY_REG32(&core_if->dev_if->dev_global_regs->daintmsk,
daintmsk.d32, 0);
}
}
/**
* This function initializes dma descriptor chain.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to start the transfer on.
*/
static void init_dma_desc_chain(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
dwc_otg_dev_dma_desc_t *dma_desc;
uint32_t offset;
uint32_t xfer_est;
int i;
unsigned maxxfer_local, total_len;
if (!ep->is_in && ep->type == DWC_OTG_EP_TYPE_INTR &&
(ep->maxpacket%4)) {
maxxfer_local = ep->maxpacket;
total_len = ep->xfer_len;
} else {
maxxfer_local = ep->maxxfer;
total_len = ep->total_len;
}
ep->desc_cnt = (total_len / maxxfer_local) +
((total_len % maxxfer_local) ? 1 : 0);
if (!ep->desc_cnt)
ep->desc_cnt = 1;
if (ep->desc_cnt > MAX_DMA_DESC_CNT)
ep->desc_cnt = MAX_DMA_DESC_CNT;
dma_desc = ep->desc_addr;
if (maxxfer_local == ep->maxpacket) {
if ((total_len % maxxfer_local) &&
(total_len/maxxfer_local < MAX_DMA_DESC_CNT)) {
xfer_est = (ep->desc_cnt - 1) * maxxfer_local +
(total_len % maxxfer_local);
} else
xfer_est = ep->desc_cnt * maxxfer_local;
}
else
xfer_est = total_len;
offset = 0;
for (i = 0; i < ep->desc_cnt; ++i) {
/** DMA Descriptor Setup */
if (xfer_est > maxxfer_local) {
dma_desc->status.b.bs = BS_HOST_BUSY;
dma_desc->status.b.l = 0;
dma_desc->status.b.ioc = 0;
dma_desc->status.b.sp = 0;
dma_desc->status.b.bytes = maxxfer_local;
dma_desc->buf = ep->dma_addr + offset;
dma_desc->status.b.sts = 0;
dma_desc->status.b.bs = BS_HOST_READY;
xfer_est -= maxxfer_local;
offset += maxxfer_local;
} else {
dma_desc->status.b.bs = BS_HOST_BUSY;
dma_desc->status.b.l = 1;
dma_desc->status.b.ioc = 1;
if (ep->is_in) {
dma_desc->status.b.sp =
(xfer_est %
ep->maxpacket) ? 1 : ((ep->
sent_zlp) ? 1 : 0);
dma_desc->status.b.bytes = xfer_est;
} else {
if (maxxfer_local == ep->maxpacket)
dma_desc->status.b.bytes = xfer_est;
else
dma_desc->status.b.bytes =
xfer_est + ((4 - (xfer_est & 0x3)) & 0x3);
}
dma_desc->buf = ep->dma_addr + offset;
dma_desc->status.b.sts = 0;
dma_desc->status.b.bs = BS_HOST_READY;
}
dma_desc++;
}
}
/**
* This function is called when to write ISOC data into appropriate dedicated
* periodic FIFO.
*/
static int32_t write_isoc_tx_fifo(dwc_otg_core_if_t * core_if, dwc_ep_t * dwc_ep)
{
dwc_otg_dev_if_t *dev_if = core_if->dev_if;
dwc_otg_dev_in_ep_regs_t *ep_regs;
dtxfsts_data_t txstatus = {.d32 = 0 };
uint32_t len = 0;
int epnum = dwc_ep->num;
int dwords;
DWC_DEBUGPL(DBG_PCD, "Dedicated TxFifo Empty: %d \n", epnum);
ep_regs = core_if->dev_if->in_ep_regs[epnum];
len = dwc_ep->xfer_len - dwc_ep->xfer_count;
if (len > dwc_ep->maxpacket) {
len = dwc_ep->maxpacket;
}
dwords = (len + 3) / 4;
/* While there is space in the queue and space in the FIFO and
* More data to tranfer, Write packets to the Tx FIFO */
txstatus.d32 = DWC_READ_REG32(&dev_if->in_ep_regs[epnum]->dtxfsts);
DWC_DEBUGPL(DBG_PCDV, "b4 dtxfsts[%d]=0x%08x\n", epnum, txstatus.d32);
while (txstatus.b.txfspcavail > dwords &&
dwc_ep->xfer_count < dwc_ep->xfer_len &&
dwc_ep->xfer_len != 0) {
/* Write the FIFO */
dwc_otg_ep_write_packet(core_if, dwc_ep, 0);
len = dwc_ep->xfer_len - dwc_ep->xfer_count;
if (len > dwc_ep->maxpacket) {
len = dwc_ep->maxpacket;
}
dwords = (len + 3) / 4;
txstatus.d32 =
DWC_READ_REG32(&dev_if->in_ep_regs[epnum]->dtxfsts);
DWC_DEBUGPL(DBG_PCDV, "dtxfsts[%d]=0x%08x\n", epnum,
txstatus.d32);
}
DWC_DEBUGPL(DBG_PCDV, "b4 dtxfsts[%d]=0x%08x\n", epnum,
DWC_READ_REG32(&dev_if->in_ep_regs[epnum]->dtxfsts));
return 1;
}
/**
* This function does the setup for a data transfer for an EP and
* starts the transfer. For an IN transfer, the packets will be
* loaded into the appropriate Tx FIFO in the ISR. For OUT transfers,
* the packets are unloaded from the Rx FIFO in the ISR. the ISR.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to start the transfer on.
*/
void dwc_otg_ep_start_transfer(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
depctl_data_t depctl;
deptsiz_data_t deptsiz;
gintmsk_data_t intr_mask = {.d32 = 0 };
DWC_DEBUGPL((DBG_PCDV | DBG_CILV), "%s()\n", __func__);
DWC_DEBUGPL(DBG_PCD, "ep%d-%s xfer_len=%d xfer_cnt=%d "
"xfer_buff=%p start_xfer_buff=%p, total_len = %d\n",
ep->num, (ep->is_in ? "IN" : "OUT"), ep->xfer_len,
ep->xfer_count, ep->xfer_buff, ep->start_xfer_buff,
ep->total_len);
/* IN endpoint */
if (ep->is_in == 1) {
dwc_otg_dev_in_ep_regs_t *in_regs =
core_if->dev_if->in_ep_regs[ep->num];
gnptxsts_data_t gtxstatus;
gtxstatus.d32 =
DWC_READ_REG32(&core_if->core_global_regs->gnptxsts);
if (core_if->en_multiple_tx_fifo == 0
&& gtxstatus.b.nptxqspcavail == 0
&& !core_if->dma_enable) {
#ifdef DEBUG
DWC_PRINTF("TX Queue Full (0x%0x)\n", gtxstatus.d32);
#endif
return;
}
depctl.d32 = DWC_READ_REG32(&(in_regs->diepctl));
deptsiz.d32 = DWC_READ_REG32(&(in_regs->dieptsiz));
if (ep->maxpacket > ep->maxxfer / MAX_PKT_CNT)
ep->xfer_len += (ep->maxxfer < (ep->total_len - ep->xfer_len)) ?
ep->maxxfer : (ep->total_len - ep->xfer_len);
else
ep->xfer_len += (MAX_PKT_CNT * ep->maxpacket < (ep->total_len - ep->xfer_len)) ?
MAX_PKT_CNT * ep->maxpacket : (ep->total_len - ep->xfer_len);
/* Zero Length Packet? */
if ((ep->xfer_len - ep->xfer_count) == 0) {
deptsiz.b.xfersize = 0;
deptsiz.b.pktcnt = 1;
} else {
/* Program the transfer size and packet count
* as follows: xfersize = N * maxpacket +
* short_packet pktcnt = N + (short_packet
* exist ? 1 : 0)
*/
deptsiz.b.xfersize = ep->xfer_len - ep->xfer_count;
deptsiz.b.pktcnt =
(ep->xfer_len - ep->xfer_count - 1 +
ep->maxpacket) / ep->maxpacket;
if (deptsiz.b.pktcnt > MAX_PKT_CNT) {
deptsiz.b.pktcnt = MAX_PKT_CNT;
deptsiz.b.xfersize = deptsiz.b.pktcnt * ep->maxpacket;
}
if (ep->type == DWC_OTG_EP_TYPE_ISOC)
deptsiz.b.mc = deptsiz.b.pktcnt;
}
/* Write the DMA register */
if (core_if->dma_enable) {
if (core_if->dma_desc_enable == 0) {
if (ep->type != DWC_OTG_EP_TYPE_ISOC)
deptsiz.b.mc = 1;
DWC_WRITE_REG32(&in_regs->dieptsiz,
deptsiz.d32);
DWC_WRITE_REG32(&(in_regs->diepdma),
(uint32_t) ep->dma_addr);
} else {
#ifdef DWC_UTE_CFI
/* The descriptor chain should be already initialized by now */
if (ep->buff_mode != BM_STANDARD) {
DWC_WRITE_REG32(&in_regs->diepdma,
ep->descs_dma_addr);
} else {
#endif
init_dma_desc_chain(core_if, ep);
/** DIEPDMAn Register write */
DWC_WRITE_REG32(&in_regs->diepdma,
ep->dma_desc_addr);
#ifdef DWC_UTE_CFI
}
#endif
}
} else {
DWC_WRITE_REG32(&in_regs->dieptsiz, deptsiz.d32);
if (ep->type != DWC_OTG_EP_TYPE_ISOC) {
/**
* Enable the Non-Periodic Tx FIFO empty interrupt,
* or the Tx FIFO epmty interrupt in dedicated Tx FIFO mode,
* the data will be written into the fifo by the ISR.
*/
if (core_if->en_multiple_tx_fifo == 0) {
intr_mask.b.nptxfempty = 1;
DWC_MODIFY_REG32
(&core_if->core_global_regs->gintmsk,
intr_mask.d32, intr_mask.d32);
} else {
/* Enable the Tx FIFO Empty Interrupt for this EP */
if (ep->xfer_len > 0) {
uint32_t fifoemptymsk = 0;
fifoemptymsk = 1 << ep->num;
DWC_MODIFY_REG32
(&core_if->dev_if->dev_global_regs->dtknqr4_fifoemptymsk,
0, fifoemptymsk);
}
}
} else {
write_isoc_tx_fifo(core_if, ep);
}
}
if (!core_if->core_params->en_multiple_tx_fifo && core_if->dma_enable)
depctl.b.nextep = core_if->nextep_seq[ep->num];
if (ep->type == DWC_OTG_EP_TYPE_ISOC)
{
dsts_data_t dsts = {.d32 = 0};
if (ep->bInterval == 1) {
dsts.d32 =
DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dsts);
ep->frame_num = dsts.b.soffn + ep->bInterval;
if (ep->frame_num > 0x3FFF)
{
ep->frm_overrun = 1;
ep->frame_num &= 0x3FFF;
} else
ep->frm_overrun = 0;
if (ep->frame_num & 0x1) {
depctl.b.setd1pid = 1;
} else {
depctl.b.setd0pid = 1;
}
}
}
/* EP enable, IN data in FIFO */
depctl.b.cnak = 1;
depctl.b.epena = 1;
DWC_WRITE_REG32(&in_regs->diepctl, depctl.d32);
} else {
/* OUT endpoint */
dwc_otg_dev_out_ep_regs_t *out_regs =
core_if->dev_if->out_ep_regs[ep->num];
depctl.d32 = DWC_READ_REG32(&(out_regs->doepctl));
deptsiz.d32 = DWC_READ_REG32(&(out_regs->doeptsiz));
if (!core_if->dma_desc_enable) {
if (ep->maxpacket > ep->maxxfer / MAX_PKT_CNT)
ep->xfer_len += (ep->maxxfer < (ep->total_len - ep->xfer_len)) ?
ep->maxxfer : (ep->total_len - ep->xfer_len);
else
ep->xfer_len += (MAX_PKT_CNT * ep->maxpacket < (ep->total_len
- ep->xfer_len)) ? MAX_PKT_CNT * ep->maxpacket : (ep->total_len - ep->xfer_len);
}
/* Program the transfer size and packet count as follows:
*
* pktcnt = N
* xfersize = N * maxpacket
*/
if ((ep->xfer_len - ep->xfer_count) == 0) {
/* Zero Length Packet */
deptsiz.b.xfersize = ep->maxpacket;
deptsiz.b.pktcnt = 1;
} else {
deptsiz.b.pktcnt =
(ep->xfer_len - ep->xfer_count +
(ep->maxpacket - 1)) / ep->maxpacket;
if (deptsiz.b.pktcnt > MAX_PKT_CNT) {
deptsiz.b.pktcnt = MAX_PKT_CNT;
}
if (!core_if->dma_desc_enable) {
ep->xfer_len =
deptsiz.b.pktcnt * ep->maxpacket + ep->xfer_count;
}
deptsiz.b.xfersize = ep->xfer_len - ep->xfer_count;
}
DWC_DEBUGPL(DBG_PCDV, "ep%d xfersize=%d pktcnt=%d\n",
ep->num, deptsiz.b.xfersize, deptsiz.b.pktcnt);
if (core_if->dma_enable) {
if (!core_if->dma_desc_enable) {
DWC_WRITE_REG32(&out_regs->doeptsiz,
deptsiz.d32);
DWC_WRITE_REG32(&(out_regs->doepdma),
(uint32_t) ep->dma_addr);
} else {
#ifdef DWC_UTE_CFI
/* The descriptor chain should be already initialized by now */
if (ep->buff_mode != BM_STANDARD) {
DWC_WRITE_REG32(&out_regs->doepdma,
ep->descs_dma_addr);
} else {
#endif
/** This is used for interrupt out transfers*/
if (!ep->xfer_len)
ep->xfer_len = ep->total_len;
init_dma_desc_chain(core_if, ep);
if (core_if->core_params->dev_out_nak) {
if (ep->type == DWC_OTG_EP_TYPE_BULK) {
deptsiz.b.pktcnt = (ep->total_len +
(ep->maxpacket - 1)) / ep->maxpacket;
deptsiz.b.xfersize = ep->total_len;
/* Remember initial value of doeptsiz */
core_if->start_doeptsiz_val[ep->num] = deptsiz.d32;
DWC_WRITE_REG32(&out_regs->doeptsiz,
deptsiz.d32);
}
}
/** DOEPDMAn Register write */
DWC_WRITE_REG32(&out_regs->doepdma,
ep->dma_desc_addr);
#ifdef DWC_UTE_CFI
}
#endif
}
} else {
DWC_WRITE_REG32(&out_regs->doeptsiz, deptsiz.d32);
}
if (ep->type == DWC_OTG_EP_TYPE_ISOC)
{
dsts_data_t dsts = {.d32 = 0};
if (ep->bInterval == 1) {
dsts.d32 =
DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dsts);
ep->frame_num = dsts.b.soffn + ep->bInterval;
if (ep->frame_num > 0x3FFF)
{
ep->frm_overrun = 1;
ep->frame_num &= 0x3FFF;
} else
ep->frm_overrun = 0;
if (ep->frame_num & 0x1) {
depctl.b.setd1pid = 1;
} else {
depctl.b.setd0pid = 1;
}
}
}
/* EP enable */
depctl.b.cnak = 1;
depctl.b.epena = 1;
DWC_WRITE_REG32(&out_regs->doepctl, depctl.d32);
DWC_DEBUGPL(DBG_PCD, "DOEPCTL=%08x DOEPTSIZ=%08x\n",
DWC_READ_REG32(&out_regs->doepctl),
DWC_READ_REG32(&out_regs->doeptsiz));
DWC_DEBUGPL(DBG_PCD, "DAINTMSK=%08x GINTMSK=%08x\n",
DWC_READ_REG32(&core_if->dev_if->
dev_global_regs->daintmsk),
DWC_READ_REG32(&core_if->
core_global_regs->gintmsk));
/* Timer is scheduling only for out bulk transfers for
* "Device DDMA OUT NAK Enhancement" feature to inform user
* about received data payload in case of timeout
*/
if (core_if->core_params->dev_out_nak) {
if (ep->type == DWC_OTG_EP_TYPE_BULK) {
core_if->ep_xfer_info[ep->num].core_if = core_if;
core_if->ep_xfer_info[ep->num].ep = ep;
core_if->ep_xfer_info[ep->num].state = 1;
/* Start a timer for this transfer. */
DWC_TIMER_SCHEDULE(core_if->ep_xfer_timer[ep->num], 10000);
}
}
}
}
/**
* This function setup a zero length transfer in Buffer DMA and
* Slave modes for usb requests with zero field set
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to start the transfer on.
*
*/
void dwc_otg_ep_start_zl_transfer(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
depctl_data_t depctl;
deptsiz_data_t deptsiz;
gintmsk_data_t intr_mask = {.d32 = 0 };
DWC_DEBUGPL((DBG_PCDV | DBG_CILV), "%s()\n", __func__);
DWC_PRINTF("zero length transfer is called\n");
/* IN endpoint */
if (ep->is_in == 1) {
dwc_otg_dev_in_ep_regs_t *in_regs =
core_if->dev_if->in_ep_regs[ep->num];
depctl.d32 = DWC_READ_REG32(&(in_regs->diepctl));
deptsiz.d32 = DWC_READ_REG32(&(in_regs->dieptsiz));
deptsiz.b.xfersize = 0;
deptsiz.b.pktcnt = 1;
/* Write the DMA register */
if (core_if->dma_enable) {
if (core_if->dma_desc_enable == 0) {
deptsiz.b.mc = 1;
DWC_WRITE_REG32(&in_regs->dieptsiz,
deptsiz.d32);
DWC_WRITE_REG32(&(in_regs->diepdma),
(uint32_t) ep->dma_addr);
}
} else {
DWC_WRITE_REG32(&in_regs->dieptsiz, deptsiz.d32);
/**
* Enable the Non-Periodic Tx FIFO empty interrupt,
* or the Tx FIFO epmty interrupt in dedicated Tx FIFO mode,
* the data will be written into the fifo by the ISR.
*/
if (core_if->en_multiple_tx_fifo == 0) {
intr_mask.b.nptxfempty = 1;
DWC_MODIFY_REG32(&core_if->
core_global_regs->gintmsk,
intr_mask.d32, intr_mask.d32);
} else {
/* Enable the Tx FIFO Empty Interrupt for this EP */
if (ep->xfer_len > 0) {
uint32_t fifoemptymsk = 0;
fifoemptymsk = 1 << ep->num;
DWC_MODIFY_REG32(&core_if->
dev_if->dev_global_regs->dtknqr4_fifoemptymsk,
0, fifoemptymsk);
}
}
}
if (!core_if->core_params->en_multiple_tx_fifo && core_if->dma_enable)
depctl.b.nextep = core_if->nextep_seq[ep->num];
/* EP enable, IN data in FIFO */
depctl.b.cnak = 1;
depctl.b.epena = 1;
DWC_WRITE_REG32(&in_regs->diepctl, depctl.d32);
} else {
/* OUT endpoint */
dwc_otg_dev_out_ep_regs_t *out_regs =
core_if->dev_if->out_ep_regs[ep->num];
depctl.d32 = DWC_READ_REG32(&(out_regs->doepctl));
deptsiz.d32 = DWC_READ_REG32(&(out_regs->doeptsiz));
/* Zero Length Packet */
deptsiz.b.xfersize = ep->maxpacket;
deptsiz.b.pktcnt = 1;
if (core_if->dma_enable) {
if (!core_if->dma_desc_enable) {
DWC_WRITE_REG32(&out_regs->doeptsiz,
deptsiz.d32);
DWC_WRITE_REG32(&(out_regs->doepdma),
(uint32_t) ep->dma_addr);
}
} else {
DWC_WRITE_REG32(&out_regs->doeptsiz, deptsiz.d32);
}
/* EP enable */
depctl.b.cnak = 1;
depctl.b.epena = 1;
DWC_WRITE_REG32(&out_regs->doepctl, depctl.d32);
}
}
/**
* This function does the setup for a data transfer for EP0 and starts
* the transfer. For an IN transfer, the packets will be loaded into
* the appropriate Tx FIFO in the ISR. For OUT transfers, the packets are
* unloaded from the Rx FIFO in the ISR.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP0 data.
*/
void dwc_otg_ep0_start_transfer(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
depctl_data_t depctl;
deptsiz0_data_t deptsiz;
gintmsk_data_t intr_mask = {.d32 = 0 };
dwc_otg_dev_dma_desc_t *dma_desc;
DWC_DEBUGPL(DBG_PCD, "ep%d-%s xfer_len=%d xfer_cnt=%d "
"xfer_buff=%p start_xfer_buff=%p \n",
ep->num, (ep->is_in ? "IN" : "OUT"), ep->xfer_len,
ep->xfer_count, ep->xfer_buff, ep->start_xfer_buff);
ep->total_len = ep->xfer_len;
/* IN endpoint */
if (ep->is_in == 1) {
dwc_otg_dev_in_ep_regs_t *in_regs =
core_if->dev_if->in_ep_regs[0];
gnptxsts_data_t gtxstatus;
gtxstatus.d32 =
DWC_READ_REG32(&core_if->core_global_regs->gnptxsts);
if (core_if->en_multiple_tx_fifo == 0
&& gtxstatus.b.nptxqspcavail == 0
&& !core_if->dma_enable) {
#ifdef DEBUG
deptsiz.d32 = DWC_READ_REG32(&in_regs->dieptsiz);
DWC_DEBUGPL(DBG_PCD, "DIEPCTL0=%0x\n",
DWC_READ_REG32(&in_regs->diepctl));
DWC_DEBUGPL(DBG_PCD, "DIEPTSIZ0=%0x (sz=%d, pcnt=%d)\n",
deptsiz.d32,
deptsiz.b.xfersize, deptsiz.b.pktcnt);
DWC_PRINTF("TX Queue or FIFO Full (0x%0x)\n",
gtxstatus.d32);
#endif
return;
}
depctl.d32 = DWC_READ_REG32(&in_regs->diepctl);
deptsiz.d32 = DWC_READ_REG32(&in_regs->dieptsiz);
/* Zero Length Packet? */
if (ep->xfer_len == 0) {
deptsiz.b.xfersize = 0;
deptsiz.b.pktcnt = 1;
} else {
/* Program the transfer size and packet count
* as follows: xfersize = N * maxpacket +
* short_packet pktcnt = N + (short_packet
* exist ? 1 : 0)
*/
if (ep->xfer_len > ep->maxpacket) {
ep->xfer_len = ep->maxpacket;
deptsiz.b.xfersize = ep->maxpacket;
} else {
deptsiz.b.xfersize = ep->xfer_len;
}
deptsiz.b.pktcnt = 1;
}
DWC_DEBUGPL(DBG_PCDV,
"IN len=%d xfersize=%d pktcnt=%d [%08x]\n",
ep->xfer_len, deptsiz.b.xfersize, deptsiz.b.pktcnt,
deptsiz.d32);
/* Write the DMA register */
if (core_if->dma_enable) {
if (core_if->dma_desc_enable == 0) {
DWC_WRITE_REG32(&in_regs->dieptsiz,
deptsiz.d32);
DWC_WRITE_REG32(&(in_regs->diepdma),
(uint32_t) ep->dma_addr);
} else {
dma_desc = core_if->dev_if->in_desc_addr;
/** DMA Descriptor Setup */
dma_desc->status.b.bs = BS_HOST_BUSY;
dma_desc->status.b.l = 1;
dma_desc->status.b.ioc = 1;
dma_desc->status.b.sp =
(ep->xfer_len == ep->maxpacket) ? 0 : 1;
dma_desc->status.b.bytes = ep->xfer_len;
dma_desc->buf = ep->dma_addr;
dma_desc->status.b.sts = 0;
dma_desc->status.b.bs = BS_HOST_READY;
/** DIEPDMA0 Register write */
DWC_WRITE_REG32(&in_regs->diepdma,
core_if->
dev_if->dma_in_desc_addr);
}
} else {
DWC_WRITE_REG32(&in_regs->dieptsiz, deptsiz.d32);
}
if (!core_if->core_params->en_multiple_tx_fifo && core_if->dma_enable)
depctl.b.nextep = core_if->nextep_seq[ep->num];
/* EP enable, IN data in FIFO */
depctl.b.cnak = 1;
depctl.b.epena = 1;
DWC_WRITE_REG32(&in_regs->diepctl, depctl.d32);
/**
* Enable the Non-Periodic Tx FIFO empty interrupt, the
* data will be written into the fifo by the ISR.
*/
if (!core_if->dma_enable) {
if (core_if->en_multiple_tx_fifo == 0) {
intr_mask.b.nptxfempty = 1;
DWC_MODIFY_REG32(&core_if->
core_global_regs->gintmsk,
intr_mask.d32, intr_mask.d32);
} else {
/* Enable the Tx FIFO Empty Interrupt for this EP */
if (ep->xfer_len > 0) {
uint32_t fifoemptymsk = 0;
fifoemptymsk |= 1 << ep->num;
DWC_MODIFY_REG32(&core_if->
dev_if->dev_global_regs->dtknqr4_fifoemptymsk,
0, fifoemptymsk);
}
}
}
} else {
/* OUT endpoint */
dwc_otg_dev_out_ep_regs_t *out_regs =
core_if->dev_if->out_ep_regs[0];
depctl.d32 = DWC_READ_REG32(&out_regs->doepctl);
deptsiz.d32 = DWC_READ_REG32(&out_regs->doeptsiz);
/* Program the transfer size and packet count as follows:
* xfersize = N * (maxpacket + 4 - (maxpacket % 4))
* pktcnt = N */
/* Zero Length Packet */
deptsiz.b.xfersize = ep->maxpacket;
deptsiz.b.pktcnt = 1;
DWC_DEBUGPL(DBG_PCDV, "len=%d xfersize=%d pktcnt=%d\n",
ep->xfer_len, deptsiz.b.xfersize, deptsiz.b.pktcnt);
if (core_if->dma_enable) {
if (!core_if->dma_desc_enable) {
DWC_WRITE_REG32(&out_regs->doeptsiz,
deptsiz.d32);
DWC_WRITE_REG32(&(out_regs->doepdma),
(uint32_t) ep->dma_addr);
} else {
dma_desc = core_if->dev_if->out_desc_addr;
/** DMA Descriptor Setup */
dma_desc->status.b.bs = BS_HOST_BUSY;
dma_desc->status.b.l = 1;
dma_desc->status.b.ioc = 1;
dma_desc->status.b.bytes = ep->maxpacket;
dma_desc->buf = ep->dma_addr;
dma_desc->status.b.sts = 0;
dma_desc->status.b.bs = BS_HOST_READY;
/** DOEPDMA0 Register write */
DWC_WRITE_REG32(&out_regs->doepdma,
core_if->
dev_if->dma_out_desc_addr);
}
} else {
DWC_WRITE_REG32(&out_regs->doeptsiz, deptsiz.d32);
}
/* EP enable */
depctl.b.cnak = 1;
depctl.b.epena = 1;
DWC_WRITE_REG32(&(out_regs->doepctl), depctl.d32);
}
}
/**
* This function continues control IN transfers started by
* dwc_otg_ep0_start_transfer, when the transfer does not fit in a
* single packet. NOTE: The DIEPCTL0/DOEPCTL0 registers only have one
* bit for the packet count.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP0 data.
*/
void dwc_otg_ep0_continue_transfer(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
depctl_data_t depctl;
deptsiz0_data_t deptsiz;
gintmsk_data_t intr_mask = {.d32 = 0 };
dwc_otg_dev_dma_desc_t *dma_desc;
if (ep->is_in == 1) {
dwc_otg_dev_in_ep_regs_t *in_regs =
core_if->dev_if->in_ep_regs[0];
gnptxsts_data_t tx_status = {.d32 = 0 };
tx_status.d32 =
DWC_READ_REG32(&core_if->core_global_regs->gnptxsts);
/** @todo Should there be check for room in the Tx
* Status Queue. If not remove the code above this comment. */
depctl.d32 = DWC_READ_REG32(&in_regs->diepctl);
deptsiz.d32 = DWC_READ_REG32(&in_regs->dieptsiz);
/* Program the transfer size and packet count
* as follows: xfersize = N * maxpacket +
* short_packet pktcnt = N + (short_packet
* exist ? 1 : 0)
*/
if (core_if->dma_desc_enable == 0) {
deptsiz.b.xfersize =
(ep->total_len - ep->xfer_count) >
ep->maxpacket ? ep->maxpacket : (ep->total_len -
ep->xfer_count);
deptsiz.b.pktcnt = 1;
if (core_if->dma_enable == 0) {
ep->xfer_len += deptsiz.b.xfersize;
} else {
ep->xfer_len = deptsiz.b.xfersize;
}
DWC_WRITE_REG32(&in_regs->dieptsiz, deptsiz.d32);
} else {
ep->xfer_len =
(ep->total_len - ep->xfer_count) >
ep->maxpacket ? ep->maxpacket : (ep->total_len -
ep->xfer_count);
dma_desc = core_if->dev_if->in_desc_addr;
/** DMA Descriptor Setup */
dma_desc->status.b.bs = BS_HOST_BUSY;
dma_desc->status.b.l = 1;
dma_desc->status.b.ioc = 1;
dma_desc->status.b.sp =
(ep->xfer_len == ep->maxpacket) ? 0 : 1;
dma_desc->status.b.bytes = ep->xfer_len;
dma_desc->buf = ep->dma_addr;
dma_desc->status.b.sts = 0;
dma_desc->status.b.bs = BS_HOST_READY;
/** DIEPDMA0 Register write */
DWC_WRITE_REG32(&in_regs->diepdma,
core_if->dev_if->dma_in_desc_addr);
}
DWC_DEBUGPL(DBG_PCDV,
"IN len=%d xfersize=%d pktcnt=%d [%08x]\n",
ep->xfer_len, deptsiz.b.xfersize, deptsiz.b.pktcnt,
deptsiz.d32);
/* Write the DMA register */
if (core_if->hwcfg2.b.architecture == DWC_INT_DMA_ARCH) {
if (core_if->dma_desc_enable == 0)
DWC_WRITE_REG32(&(in_regs->diepdma),
(uint32_t) ep->dma_addr);
}
if (!core_if->core_params->en_multiple_tx_fifo && core_if->dma_enable)
depctl.b.nextep = core_if->nextep_seq[ep->num];
/* EP enable, IN data in FIFO */
depctl.b.cnak = 1;
depctl.b.epena = 1;
DWC_WRITE_REG32(&in_regs->diepctl, depctl.d32);
/**
* Enable the Non-Periodic Tx FIFO empty interrupt, the
* data will be written into the fifo by the ISR.
*/
if (!core_if->dma_enable) {
if (core_if->en_multiple_tx_fifo == 0) {
/* First clear it from GINTSTS */
intr_mask.b.nptxfempty = 1;
DWC_MODIFY_REG32(&core_if->
core_global_regs->gintmsk,
intr_mask.d32, intr_mask.d32);
} else {
/* Enable the Tx FIFO Empty Interrupt for this EP */
if (ep->xfer_len > 0) {
uint32_t fifoemptymsk = 0;
fifoemptymsk |= 1 << ep->num;
DWC_MODIFY_REG32(&core_if->
dev_if->dev_global_regs->dtknqr4_fifoemptymsk,
0, fifoemptymsk);
}
}
}
} else {
dwc_otg_dev_out_ep_regs_t *out_regs =
core_if->dev_if->out_ep_regs[0];
depctl.d32 = DWC_READ_REG32(&out_regs->doepctl);
deptsiz.d32 = DWC_READ_REG32(&out_regs->doeptsiz);
/* Program the transfer size and packet count
* as follows: xfersize = N * maxpacket +
* short_packet pktcnt = N + (short_packet
* exist ? 1 : 0)
*/
deptsiz.b.xfersize = ep->maxpacket;
deptsiz.b.pktcnt = 1;
if (core_if->dma_desc_enable == 0) {
DWC_WRITE_REG32(&out_regs->doeptsiz, deptsiz.d32);
} else {
dma_desc = core_if->dev_if->out_desc_addr;
/** DMA Descriptor Setup */
dma_desc->status.b.bs = BS_HOST_BUSY;
dma_desc->status.b.l = 1;
dma_desc->status.b.ioc = 1;
dma_desc->status.b.bytes = ep->maxpacket;
dma_desc->buf = ep->dma_addr;
dma_desc->status.b.sts = 0;
dma_desc->status.b.bs = BS_HOST_READY;
/** DOEPDMA0 Register write */
DWC_WRITE_REG32(&out_regs->doepdma,
core_if->dev_if->dma_out_desc_addr);
}
DWC_DEBUGPL(DBG_PCDV,
"IN len=%d xfersize=%d pktcnt=%d [%08x]\n",
ep->xfer_len, deptsiz.b.xfersize, deptsiz.b.pktcnt,
deptsiz.d32);
/* Write the DMA register */
if (core_if->hwcfg2.b.architecture == DWC_INT_DMA_ARCH) {
if (core_if->dma_desc_enable == 0)
DWC_WRITE_REG32(&(out_regs->doepdma),
(uint32_t) ep->dma_addr);
}
/* EP enable, IN data in FIFO */
depctl.b.cnak = 1;
depctl.b.epena = 1;
DWC_WRITE_REG32(&out_regs->doepctl, depctl.d32);
}
}
#ifdef DEBUG
void dump_msg(const u8 * buf, unsigned int length)
{
unsigned int start, num, i;
char line[52], *p;
if (length >= 512)
return;
start = 0;
while (length > 0) {
num = length < 16u ? length : 16u;
p = line;
for (i = 0; i < num; ++i) {
if (i == 8)
*p++ = ' ';
DWC_SPRINTF(p, " %02x", buf[i]);
p += 3;
}
*p = 0;
DWC_PRINTF("%6x: %s\n", start, line);
buf += num;
start += num;
length -= num;
}
}
#else
static inline void dump_msg(const u8 * buf, unsigned int length)
{
}
#endif
/**
* This function writes a packet into the Tx FIFO associated with the
* EP. For non-periodic EPs the non-periodic Tx FIFO is written. For
* periodic EPs the periodic Tx FIFO associated with the EP is written
* with all packets for the next micro-frame.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to write packet for.
* @param dma Indicates if DMA is being used.
*/
void dwc_otg_ep_write_packet(dwc_otg_core_if_t * core_if, dwc_ep_t * ep,
int dma)
{
/**
* The buffer is padded to DWORD on a per packet basis in
* slave/dma mode if the MPS is not DWORD aligned. The last
* packet, if short, is also padded to a multiple of DWORD.
*
* ep->xfer_buff always starts DWORD aligned in memory and is a
* multiple of DWORD in length
*
* ep->xfer_len can be any number of bytes
*
* ep->xfer_count is a multiple of ep->maxpacket until the last
* packet
*
* FIFO access is DWORD */
uint32_t i;
uint32_t byte_count;
uint32_t dword_count;
uint32_t *fifo;
uint32_t *data_buff = (uint32_t *) ep->xfer_buff;
DWC_DEBUGPL((DBG_PCDV | DBG_CILV), "%s(%p,%p)\n", __func__, core_if,
ep);
if (ep->xfer_count >= ep->xfer_len) {
DWC_WARN("%s() No data for EP%d!!!\n", __func__, ep->num);
return;
}
/* Find the byte length of the packet either short packet or MPS */
if ((ep->xfer_len - ep->xfer_count) < ep->maxpacket) {
byte_count = ep->xfer_len - ep->xfer_count;
} else {
byte_count = ep->maxpacket;
}
/* Find the DWORD length, padded by extra bytes as neccessary if MPS
* is not a multiple of DWORD */
dword_count = (byte_count + 3) / 4;
#ifdef VERBOSE
dump_msg(ep->xfer_buff, byte_count);
#endif
/**@todo NGS Where are the Periodic Tx FIFO addresses
* intialized? What should this be? */
fifo = core_if->data_fifo[ep->num];
DWC_DEBUGPL((DBG_PCDV | DBG_CILV), "fifo=%p buff=%p *p=%08x bc=%d\n",
fifo, data_buff, *data_buff, byte_count);
if (!dma) {
for (i = 0; i < dword_count; i++, data_buff++) {
DWC_WRITE_REG32(fifo, *data_buff);
}
}
ep->xfer_count += byte_count;
ep->xfer_buff += byte_count;
ep->dma_addr += byte_count;
}
/**
* Set the EP STALL.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to set the stall on.
*/
void dwc_otg_ep_set_stall(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
depctl_data_t depctl;
volatile uint32_t *depctl_addr;
DWC_DEBUGPL(DBG_PCD, "%s ep%d-%s\n", __func__, ep->num,
(ep->is_in ? "IN" : "OUT"));
if (ep->is_in == 1) {
depctl_addr = &(core_if->dev_if->in_ep_regs[ep->num]->diepctl);
depctl.d32 = DWC_READ_REG32(depctl_addr);
/* set the disable and stall bits */
if (depctl.b.epena) {
depctl.b.epdis = 1;
}
depctl.b.stall = 1;
DWC_WRITE_REG32(depctl_addr, depctl.d32);
} else {
depctl_addr = &(core_if->dev_if->out_ep_regs[ep->num]->doepctl);
depctl.d32 = DWC_READ_REG32(depctl_addr);
/* set the stall bit */
depctl.b.stall = 1;
DWC_WRITE_REG32(depctl_addr, depctl.d32);
}
DWC_DEBUGPL(DBG_PCD, "DEPCTL=%0x\n", DWC_READ_REG32(depctl_addr));
return;
}
/**
* Clear the EP STALL.
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to clear stall from.
*/
void dwc_otg_ep_clear_stall(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
depctl_data_t depctl;
volatile uint32_t *depctl_addr;
DWC_DEBUGPL(DBG_PCD, "%s ep%d-%s\n", __func__, ep->num,
(ep->is_in ? "IN" : "OUT"));
if (ep->is_in == 1) {
depctl_addr = &(core_if->dev_if->in_ep_regs[ep->num]->diepctl);
} else {
depctl_addr = &(core_if->dev_if->out_ep_regs[ep->num]->doepctl);
}
depctl.d32 = DWC_READ_REG32(depctl_addr);
/* clear the stall bits */
depctl.b.stall = 0;
/*
* USB Spec 9.4.5: For endpoints using data toggle, regardless
* of whether an endpoint has the Halt feature set, a
* ClearFeature(ENDPOINT_HALT) request always results in the
* data toggle being reinitialized to DATA0.
*/
if (ep->type == DWC_OTG_EP_TYPE_INTR ||
ep->type == DWC_OTG_EP_TYPE_BULK) {
depctl.b.setd0pid = 1; /* DATA0 */
}
DWC_WRITE_REG32(depctl_addr, depctl.d32);
DWC_DEBUGPL(DBG_PCD, "DEPCTL=%0x\n", DWC_READ_REG32(depctl_addr));
return;
}
/**
* This function reads a packet from the Rx FIFO into the destination
* buffer. To read SETUP data use dwc_otg_read_setup_packet.
*
* @param core_if Programming view of DWC_otg controller.
* @param dest Destination buffer for the packet.
* @param bytes Number of bytes to copy to the destination.
*/
void dwc_otg_read_packet(dwc_otg_core_if_t * core_if,
uint8_t * dest, uint16_t bytes)
{
int i;
int word_count = (bytes + 3) / 4;
volatile uint32_t *fifo = core_if->data_fifo[0];
uint32_t *data_buff = (uint32_t *) dest;
/**
* @todo Account for the case where _dest is not dword aligned. This
* requires reading data from the FIFO into a uint32_t temp buffer,
* then moving it into the data buffer.
*/
DWC_DEBUGPL((DBG_PCDV | DBG_CILV), "%s(%p,%p,%d)\n", __func__,
core_if, dest, bytes);
for (i = 0; i < word_count; i++, data_buff++) {
*data_buff = DWC_READ_REG32(fifo);
}
return;
}
/**
* This functions reads the device registers and prints them
*
* @param core_if Programming view of DWC_otg controller.
*/
void dwc_otg_dump_dev_registers(dwc_otg_core_if_t * core_if)
{
int i;
volatile uint32_t *addr;
DWC_PRINTF("Device Global Registers\n");
addr = &core_if->dev_if->dev_global_regs->dcfg;
DWC_PRINTF("DCFG @0x%08lX : 0x%08X\n", (unsigned long) addr,
DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->dctl;
DWC_PRINTF("DCTL @0x%08lX : 0x%08X\n", (unsigned long) addr,
DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->dsts;
DWC_PRINTF("DSTS @0x%08lX : 0x%08X\n", (unsigned long) addr,
DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->diepmsk;
DWC_PRINTF("DIEPMSK @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->doepmsk;
DWC_PRINTF("DOEPMSK @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->daint;
DWC_PRINTF("DAINT @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->daintmsk;
DWC_PRINTF("DAINTMSK @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->dtknqr1;
DWC_PRINTF("DTKNQR1 @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
if (core_if->hwcfg2.b.dev_token_q_depth > 6) {
addr = &core_if->dev_if->dev_global_regs->dtknqr2;
DWC_PRINTF("DTKNQR2 @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
}
addr = &core_if->dev_if->dev_global_regs->dvbusdis;
DWC_PRINTF("DVBUSID @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->dvbuspulse;
DWC_PRINTF("DVBUSPULSE @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->dtknqr3_dthrctl;
DWC_PRINTF("DTKNQR3_DTHRCTL @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
if (core_if->hwcfg2.b.dev_token_q_depth > 22) {
addr = &core_if->dev_if->dev_global_regs->dtknqr4_fifoemptymsk;
DWC_PRINTF("DTKNQR4 @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
}
addr = &core_if->dev_if->dev_global_regs->dtknqr4_fifoemptymsk;
DWC_PRINTF("FIFOEMPMSK @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
if (core_if->hwcfg2.b.multi_proc_int) {
addr = &core_if->dev_if->dev_global_regs->deachint;
DWC_PRINTF("DEACHINT @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->dev_global_regs->deachintmsk;
DWC_PRINTF("DEACHINTMSK @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
for (i = 0; i <= core_if->dev_if->num_in_eps; i++) {
addr =
&core_if->dev_if->dev_global_regs->
diepeachintmsk[i];
DWC_PRINTF("DIEPEACHINTMSK[%d] @0x%08lX : 0x%08X\n",
i, (unsigned long)addr,
DWC_READ_REG32(addr));
}
for (i = 0; i <= core_if->dev_if->num_out_eps; i++) {
addr =
&core_if->dev_if->dev_global_regs->
doepeachintmsk[i];
DWC_PRINTF("DOEPEACHINTMSK[%d] @0x%08lX : 0x%08X\n",
i, (unsigned long)addr,
DWC_READ_REG32(addr));
}
}
for (i = 0; i <= core_if->dev_if->num_in_eps; i++) {
DWC_PRINTF("Device IN EP %d Registers\n", i);
addr = &core_if->dev_if->in_ep_regs[i]->diepctl;
DWC_PRINTF("DIEPCTL @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->in_ep_regs[i]->diepint;
DWC_PRINTF("DIEPINT @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->in_ep_regs[i]->dieptsiz;
DWC_PRINTF("DIETSIZ @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->in_ep_regs[i]->diepdma;
DWC_PRINTF("DIEPDMA @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->in_ep_regs[i]->dtxfsts;
DWC_PRINTF("DTXFSTS @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->in_ep_regs[i]->diepdmab;
DWC_PRINTF("DIEPDMAB @0x%08lX : 0x%08X\n",
(unsigned long)addr, 0 /*DWC_READ_REG32(addr) */ );
}
for (i = 0; i <= core_if->dev_if->num_out_eps; i++) {
DWC_PRINTF("Device OUT EP %d Registers\n", i);
addr = &core_if->dev_if->out_ep_regs[i]->doepctl;
DWC_PRINTF("DOEPCTL @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->out_ep_regs[i]->doepint;
DWC_PRINTF("DOEPINT @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->out_ep_regs[i]->doeptsiz;
DWC_PRINTF("DOETSIZ @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->dev_if->out_ep_regs[i]->doepdma;
DWC_PRINTF("DOEPDMA @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
if (core_if->dma_enable) { /* Don't access this register in SLAVE mode */
addr = &core_if->dev_if->out_ep_regs[i]->doepdmab;
DWC_PRINTF("DOEPDMAB @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
}
}
}
/**
* This functions reads the SPRAM and prints its content
*
* @param core_if Programming view of DWC_otg controller.
*/
void dwc_otg_dump_spram(dwc_otg_core_if_t * core_if)
{
volatile uint8_t *addr, *start_addr, *end_addr;
DWC_PRINTF("SPRAM Data:\n");
start_addr = (void *)core_if->core_global_regs;
DWC_PRINTF("Base Address: 0x%8lX\n", (unsigned long)start_addr);
start_addr += 0x00028000;
end_addr = (void *)core_if->core_global_regs;
end_addr += 0x000280e0;
for (addr = start_addr; addr < end_addr; addr += 16) {
DWC_PRINTF
("0x%8lX:\t%2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X %2X\n",
(unsigned long)addr, addr[0], addr[1], addr[2], addr[3],
addr[4], addr[5], addr[6], addr[7], addr[8], addr[9],
addr[10], addr[11], addr[12], addr[13], addr[14], addr[15]
);
}
return;
}
/**
* This function reads the host registers and prints them
*
* @param core_if Programming view of DWC_otg controller.
*/
void dwc_otg_dump_host_registers(dwc_otg_core_if_t * core_if)
{
int i;
volatile uint32_t *addr;
DWC_PRINTF("Host Global Registers\n");
addr = &core_if->host_if->host_global_regs->hcfg;
DWC_PRINTF("HCFG @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->host_if->host_global_regs->hfir;
DWC_PRINTF("HFIR @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->host_if->host_global_regs->hfnum;
DWC_PRINTF("HFNUM @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->host_if->host_global_regs->hptxsts;
DWC_PRINTF("HPTXSTS @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->host_if->host_global_regs->haint;
DWC_PRINTF("HAINT @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->host_if->host_global_regs->haintmsk;
DWC_PRINTF("HAINTMSK @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
if (core_if->dma_desc_enable) {
addr = &core_if->host_if->host_global_regs->hflbaddr;
DWC_PRINTF("HFLBADDR @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
}
addr = core_if->host_if->hprt0;
DWC_PRINTF("HPRT0 @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
for (i = 0; i < core_if->core_params->host_channels; i++) {
DWC_PRINTF("Host Channel %d Specific Registers\n", i);
addr = &core_if->host_if->hc_regs[i]->hcchar;
DWC_PRINTF("HCCHAR @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->host_if->hc_regs[i]->hcsplt;
DWC_PRINTF("HCSPLT @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->host_if->hc_regs[i]->hcint;
DWC_PRINTF("HCINT @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->host_if->hc_regs[i]->hcintmsk;
DWC_PRINTF("HCINTMSK @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->host_if->hc_regs[i]->hctsiz;
DWC_PRINTF("HCTSIZ @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->host_if->hc_regs[i]->hcdma;
DWC_PRINTF("HCDMA @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
if (core_if->dma_desc_enable) {
addr = &core_if->host_if->hc_regs[i]->hcdmab;
DWC_PRINTF("HCDMAB @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
}
}
return;
}
/**
* This function reads the core global registers and prints them
*
* @param core_if Programming view of DWC_otg controller.
*/
void dwc_otg_dump_global_registers(dwc_otg_core_if_t * core_if)
{
int i, ep_num;
volatile uint32_t *addr;
char *txfsiz;
DWC_PRINTF("Core Global Registers\n");
addr = &core_if->core_global_regs->gotgctl;
DWC_PRINTF("GOTGCTL @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gotgint;
DWC_PRINTF("GOTGINT @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gahbcfg;
DWC_PRINTF("GAHBCFG @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gusbcfg;
DWC_PRINTF("GUSBCFG @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->grstctl;
DWC_PRINTF("GRSTCTL @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gintsts;
DWC_PRINTF("GINTSTS @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gintmsk;
DWC_PRINTF("GINTMSK @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->grxstsr;
DWC_PRINTF("GRXSTSR @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->grxfsiz;
DWC_PRINTF("GRXFSIZ @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gnptxfsiz;
DWC_PRINTF("GNPTXFSIZ @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gnptxsts;
DWC_PRINTF("GNPTXSTS @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gi2cctl;
DWC_PRINTF("GI2CCTL @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gpvndctl;
DWC_PRINTF("GPVNDCTL @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->ggpio;
DWC_PRINTF("GGPIO @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->guid;
DWC_PRINTF("GUID @0x%08lX : 0x%08X\n",
(unsigned long)addr, DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gsnpsid;
DWC_PRINTF("GSNPSID @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->ghwcfg1;
DWC_PRINTF("GHWCFG1 @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->ghwcfg2;
DWC_PRINTF("GHWCFG2 @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->ghwcfg3;
DWC_PRINTF("GHWCFG3 @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->ghwcfg4;
DWC_PRINTF("GHWCFG4 @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->glpmcfg;
DWC_PRINTF("GLPMCFG @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gpwrdn;
DWC_PRINTF("GPWRDN @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->gdfifocfg;
DWC_PRINTF("GDFIFOCFG @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
addr = &core_if->core_global_regs->adpctl;
DWC_PRINTF("ADPCTL @0x%08lX : 0x%08X\n", (unsigned long)addr,
dwc_otg_adp_read_reg(core_if));
addr = &core_if->core_global_regs->hptxfsiz;
DWC_PRINTF("HPTXFSIZ @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
if (core_if->en_multiple_tx_fifo == 0) {
ep_num = core_if->hwcfg4.b.num_dev_perio_in_ep;
txfsiz = "DPTXFSIZ";
} else {
ep_num = core_if->hwcfg4.b.num_in_eps;
txfsiz = "DIENPTXF";
}
for (i = 0; i < ep_num; i++) {
addr = &core_if->core_global_regs->dtxfsiz[i];
DWC_PRINTF("%s[%d] @0x%08lX : 0x%08X\n", txfsiz, i + 1,
(unsigned long)addr, DWC_READ_REG32(addr));
}
addr = core_if->pcgcctl;
DWC_PRINTF("PCGCCTL @0x%08lX : 0x%08X\n", (unsigned long)addr,
DWC_READ_REG32(addr));
}
/**
* Flush a Tx FIFO.
*
* @param core_if Programming view of DWC_otg controller.
* @param num Tx FIFO to flush.
*/
void dwc_otg_flush_tx_fifo(dwc_otg_core_if_t * core_if, const int num)
{
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
volatile grstctl_t greset = {.d32 = 0 };
int count = 0;
DWC_DEBUGPL((DBG_CIL | DBG_PCDV), "Flush Tx FIFO %d\n", num);
greset.b.txfflsh = 1;
greset.b.txfnum = num;
DWC_WRITE_REG32(&global_regs->grstctl, greset.d32);
do {
greset.d32 = DWC_READ_REG32(&global_regs->grstctl);
if (++count > 10000) {
DWC_WARN("%s() HANG! GRSTCTL=%0x GNPTXSTS=0x%08x\n",
__func__, greset.d32,
DWC_READ_REG32(&global_regs->gnptxsts));
break;
}
dwc_udelay(1);
} while (greset.b.txfflsh == 1);
/* Wait for 3 PHY Clocks */
dwc_udelay(1);
}
/**
* Flush Rx FIFO.
*
* @param core_if Programming view of DWC_otg controller.
*/
void dwc_otg_flush_rx_fifo(dwc_otg_core_if_t * core_if)
{
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
volatile grstctl_t greset = {.d32 = 0 };
int count = 0;
DWC_DEBUGPL((DBG_CIL | DBG_PCDV), "%s\n", __func__);
/*
*
*/
greset.b.rxfflsh = 1;
DWC_WRITE_REG32(&global_regs->grstctl, greset.d32);
do {
greset.d32 = DWC_READ_REG32(&global_regs->grstctl);
if (++count > 10000) {
DWC_WARN("%s() HANG! GRSTCTL=%0x\n", __func__,
greset.d32);
break;
}
dwc_udelay(1);
} while (greset.b.rxfflsh == 1);
/* Wait for 3 PHY Clocks */
dwc_udelay(1);
}
/**
* Do core a soft reset of the core. Be careful with this because it
* resets all the internal state machines of the core.
*/
void dwc_otg_core_reset(dwc_otg_core_if_t * core_if)
{
dwc_otg_core_global_regs_t *global_regs = core_if->core_global_regs;
volatile grstctl_t greset = {.d32 = 0 };
int count = 0;
DWC_DEBUGPL(DBG_CILV, "%s\n", __func__);
/* Wait for AHB master IDLE state. */
do {
dwc_udelay(10);
greset.d32 = DWC_READ_REG32(&global_regs->grstctl);
if (++count > 100000) {
DWC_WARN("%s() HANG! AHB Idle GRSTCTL=%0x\n", __func__,
greset.d32);
return;
}
}
while (greset.b.ahbidle == 0);
/* Core Soft Reset */
count = 0;
greset.b.csftrst = 1;
DWC_WRITE_REG32(&global_regs->grstctl, greset.d32);
do {
greset.d32 = DWC_READ_REG32(&global_regs->grstctl);
if (++count > 10000) {
DWC_WARN("%s() HANG! Soft Reset GRSTCTL=%0x\n",
__func__, greset.d32);
break;
}
dwc_udelay(1);
}
while (greset.b.csftrst == 1);
/* Wait for 3 PHY Clocks */
dwc_mdelay(100);
}
uint8_t dwc_otg_is_device_mode(dwc_otg_core_if_t * _core_if)
{
return (dwc_otg_mode(_core_if) != DWC_HOST_MODE);
}
uint8_t dwc_otg_is_host_mode(dwc_otg_core_if_t * _core_if)
{
return (dwc_otg_mode(_core_if) == DWC_HOST_MODE);
}
/**
* Register HCD callbacks. The callbacks are used to start and stop
* the HCD for interrupt processing.
*
* @param core_if Programming view of DWC_otg controller.
* @param cb the HCD callback structure.
* @param p pointer to be passed to callback function (usb_hcd*).
*/
void dwc_otg_cil_register_hcd_callbacks(dwc_otg_core_if_t * core_if,
dwc_otg_cil_callbacks_t * cb, void *p)
{
core_if->hcd_cb = cb;
cb->p = p;
}
/**
* Register PCD callbacks. The callbacks are used to start and stop
* the PCD for interrupt processing.
*
* @param core_if Programming view of DWC_otg controller.
* @param cb the PCD callback structure.
* @param p pointer to be passed to callback function (pcd*).
*/
void dwc_otg_cil_register_pcd_callbacks(dwc_otg_core_if_t * core_if,
dwc_otg_cil_callbacks_t * cb, void *p)
{
core_if->pcd_cb = cb;
cb->p = p;
}
#ifdef DWC_EN_ISOC
/**
* This function writes isoc data per 1 (micro)frame into tx fifo
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to start the transfer on.
*
*/
void write_isoc_frame_data(dwc_otg_core_if_t * core_if, dwc_ep_t * ep)
{
dwc_otg_dev_in_ep_regs_t *ep_regs;
dtxfsts_data_t txstatus = {.d32 = 0 };
uint32_t len = 0;
uint32_t dwords;
ep->xfer_len = ep->data_per_frame;
ep->xfer_count = 0;
ep_regs = core_if->dev_if->in_ep_regs[ep->num];
len = ep->xfer_len - ep->xfer_count;
if (len > ep->maxpacket) {
len = ep->maxpacket;
}
dwords = (len + 3) / 4;
/* While there is space in the queue and space in the FIFO and
* More data to tranfer, Write packets to the Tx FIFO */
txstatus.d32 =
DWC_READ_REG32(&core_if->dev_if->in_ep_regs[ep->num]->dtxfsts);
DWC_DEBUGPL(DBG_PCDV, "b4 dtxfsts[%d]=0x%08x\n", ep->num, txstatus.d32);
while (txstatus.b.txfspcavail > dwords &&
ep->xfer_count < ep->xfer_len && ep->xfer_len != 0) {
/* Write the FIFO */
dwc_otg_ep_write_packet(core_if, ep, 0);
len = ep->xfer_len - ep->xfer_count;
if (len > ep->maxpacket) {
len = ep->maxpacket;
}
dwords = (len + 3) / 4;
txstatus.d32 =
DWC_READ_REG32(&core_if->dev_if->
in_ep_regs[ep->num]->dtxfsts);
DWC_DEBUGPL(DBG_PCDV, "dtxfsts[%d]=0x%08x\n", ep->num,
txstatus.d32);
}
}
/**
* This function initializes a descriptor chain for Isochronous transfer
*
* @param core_if Programming view of DWC_otg controller.
* @param ep The EP to start the transfer on.
*
*/
void dwc_otg_iso_ep_start_frm_transfer(dwc_otg_core_if_t * core_if,
dwc_ep_t * ep)
{
deptsiz_data_t deptsiz = {.d32 = 0 };
depctl_data_t depctl = {.d32 = 0 };
dsts_data_t dsts = {.d32 = 0 };
volatile uint32_t *addr;
if (ep->is_in) {
addr = &core_if->dev_if->in_ep_regs[ep->num]->diepctl;
} else {
addr = &core_if->dev_if->out_ep_regs[ep->num]->doepctl;
}
ep->xfer_len = ep->data_per_frame;
ep->xfer_count = 0;
ep->xfer_buff = ep->cur_pkt_addr;
ep->dma_addr = ep->cur_pkt_dma_addr;
if (ep->is_in) {
/* Program the transfer size and packet count
* as follows: xfersize = N * maxpacket +
* short_packet pktcnt = N + (short_packet
* exist ? 1 : 0)
*/
deptsiz.b.xfersize = ep->xfer_len;
deptsiz.b.pktcnt =
(ep->xfer_len - 1 + ep->maxpacket) / ep->maxpacket;
deptsiz.b.mc = deptsiz.b.pktcnt;
DWC_WRITE_REG32(&core_if->dev_if->in_ep_regs[ep->num]->dieptsiz,
deptsiz.d32);
/* Write the DMA register */
if (core_if->dma_enable) {
DWC_WRITE_REG32(&
(core_if->dev_if->in_ep_regs[ep->num]->
diepdma), (uint32_t) ep->dma_addr);
}
} else {
deptsiz.b.pktcnt =
(ep->xfer_len + (ep->maxpacket - 1)) / ep->maxpacket;
deptsiz.b.xfersize = deptsiz.b.pktcnt * ep->maxpacket;
DWC_WRITE_REG32(&core_if->dev_if->out_ep_regs[ep->num]->
doeptsiz, deptsiz.d32);
if (core_if->dma_enable) {
DWC_WRITE_REG32(&
(core_if->dev_if->out_ep_regs[ep->num]->
doepdma), (uint32_t) ep->dma_addr);
}
}
/** Enable endpoint, clear nak */
depctl.d32 = 0;
if (ep->bInterval == 1) {
dsts.d32 =
DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dsts);
ep->next_frame = dsts.b.soffn + ep->bInterval;
if (ep->next_frame & 0x1) {
depctl.b.setd1pid = 1;
} else {
depctl.b.setd0pid = 1;
}
} else {
ep->next_frame += ep->bInterval;
if (ep->next_frame & 0x1) {
depctl.b.setd1pid = 1;
} else {
depctl.b.setd0pid = 1;
}
}
depctl.b.epena = 1;
depctl.b.cnak = 1;
DWC_MODIFY_REG32(addr, 0, depctl.d32);
depctl.d32 = DWC_READ_REG32(addr);
if (ep->is_in && core_if->dma_enable == 0) {
write_isoc_frame_data(core_if, ep);
}
}
#endif /* DWC_EN_ISOC */
static void dwc_otg_set_uninitialized(int32_t * p, int size)
{
int i;
for (i = 0; i < size; i++) {
p[i] = -1;
}
}
static int dwc_otg_param_initialized(int32_t val)
{
return val != -1;
}
static int dwc_otg_setup_params(dwc_otg_core_if_t * core_if)
{
int i;
core_if->core_params = DWC_ALLOC(sizeof(*core_if->core_params));
if (!core_if->core_params) {
return -DWC_E_NO_MEMORY;
}
dwc_otg_set_uninitialized((int32_t *) core_if->core_params,
sizeof(*core_if->core_params) /
sizeof(int32_t));
DWC_PRINTF("Setting default values for core params\n");
dwc_otg_set_param_otg_cap(core_if, dwc_param_otg_cap_default);
dwc_otg_set_param_dma_enable(core_if, dwc_param_dma_enable_default);
dwc_otg_set_param_dma_desc_enable(core_if,
dwc_param_dma_desc_enable_default);
dwc_otg_set_param_opt(core_if, dwc_param_opt_default);
dwc_otg_set_param_dma_burst_size(core_if,
dwc_param_dma_burst_size_default);
dwc_otg_set_param_host_support_fs_ls_low_power(core_if,
dwc_param_host_support_fs_ls_low_power_default);
dwc_otg_set_param_enable_dynamic_fifo(core_if,
dwc_param_enable_dynamic_fifo_default);
dwc_otg_set_param_data_fifo_size(core_if,
dwc_param_data_fifo_size_default);
dwc_otg_set_param_dev_rx_fifo_size(core_if,
dwc_param_dev_rx_fifo_size_default);
dwc_otg_set_param_dev_nperio_tx_fifo_size(core_if,
dwc_param_dev_nperio_tx_fifo_size_default);
dwc_otg_set_param_host_rx_fifo_size(core_if,
dwc_param_host_rx_fifo_size_default);
dwc_otg_set_param_host_nperio_tx_fifo_size(core_if,
dwc_param_host_nperio_tx_fifo_size_default);
dwc_otg_set_param_host_perio_tx_fifo_size(core_if,
dwc_param_host_perio_tx_fifo_size_default);
dwc_otg_set_param_max_transfer_size(core_if,
dwc_param_max_transfer_size_default);
dwc_otg_set_param_max_packet_count(core_if,
dwc_param_max_packet_count_default);
dwc_otg_set_param_host_channels(core_if,
dwc_param_host_channels_default);
dwc_otg_set_param_dev_endpoints(core_if,
dwc_param_dev_endpoints_default);
dwc_otg_set_param_phy_type(core_if, dwc_param_phy_type_default);
dwc_otg_set_param_speed(core_if, dwc_param_speed_default);
dwc_otg_set_param_host_ls_low_power_phy_clk(core_if,
dwc_param_host_ls_low_power_phy_clk_default);
dwc_otg_set_param_phy_ulpi_ddr(core_if, dwc_param_phy_ulpi_ddr_default);
dwc_otg_set_param_phy_ulpi_ext_vbus(core_if,
dwc_param_phy_ulpi_ext_vbus_default);
dwc_otg_set_param_phy_utmi_width(core_if,
dwc_param_phy_utmi_width_default);
dwc_otg_set_param_ts_dline(core_if, dwc_param_ts_dline_default);
dwc_otg_set_param_i2c_enable(core_if, dwc_param_i2c_enable_default);
dwc_otg_set_param_ulpi_fs_ls(core_if, dwc_param_ulpi_fs_ls_default);
dwc_otg_set_param_en_multiple_tx_fifo(core_if,
dwc_param_en_multiple_tx_fifo_default);
for (i = 0; i < 15; i++) {
dwc_otg_set_param_dev_perio_tx_fifo_size(core_if,
dwc_param_dev_perio_tx_fifo_size_default,
i);
}
for (i = 0; i < 15; i++) {
dwc_otg_set_param_dev_tx_fifo_size(core_if,
dwc_param_dev_tx_fifo_size_default,
i);
}
dwc_otg_set_param_thr_ctl(core_if, dwc_param_thr_ctl_default);
dwc_otg_set_param_mpi_enable(core_if, dwc_param_mpi_enable_default);
dwc_otg_set_param_pti_enable(core_if, dwc_param_pti_enable_default);
dwc_otg_set_param_lpm_enable(core_if, dwc_param_lpm_enable_default);
dwc_otg_set_param_ic_usb_cap(core_if, dwc_param_ic_usb_cap_default);
dwc_otg_set_param_tx_thr_length(core_if,
dwc_param_tx_thr_length_default);
dwc_otg_set_param_rx_thr_length(core_if,
dwc_param_rx_thr_length_default);
dwc_otg_set_param_ahb_thr_ratio(core_if,
dwc_param_ahb_thr_ratio_default);
dwc_otg_set_param_power_down(core_if, dwc_param_power_down_default);
dwc_otg_set_param_reload_ctl(core_if, dwc_param_reload_ctl_default);
dwc_otg_set_param_dev_out_nak(core_if, dwc_param_dev_out_nak_default);
dwc_otg_set_param_cont_on_bna(core_if, dwc_param_cont_on_bna_default);
dwc_otg_set_param_ahb_single(core_if, dwc_param_ahb_single_default);
dwc_otg_set_param_otg_ver(core_if, dwc_param_otg_ver_default);
dwc_otg_set_param_adp_enable(core_if, dwc_param_adp_enable_default);
return 0;
}
uint8_t dwc_otg_is_dma_enable(dwc_otg_core_if_t * core_if)
{
return core_if->dma_enable;
}
/* Checks if the parameter is outside of its valid range of values */
#define DWC_OTG_PARAM_TEST(_param_, _low_, _high_) \
(((_param_) < (_low_)) || \
((_param_) > (_high_)))
/* Parameter access functions */
int dwc_otg_set_param_otg_cap(dwc_otg_core_if_t * core_if, int32_t val)
{
int valid;
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 2)) {
DWC_WARN("Wrong value for otg_cap parameter\n");
DWC_WARN("otg_cap parameter must be 0,1 or 2\n");
retval = -DWC_E_INVALID;
goto out;
}
valid = 1;
switch (val) {
case DWC_OTG_CAP_PARAM_HNP_SRP_CAPABLE:
if (core_if->hwcfg2.b.op_mode !=
DWC_HWCFG2_OP_MODE_HNP_SRP_CAPABLE_OTG)
valid = 0;
break;
case DWC_OTG_CAP_PARAM_SRP_ONLY_CAPABLE:
if ((core_if->hwcfg2.b.op_mode !=
DWC_HWCFG2_OP_MODE_HNP_SRP_CAPABLE_OTG)
&& (core_if->hwcfg2.b.op_mode !=
DWC_HWCFG2_OP_MODE_SRP_ONLY_CAPABLE_OTG)
&& (core_if->hwcfg2.b.op_mode !=
DWC_HWCFG2_OP_MODE_SRP_CAPABLE_DEVICE)
&& (core_if->hwcfg2.b.op_mode !=
DWC_HWCFG2_OP_MODE_SRP_CAPABLE_HOST)) {
valid = 0;
}
break;
case DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE:
/* always valid */
break;
}
if (!valid) {
if (dwc_otg_param_initialized(core_if->core_params->otg_cap)) {
DWC_ERROR
("%d invalid for otg_cap paremter. Check HW configuration.\n",
val);
}
val =
(((core_if->hwcfg2.b.op_mode ==
DWC_HWCFG2_OP_MODE_HNP_SRP_CAPABLE_OTG)
|| (core_if->hwcfg2.b.op_mode ==
DWC_HWCFG2_OP_MODE_SRP_ONLY_CAPABLE_OTG)
|| (core_if->hwcfg2.b.op_mode ==
DWC_HWCFG2_OP_MODE_SRP_CAPABLE_DEVICE)
|| (core_if->hwcfg2.b.op_mode ==
DWC_HWCFG2_OP_MODE_SRP_CAPABLE_HOST)) ?
DWC_OTG_CAP_PARAM_SRP_ONLY_CAPABLE :
DWC_OTG_CAP_PARAM_NO_HNP_SRP_CAPABLE);
retval = -DWC_E_INVALID;
}
core_if->core_params->otg_cap = val;
out:
return retval;
}
int32_t dwc_otg_get_param_otg_cap(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->otg_cap;
}
int dwc_otg_set_param_opt(dwc_otg_core_if_t * core_if, int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong value for opt parameter\n");
return -DWC_E_INVALID;
}
core_if->core_params->opt = val;
return 0;
}
int32_t dwc_otg_get_param_opt(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->opt;
}
int dwc_otg_set_param_dma_enable(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong value for dma enable\n");
return -DWC_E_INVALID;
}
if ((val == 1) && (core_if->hwcfg2.b.architecture == 0)) {
if (dwc_otg_param_initialized(core_if->core_params->dma_enable)) {
DWC_ERROR
("%d invalid for dma_enable paremter. Check HW configuration.\n",
val);
}
val = 0;
retval = -DWC_E_INVALID;
}
core_if->core_params->dma_enable = val;
if (val == 0) {
dwc_otg_set_param_dma_desc_enable(core_if, 0);
}
return retval;
}
int32_t dwc_otg_get_param_dma_enable(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->dma_enable;
}
int dwc_otg_set_param_dma_desc_enable(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong value for dma_enable\n");
DWC_WARN("dma_desc_enable must be 0 or 1\n");
return -DWC_E_INVALID;
}
if ((val == 1)
&& ((dwc_otg_get_param_dma_enable(core_if) == 0)
|| (core_if->hwcfg4.b.desc_dma == 0))) {
if (dwc_otg_param_initialized
(core_if->core_params->dma_desc_enable)) {
DWC_ERROR
("%d invalid for dma_desc_enable paremter. Check HW configuration.\n",
val);
}
val = 0;
retval = -DWC_E_INVALID;
}
core_if->core_params->dma_desc_enable = val;
return retval;
}
int32_t dwc_otg_get_param_dma_desc_enable(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->dma_desc_enable;
}
int dwc_otg_set_param_host_support_fs_ls_low_power(dwc_otg_core_if_t * core_if,
int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong value for host_support_fs_low_power\n");
DWC_WARN("host_support_fs_low_power must be 0 or 1\n");
return -DWC_E_INVALID;
}
core_if->core_params->host_support_fs_ls_low_power = val;
return 0;
}
int32_t dwc_otg_get_param_host_support_fs_ls_low_power(dwc_otg_core_if_t *
core_if)
{
return core_if->core_params->host_support_fs_ls_low_power;
}
int dwc_otg_set_param_enable_dynamic_fifo(dwc_otg_core_if_t * core_if,
int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong value for enable_dynamic_fifo\n");
DWC_WARN("enable_dynamic_fifo must be 0 or 1\n");
return -DWC_E_INVALID;
}
if ((val == 1) && (core_if->hwcfg2.b.dynamic_fifo == 0)) {
if (dwc_otg_param_initialized
(core_if->core_params->enable_dynamic_fifo)) {
DWC_ERROR
("%d invalid for enable_dynamic_fifo paremter. Check HW configuration.\n",
val);
}
val = 0;
retval = -DWC_E_INVALID;
}
core_if->core_params->enable_dynamic_fifo = val;
return retval;
}
int32_t dwc_otg_get_param_enable_dynamic_fifo(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->enable_dynamic_fifo;
}
int dwc_otg_set_param_data_fifo_size(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 32, 32768)) {
DWC_WARN("Wrong value for data_fifo_size\n");
DWC_WARN("data_fifo_size must be 32-32768\n");
return -DWC_E_INVALID;
}
if (val > core_if->hwcfg3.b.dfifo_depth) {
if (dwc_otg_param_initialized
(core_if->core_params->data_fifo_size)) {
DWC_ERROR
("%d invalid for data_fifo_size parameter. Check HW configuration.\n",
val);
}
val = core_if->hwcfg3.b.dfifo_depth;
retval = -DWC_E_INVALID;
}
core_if->core_params->data_fifo_size = val;
return retval;
}
int32_t dwc_otg_get_param_data_fifo_size(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->data_fifo_size;
}
int dwc_otg_set_param_dev_rx_fifo_size(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 16, 32768)) {
DWC_WARN("Wrong value for dev_rx_fifo_size\n");
DWC_WARN("dev_rx_fifo_size must be 16-32768\n");
return -DWC_E_INVALID;
}
if (val > DWC_READ_REG32(&core_if->core_global_regs->grxfsiz)) {
if (dwc_otg_param_initialized(core_if->core_params->dev_rx_fifo_size)) {
DWC_WARN("%d invalid for dev_rx_fifo_size parameter\n", val);
}
val = DWC_READ_REG32(&core_if->core_global_regs->grxfsiz);
retval = -DWC_E_INVALID;
}
core_if->core_params->dev_rx_fifo_size = val;
return retval;
}
int32_t dwc_otg_get_param_dev_rx_fifo_size(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->dev_rx_fifo_size;
}
int dwc_otg_set_param_dev_nperio_tx_fifo_size(dwc_otg_core_if_t * core_if,
int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 16, 32768)) {
DWC_WARN("Wrong value for dev_nperio_tx_fifo\n");
DWC_WARN("dev_nperio_tx_fifo must be 16-32768\n");
return -DWC_E_INVALID;
}
if (val > (DWC_READ_REG32(&core_if->core_global_regs->gnptxfsiz) >> 16)) {
if (dwc_otg_param_initialized
(core_if->core_params->dev_nperio_tx_fifo_size)) {
DWC_ERROR
("%d invalid for dev_nperio_tx_fifo_size. Check HW configuration.\n",
val);
}
val =
(DWC_READ_REG32(&core_if->core_global_regs->gnptxfsiz) >>
16);
retval = -DWC_E_INVALID;
}
core_if->core_params->dev_nperio_tx_fifo_size = val;
return retval;
}
int32_t dwc_otg_get_param_dev_nperio_tx_fifo_size(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->dev_nperio_tx_fifo_size;
}
int dwc_otg_set_param_host_rx_fifo_size(dwc_otg_core_if_t * core_if,
int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 16, 32768)) {
DWC_WARN("Wrong value for host_rx_fifo_size\n");
DWC_WARN("host_rx_fifo_size must be 16-32768\n");
return -DWC_E_INVALID;
}
if (val > DWC_READ_REG32(&core_if->core_global_regs->grxfsiz)) {
if (dwc_otg_param_initialized
(core_if->core_params->host_rx_fifo_size)) {
DWC_ERROR
("%d invalid for host_rx_fifo_size. Check HW configuration.\n",
val);
}
val = DWC_READ_REG32(&core_if->core_global_regs->grxfsiz);
retval = -DWC_E_INVALID;
}
core_if->core_params->host_rx_fifo_size = val;
return retval;
}
int32_t dwc_otg_get_param_host_rx_fifo_size(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->host_rx_fifo_size;
}
int dwc_otg_set_param_host_nperio_tx_fifo_size(dwc_otg_core_if_t * core_if,
int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 16, 32768)) {
DWC_WARN("Wrong value for host_nperio_tx_fifo_size\n");
DWC_WARN("host_nperio_tx_fifo_size must be 16-32768\n");
return -DWC_E_INVALID;
}
if (val > (DWC_READ_REG32(&core_if->core_global_regs->gnptxfsiz) >> 16)) {
if (dwc_otg_param_initialized
(core_if->core_params->host_nperio_tx_fifo_size)) {
DWC_ERROR
("%d invalid for host_nperio_tx_fifo_size. Check HW configuration.\n",
val);
}
val =
(DWC_READ_REG32(&core_if->core_global_regs->gnptxfsiz) >>
16);
retval = -DWC_E_INVALID;
}
core_if->core_params->host_nperio_tx_fifo_size = val;
return retval;
}
int32_t dwc_otg_get_param_host_nperio_tx_fifo_size(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->host_nperio_tx_fifo_size;
}
int dwc_otg_set_param_host_perio_tx_fifo_size(dwc_otg_core_if_t * core_if,
int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 16, 32768)) {
DWC_WARN("Wrong value for host_perio_tx_fifo_size\n");
DWC_WARN("host_perio_tx_fifo_size must be 16-32768\n");
return -DWC_E_INVALID;
}
if (val >
((core_if->hptxfsiz.d32)>> 16)) {
if (dwc_otg_param_initialized
(core_if->core_params->host_perio_tx_fifo_size)) {
DWC_ERROR
("%d invalid for host_perio_tx_fifo_size. Check HW configuration.\n",
val);
}
val = (core_if->hptxfsiz.d32) >> 16;
retval = -DWC_E_INVALID;
}
core_if->core_params->host_perio_tx_fifo_size = val;
return retval;
}
int32_t dwc_otg_get_param_host_perio_tx_fifo_size(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->host_perio_tx_fifo_size;
}
int dwc_otg_set_param_max_transfer_size(dwc_otg_core_if_t * core_if,
int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 2047, 524288)) {
DWC_WARN("Wrong value for max_transfer_size\n");
DWC_WARN("max_transfer_size must be 2047-524288\n");
return -DWC_E_INVALID;
}
if (val >= (1 << (core_if->hwcfg3.b.xfer_size_cntr_width + 11))) {
if (dwc_otg_param_initialized
(core_if->core_params->max_transfer_size)) {
DWC_ERROR
("%d invalid for max_transfer_size. Check HW configuration.\n",
val);
}
val =
((1 << (core_if->hwcfg3.b.packet_size_cntr_width + 11)) -
1);
retval = -DWC_E_INVALID;
}
core_if->core_params->max_transfer_size = val;
return retval;
}
int32_t dwc_otg_get_param_max_transfer_size(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->max_transfer_size;
}
int dwc_otg_set_param_max_packet_count(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 15, 511)) {
DWC_WARN("Wrong value for max_packet_count\n");
DWC_WARN("max_packet_count must be 15-511\n");
return -DWC_E_INVALID;
}
if (val > (1 << (core_if->hwcfg3.b.packet_size_cntr_width + 4))) {
if (dwc_otg_param_initialized
(core_if->core_params->max_packet_count)) {
DWC_ERROR
("%d invalid for max_packet_count. Check HW configuration.\n",
val);
}
val =
((1 << (core_if->hwcfg3.b.packet_size_cntr_width + 4)) - 1);
retval = -DWC_E_INVALID;
}
core_if->core_params->max_packet_count = val;
return retval;
}
int32_t dwc_otg_get_param_max_packet_count(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->max_packet_count;
}
int dwc_otg_set_param_host_channels(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 1, 16)) {
DWC_WARN("Wrong value for host_channels\n");
DWC_WARN("host_channels must be 1-16\n");
return -DWC_E_INVALID;
}
if (val > (core_if->hwcfg2.b.num_host_chan + 1)) {
if (dwc_otg_param_initialized
(core_if->core_params->host_channels)) {
DWC_ERROR
("%d invalid for host_channels. Check HW configurations.\n",
val);
}
val = (core_if->hwcfg2.b.num_host_chan + 1);
retval = -DWC_E_INVALID;
}
core_if->core_params->host_channels = val;
return retval;
}
int32_t dwc_otg_get_param_host_channels(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->host_channels;
}
int dwc_otg_set_param_dev_endpoints(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 1, 15)) {
DWC_WARN("Wrong value for dev_endpoints\n");
DWC_WARN("dev_endpoints must be 1-15\n");
return -DWC_E_INVALID;
}
if (val > (core_if->hwcfg2.b.num_dev_ep)) {
if (dwc_otg_param_initialized
(core_if->core_params->dev_endpoints)) {
DWC_ERROR
("%d invalid for dev_endpoints. Check HW configurations.\n",
val);
}
val = core_if->hwcfg2.b.num_dev_ep;
retval = -DWC_E_INVALID;
}
core_if->core_params->dev_endpoints = val;
return retval;
}
int32_t dwc_otg_get_param_dev_endpoints(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->dev_endpoints;
}
int dwc_otg_set_param_phy_type(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
int valid = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 2)) {
DWC_WARN("Wrong value for phy_type\n");
DWC_WARN("phy_type must be 0,1 or 2\n");
return -DWC_E_INVALID;
}
#ifndef NO_FS_PHY_HW_CHECKS
if ((val == DWC_PHY_TYPE_PARAM_UTMI) &&
((core_if->hwcfg2.b.hs_phy_type == 1) ||
(core_if->hwcfg2.b.hs_phy_type == 3))) {
valid = 1;
} else if ((val == DWC_PHY_TYPE_PARAM_ULPI) &&
((core_if->hwcfg2.b.hs_phy_type == 2) ||
(core_if->hwcfg2.b.hs_phy_type == 3))) {
valid = 1;
} else if ((val == DWC_PHY_TYPE_PARAM_FS) &&
(core_if->hwcfg2.b.fs_phy_type == 1)) {
valid = 1;
}
if (!valid) {
if (dwc_otg_param_initialized(core_if->core_params->phy_type)) {
DWC_ERROR
("%d invalid for phy_type. Check HW configurations.\n",
val);
}
if (core_if->hwcfg2.b.hs_phy_type) {
if ((core_if->hwcfg2.b.hs_phy_type == 3) ||
(core_if->hwcfg2.b.hs_phy_type == 1)) {
val = DWC_PHY_TYPE_PARAM_UTMI;
} else {
val = DWC_PHY_TYPE_PARAM_ULPI;
}
}
retval = -DWC_E_INVALID;
}
#endif
core_if->core_params->phy_type = val;
return retval;
}
int32_t dwc_otg_get_param_phy_type(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->phy_type;
}
int dwc_otg_set_param_speed(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong value for speed parameter\n");
DWC_WARN("max_speed parameter must be 0 or 1\n");
return -DWC_E_INVALID;
}
if ((val == 0)
&& dwc_otg_get_param_phy_type(core_if) == DWC_PHY_TYPE_PARAM_FS) {
if (dwc_otg_param_initialized(core_if->core_params->speed)) {
DWC_ERROR
("%d invalid for speed paremter. Check HW configuration.\n",
val);
}
val =
(dwc_otg_get_param_phy_type(core_if) ==
DWC_PHY_TYPE_PARAM_FS ? 1 : 0);
retval = -DWC_E_INVALID;
}
core_if->core_params->speed = val;
return retval;
}
int32_t dwc_otg_get_param_speed(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->speed;
}
int dwc_otg_set_param_host_ls_low_power_phy_clk(dwc_otg_core_if_t * core_if,
int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN
("Wrong value for host_ls_low_power_phy_clk parameter\n");
DWC_WARN("host_ls_low_power_phy_clk must be 0 or 1\n");
return -DWC_E_INVALID;
}
if ((val == DWC_HOST_LS_LOW_POWER_PHY_CLK_PARAM_48MHZ)
&& (dwc_otg_get_param_phy_type(core_if) == DWC_PHY_TYPE_PARAM_FS)) {
if (dwc_otg_param_initialized
(core_if->core_params->host_ls_low_power_phy_clk)) {
DWC_ERROR
("%d invalid for host_ls_low_power_phy_clk. Check HW configuration.\n",
val);
}
val =
(dwc_otg_get_param_phy_type(core_if) ==
DWC_PHY_TYPE_PARAM_FS) ?
DWC_HOST_LS_LOW_POWER_PHY_CLK_PARAM_6MHZ :
DWC_HOST_LS_LOW_POWER_PHY_CLK_PARAM_48MHZ;
retval = -DWC_E_INVALID;
}
core_if->core_params->host_ls_low_power_phy_clk = val;
return retval;
}
int32_t dwc_otg_get_param_host_ls_low_power_phy_clk(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->host_ls_low_power_phy_clk;
}
int dwc_otg_set_param_phy_ulpi_ddr(dwc_otg_core_if_t * core_if, int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong value for phy_ulpi_ddr\n");
DWC_WARN("phy_upli_ddr must be 0 or 1\n");
return -DWC_E_INVALID;
}
core_if->core_params->phy_ulpi_ddr = val;
return 0;
}
int32_t dwc_otg_get_param_phy_ulpi_ddr(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->phy_ulpi_ddr;
}
int dwc_otg_set_param_phy_ulpi_ext_vbus(dwc_otg_core_if_t * core_if,
int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong valaue for phy_ulpi_ext_vbus\n");
DWC_WARN("phy_ulpi_ext_vbus must be 0 or 1\n");
return -DWC_E_INVALID;
}
core_if->core_params->phy_ulpi_ext_vbus = val;
return 0;
}
int32_t dwc_otg_get_param_phy_ulpi_ext_vbus(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->phy_ulpi_ext_vbus;
}
int dwc_otg_set_param_phy_utmi_width(dwc_otg_core_if_t * core_if, int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 8, 8) && DWC_OTG_PARAM_TEST(val, 16, 16)) {
DWC_WARN("Wrong valaue for phy_utmi_width\n");
DWC_WARN("phy_utmi_width must be 8 or 16\n");
return -DWC_E_INVALID;
}
core_if->core_params->phy_utmi_width = val;
return 0;
}
int32_t dwc_otg_get_param_phy_utmi_width(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->phy_utmi_width;
}
int dwc_otg_set_param_ulpi_fs_ls(dwc_otg_core_if_t * core_if, int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong valaue for ulpi_fs_ls\n");
DWC_WARN("ulpi_fs_ls must be 0 or 1\n");
return -DWC_E_INVALID;
}
core_if->core_params->ulpi_fs_ls = val;
return 0;
}
int32_t dwc_otg_get_param_ulpi_fs_ls(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->ulpi_fs_ls;
}
int dwc_otg_set_param_ts_dline(dwc_otg_core_if_t * core_if, int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong valaue for ts_dline\n");
DWC_WARN("ts_dline must be 0 or 1\n");
return -DWC_E_INVALID;
}
core_if->core_params->ts_dline = val;
return 0;
}
int32_t dwc_otg_get_param_ts_dline(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->ts_dline;
}
int dwc_otg_set_param_i2c_enable(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong valaue for i2c_enable\n");
DWC_WARN("i2c_enable must be 0 or 1\n");
return -DWC_E_INVALID;
}
#ifndef NO_FS_PHY_HW_CHECK
if (val == 1 && core_if->hwcfg3.b.i2c == 0) {
if (dwc_otg_param_initialized(core_if->core_params->i2c_enable)) {
DWC_ERROR
("%d invalid for i2c_enable. Check HW configuration.\n",
val);
}
val = 0;
retval = -DWC_E_INVALID;
}
#endif
core_if->core_params->i2c_enable = val;
return retval;
}
int32_t dwc_otg_get_param_i2c_enable(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->i2c_enable;
}
int dwc_otg_set_param_dev_perio_tx_fifo_size(dwc_otg_core_if_t * core_if,
int32_t val, int fifo_num)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 4, 768)) {
DWC_WARN("Wrong value for dev_perio_tx_fifo_size\n");
DWC_WARN("dev_perio_tx_fifo_size must be 4-768\n");
return -DWC_E_INVALID;
}
if (val >
(DWC_READ_REG32(&core_if->core_global_regs->dtxfsiz[fifo_num]))) {
if (dwc_otg_param_initialized
(core_if->core_params->dev_perio_tx_fifo_size[fifo_num])) {
DWC_ERROR
("`%d' invalid for parameter `dev_perio_fifo_size_%d'. Check HW configuration.\n",
val, fifo_num);
}
val = (DWC_READ_REG32(&core_if->core_global_regs->dtxfsiz[fifo_num]));
retval = -DWC_E_INVALID;
}
core_if->core_params->dev_perio_tx_fifo_size[fifo_num] = val;
return retval;
}
int32_t dwc_otg_get_param_dev_perio_tx_fifo_size(dwc_otg_core_if_t * core_if,
int fifo_num)
{
return core_if->core_params->dev_perio_tx_fifo_size[fifo_num];
}
int dwc_otg_set_param_en_multiple_tx_fifo(dwc_otg_core_if_t * core_if,
int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong valaue for en_multiple_tx_fifo,\n");
DWC_WARN("en_multiple_tx_fifo must be 0 or 1\n");
return -DWC_E_INVALID;
}
if (val == 1 && core_if->hwcfg4.b.ded_fifo_en == 0) {
if (dwc_otg_param_initialized
(core_if->core_params->en_multiple_tx_fifo)) {
DWC_ERROR
("%d invalid for parameter en_multiple_tx_fifo. Check HW configuration.\n",
val);
}
val = 0;
retval = -DWC_E_INVALID;
}
core_if->core_params->en_multiple_tx_fifo = val;
return retval;
}
int32_t dwc_otg_get_param_en_multiple_tx_fifo(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->en_multiple_tx_fifo;
}
int dwc_otg_set_param_dev_tx_fifo_size(dwc_otg_core_if_t * core_if, int32_t val,
int fifo_num)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 4, 768)) {
DWC_WARN("Wrong value for dev_tx_fifo_size\n");
DWC_WARN("dev_tx_fifo_size must be 4-768\n");
return -DWC_E_INVALID;
}
if (val >
(DWC_READ_REG32(&core_if->core_global_regs->dtxfsiz[fifo_num]))) {
if (dwc_otg_param_initialized
(core_if->core_params->dev_tx_fifo_size[fifo_num])) {
DWC_ERROR
("`%d' invalid for parameter `dev_tx_fifo_size_%d'. Check HW configuration.\n",
val, fifo_num);
}
val = (DWC_READ_REG32(&core_if->core_global_regs->dtxfsiz[fifo_num]));
retval = -DWC_E_INVALID;
}
core_if->core_params->dev_tx_fifo_size[fifo_num] = val;
return retval;
}
int32_t dwc_otg_get_param_dev_tx_fifo_size(dwc_otg_core_if_t * core_if,
int fifo_num)
{
return core_if->core_params->dev_tx_fifo_size[fifo_num];
}
int dwc_otg_set_param_thr_ctl(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 7)) {
DWC_WARN("Wrong value for thr_ctl\n");
DWC_WARN("thr_ctl must be 0-7\n");
return -DWC_E_INVALID;
}
if ((val != 0) &&
(!dwc_otg_get_param_dma_enable(core_if) ||
!core_if->hwcfg4.b.ded_fifo_en)) {
if (dwc_otg_param_initialized(core_if->core_params->thr_ctl)) {
DWC_ERROR
("%d invalid for parameter thr_ctl. Check HW configuration.\n",
val);
}
val = 0;
retval = -DWC_E_INVALID;
}
core_if->core_params->thr_ctl = val;
return retval;
}
int32_t dwc_otg_get_param_thr_ctl(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->thr_ctl;
}
int dwc_otg_set_param_lpm_enable(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("Wrong value for lpm_enable\n");
DWC_WARN("lpm_enable must be 0 or 1\n");
return -DWC_E_INVALID;
}
if (val && !core_if->hwcfg3.b.otg_lpm_en) {
if (dwc_otg_param_initialized(core_if->core_params->lpm_enable)) {
DWC_ERROR
("%d invalid for parameter lpm_enable. Check HW configuration.\n",
val);
}
val = 0;
retval = -DWC_E_INVALID;
}
core_if->core_params->lpm_enable = val;
return retval;
}
int32_t dwc_otg_get_param_lpm_enable(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->lpm_enable;
}
int dwc_otg_set_param_tx_thr_length(dwc_otg_core_if_t * core_if, int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 8, 128)) {
DWC_WARN("Wrong valaue for tx_thr_length\n");
DWC_WARN("tx_thr_length must be 8 - 128\n");
return -DWC_E_INVALID;
}
core_if->core_params->tx_thr_length = val;
return 0;
}
int32_t dwc_otg_get_param_tx_thr_length(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->tx_thr_length;
}
int dwc_otg_set_param_rx_thr_length(dwc_otg_core_if_t * core_if, int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 8, 128)) {
DWC_WARN("Wrong valaue for rx_thr_length\n");
DWC_WARN("rx_thr_length must be 8 - 128\n");
return -DWC_E_INVALID;
}
core_if->core_params->rx_thr_length = val;
return 0;
}
int32_t dwc_otg_get_param_rx_thr_length(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->rx_thr_length;
}
int dwc_otg_set_param_dma_burst_size(dwc_otg_core_if_t * core_if, int32_t val)
{
if (DWC_OTG_PARAM_TEST(val, 1, 1) &&
DWC_OTG_PARAM_TEST(val, 4, 4) &&
DWC_OTG_PARAM_TEST(val, 8, 8) &&
DWC_OTG_PARAM_TEST(val, 16, 16) &&
DWC_OTG_PARAM_TEST(val, 32, 32) &&
DWC_OTG_PARAM_TEST(val, 64, 64) &&
DWC_OTG_PARAM_TEST(val, 128, 128) &&
DWC_OTG_PARAM_TEST(val, 256, 256)) {
DWC_WARN("`%d' invalid for parameter `dma_burst_size'\n", val);
return -DWC_E_INVALID;
}
core_if->core_params->dma_burst_size = val;
return 0;
}
int32_t dwc_otg_get_param_dma_burst_size(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->dma_burst_size;
}
int dwc_otg_set_param_pti_enable(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("`%d' invalid for parameter `pti_enable'\n", val);
return -DWC_E_INVALID;
}
if (val && (core_if->snpsid < OTG_CORE_REV_2_72a)) {
if (dwc_otg_param_initialized(core_if->core_params->pti_enable)) {
DWC_ERROR
("%d invalid for parameter pti_enable. Check HW configuration.\n",
val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->pti_enable = val;
return retval;
}
int32_t dwc_otg_get_param_pti_enable(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->pti_enable;
}
int dwc_otg_set_param_mpi_enable(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("`%d' invalid for parameter `mpi_enable'\n", val);
return -DWC_E_INVALID;
}
if (val && (core_if->hwcfg2.b.multi_proc_int == 0)) {
if (dwc_otg_param_initialized(core_if->core_params->mpi_enable)) {
DWC_ERROR
("%d invalid for parameter mpi_enable. Check HW configuration.\n",
val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->mpi_enable = val;
return retval;
}
int32_t dwc_otg_get_param_mpi_enable(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->mpi_enable;
}
int dwc_otg_set_param_adp_enable(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("`%d' invalid for parameter `adp_enable'\n", val);
return -DWC_E_INVALID;
}
if (val && (core_if->hwcfg3.b.adp_supp == 0)) {
if (dwc_otg_param_initialized
(core_if->core_params->adp_supp_enable)) {
DWC_ERROR
("%d invalid for parameter adp_enable. Check HW configuration.\n",
val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->adp_supp_enable = val;
/*Set OTG version 2.0 in case of enabling ADP*/
if (val)
dwc_otg_set_param_otg_ver(core_if, 1);
return retval;
}
int32_t dwc_otg_get_param_adp_enable(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->adp_supp_enable;
}
int dwc_otg_set_param_ic_usb_cap(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("`%d' invalid for parameter `ic_usb_cap'\n", val);
DWC_WARN("ic_usb_cap must be 0 or 1\n");
return -DWC_E_INVALID;
}
if (val && (core_if->hwcfg2.b.otg_enable_ic_usb == 0)) {
if (dwc_otg_param_initialized(core_if->core_params->ic_usb_cap)) {
DWC_ERROR
("%d invalid for parameter ic_usb_cap. Check HW configuration.\n",
val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->ic_usb_cap = val;
return retval;
}
int32_t dwc_otg_get_param_ic_usb_cap(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->ic_usb_cap;
}
int dwc_otg_set_param_ahb_thr_ratio(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
int valid = 1;
if (DWC_OTG_PARAM_TEST(val, 0, 3)) {
DWC_WARN("`%d' invalid for parameter `ahb_thr_ratio'\n", val);
DWC_WARN("ahb_thr_ratio must be 0 - 3\n");
return -DWC_E_INVALID;
}
if (val
&& (core_if->snpsid < OTG_CORE_REV_2_81a
|| !dwc_otg_get_param_thr_ctl(core_if))) {
valid = 0;
} else if (val
&& ((dwc_otg_get_param_tx_thr_length(core_if) / (1 << val)) <
4)) {
valid = 0;
}
if (valid == 0) {
if (dwc_otg_param_initialized
(core_if->core_params->ahb_thr_ratio)) {
DWC_ERROR
("%d invalid for parameter ahb_thr_ratio. Check HW configuration.\n",
val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->ahb_thr_ratio = val;
return retval;
}
int32_t dwc_otg_get_param_ahb_thr_ratio(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->ahb_thr_ratio;
}
int dwc_otg_set_param_power_down(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
int valid = 1;
if (DWC_OTG_PARAM_TEST(val, 0, 2)) {
DWC_WARN("`%d' invalid for parameter `power_down'\n", val);
DWC_WARN("power_down must be 0 - 2\n");
return -DWC_E_INVALID;
}
if ((val == 2) && (core_if->snpsid < OTG_CORE_REV_2_91a)) {
valid = 0;
}
if (valid == 0) {
if (dwc_otg_param_initialized(core_if->core_params->power_down)) {
DWC_ERROR
("%d invalid for parameter power_down. Check HW configuration.\n",
val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->power_down = val;
return retval;
}
int32_t dwc_otg_get_param_power_down(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->power_down;
}
int dwc_otg_set_param_reload_ctl(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
int valid = 1;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("`%d' invalid for parameter `reload_ctl'\n", val);
DWC_WARN("reload_ctl must be 0 or 1\n");
return -DWC_E_INVALID;
}
if ((val == 1) && (core_if->snpsid < OTG_CORE_REV_2_92a)) {
valid = 0;
}
if (valid == 0) {
if (dwc_otg_param_initialized(core_if->core_params->reload_ctl)) {
DWC_ERROR("%d invalid for parameter reload_ctl."
"Check HW configuration.\n", val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->reload_ctl = val;
return retval;
}
int32_t dwc_otg_get_param_reload_ctl(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->reload_ctl;
}
int dwc_otg_set_param_dev_out_nak(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
int valid = 1;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("`%d' invalid for parameter `dev_out_nak'\n", val);
DWC_WARN("dev_out_nak must be 0 or 1\n");
return -DWC_E_INVALID;
}
if ((val == 1) && ((core_if->snpsid < OTG_CORE_REV_2_93a) ||
!(core_if->core_params->dma_desc_enable))) {
valid = 0;
}
if (valid == 0) {
if (dwc_otg_param_initialized(core_if->core_params->dev_out_nak)) {
DWC_ERROR("%d invalid for parameter dev_out_nak."
"Check HW configuration.\n", val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->dev_out_nak = val;
return retval;
}
int32_t dwc_otg_get_param_dev_out_nak(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->dev_out_nak;
}
int dwc_otg_set_param_cont_on_bna(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
int valid = 1;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("`%d' invalid for parameter `cont_on_bna'\n", val);
DWC_WARN("cont_on_bna must be 0 or 1\n");
return -DWC_E_INVALID;
}
if ((val == 1) && ((core_if->snpsid < OTG_CORE_REV_2_94a) ||
!(core_if->core_params->dma_desc_enable))) {
valid = 0;
}
if (valid == 0) {
if (dwc_otg_param_initialized(core_if->core_params->cont_on_bna)) {
DWC_ERROR("%d invalid for parameter cont_on_bna."
"Check HW configuration.\n", val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->cont_on_bna = val;
return retval;
}
int32_t dwc_otg_get_param_cont_on_bna(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->cont_on_bna;
}
int dwc_otg_set_param_ahb_single(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
int valid = 1;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("`%d' invalid for parameter `ahb_single'\n", val);
DWC_WARN("ahb_single must be 0 or 1\n");
return -DWC_E_INVALID;
}
if ((val == 1) && (core_if->snpsid < OTG_CORE_REV_2_94a)) {
valid = 0;
}
if (valid == 0) {
if (dwc_otg_param_initialized(core_if->core_params->ahb_single)) {
DWC_ERROR("%d invalid for parameter ahb_single."
"Check HW configuration.\n", val);
}
retval = -DWC_E_INVALID;
val = 0;
}
core_if->core_params->ahb_single = val;
return retval;
}
int32_t dwc_otg_get_param_ahb_single(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->ahb_single;
}
int dwc_otg_set_param_otg_ver(dwc_otg_core_if_t * core_if, int32_t val)
{
int retval = 0;
if (DWC_OTG_PARAM_TEST(val, 0, 1)) {
DWC_WARN("`%d' invalid for parameter `otg_ver'\n", val);
DWC_WARN
("otg_ver must be 0(for OTG 1.3 support) or 1(for OTG 2.0 support)\n");
return -DWC_E_INVALID;
}
core_if->core_params->otg_ver = val;
return retval;
}
int32_t dwc_otg_get_param_otg_ver(dwc_otg_core_if_t * core_if)
{
return core_if->core_params->otg_ver;
}
uint32_t dwc_otg_get_hnpstatus(dwc_otg_core_if_t * core_if)
{
gotgctl_data_t otgctl;
otgctl.d32 = DWC_READ_REG32(&core_if->core_global_regs->gotgctl);
return otgctl.b.hstnegscs;
}
uint32_t dwc_otg_get_srpstatus(dwc_otg_core_if_t * core_if)
{
gotgctl_data_t otgctl;
otgctl.d32 = DWC_READ_REG32(&core_if->core_global_regs->gotgctl);
return otgctl.b.sesreqscs;
}
void dwc_otg_set_hnpreq(dwc_otg_core_if_t * core_if, uint32_t val)
{
if(core_if->otg_ver == 0) {
gotgctl_data_t otgctl;
otgctl.d32 = DWC_READ_REG32(&core_if->core_global_regs->gotgctl);
otgctl.b.hnpreq = val;
DWC_WRITE_REG32(&core_if->core_global_regs->gotgctl, otgctl.d32);
} else {
core_if->otg_sts = val;
}
}
uint32_t dwc_otg_get_gsnpsid(dwc_otg_core_if_t * core_if)
{
return core_if->snpsid;
}
uint32_t dwc_otg_get_mode(dwc_otg_core_if_t * core_if)
{
gintsts_data_t gintsts;
gintsts.d32 = DWC_READ_REG32(&core_if->core_global_regs->gintsts);
return gintsts.b.curmode;
}
uint32_t dwc_otg_get_hnpcapable(dwc_otg_core_if_t * core_if)
{
gusbcfg_data_t usbcfg;
usbcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->gusbcfg);
return usbcfg.b.hnpcap;
}
void dwc_otg_set_hnpcapable(dwc_otg_core_if_t * core_if, uint32_t val)
{
gusbcfg_data_t usbcfg;
usbcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->gusbcfg);
usbcfg.b.hnpcap = val;
DWC_WRITE_REG32(&core_if->core_global_regs->gusbcfg, usbcfg.d32);
}
uint32_t dwc_otg_get_srpcapable(dwc_otg_core_if_t * core_if)
{
gusbcfg_data_t usbcfg;
usbcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->gusbcfg);
return usbcfg.b.srpcap;
}
void dwc_otg_set_srpcapable(dwc_otg_core_if_t * core_if, uint32_t val)
{
gusbcfg_data_t usbcfg;
usbcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->gusbcfg);
usbcfg.b.srpcap = val;
DWC_WRITE_REG32(&core_if->core_global_regs->gusbcfg, usbcfg.d32);
}
uint32_t dwc_otg_get_devspeed(dwc_otg_core_if_t * core_if)
{
dcfg_data_t dcfg;
dcfg.d32 = DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dcfg);
return dcfg.b.devspd;
}
void dwc_otg_set_devspeed(dwc_otg_core_if_t * core_if, uint32_t val)
{
dcfg_data_t dcfg;
dcfg.d32 = DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dcfg);
dcfg.b.devspd = val;
DWC_WRITE_REG32(&core_if->dev_if->dev_global_regs->dcfg, dcfg.d32);
}
uint32_t dwc_otg_get_busconnected(dwc_otg_core_if_t * core_if)
{
hprt0_data_t hprt0;
hprt0.d32 = DWC_READ_REG32(core_if->host_if->hprt0);
return hprt0.b.prtconnsts;
}
uint32_t dwc_otg_get_enumspeed(dwc_otg_core_if_t * core_if)
{
dsts_data_t dsts;
dsts.d32 = DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dsts);
return dsts.b.enumspd;
}
uint32_t dwc_otg_get_prtpower(dwc_otg_core_if_t * core_if)
{
hprt0_data_t hprt0;
hprt0.d32 = DWC_READ_REG32(core_if->host_if->hprt0);
return hprt0.b.prtpwr;
}
uint32_t dwc_otg_get_core_state(dwc_otg_core_if_t * core_if)
{
return core_if->hibernation_suspend;
}
void dwc_otg_set_prtpower(dwc_otg_core_if_t * core_if, uint32_t val)
{
hprt0_data_t hprt0;
hprt0.d32 = dwc_otg_read_hprt0(core_if);
hprt0.b.prtpwr = val;
DWC_WRITE_REG32(core_if->host_if->hprt0, hprt0.d32);
}
uint32_t dwc_otg_get_prtsuspend(dwc_otg_core_if_t * core_if)
{
hprt0_data_t hprt0;
hprt0.d32 = DWC_READ_REG32(core_if->host_if->hprt0);
return hprt0.b.prtsusp;
}
void dwc_otg_set_prtsuspend(dwc_otg_core_if_t * core_if, uint32_t val)
{
hprt0_data_t hprt0;
hprt0.d32 = dwc_otg_read_hprt0(core_if);
hprt0.b.prtsusp = val;
DWC_WRITE_REG32(core_if->host_if->hprt0, hprt0.d32);
}
uint32_t dwc_otg_get_fr_interval(dwc_otg_core_if_t * core_if)
{
hfir_data_t hfir;
hfir.d32 = DWC_READ_REG32(&core_if->host_if->host_global_regs->hfir);
return hfir.b.frint;
}
void dwc_otg_set_fr_interval(dwc_otg_core_if_t * core_if, uint32_t val)
{
hfir_data_t hfir;
uint32_t fram_int;
fram_int = calc_frame_interval(core_if);
hfir.d32 = DWC_READ_REG32(&core_if->host_if->host_global_regs->hfir);
if (!core_if->core_params->reload_ctl) {
DWC_WARN("\nCannot reload HFIR register.HFIR.HFIRRldCtrl bit is"
"not set to 1.\nShould load driver with reload_ctl=1"
" module parameter\n");
return;
}
switch (fram_int) {
case 3750:
if ((val < 3350) || (val > 4150)) {
DWC_WARN("HFIR interval for HS core and 30 MHz"
"clock freq should be from 3350 to 4150\n");
return;
}
break;
case 30000:
if ((val < 26820) || (val > 33180)) {
DWC_WARN("HFIR interval for FS/LS core and 30 MHz"
"clock freq should be from 26820 to 33180\n");
return;
}
break;
case 6000:
if ((val < 5360) || (val > 6640)) {
DWC_WARN("HFIR interval for HS core and 48 MHz"
"clock freq should be from 5360 to 6640\n");
return;
}
break;
case 48000:
if ((val < 42912) || (val > 53088)) {
DWC_WARN("HFIR interval for FS/LS core and 48 MHz"
"clock freq should be from 42912 to 53088\n");
return;
}
break;
case 7500:
if ((val < 6700) || (val > 8300)) {
DWC_WARN("HFIR interval for HS core and 60 MHz"
"clock freq should be from 6700 to 8300\n");
return;
}
break;
case 60000:
if ((val < 53640) || (val > 65536)) {
DWC_WARN("HFIR interval for FS/LS core and 60 MHz"
"clock freq should be from 53640 to 65536\n");
return;
}
break;
default:
DWC_WARN("Unknown frame interval\n");
return;
break;
}
hfir.b.frint = val;
DWC_WRITE_REG32(&core_if->host_if->host_global_regs->hfir, hfir.d32);
}
uint32_t dwc_otg_get_mode_ch_tim(dwc_otg_core_if_t * core_if)
{
hcfg_data_t hcfg;
hcfg.d32 = DWC_READ_REG32(&core_if->host_if->host_global_regs->hcfg);
return hcfg.b.modechtimen;
}
void dwc_otg_set_mode_ch_tim(dwc_otg_core_if_t * core_if, uint32_t val)
{
hcfg_data_t hcfg;
hcfg.d32 = DWC_READ_REG32(&core_if->host_if->host_global_regs->hcfg);
hcfg.b.modechtimen = val;
DWC_WRITE_REG32(&core_if->host_if->host_global_regs->hcfg, hcfg.d32);
}
void dwc_otg_set_prtresume(dwc_otg_core_if_t * core_if, uint32_t val)
{
hprt0_data_t hprt0;
hprt0.d32 = dwc_otg_read_hprt0(core_if);
hprt0.b.prtres = val;
DWC_WRITE_REG32(core_if->host_if->hprt0, hprt0.d32);
}
uint32_t dwc_otg_get_remotewakesig(dwc_otg_core_if_t * core_if)
{
dctl_data_t dctl;
dctl.d32 = DWC_READ_REG32(&core_if->dev_if->dev_global_regs->dctl);
return dctl.b.rmtwkupsig;
}
uint32_t dwc_otg_get_lpm_portsleepstatus(dwc_otg_core_if_t * core_if)
{
glpmcfg_data_t lpmcfg;
lpmcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->glpmcfg);
DWC_ASSERT(!
((core_if->lx_state == DWC_OTG_L1) ^ lpmcfg.b.prt_sleep_sts),
"lx_state = %d, lmpcfg.prt_sleep_sts = %d\n",
core_if->lx_state, lpmcfg.b.prt_sleep_sts);
return lpmcfg.b.prt_sleep_sts;
}
uint32_t dwc_otg_get_lpm_remotewakeenabled(dwc_otg_core_if_t * core_if)
{
glpmcfg_data_t lpmcfg;
lpmcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->glpmcfg);
return lpmcfg.b.rem_wkup_en;
}
uint32_t dwc_otg_get_lpmresponse(dwc_otg_core_if_t * core_if)
{
glpmcfg_data_t lpmcfg;
lpmcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->glpmcfg);
return lpmcfg.b.appl_resp;
}
void dwc_otg_set_lpmresponse(dwc_otg_core_if_t * core_if, uint32_t val)
{
glpmcfg_data_t lpmcfg;
lpmcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->glpmcfg);
lpmcfg.b.appl_resp = val;
DWC_WRITE_REG32(&core_if->core_global_regs->glpmcfg, lpmcfg.d32);
}
uint32_t dwc_otg_get_hsic_connect(dwc_otg_core_if_t * core_if)
{
glpmcfg_data_t lpmcfg;
lpmcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->glpmcfg);
return lpmcfg.b.hsic_connect;
}
void dwc_otg_set_hsic_connect(dwc_otg_core_if_t * core_if, uint32_t val)
{
glpmcfg_data_t lpmcfg;
lpmcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->glpmcfg);
lpmcfg.b.hsic_connect = val;
DWC_WRITE_REG32(&core_if->core_global_regs->glpmcfg, lpmcfg.d32);
}
uint32_t dwc_otg_get_inv_sel_hsic(dwc_otg_core_if_t * core_if)
{
glpmcfg_data_t lpmcfg;
lpmcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->glpmcfg);
return lpmcfg.b.inv_sel_hsic;
}
void dwc_otg_set_inv_sel_hsic(dwc_otg_core_if_t * core_if, uint32_t val)
{
glpmcfg_data_t lpmcfg;
lpmcfg.d32 = DWC_READ_REG32(&core_if->core_global_regs->glpmcfg);
lpmcfg.b.inv_sel_hsic = val;
DWC_WRITE_REG32(&core_if->core_global_regs->glpmcfg, lpmcfg.d32);
}
uint32_t dwc_otg_get_gotgctl(dwc_otg_core_if_t * core_if)
{
return DWC_READ_REG32(&core_if->core_global_regs->gotgctl);
}
void dwc_otg_set_gotgctl(dwc_otg_core_if_t * core_if, uint32_t val)
{
DWC_WRITE_REG32(&core_if->core_global_regs->gotgctl, val);
}
uint32_t dwc_otg_get_gusbcfg(dwc_otg_core_if_t * core_if)
{
return DWC_READ_REG32(&core_if->core_global_regs->gusbcfg);
}
void dwc_otg_set_gusbcfg(dwc_otg_core_if_t * core_if, uint32_t val)
{
DWC_WRITE_REG32(&core_if->core_global_regs->gusbcfg, val);
}
uint32_t dwc_otg_get_grxfsiz(dwc_otg_core_if_t * core_if)
{
return DWC_READ_REG32(&core_if->core_global_regs->grxfsiz);
}
void dwc_otg_set_grxfsiz(dwc_otg_core_if_t * core_if, uint32_t val)
{
DWC_WRITE_REG32(&core_if->core_global_regs->grxfsiz, val);
}
uint32_t dwc_otg_get_gnptxfsiz(dwc_otg_core_if_t * core_if)
{
return DWC_READ_REG32(&core_if->core_global_regs->gnptxfsiz);
}
void dwc_otg_set_gnptxfsiz(dwc_otg_core_if_t * core_if, uint32_t val)
{
DWC_WRITE_REG32(&core_if->core_global_regs->gnptxfsiz, val);
}
uint32_t dwc_otg_get_gpvndctl(dwc_otg_core_if_t * core_if)
{
return DWC_READ_REG32(&core_if->core_global_regs->gpvndctl);
}
void dwc_otg_set_gpvndctl(dwc_otg_core_if_t * core_if, uint32_t val)
{
DWC_WRITE_REG32(&core_if->core_global_regs->gpvndctl, val);
}
uint32_t dwc_otg_get_ggpio(dwc_otg_core_if_t * core_if)
{
return DWC_READ_REG32(&core_if->core_global_regs->ggpio);
}
void dwc_otg_set_ggpio(dwc_otg_core_if_t * core_if, uint32_t val)
{
DWC_WRITE_REG32(&core_if->core_global_regs->ggpio, val);
}
uint32_t dwc_otg_get_hprt0(dwc_otg_core_if_t * core_if)
{
return DWC_READ_REG32(core_if->host_if->hprt0);
}
void dwc_otg_set_hprt0(dwc_otg_core_if_t * core_if, uint32_t val)
{
DWC_WRITE_REG32(core_if->host_if->hprt0, val);
}
uint32_t dwc_otg_get_guid(dwc_otg_core_if_t * core_if)
{
return DWC_READ_REG32(&core_if->core_global_regs->guid);
}
void dwc_otg_set_guid(dwc_otg_core_if_t * core_if, uint32_t val)
{
DWC_WRITE_REG32(&core_if->core_global_regs->guid, val);
}
uint32_t dwc_otg_get_hptxfsiz(dwc_otg_core_if_t * core_if)
{
return DWC_READ_REG32(&core_if->core_global_regs->hptxfsiz);
}
uint16_t dwc_otg_get_otg_version(dwc_otg_core_if_t * core_if)
{
return ((core_if->otg_ver == 1) ? (uint16_t)0x0200 : (uint16_t)0x0103);
}
/**
* Start the SRP timer to detect when the SRP does not complete within
* 6 seconds.
*
* @param core_if the pointer to core_if strucure.
*/
void dwc_otg_pcd_start_srp_timer(dwc_otg_core_if_t * core_if)
{
core_if->srp_timer_started = 1;
DWC_TIMER_SCHEDULE(core_if->srp_timer, 6000 /* 6 secs */ );
}
void dwc_otg_initiate_srp(dwc_otg_core_if_t * core_if)
{
uint32_t *addr = (uint32_t *) & (core_if->core_global_regs->gotgctl);
gotgctl_data_t mem;
gotgctl_data_t val;
val.d32 = DWC_READ_REG32(addr);
if (val.b.sesreq) {
DWC_ERROR("Session Request Already active!\n");
return;
}
DWC_INFO("Session Request Initated\n"); //NOTICE
mem.d32 = DWC_READ_REG32(addr);
mem.b.sesreq = 1;
DWC_WRITE_REG32(addr, mem.d32);
/* Start the SRP timer */
dwc_otg_pcd_start_srp_timer(core_if);
return;
}