Merge branch 'for-linus' of git://git.kernel.org/pub/scm/linux/kernel/git/ieee1394...

[pandora-kernel.git] / sound / pci / asihpi / hpi6205.c

/******************************************************************************

    AudioScience HPI driver
    Copyright (C) 1997-2010  AudioScience Inc. <support@audioscience.com>

    This program is free software; you can redistribute it and/or modify
    it under the terms of version 2 of the GNU General Public License as
    published by the Free Software Foundation;

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program; if not, write to the Free Software
    Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA

 Hardware Programming Interface (HPI) for AudioScience
 ASI50xx, AS51xx, ASI6xxx, ASI87xx ASI89xx series adapters.
 These PCI and PCIe bus adapters are based on a
 TMS320C6205 PCI bus mastering DSP,
 and (except ASI50xx) TI TMS320C6xxx floating point DSP

 Exported function:
 void HPI_6205(struct hpi_message *phm, struct hpi_response *phr)

(C) Copyright AudioScience Inc. 1998-2010
*******************************************************************************/
#define SOURCEFILE_NAME "hpi6205.c"

#include "hpi_internal.h"
#include "hpimsginit.h"
#include "hpidebug.h"
#include "hpi6205.h"
#include "hpidspcd.h"
#include "hpicmn.h"

/*****************************************************************************/
/* HPI6205 specific error codes */
#define HPI6205_ERROR_BASE 1000 /* not actually used anywhere */

/* operational/messaging errors */
#define HPI6205_ERROR_MSG_RESP_IDLE_TIMEOUT     1015
#define HPI6205_ERROR_MSG_RESP_TIMEOUT          1016

/* initialization/bootload errors */
#define HPI6205_ERROR_6205_NO_IRQ               1002
#define HPI6205_ERROR_6205_INIT_FAILED          1003
#define HPI6205_ERROR_6205_REG                  1006
#define HPI6205_ERROR_6205_DSPPAGE              1007
#define HPI6205_ERROR_C6713_HPIC                1009
#define HPI6205_ERROR_C6713_HPIA                1010
#define HPI6205_ERROR_C6713_PLL                 1011
#define HPI6205_ERROR_DSP_INTMEM                1012
#define HPI6205_ERROR_DSP_EXTMEM                1013
#define HPI6205_ERROR_DSP_PLD                   1014
#define HPI6205_ERROR_6205_EEPROM               1017
#define HPI6205_ERROR_DSP_EMIF                  1018

/*****************************************************************************/
/* for C6205 PCI i/f */
/* Host Status Register (HSR) bitfields */
#define C6205_HSR_INTSRC        0x01
#define C6205_HSR_INTAVAL       0x02
#define C6205_HSR_INTAM         0x04
#define C6205_HSR_CFGERR        0x08
#define C6205_HSR_EEREAD        0x10
/* Host-to-DSP Control Register (HDCR) bitfields */
#define C6205_HDCR_WARMRESET    0x01
#define C6205_HDCR_DSPINT       0x02
#define C6205_HDCR_PCIBOOT      0x04
/* DSP Page Register (DSPP) bitfields, */
/* defines 4 Mbyte page that BAR0 points to */
#define C6205_DSPP_MAP1         0x400

/* BAR0 maps to prefetchable 4 Mbyte memory block set by DSPP.
 * BAR1 maps to non-prefetchable 8 Mbyte memory block
 * of DSP memory mapped registers (starting at 0x01800000).
 * 0x01800000 is hardcoded in the PCI i/f, so that only the offset from this
 * needs to be added to the BAR1 base address set in the PCI config reg
 */
#define C6205_BAR1_PCI_IO_OFFSET (0x027FFF0L)
#define C6205_BAR1_HSR  (C6205_BAR1_PCI_IO_OFFSET)
#define C6205_BAR1_HDCR (C6205_BAR1_PCI_IO_OFFSET+4)
#define C6205_BAR1_DSPP (C6205_BAR1_PCI_IO_OFFSET+8)

/* used to control LED (revA) and reset C6713 (revB) */
#define C6205_BAR0_TIMER1_CTL (0x01980000L)

/* For first 6713 in CE1 space, using DA17,16,2 */
#define HPICL_ADDR      0x01400000L
#define HPICH_ADDR      0x01400004L
#define HPIAL_ADDR      0x01410000L
#define HPIAH_ADDR      0x01410004L
#define HPIDIL_ADDR     0x01420000L
#define HPIDIH_ADDR     0x01420004L
#define HPIDL_ADDR      0x01430000L
#define HPIDH_ADDR      0x01430004L

#define C6713_EMIF_GCTL         0x01800000
#define C6713_EMIF_CE1          0x01800004
#define C6713_EMIF_CE0          0x01800008
#define C6713_EMIF_CE2          0x01800010
#define C6713_EMIF_CE3          0x01800014
#define C6713_EMIF_SDRAMCTL     0x01800018
#define C6713_EMIF_SDRAMTIMING  0x0180001C
#define C6713_EMIF_SDRAMEXT     0x01800020

struct hpi_hw_obj {
        /* PCI registers */
        __iomem u32 *prHSR;
        __iomem u32 *prHDCR;
        __iomem u32 *prDSPP;

        u32 dsp_page;

        struct consistent_dma_area h_locked_mem;
        struct bus_master_interface *p_interface_buffer;

        u16 flag_outstream_just_reset[HPI_MAX_STREAMS];
        /* a non-NULL handle means there is an HPI allocated buffer */
        struct consistent_dma_area instream_host_buffers[HPI_MAX_STREAMS];
        struct consistent_dma_area outstream_host_buffers[HPI_MAX_STREAMS];
        /* non-zero size means a buffer exists, may be external */
        u32 instream_host_buffer_size[HPI_MAX_STREAMS];
        u32 outstream_host_buffer_size[HPI_MAX_STREAMS];

        struct consistent_dma_area h_control_cache;
        struct hpi_control_cache *p_cache;
};

/*****************************************************************************/
/* local prototypes */

#define check_before_bbm_copy(status, p_bbm_data, l_first_write, l_second_write)

static int wait_dsp_ack(struct hpi_hw_obj *phw, int state, int timeout_us);

static void send_dsp_command(struct hpi_hw_obj *phw, int cmd);

static u16 adapter_boot_load_dsp(struct hpi_adapter_obj *pao,
        u32 *pos_error_code);

static u16 message_response_sequence(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void hw_message(struct hpi_adapter_obj *pao, struct hpi_message *phm,
        struct hpi_response *phr);

#define HPI6205_TIMEOUT 1000000

static void subsys_create_adapter(struct hpi_message *phm,
        struct hpi_response *phr);
static void adapter_delete(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static u16 create_adapter_obj(struct hpi_adapter_obj *pao,
        u32 *pos_error_code);

static void delete_adapter_obj(struct hpi_adapter_obj *pao);

static void outstream_host_buffer_allocate(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void outstream_host_buffer_get_info(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void outstream_host_buffer_free(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);
static void outstream_write(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void outstream_get_info(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void outstream_start(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void outstream_open(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void outstream_reset(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void instream_host_buffer_allocate(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void instream_host_buffer_get_info(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void instream_host_buffer_free(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void instream_read(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void instream_get_info(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static void instream_start(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr);

static u32 boot_loader_read_mem32(struct hpi_adapter_obj *pao, int dsp_index,
        u32 address);

static void boot_loader_write_mem32(struct hpi_adapter_obj *pao,
        int dsp_index, u32 address, u32 data);

static u16 boot_loader_config_emif(struct hpi_adapter_obj *pao,
        int dsp_index);

static u16 boot_loader_test_memory(struct hpi_adapter_obj *pao, int dsp_index,
        u32 address, u32 length);

static u16 boot_loader_test_internal_memory(struct hpi_adapter_obj *pao,
        int dsp_index);

static u16 boot_loader_test_external_memory(struct hpi_adapter_obj *pao,
        int dsp_index);

static u16 boot_loader_test_pld(struct hpi_adapter_obj *pao, int dsp_index);

/*****************************************************************************/

static void subsys_message(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        switch (phm->function) {
        case HPI_SUBSYS_CREATE_ADAPTER:
                subsys_create_adapter(phm, phr);
                break;
        default:
                phr->error = HPI_ERROR_INVALID_FUNC;
                break;
        }
}

static void control_message(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{

        struct hpi_hw_obj *phw = pao->priv;
        u16 pending_cache_error = 0;

        switch (phm->function) {
        case HPI_CONTROL_GET_STATE:
                if (pao->has_control_cache) {
                        rmb();  /* make sure we see updates DMAed from DSP */
                        if (hpi_check_control_cache(phw->p_cache, phm, phr)) {
                                break;
                        } else if (phm->u.c.attribute == HPI_METER_PEAK) {
                                pending_cache_error =
                                        HPI_ERROR_CONTROL_CACHING;
                        }
                }
                hw_message(pao, phm, phr);
                if (pending_cache_error && !phr->error)
                        phr->error = pending_cache_error;
                break;
        case HPI_CONTROL_GET_INFO:
                hw_message(pao, phm, phr);
                break;
        case HPI_CONTROL_SET_STATE:
                hw_message(pao, phm, phr);
                if (pao->has_control_cache)
                        hpi_cmn_control_cache_sync_to_msg(phw->p_cache, phm,
                                phr);
                break;
        default:
                phr->error = HPI_ERROR_INVALID_FUNC;
                break;
        }
}

static void adapter_message(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        switch (phm->function) {
        case HPI_ADAPTER_DELETE:
                adapter_delete(pao, phm, phr);
                break;

        default:
                hw_message(pao, phm, phr);
                break;
        }
}

static void outstream_message(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{

        if (phm->obj_index >= HPI_MAX_STREAMS) {
                phr->error = HPI_ERROR_INVALID_OBJ_INDEX;
                HPI_DEBUG_LOG(WARNING,
                        "Message referencing invalid stream %d "
                        "on adapter index %d\n", phm->obj_index,
                        phm->adapter_index);
                return;
        }

        switch (phm->function) {
        case HPI_OSTREAM_WRITE:
                outstream_write(pao, phm, phr);
                break;
        case HPI_OSTREAM_GET_INFO:
                outstream_get_info(pao, phm, phr);
                break;
        case HPI_OSTREAM_HOSTBUFFER_ALLOC:
                outstream_host_buffer_allocate(pao, phm, phr);
                break;
        case HPI_OSTREAM_HOSTBUFFER_GET_INFO:
                outstream_host_buffer_get_info(pao, phm, phr);
                break;
        case HPI_OSTREAM_HOSTBUFFER_FREE:
                outstream_host_buffer_free(pao, phm, phr);
                break;
        case HPI_OSTREAM_START:
                outstream_start(pao, phm, phr);
                break;
        case HPI_OSTREAM_OPEN:
                outstream_open(pao, phm, phr);
                break;
        case HPI_OSTREAM_RESET:
                outstream_reset(pao, phm, phr);
                break;
        default:
                hw_message(pao, phm, phr);
                break;
        }
}

static void instream_message(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{

        if (phm->obj_index >= HPI_MAX_STREAMS) {
                phr->error = HPI_ERROR_INVALID_OBJ_INDEX;
                HPI_DEBUG_LOG(WARNING,
                        "Message referencing invalid stream %d "
                        "on adapter index %d\n", phm->obj_index,
                        phm->adapter_index);
                return;
        }

        switch (phm->function) {
        case HPI_ISTREAM_READ:
                instream_read(pao, phm, phr);
                break;
        case HPI_ISTREAM_GET_INFO:
                instream_get_info(pao, phm, phr);
                break;
        case HPI_ISTREAM_HOSTBUFFER_ALLOC:
                instream_host_buffer_allocate(pao, phm, phr);
                break;
        case HPI_ISTREAM_HOSTBUFFER_GET_INFO:
                instream_host_buffer_get_info(pao, phm, phr);
                break;
        case HPI_ISTREAM_HOSTBUFFER_FREE:
                instream_host_buffer_free(pao, phm, phr);
                break;
        case HPI_ISTREAM_START:
                instream_start(pao, phm, phr);
                break;
        default:
                hw_message(pao, phm, phr);
                break;
        }
}

/*****************************************************************************/
/** Entry point to this HPI backend
 * All calls to the HPI start here
 */
void _HPI_6205(struct hpi_adapter_obj *pao, struct hpi_message *phm,
        struct hpi_response *phr)
{
        if (pao && (pao->dsp_crashed >= 10)
                && (phm->function != HPI_ADAPTER_DEBUG_READ)) {
                /* allow last resort debug read even after crash */
                hpi_init_response(phr, phm->object, phm->function,
                        HPI_ERROR_DSP_HARDWARE);
                HPI_DEBUG_LOG(WARNING, " %d,%d dsp crashed.\n", phm->object,
                        phm->function);
                return;
        }

        /* Init default response  */
        if (phm->function != HPI_SUBSYS_CREATE_ADAPTER)
                phr->error = HPI_ERROR_PROCESSING_MESSAGE;

        HPI_DEBUG_LOG(VERBOSE, "start of switch\n");
        switch (phm->type) {
        case HPI_TYPE_MESSAGE:
                switch (phm->object) {
                case HPI_OBJ_SUBSYSTEM:
                        subsys_message(pao, phm, phr);
                        break;

                case HPI_OBJ_ADAPTER:
                        adapter_message(pao, phm, phr);
                        break;

                case HPI_OBJ_CONTROLEX:
                case HPI_OBJ_CONTROL:
                        control_message(pao, phm, phr);
                        break;

                case HPI_OBJ_OSTREAM:
                        outstream_message(pao, phm, phr);
                        break;

                case HPI_OBJ_ISTREAM:
                        instream_message(pao, phm, phr);
                        break;

                default:
                        hw_message(pao, phm, phr);
                        break;
                }
                break;

        default:
                phr->error = HPI_ERROR_INVALID_TYPE;
                break;
        }
}

void HPI_6205(struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_adapter_obj *pao = NULL;

        if (phm->object != HPI_OBJ_SUBSYSTEM) {
                /* normal messages must have valid adapter index */
                pao = hpi_find_adapter(phm->adapter_index);
        } else {
                /* subsys messages don't address an adapter */
                _HPI_6205(NULL, phm, phr);
                return;
        }

        if (pao)
                _HPI_6205(pao, phm, phr);
        else
                hpi_init_response(phr, phm->object, phm->function,
                        HPI_ERROR_BAD_ADAPTER_NUMBER);
}

/*****************************************************************************/
/* SUBSYSTEM */

/** Create an adapter object and initialise it based on resource information
 * passed in in the message
 * *** NOTE - you cannot use this function AND the FindAdapters function at the
 * same time, the application must use only one of them to get the adapters ***
 */
static void subsys_create_adapter(struct hpi_message *phm,
        struct hpi_response *phr)
{
        /* create temp adapter obj, because we don't know what index yet */
        struct hpi_adapter_obj ao;
        u32 os_error_code;
        u16 err;

        HPI_DEBUG_LOG(DEBUG, " subsys_create_adapter\n");

        memset(&ao, 0, sizeof(ao));

        ao.priv = kzalloc(sizeof(struct hpi_hw_obj), GFP_KERNEL);
        if (!ao.priv) {
                HPI_DEBUG_LOG(ERROR, "can't get mem for adapter object\n");
                phr->error = HPI_ERROR_MEMORY_ALLOC;
                return;
        }

        ao.pci = *phm->u.s.resource.r.pci;
        err = create_adapter_obj(&ao, &os_error_code);
        if (err) {
                delete_adapter_obj(&ao);
                if (err >= HPI_ERROR_BACKEND_BASE) {
                        phr->error = HPI_ERROR_DSP_BOOTLOAD;
                        phr->specific_error = err;
                } else {
                        phr->error = err;
                }
                phr->u.s.data = os_error_code;
                return;
        }

        phr->u.s.adapter_type = ao.adapter_type;
        phr->u.s.adapter_index = ao.index;
        phr->error = 0;
}

/** delete an adapter - required by WDM driver */
static void adapter_delete(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw;

        if (!pao) {
                phr->error = HPI_ERROR_INVALID_OBJ_INDEX;
                return;
        }
        phw = (struct hpi_hw_obj *)pao->priv;
        /* reset adapter h/w */
        /* Reset C6713 #1 */
        boot_loader_write_mem32(pao, 0, C6205_BAR0_TIMER1_CTL, 0);
        /* reset C6205 */
        iowrite32(C6205_HDCR_WARMRESET, phw->prHDCR);

        delete_adapter_obj(pao);
        hpi_delete_adapter(pao);
        phr->error = 0;
}

/** Create adapter object
  allocate buffers, bootload DSPs, initialise control cache
*/
static u16 create_adapter_obj(struct hpi_adapter_obj *pao,
        u32 *pos_error_code)
{
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface;
        u32 phys_addr;
        int i;
        u16 err;

        /* init error reporting */
        pao->dsp_crashed = 0;

        for (i = 0; i < HPI_MAX_STREAMS; i++)
                phw->flag_outstream_just_reset[i] = 1;

        /* The C6205 memory area 1 is 8Mbyte window into DSP registers */
        phw->prHSR =
                pao->pci.ap_mem_base[1] +
                C6205_BAR1_HSR / sizeof(*pao->pci.ap_mem_base[1]);
        phw->prHDCR =
                pao->pci.ap_mem_base[1] +
                C6205_BAR1_HDCR / sizeof(*pao->pci.ap_mem_base[1]);
        phw->prDSPP =
                pao->pci.ap_mem_base[1] +
                C6205_BAR1_DSPP / sizeof(*pao->pci.ap_mem_base[1]);

        pao->has_control_cache = 0;

        if (hpios_locked_mem_alloc(&phw->h_locked_mem,
                        sizeof(struct bus_master_interface),
                        pao->pci.pci_dev))
                phw->p_interface_buffer = NULL;
        else if (hpios_locked_mem_get_virt_addr(&phw->h_locked_mem,
                        (void *)&phw->p_interface_buffer))
                phw->p_interface_buffer = NULL;

        HPI_DEBUG_LOG(DEBUG, "interface buffer address %p\n",
                phw->p_interface_buffer);

        if (phw->p_interface_buffer) {
                memset((void *)phw->p_interface_buffer, 0,
                        sizeof(struct bus_master_interface));
                phw->p_interface_buffer->dsp_ack = H620_HIF_UNKNOWN;
        }

        err = adapter_boot_load_dsp(pao, pos_error_code);
        if (err) {
                HPI_DEBUG_LOG(ERROR, "DSP code load failed\n");
                /* no need to clean up as SubSysCreateAdapter */
                /* calls DeleteAdapter on error. */
                return err;
        }
        HPI_DEBUG_LOG(INFO, "load DSP code OK\n");

        /* allow boot load even if mem alloc wont work */
        if (!phw->p_interface_buffer)
                return HPI_ERROR_MEMORY_ALLOC;

        interface = phw->p_interface_buffer;

        /* make sure the DSP has started ok */
        if (!wait_dsp_ack(phw, H620_HIF_RESET, HPI6205_TIMEOUT * 10)) {
                HPI_DEBUG_LOG(ERROR, "timed out waiting reset state \n");
                return HPI6205_ERROR_6205_INIT_FAILED;
        }
        /* Note that *pao, *phw are zeroed after allocation,
         * so pointers and flags are NULL by default.
         * Allocate bus mastering control cache buffer and tell the DSP about it
         */
        if (interface->control_cache.number_of_controls) {
                u8 *p_control_cache_virtual;

                err = hpios_locked_mem_alloc(&phw->h_control_cache,
                        interface->control_cache.size_in_bytes,
                        pao->pci.pci_dev);
                if (!err)
                        err = hpios_locked_mem_get_virt_addr(&phw->
                                h_control_cache,
                                (void *)&p_control_cache_virtual);
                if (!err) {
                        memset(p_control_cache_virtual, 0,
                                interface->control_cache.size_in_bytes);

                        phw->p_cache =
                                hpi_alloc_control_cache(interface->
                                control_cache.number_of_controls,
                                interface->control_cache.size_in_bytes,
                                p_control_cache_virtual);

                        if (!phw->p_cache)
                                err = HPI_ERROR_MEMORY_ALLOC;
                }
                if (!err) {
                        err = hpios_locked_mem_get_phys_addr(&phw->
                                h_control_cache, &phys_addr);
                        interface->control_cache.physical_address32 =
                                phys_addr;
                }

                if (!err)
                        pao->has_control_cache = 1;
                else {
                        if (hpios_locked_mem_valid(&phw->h_control_cache))
                                hpios_locked_mem_free(&phw->h_control_cache);
                        pao->has_control_cache = 0;
                }
        }
        send_dsp_command(phw, H620_HIF_IDLE);

        {
                struct hpi_message hm;
                struct hpi_response hr;
                u32 max_streams;

                HPI_DEBUG_LOG(VERBOSE, "init ADAPTER_GET_INFO\n");
                memset(&hm, 0, sizeof(hm));
                hm.type = HPI_TYPE_MESSAGE;
                hm.size = sizeof(hm);
                hm.object = HPI_OBJ_ADAPTER;
                hm.function = HPI_ADAPTER_GET_INFO;
                hm.adapter_index = 0;
                memset(&hr, 0, sizeof(hr));
                hr.size = sizeof(hr);

                err = message_response_sequence(pao, &hm, &hr);
                if (err) {
                        HPI_DEBUG_LOG(ERROR, "message transport error %d\n",
                                err);
                        return err;
                }
                if (hr.error)
                        return hr.error;

                pao->adapter_type = hr.u.ax.info.adapter_type;
                pao->index = hr.u.ax.info.adapter_index;

                max_streams =
                        hr.u.ax.info.num_outstreams +
                        hr.u.ax.info.num_instreams;

                hpios_locked_mem_prepare((max_streams * 6) / 10, max_streams,
                        65536, pao->pci.pci_dev);

                HPI_DEBUG_LOG(VERBOSE,
                        "got adapter info type %x index %d serial %d\n",
                        hr.u.ax.info.adapter_type, hr.u.ax.info.adapter_index,
                        hr.u.ax.info.serial_number);
        }

        pao->open = 0;  /* upon creation the adapter is closed */

        if (phw->p_cache)
                phw->p_cache->adap_idx = pao->index;

        HPI_DEBUG_LOG(INFO, "bootload DSP OK\n");

        return hpi_add_adapter(pao);
}

/** Free memory areas allocated by adapter
 * this routine is called from AdapterDelete,
  * and SubSysCreateAdapter if duplicate index
*/
static void delete_adapter_obj(struct hpi_adapter_obj *pao)
{
        struct hpi_hw_obj *phw = pao->priv;
        int i;

        if (hpios_locked_mem_valid(&phw->h_control_cache)) {
                hpios_locked_mem_free(&phw->h_control_cache);
                hpi_free_control_cache(phw->p_cache);
        }

        if (hpios_locked_mem_valid(&phw->h_locked_mem)) {
                hpios_locked_mem_free(&phw->h_locked_mem);
                phw->p_interface_buffer = NULL;
        }

        for (i = 0; i < HPI_MAX_STREAMS; i++)
                if (hpios_locked_mem_valid(&phw->instream_host_buffers[i])) {
                        hpios_locked_mem_free(&phw->instream_host_buffers[i]);
                        /*?phw->InStreamHostBuffers[i] = NULL; */
                        phw->instream_host_buffer_size[i] = 0;
                }

        for (i = 0; i < HPI_MAX_STREAMS; i++)
                if (hpios_locked_mem_valid(&phw->outstream_host_buffers[i])) {
                        hpios_locked_mem_free(&phw->outstream_host_buffers
                                [i]);
                        phw->outstream_host_buffer_size[i] = 0;
                }

        hpios_locked_mem_unprepare(pao->pci.pci_dev);

        kfree(phw);
}

/*****************************************************************************/
/* Adapter functions */

/*****************************************************************************/
/* OutStream Host buffer functions */

/** Allocate or attach buffer for busmastering
*/
static void outstream_host_buffer_allocate(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        u16 err = 0;
        u32 command = phm->u.d.u.buffer.command;
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface = phw->p_interface_buffer;

        hpi_init_response(phr, phm->object, phm->function, 0);

        if (command == HPI_BUFFER_CMD_EXTERNAL
                || command == HPI_BUFFER_CMD_INTERNAL_ALLOC) {
                /* ALLOC phase, allocate a buffer with power of 2 size,
                   get its bus address for PCI bus mastering
                 */
                phm->u.d.u.buffer.buffer_size =
                        roundup_pow_of_two(phm->u.d.u.buffer.buffer_size);
                /* return old size and allocated size,
                   so caller can detect change */
                phr->u.d.u.stream_info.data_available =
                        phw->outstream_host_buffer_size[phm->obj_index];
                phr->u.d.u.stream_info.buffer_size =
                        phm->u.d.u.buffer.buffer_size;

                if (phw->outstream_host_buffer_size[phm->obj_index] ==
                        phm->u.d.u.buffer.buffer_size) {
                        /* Same size, no action required */
                        return;
                }

                if (hpios_locked_mem_valid(&phw->outstream_host_buffers[phm->
                                        obj_index]))
                        hpios_locked_mem_free(&phw->outstream_host_buffers
                                [phm->obj_index]);

                err = hpios_locked_mem_alloc(&phw->outstream_host_buffers
                        [phm->obj_index], phm->u.d.u.buffer.buffer_size,
                        pao->pci.pci_dev);

                if (err) {
                        phr->error = HPI_ERROR_INVALID_DATASIZE;
                        phw->outstream_host_buffer_size[phm->obj_index] = 0;
                        return;
                }

                err = hpios_locked_mem_get_phys_addr
                        (&phw->outstream_host_buffers[phm->obj_index],
                        &phm->u.d.u.buffer.pci_address);
                /* get the phys addr into msg for single call alloc caller
                 * needs to do this for split alloc (or use the same message)
                 * return the phy address for split alloc in the respose too
                 */
                phr->u.d.u.stream_info.auxiliary_data_available =
                        phm->u.d.u.buffer.pci_address;

                if (err) {
                        hpios_locked_mem_free(&phw->outstream_host_buffers
                                [phm->obj_index]);
                        phw->outstream_host_buffer_size[phm->obj_index] = 0;
                        phr->error = HPI_ERROR_MEMORY_ALLOC;
                        return;
                }
        }

        if (command == HPI_BUFFER_CMD_EXTERNAL
                || command == HPI_BUFFER_CMD_INTERNAL_GRANTADAPTER) {
                /* GRANT phase.  Set up the BBM status, tell the DSP about
                   the buffer so it can start using BBM.
                 */
                struct hpi_hostbuffer_status *status;

                if (phm->u.d.u.buffer.buffer_size & (phm->u.d.u.buffer.
                                buffer_size - 1)) {
                        HPI_DEBUG_LOG(ERROR,
                                "Buffer size must be 2^N not %d\n",
                                phm->u.d.u.buffer.buffer_size);
                        phr->error = HPI_ERROR_INVALID_DATASIZE;
                        return;
                }
                phw->outstream_host_buffer_size[phm->obj_index] =
                        phm->u.d.u.buffer.buffer_size;
                status = &interface->outstream_host_buffer_status[phm->
                        obj_index];
                status->samples_processed = 0;
                status->stream_state = HPI_STATE_STOPPED;
                status->dSP_index = 0;
                status->host_index = status->dSP_index;
                status->size_in_bytes = phm->u.d.u.buffer.buffer_size;
                status->auxiliary_data_available = 0;

                hw_message(pao, phm, phr);

                if (phr->error
                        && hpios_locked_mem_valid(&phw->
                                outstream_host_buffers[phm->obj_index])) {
                        hpios_locked_mem_free(&phw->outstream_host_buffers
                                [phm->obj_index]);
                        phw->outstream_host_buffer_size[phm->obj_index] = 0;
                }
        }
}

static void outstream_host_buffer_get_info(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface = phw->p_interface_buffer;
        struct hpi_hostbuffer_status *status;
        u8 *p_bbm_data;

        if (hpios_locked_mem_valid(&phw->outstream_host_buffers[phm->
                                obj_index])) {
                if (hpios_locked_mem_get_virt_addr(&phw->
                                outstream_host_buffers[phm->obj_index],
                                (void *)&p_bbm_data)) {
                        phr->error = HPI_ERROR_INVALID_OPERATION;
                        return;
                }
                status = &interface->outstream_host_buffer_status[phm->
                        obj_index];
                hpi_init_response(phr, HPI_OBJ_OSTREAM,
                        HPI_OSTREAM_HOSTBUFFER_GET_INFO, 0);
                phr->u.d.u.hostbuffer_info.p_buffer = p_bbm_data;
                phr->u.d.u.hostbuffer_info.p_status = status;
        } else {
                hpi_init_response(phr, HPI_OBJ_OSTREAM,
                        HPI_OSTREAM_HOSTBUFFER_GET_INFO,
                        HPI_ERROR_INVALID_OPERATION);
        }
}

static void outstream_host_buffer_free(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw = pao->priv;
        u32 command = phm->u.d.u.buffer.command;

        if (phw->outstream_host_buffer_size[phm->obj_index]) {
                if (command == HPI_BUFFER_CMD_EXTERNAL
                        || command == HPI_BUFFER_CMD_INTERNAL_REVOKEADAPTER) {
                        phw->outstream_host_buffer_size[phm->obj_index] = 0;
                        hw_message(pao, phm, phr);
                        /* Tell adapter to stop using the host buffer. */
                }
                if (command == HPI_BUFFER_CMD_EXTERNAL
                        || command == HPI_BUFFER_CMD_INTERNAL_FREE)
                        hpios_locked_mem_free(&phw->outstream_host_buffers
                                [phm->obj_index]);
        }
        /* Should HPI_ERROR_INVALID_OPERATION be returned
           if no host buffer is allocated? */
        else
                hpi_init_response(phr, HPI_OBJ_OSTREAM,
                        HPI_OSTREAM_HOSTBUFFER_FREE, 0);

}

static u32 outstream_get_space_available(struct hpi_hostbuffer_status *status)
{
        return status->size_in_bytes - (status->host_index -
                status->dSP_index);
}

static void outstream_write(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface = phw->p_interface_buffer;
        struct hpi_hostbuffer_status *status;
        u32 space_available;

        if (!phw->outstream_host_buffer_size[phm->obj_index]) {
                /* there  is no BBM buffer, write via message */
                hw_message(pao, phm, phr);
                return;
        }

        hpi_init_response(phr, phm->object, phm->function, 0);
        status = &interface->outstream_host_buffer_status[phm->obj_index];

        space_available = outstream_get_space_available(status);
        if (space_available < phm->u.d.u.data.data_size) {
                phr->error = HPI_ERROR_INVALID_DATASIZE;
                return;
        }

        /* HostBuffers is used to indicate host buffer is internally allocated.
           otherwise, assumed external, data written externally */
        if (phm->u.d.u.data.pb_data
                && hpios_locked_mem_valid(&phw->outstream_host_buffers[phm->
                                obj_index])) {
                u8 *p_bbm_data;
                u32 l_first_write;
                u8 *p_app_data = (u8 *)phm->u.d.u.data.pb_data;

                if (hpios_locked_mem_get_virt_addr(&phw->
                                outstream_host_buffers[phm->obj_index],
                                (void *)&p_bbm_data)) {
                        phr->error = HPI_ERROR_INVALID_OPERATION;
                        return;
                }

                /* either all data,
                   or enough to fit from current to end of BBM buffer */
                l_first_write =
                        min(phm->u.d.u.data.data_size,
                        status->size_in_bytes -
                        (status->host_index & (status->size_in_bytes - 1)));

                memcpy(p_bbm_data +
                        (status->host_index & (status->size_in_bytes - 1)),
                        p_app_data, l_first_write);
                /* remaining data if any */
                memcpy(p_bbm_data, p_app_data + l_first_write,
                        phm->u.d.u.data.data_size - l_first_write);
        }

        /*
         * This version relies on the DSP code triggering an OStream buffer
         * update immediately following a SET_FORMAT call. The host has
         * already written data into the BBM buffer, but the DSP won't know
         * about it until dwHostIndex is adjusted.
         */
        if (phw->flag_outstream_just_reset[phm->obj_index]) {
                /* Format can only change after reset. Must tell DSP. */
                u16 function = phm->function;
                phw->flag_outstream_just_reset[phm->obj_index] = 0;
                phm->function = HPI_OSTREAM_SET_FORMAT;
                hw_message(pao, phm, phr);      /* send the format to the DSP */
                phm->function = function;
                if (phr->error)
                        return;
        }

        status->host_index += phm->u.d.u.data.data_size;
}

static void outstream_get_info(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface = phw->p_interface_buffer;
        struct hpi_hostbuffer_status *status;

        if (!phw->outstream_host_buffer_size[phm->obj_index]) {
                hw_message(pao, phm, phr);
                return;
        }

        hpi_init_response(phr, phm->object, phm->function, 0);

        status = &interface->outstream_host_buffer_status[phm->obj_index];

        phr->u.d.u.stream_info.state = (u16)status->stream_state;
        phr->u.d.u.stream_info.samples_transferred =
                status->samples_processed;
        phr->u.d.u.stream_info.buffer_size = status->size_in_bytes;
        phr->u.d.u.stream_info.data_available =
                status->size_in_bytes - outstream_get_space_available(status);
        phr->u.d.u.stream_info.auxiliary_data_available =
                status->auxiliary_data_available;
}

static void outstream_start(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        hw_message(pao, phm, phr);
}

static void outstream_reset(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw = pao->priv;
        phw->flag_outstream_just_reset[phm->obj_index] = 1;
        hw_message(pao, phm, phr);
}

static void outstream_open(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        outstream_reset(pao, phm, phr);
}

/*****************************************************************************/
/* InStream Host buffer functions */

static void instream_host_buffer_allocate(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        u16 err = 0;
        u32 command = phm->u.d.u.buffer.command;
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface = phw->p_interface_buffer;

        hpi_init_response(phr, phm->object, phm->function, 0);

        if (command == HPI_BUFFER_CMD_EXTERNAL
                || command == HPI_BUFFER_CMD_INTERNAL_ALLOC) {

                phm->u.d.u.buffer.buffer_size =
                        roundup_pow_of_two(phm->u.d.u.buffer.buffer_size);
                phr->u.d.u.stream_info.data_available =
                        phw->instream_host_buffer_size[phm->obj_index];
                phr->u.d.u.stream_info.buffer_size =
                        phm->u.d.u.buffer.buffer_size;

                if (phw->instream_host_buffer_size[phm->obj_index] ==
                        phm->u.d.u.buffer.buffer_size) {
                        /* Same size, no action required */
                        return;
                }

                if (hpios_locked_mem_valid(&phw->instream_host_buffers[phm->
                                        obj_index]))
                        hpios_locked_mem_free(&phw->instream_host_buffers
                                [phm->obj_index]);

                err = hpios_locked_mem_alloc(&phw->instream_host_buffers[phm->
                                obj_index], phm->u.d.u.buffer.buffer_size,
                        pao->pci.pci_dev);

                if (err) {
                        phr->error = HPI_ERROR_INVALID_DATASIZE;
                        phw->instream_host_buffer_size[phm->obj_index] = 0;
                        return;
                }

                err = hpios_locked_mem_get_phys_addr
                        (&phw->instream_host_buffers[phm->obj_index],
                        &phm->u.d.u.buffer.pci_address);
                /* get the phys addr into msg for single call alloc. Caller
                   needs to do this for split alloc so return the phy address */
                phr->u.d.u.stream_info.auxiliary_data_available =
                        phm->u.d.u.buffer.pci_address;
                if (err) {
                        hpios_locked_mem_free(&phw->instream_host_buffers
                                [phm->obj_index]);
                        phw->instream_host_buffer_size[phm->obj_index] = 0;
                        phr->error = HPI_ERROR_MEMORY_ALLOC;
                        return;
                }
        }

        if (command == HPI_BUFFER_CMD_EXTERNAL
                || command == HPI_BUFFER_CMD_INTERNAL_GRANTADAPTER) {
                struct hpi_hostbuffer_status *status;

                if (phm->u.d.u.buffer.buffer_size & (phm->u.d.u.buffer.
                                buffer_size - 1)) {
                        HPI_DEBUG_LOG(ERROR,
                                "Buffer size must be 2^N not %d\n",
                                phm->u.d.u.buffer.buffer_size);
                        phr->error = HPI_ERROR_INVALID_DATASIZE;
                        return;
                }

                phw->instream_host_buffer_size[phm->obj_index] =
                        phm->u.d.u.buffer.buffer_size;
                status = &interface->instream_host_buffer_status[phm->
                        obj_index];
                status->samples_processed = 0;
                status->stream_state = HPI_STATE_STOPPED;
                status->dSP_index = 0;
                status->host_index = status->dSP_index;
                status->size_in_bytes = phm->u.d.u.buffer.buffer_size;
                status->auxiliary_data_available = 0;

                hw_message(pao, phm, phr);

                if (phr->error
                        && hpios_locked_mem_valid(&phw->
                                instream_host_buffers[phm->obj_index])) {
                        hpios_locked_mem_free(&phw->instream_host_buffers
                                [phm->obj_index]);
                        phw->instream_host_buffer_size[phm->obj_index] = 0;
                }
        }
}

static void instream_host_buffer_get_info(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface = phw->p_interface_buffer;
        struct hpi_hostbuffer_status *status;
        u8 *p_bbm_data;

        if (hpios_locked_mem_valid(&phw->instream_host_buffers[phm->
                                obj_index])) {
                if (hpios_locked_mem_get_virt_addr(&phw->
                                instream_host_buffers[phm->obj_index],
                                (void *)&p_bbm_data)) {
                        phr->error = HPI_ERROR_INVALID_OPERATION;
                        return;
                }
                status = &interface->instream_host_buffer_status[phm->
                        obj_index];
                hpi_init_response(phr, HPI_OBJ_ISTREAM,
                        HPI_ISTREAM_HOSTBUFFER_GET_INFO, 0);
                phr->u.d.u.hostbuffer_info.p_buffer = p_bbm_data;
                phr->u.d.u.hostbuffer_info.p_status = status;
        } else {
                hpi_init_response(phr, HPI_OBJ_ISTREAM,
                        HPI_ISTREAM_HOSTBUFFER_GET_INFO,
                        HPI_ERROR_INVALID_OPERATION);
        }
}

static void instream_host_buffer_free(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw = pao->priv;
        u32 command = phm->u.d.u.buffer.command;

        if (phw->instream_host_buffer_size[phm->obj_index]) {
                if (command == HPI_BUFFER_CMD_EXTERNAL
                        || command == HPI_BUFFER_CMD_INTERNAL_REVOKEADAPTER) {
                        phw->instream_host_buffer_size[phm->obj_index] = 0;
                        hw_message(pao, phm, phr);
                }

                if (command == HPI_BUFFER_CMD_EXTERNAL
                        || command == HPI_BUFFER_CMD_INTERNAL_FREE)
                        hpios_locked_mem_free(&phw->instream_host_buffers
                                [phm->obj_index]);

        } else {
                /* Should HPI_ERROR_INVALID_OPERATION be returned
                   if no host buffer is allocated? */
                hpi_init_response(phr, HPI_OBJ_ISTREAM,
                        HPI_ISTREAM_HOSTBUFFER_FREE, 0);

        }

}

static void instream_start(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        hw_message(pao, phm, phr);
}

static u32 instream_get_bytes_available(struct hpi_hostbuffer_status *status)
{
        return status->dSP_index - status->host_index;
}

static void instream_read(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface = phw->p_interface_buffer;
        struct hpi_hostbuffer_status *status;
        u32 data_available;
        u8 *p_bbm_data;
        u32 l_first_read;
        u8 *p_app_data = (u8 *)phm->u.d.u.data.pb_data;

        if (!phw->instream_host_buffer_size[phm->obj_index]) {
                hw_message(pao, phm, phr);
                return;
        }
        hpi_init_response(phr, phm->object, phm->function, 0);

        status = &interface->instream_host_buffer_status[phm->obj_index];
        data_available = instream_get_bytes_available(status);
        if (data_available < phm->u.d.u.data.data_size) {
                phr->error = HPI_ERROR_INVALID_DATASIZE;
                return;
        }

        if (hpios_locked_mem_valid(&phw->instream_host_buffers[phm->
                                obj_index])) {
                if (hpios_locked_mem_get_virt_addr(&phw->
                                instream_host_buffers[phm->obj_index],
                                (void *)&p_bbm_data)) {
                        phr->error = HPI_ERROR_INVALID_OPERATION;
                        return;
                }

                /* either all data,
                   or enough to fit from current to end of BBM buffer */
                l_first_read =
                        min(phm->u.d.u.data.data_size,
                        status->size_in_bytes -
                        (status->host_index & (status->size_in_bytes - 1)));

                memcpy(p_app_data,
                        p_bbm_data +
                        (status->host_index & (status->size_in_bytes - 1)),
                        l_first_read);
                /* remaining data if any */
                memcpy(p_app_data + l_first_read, p_bbm_data,
                        phm->u.d.u.data.data_size - l_first_read);
        }
        status->host_index += phm->u.d.u.data.data_size;
}

static void instream_get_info(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface = phw->p_interface_buffer;
        struct hpi_hostbuffer_status *status;
        if (!phw->instream_host_buffer_size[phm->obj_index]) {
                hw_message(pao, phm, phr);
                return;
        }

        status = &interface->instream_host_buffer_status[phm->obj_index];

        hpi_init_response(phr, phm->object, phm->function, 0);

        phr->u.d.u.stream_info.state = (u16)status->stream_state;
        phr->u.d.u.stream_info.samples_transferred =
                status->samples_processed;
        phr->u.d.u.stream_info.buffer_size = status->size_in_bytes;
        phr->u.d.u.stream_info.data_available =
                instream_get_bytes_available(status);
        phr->u.d.u.stream_info.auxiliary_data_available =
                status->auxiliary_data_available;
}

/*****************************************************************************/
/* LOW-LEVEL */
#define HPI6205_MAX_FILES_TO_LOAD 2

static u16 adapter_boot_load_dsp(struct hpi_adapter_obj *pao,
        u32 *pos_error_code)
{
        struct hpi_hw_obj *phw = pao->priv;
        struct dsp_code dsp_code;
        u16 boot_code_id[HPI6205_MAX_FILES_TO_LOAD];
        u32 temp;
        int dsp = 0, i = 0;
        u16 err = 0;

        boot_code_id[0] = HPI_ADAPTER_ASI(0x6205);

        boot_code_id[1] = pao->pci.pci_dev->subsystem_device;
        boot_code_id[1] = HPI_ADAPTER_FAMILY_ASI(boot_code_id[1]);

        /* fix up cases where bootcode id[1] != subsys id */
        switch (boot_code_id[1]) {
        case HPI_ADAPTER_FAMILY_ASI(0x5000):
                boot_code_id[0] = boot_code_id[1];
                boot_code_id[1] = 0;
                break;
        case HPI_ADAPTER_FAMILY_ASI(0x5300):
        case HPI_ADAPTER_FAMILY_ASI(0x5400):
        case HPI_ADAPTER_FAMILY_ASI(0x6300):
                boot_code_id[1] = HPI_ADAPTER_FAMILY_ASI(0x6400);
                break;
        case HPI_ADAPTER_FAMILY_ASI(0x5500):
        case HPI_ADAPTER_FAMILY_ASI(0x5600):
        case HPI_ADAPTER_FAMILY_ASI(0x6500):
                boot_code_id[1] = HPI_ADAPTER_FAMILY_ASI(0x6600);
                break;
        case HPI_ADAPTER_FAMILY_ASI(0x8800):
                boot_code_id[1] = HPI_ADAPTER_FAMILY_ASI(0x8900);
                break;
        default:
                break;
        }

        /* reset DSP by writing a 1 to the WARMRESET bit */
        temp = C6205_HDCR_WARMRESET;
        iowrite32(temp, phw->prHDCR);
        hpios_delay_micro_seconds(1000);

        /* check that PCI i/f was configured by EEPROM */
        temp = ioread32(phw->prHSR);
        if ((temp & (C6205_HSR_CFGERR | C6205_HSR_EEREAD)) !=
                C6205_HSR_EEREAD)
                return HPI6205_ERROR_6205_EEPROM;
        temp |= 0x04;
        /* disable PINTA interrupt */
        iowrite32(temp, phw->prHSR);

        /* check control register reports PCI boot mode */
        temp = ioread32(phw->prHDCR);
        if (!(temp & C6205_HDCR_PCIBOOT))
                return HPI6205_ERROR_6205_REG;

        /* try writing a few numbers to the DSP page register */
        /* and reading them back. */
        temp = 3;
        iowrite32(temp, phw->prDSPP);
        if ((temp | C6205_DSPP_MAP1) != ioread32(phw->prDSPP))
                return HPI6205_ERROR_6205_DSPPAGE;
        temp = 2;
        iowrite32(temp, phw->prDSPP);
        if ((temp | C6205_DSPP_MAP1) != ioread32(phw->prDSPP))
                return HPI6205_ERROR_6205_DSPPAGE;
        temp = 1;
        iowrite32(temp, phw->prDSPP);
        if ((temp | C6205_DSPP_MAP1) != ioread32(phw->prDSPP))
                return HPI6205_ERROR_6205_DSPPAGE;
        /* reset DSP page to the correct number */
        temp = 0;
        iowrite32(temp, phw->prDSPP);
        if ((temp | C6205_DSPP_MAP1) != ioread32(phw->prDSPP))
                return HPI6205_ERROR_6205_DSPPAGE;
        phw->dsp_page = 0;

        /* release 6713 from reset before 6205 is bootloaded.
           This ensures that the EMIF is inactive,
           and the 6713 HPI gets the correct bootmode etc
         */
        if (boot_code_id[1] != 0) {
                /* DSP 1 is a C6713 */
                /* CLKX0 <- '1' release the C6205 bootmode pulldowns */
                boot_loader_write_mem32(pao, 0, (0x018C0024L), 0x00002202);
                hpios_delay_micro_seconds(100);
                /* Reset the 6713 #1 - revB */
                boot_loader_write_mem32(pao, 0, C6205_BAR0_TIMER1_CTL, 0);

                /* dummy read every 4 words for 6205 advisory 1.4.4 */
                boot_loader_read_mem32(pao, 0, 0);

                hpios_delay_micro_seconds(100);
                /* Release C6713 from reset - revB */
                boot_loader_write_mem32(pao, 0, C6205_BAR0_TIMER1_CTL, 4);
                hpios_delay_micro_seconds(100);
        }

        for (dsp = 0; dsp < HPI6205_MAX_FILES_TO_LOAD; dsp++) {
                /* is there a DSP to load? */
                if (boot_code_id[dsp] == 0)
                        continue;

                err = boot_loader_config_emif(pao, dsp);
                if (err)
                        return err;

                err = boot_loader_test_internal_memory(pao, dsp);
                if (err)
                        return err;

                err = boot_loader_test_external_memory(pao, dsp);
                if (err)
                        return err;

                err = boot_loader_test_pld(pao, dsp);
                if (err)
                        return err;

                /* write the DSP code down into the DSPs memory */
                dsp_code.ps_dev = pao->pci.pci_dev;
                err = hpi_dsp_code_open(boot_code_id[dsp], &dsp_code,
                        pos_error_code);
                if (err)
                        return err;

                while (1) {
                        u32 length;
                        u32 address;
                        u32 type;
                        u32 *pcode;

                        err = hpi_dsp_code_read_word(&dsp_code, &length);
                        if (err)
                                break;
                        if (length == 0xFFFFFFFF)
                                break;  /* end of code */

                        err = hpi_dsp_code_read_word(&dsp_code, &address);
                        if (err)
                                break;
                        err = hpi_dsp_code_read_word(&dsp_code, &type);
                        if (err)
                                break;
                        err = hpi_dsp_code_read_block(length, &dsp_code,
                                &pcode);
                        if (err)
                                break;
                        for (i = 0; i < (int)length; i++) {
                                boot_loader_write_mem32(pao, dsp, address,
                                        *pcode);
                                /* dummy read every 4 words */
                                /* for 6205 advisory 1.4.4 */
                                if (i % 4 == 0)
                                        boot_loader_read_mem32(pao, dsp,
                                                address);
                                pcode++;
                                address += 4;
                        }

                }
                if (err) {
                        hpi_dsp_code_close(&dsp_code);
                        return err;
                }

                /* verify code */
                hpi_dsp_code_rewind(&dsp_code);
                while (1) {
                        u32 length = 0;
                        u32 address = 0;
                        u32 type = 0;
                        u32 *pcode = NULL;
                        u32 data = 0;

                        hpi_dsp_code_read_word(&dsp_code, &length);
                        if (length == 0xFFFFFFFF)
                                break;  /* end of code */

                        hpi_dsp_code_read_word(&dsp_code, &address);
                        hpi_dsp_code_read_word(&dsp_code, &type);
                        hpi_dsp_code_read_block(length, &dsp_code, &pcode);

                        for (i = 0; i < (int)length; i++) {
                                data = boot_loader_read_mem32(pao, dsp,
                                        address);
                                if (data != *pcode) {
                                        err = 0;
                                        break;
                                }
                                pcode++;
                                address += 4;
                        }
                        if (err)
                                break;
                }
                hpi_dsp_code_close(&dsp_code);
                if (err)
                        return err;
        }

        /* After bootloading all DSPs, start DSP0 running
         * The DSP0 code will handle starting and synchronizing with its slaves
         */
        if (phw->p_interface_buffer) {
                /* we need to tell the card the physical PCI address */
                u32 physicalPC_iaddress;
                struct bus_master_interface *interface =
                        phw->p_interface_buffer;
                u32 host_mailbox_address_on_dsp;
                u32 physicalPC_iaddress_verify = 0;
                int time_out = 10;
                /* set ack so we know when DSP is ready to go */
                /* (dwDspAck will be changed to HIF_RESET) */
                interface->dsp_ack = H620_HIF_UNKNOWN;
                wmb();  /* ensure ack is written before dsp writes back */

                err = hpios_locked_mem_get_phys_addr(&phw->h_locked_mem,
                        &physicalPC_iaddress);

                /* locate the host mailbox on the DSP. */
                host_mailbox_address_on_dsp = 0x80000000;
                while ((physicalPC_iaddress != physicalPC_iaddress_verify)
                        && time_out--) {
                        boot_loader_write_mem32(pao, 0,
                                host_mailbox_address_on_dsp,
                                physicalPC_iaddress);
                        physicalPC_iaddress_verify =
                                boot_loader_read_mem32(pao, 0,
                                host_mailbox_address_on_dsp);
                }
        }
        HPI_DEBUG_LOG(DEBUG, "starting DS_ps running\n");
        /* enable interrupts */
        temp = ioread32(phw->prHSR);
        temp &= ~(u32)C6205_HSR_INTAM;
        iowrite32(temp, phw->prHSR);

        /* start code running... */
        temp = ioread32(phw->prHDCR);
        temp |= (u32)C6205_HDCR_DSPINT;
        iowrite32(temp, phw->prHDCR);

        /* give the DSP 10ms to start up */
        hpios_delay_micro_seconds(10000);
        return err;

}

/*****************************************************************************/
/* Bootloader utility functions */

static u32 boot_loader_read_mem32(struct hpi_adapter_obj *pao, int dsp_index,
        u32 address)
{
        struct hpi_hw_obj *phw = pao->priv;
        u32 data = 0;
        __iomem u32 *p_data;

        if (dsp_index == 0) {
                /* DSP 0 is always C6205 */
                if ((address >= 0x01800000) & (address < 0x02000000)) {
                        /* BAR1 register access */
                        p_data = pao->pci.ap_mem_base[1] +
                                (address & 0x007fffff) /
                                sizeof(*pao->pci.ap_mem_base[1]);
                        /* HPI_DEBUG_LOG(WARNING,
                           "BAR1 access %08x\n", dwAddress); */
                } else {
                        u32 dw4M_page = address >> 22L;
                        if (dw4M_page != phw->dsp_page) {
                                phw->dsp_page = dw4M_page;
                                /* *INDENT OFF* */
                                iowrite32(phw->dsp_page, phw->prDSPP);
                                /* *INDENT-ON* */
                        }
                        address &= 0x3fffff;    /* address within 4M page */
                        /* BAR0 memory access */
                        p_data = pao->pci.ap_mem_base[0] +
                                address / sizeof(u32);
                }
                data = ioread32(p_data);
        } else if (dsp_index == 1) {
                /* DSP 1 is a C6713 */
                u32 lsb;
                boot_loader_write_mem32(pao, 0, HPIAL_ADDR, address);
                boot_loader_write_mem32(pao, 0, HPIAH_ADDR, address >> 16);
                lsb = boot_loader_read_mem32(pao, 0, HPIDL_ADDR);
                data = boot_loader_read_mem32(pao, 0, HPIDH_ADDR);
                data = (data << 16) | (lsb & 0xFFFF);
        }
        return data;
}

static void boot_loader_write_mem32(struct hpi_adapter_obj *pao,
        int dsp_index, u32 address, u32 data)
{
        struct hpi_hw_obj *phw = pao->priv;
        __iomem u32 *p_data;
        /*      u32 dwVerifyData=0; */

        if (dsp_index == 0) {
                /* DSP 0 is always C6205 */
                if ((address >= 0x01800000) & (address < 0x02000000)) {
                        /* BAR1 - DSP  register access using */
                        /* Non-prefetchable PCI access */
                        p_data = pao->pci.ap_mem_base[1] +
                                (address & 0x007fffff) /
                                sizeof(*pao->pci.ap_mem_base[1]);
                } else {
                        /* BAR0 access - all of DSP memory using */
                        /* pre-fetchable PCI access */
                        u32 dw4M_page = address >> 22L;
                        if (dw4M_page != phw->dsp_page) {
                                phw->dsp_page = dw4M_page;
                                /* *INDENT-OFF* */
                                iowrite32(phw->dsp_page, phw->prDSPP);
                                /* *INDENT-ON* */
                        }
                        address &= 0x3fffff;    /* address within 4M page */
                        p_data = pao->pci.ap_mem_base[0] +
                                address / sizeof(u32);
                }
                iowrite32(data, p_data);
        } else if (dsp_index == 1) {
                /* DSP 1 is a C6713 */
                boot_loader_write_mem32(pao, 0, HPIAL_ADDR, address);
                boot_loader_write_mem32(pao, 0, HPIAH_ADDR, address >> 16);

                /* dummy read every 4 words for 6205 advisory 1.4.4 */
                boot_loader_read_mem32(pao, 0, 0);

                boot_loader_write_mem32(pao, 0, HPIDL_ADDR, data);
                boot_loader_write_mem32(pao, 0, HPIDH_ADDR, data >> 16);

                /* dummy read every 4 words for 6205 advisory 1.4.4 */
                boot_loader_read_mem32(pao, 0, 0);
        }
}

static u16 boot_loader_config_emif(struct hpi_adapter_obj *pao, int dsp_index)
{
        if (dsp_index == 0) {
                u32 setting;

                /* DSP 0 is always C6205 */

                /* Set the EMIF */
                /* memory map of C6205 */
                /* 00000000-0000FFFF    16Kx32 internal program */
                /* 00400000-00BFFFFF    CE0     2Mx32 SDRAM running @ 100MHz */

                /* EMIF config */
                /*------------ */
                /* Global EMIF control */
                boot_loader_write_mem32(pao, dsp_index, 0x01800000, 0x3779);
#define WS_OFS 28
#define WST_OFS 22
#define WH_OFS 20
#define RS_OFS 16
#define RST_OFS 8
#define MTYPE_OFS 4
#define RH_OFS 0

                /* EMIF CE0 setup - 2Mx32 Sync DRAM on ASI5000 cards only */
                setting = 0x00000030;
                boot_loader_write_mem32(pao, dsp_index, 0x01800008, setting);
                if (setting != boot_loader_read_mem32(pao, dsp_index,
                                0x01800008))
                        return HPI6205_ERROR_DSP_EMIF;

                /* EMIF CE1 setup - 32 bit async. This is 6713 #1 HPI, */
                /* which occupies D15..0. 6713 starts at 27MHz, so need */
                /* plenty of wait states. See dsn8701.rtf, and 6713 errata. */
                /* WST should be 71, but 63  is max possible */
                setting =
                        (1L << WS_OFS) | (63L << WST_OFS) | (1L << WH_OFS) |
                        (1L << RS_OFS) | (63L << RST_OFS) | (1L << RH_OFS) |
                        (2L << MTYPE_OFS);
                boot_loader_write_mem32(pao, dsp_index, 0x01800004, setting);
                if (setting != boot_loader_read_mem32(pao, dsp_index,
                                0x01800004))
                        return HPI6205_ERROR_DSP_EMIF;

                /* EMIF CE2 setup - 32 bit async. This is 6713 #2 HPI, */
                /* which occupies D15..0. 6713 starts at 27MHz, so need */
                /* plenty of wait states */
                setting =
                        (1L << WS_OFS) | (28L << WST_OFS) | (1L << WH_OFS) |
                        (1L << RS_OFS) | (63L << RST_OFS) | (1L << RH_OFS) |
                        (2L << MTYPE_OFS);
                boot_loader_write_mem32(pao, dsp_index, 0x01800010, setting);
                if (setting != boot_loader_read_mem32(pao, dsp_index,
                                0x01800010))
                        return HPI6205_ERROR_DSP_EMIF;

                /* EMIF CE3 setup - 32 bit async. */
                /* This is the PLD on the ASI5000 cards only */
                setting =
                        (1L << WS_OFS) | (10L << WST_OFS) | (1L << WH_OFS) |
                        (1L << RS_OFS) | (10L << RST_OFS) | (1L << RH_OFS) |
                        (2L << MTYPE_OFS);
                boot_loader_write_mem32(pao, dsp_index, 0x01800014, setting);
                if (setting != boot_loader_read_mem32(pao, dsp_index,
                                0x01800014))
                        return HPI6205_ERROR_DSP_EMIF;

                /* set EMIF SDRAM control for 2Mx32 SDRAM (512x32x4 bank) */
                /*  need to use this else DSP code crashes? */
                boot_loader_write_mem32(pao, dsp_index, 0x01800018,
                        0x07117000);

                /* EMIF SDRAM Refresh Timing */
                /* EMIF SDRAM timing  (orig = 0x410, emulator = 0x61a) */
                boot_loader_write_mem32(pao, dsp_index, 0x0180001C,
                        0x00000410);

        } else if (dsp_index == 1) {
                /* test access to the C6713s HPI registers */
                u32 write_data = 0, read_data = 0, i = 0;

                /* Set up HPIC for little endian, by setiing HPIC:HWOB=1 */
                write_data = 1;
                boot_loader_write_mem32(pao, 0, HPICL_ADDR, write_data);
                boot_loader_write_mem32(pao, 0, HPICH_ADDR, write_data);
                /* C67 HPI is on lower 16bits of 32bit EMIF */
                read_data =
                        0xFFF7 & boot_loader_read_mem32(pao, 0, HPICL_ADDR);
                if (write_data != read_data) {
                        HPI_DEBUG_LOG(ERROR, "HPICL %x %x\n", write_data,
                                read_data);
                        return HPI6205_ERROR_C6713_HPIC;
                }
                /* HPIA - walking ones test */
                write_data = 1;
                for (i = 0; i < 32; i++) {
                        boot_loader_write_mem32(pao, 0, HPIAL_ADDR,
                                write_data);
                        boot_loader_write_mem32(pao, 0, HPIAH_ADDR,
                                (write_data >> 16));
                        read_data =
                                0xFFFF & boot_loader_read_mem32(pao, 0,
                                HPIAL_ADDR);
                        read_data =
                                read_data | ((0xFFFF &
                                        boot_loader_read_mem32(pao, 0,
                                                HPIAH_ADDR))
                                << 16);
                        if (read_data != write_data) {
                                HPI_DEBUG_LOG(ERROR, "HPIA %x %x\n",
                                        write_data, read_data);
                                return HPI6205_ERROR_C6713_HPIA;
                        }
                        write_data = write_data << 1;
                }

                /* setup C67x PLL
                 *  ** C6713 datasheet says we cannot program PLL from HPI,
                 * and indeed if we try to set the PLL multiply from the HPI,
                 * the PLL does not seem to lock, so we enable the PLL and
                 * use the default multiply of x 7, which for a 27MHz clock
                 * gives a DSP speed of 189MHz
                 */
                /* bypass PLL */
                boot_loader_write_mem32(pao, dsp_index, 0x01B7C100, 0x0000);
                hpios_delay_micro_seconds(1000);
                /* EMIF = 189/3=63MHz */
                boot_loader_write_mem32(pao, dsp_index, 0x01B7C120, 0x8002);
                /* peri = 189/2 */
                boot_loader_write_mem32(pao, dsp_index, 0x01B7C11C, 0x8001);
                /* cpu  = 189/1 */
                boot_loader_write_mem32(pao, dsp_index, 0x01B7C118, 0x8000);
                hpios_delay_micro_seconds(1000);
                /* ** SGT test to take GPO3 high when we start the PLL */
                /* and low when the delay is completed */
                /* FSX0 <- '1' (GPO3) */
                boot_loader_write_mem32(pao, 0, (0x018C0024L), 0x00002A0A);
                /* PLL not bypassed */
                boot_loader_write_mem32(pao, dsp_index, 0x01B7C100, 0x0001);
                hpios_delay_micro_seconds(1000);
                /* FSX0 <- '0' (GPO3) */
                boot_loader_write_mem32(pao, 0, (0x018C0024L), 0x00002A02);

                /* 6205 EMIF CE1 resetup - 32 bit async. */
                /* Now 6713 #1 is running at 189MHz can reduce waitstates */
                boot_loader_write_mem32(pao, 0, 0x01800004,     /* CE1 */
                        (1L << WS_OFS) | (8L << WST_OFS) | (1L << WH_OFS) |
                        (1L << RS_OFS) | (12L << RST_OFS) | (1L << RH_OFS) |
                        (2L << MTYPE_OFS));

                hpios_delay_micro_seconds(1000);

                /* check that we can read one of the PLL registers */
                /* PLL should not be bypassed! */
                if ((boot_loader_read_mem32(pao, dsp_index, 0x01B7C100) & 0xF)
                        != 0x0001) {
                        return HPI6205_ERROR_C6713_PLL;
                }
                /* setup C67x EMIF  (note this is the only use of
                   BAR1 via BootLoader_WriteMem32) */
                boot_loader_write_mem32(pao, dsp_index, C6713_EMIF_GCTL,
                        0x000034A8);

                /* EMIF CE0 setup - 2Mx32 Sync DRAM
                   31..28       Wr setup
                   27..22       Wr strobe
                   21..20       Wr hold
                   19..16       Rd setup
                   15..14       -
                   13..8        Rd strobe
                   7..4         MTYPE   0011            Sync DRAM 32bits
                   3            Wr hold MSB
                   2..0         Rd hold
                 */
                boot_loader_write_mem32(pao, dsp_index, C6713_EMIF_CE0,
                        0x00000030);

                /* EMIF SDRAM Extension
                   0x00
                   31-21        0000b 0000b 000b
                   20           WR2RD = 2cycles-1  = 1b

                   19-18        WR2DEAC = 3cycle-1 = 10b
                   17           WR2WR = 2cycle-1   = 1b
                   16-15        R2WDQM = 4cycle-1  = 11b
                   14-12        RD2WR = 6cycles-1  = 101b

                   11-10        RD2DEAC = 4cycle-1 = 11b
                   9            RD2RD = 2cycle-1   = 1b
                   8-7          THZP = 3cycle-1    = 10b
                   6-5          TWR  = 2cycle-1    = 01b (tWR = 17ns)
                   4            TRRD = 2cycle      = 0b  (tRRD = 14ns)
                   3-1          TRAS = 5cycle-1    = 100b (Tras=42ns)
                   1            CAS latency = 3cyc = 1b
                   (for Micron 2M32-7 operating at 100MHz)
                 */
                boot_loader_write_mem32(pao, dsp_index, C6713_EMIF_SDRAMEXT,
                        0x001BDF29);

                /* EMIF SDRAM control - set up for a 2Mx32 SDRAM (512x32x4 bank)
                   31           -       0b       -
                   30           SDBSZ   1b              4 bank
                   29..28       SDRSZ   00b             11 row address pins

                   27..26       SDCSZ   01b             8 column address pins
                   25           RFEN    1b              refersh enabled
                   24           INIT    1b              init SDRAM!

                   23..20       TRCD    0001b                   (Trcd/Tcyc)-1 = (20/10)-1 = 1

                   19..16       TRP     0001b                   (Trp/Tcyc)-1 = (20/10)-1 = 1

                   15..12       TRC     0110b                   (Trc/Tcyc)-1 = (70/10)-1 = 6

                   11..0        -       0000b 0000b 0000b
                 */
                boot_loader_write_mem32(pao, dsp_index, C6713_EMIF_SDRAMCTL,
                        0x47116000);

                /* SDRAM refresh timing
                   Need 4,096 refresh cycles every 64ms = 15.625us = 1562cycles of 100MHz = 0x61A
                 */
                boot_loader_write_mem32(pao, dsp_index,
                        C6713_EMIF_SDRAMTIMING, 0x00000410);

                hpios_delay_micro_seconds(1000);
        } else if (dsp_index == 2) {
                /* DSP 2 is a C6713 */
        }

        return 0;
}

static u16 boot_loader_test_memory(struct hpi_adapter_obj *pao, int dsp_index,
        u32 start_address, u32 length)
{
        u32 i = 0, j = 0;
        u32 test_addr = 0;
        u32 test_data = 0, data = 0;

        length = 1000;

        /* for 1st word, test each bit in the 32bit word, */
        /* dwLength specifies number of 32bit words to test */
        /*for(i=0; i<dwLength; i++) */
        i = 0;
        {
                test_addr = start_address + i * 4;
                test_data = 0x00000001;
                for (j = 0; j < 32; j++) {
                        boot_loader_write_mem32(pao, dsp_index, test_addr,
                                test_data);
                        data = boot_loader_read_mem32(pao, dsp_index,
                                test_addr);
                        if (data != test_data) {
                                HPI_DEBUG_LOG(VERBOSE,
                                        "Memtest error details  "
                                        "%08x %08x %08x %i\n", test_addr,
                                        test_data, data, dsp_index);
                                return 1;       /* error */
                        }
                        test_data = test_data << 1;
                }       /* for(j) */
        }       /* for(i) */

        /* for the next 100 locations test each location, leaving it as zero */
        /* write a zero to the next word in memory before we read */
        /* the previous write to make sure every memory location is unique */
        for (i = 0; i < 100; i++) {
                test_addr = start_address + i * 4;
                test_data = 0xA5A55A5A;
                boot_loader_write_mem32(pao, dsp_index, test_addr, test_data);
                boot_loader_write_mem32(pao, dsp_index, test_addr + 4, 0);
                data = boot_loader_read_mem32(pao, dsp_index, test_addr);
                if (data != test_data) {
                        HPI_DEBUG_LOG(VERBOSE,
                                "Memtest error details  "
                                "%08x %08x %08x %i\n", test_addr, test_data,
                                data, dsp_index);
                        return 1;       /* error */
                }
                /* leave location as zero */
                boot_loader_write_mem32(pao, dsp_index, test_addr, 0x0);
        }

        /* zero out entire memory block */
        for (i = 0; i < length; i++) {
                test_addr = start_address + i * 4;
                boot_loader_write_mem32(pao, dsp_index, test_addr, 0x0);
        }
        return 0;
}

static u16 boot_loader_test_internal_memory(struct hpi_adapter_obj *pao,
        int dsp_index)
{
        int err = 0;
        if (dsp_index == 0) {
                /* DSP 0 is a C6205 */
                /* 64K prog mem */
                err = boot_loader_test_memory(pao, dsp_index, 0x00000000,
                        0x10000);
                if (!err)
                        /* 64K data mem */
                        err = boot_loader_test_memory(pao, dsp_index,
                                0x80000000, 0x10000);
        } else if (dsp_index == 1) {
                /* DSP 1 is a C6713 */
                /* 192K internal mem */
                err = boot_loader_test_memory(pao, dsp_index, 0x00000000,
                        0x30000);
                if (!err)
                        /* 64K internal mem / L2 cache */
                        err = boot_loader_test_memory(pao, dsp_index,
                                0x00030000, 0x10000);
        }

        if (err)
                return HPI6205_ERROR_DSP_INTMEM;
        else
                return 0;
}

static u16 boot_loader_test_external_memory(struct hpi_adapter_obj *pao,
        int dsp_index)
{
        u32 dRAM_start_address = 0;
        u32 dRAM_size = 0;

        if (dsp_index == 0) {
                /* only test for SDRAM if an ASI5000 card */
                if (pao->pci.pci_dev->subsystem_device == 0x5000) {
                        /* DSP 0 is always C6205 */
                        dRAM_start_address = 0x00400000;
                        dRAM_size = 0x200000;
                        /*dwDRAMinc=1024; */
                } else
                        return 0;
        } else if (dsp_index == 1) {
                /* DSP 1 is a C6713 */
                dRAM_start_address = 0x80000000;
                dRAM_size = 0x200000;
                /*dwDRAMinc=1024; */
        }

        if (boot_loader_test_memory(pao, dsp_index, dRAM_start_address,
                        dRAM_size))
                return HPI6205_ERROR_DSP_EXTMEM;
        return 0;
}

static u16 boot_loader_test_pld(struct hpi_adapter_obj *pao, int dsp_index)
{
        u32 data = 0;
        if (dsp_index == 0) {
                /* only test for DSP0 PLD on ASI5000 card */
                if (pao->pci.pci_dev->subsystem_device == 0x5000) {
                        /* PLD is located at CE3=0x03000000 */
                        data = boot_loader_read_mem32(pao, dsp_index,
                                0x03000008);
                        if ((data & 0xF) != 0x5)
                                return HPI6205_ERROR_DSP_PLD;
                        data = boot_loader_read_mem32(pao, dsp_index,
                                0x0300000C);
                        if ((data & 0xF) != 0xA)
                                return HPI6205_ERROR_DSP_PLD;
                }
        } else if (dsp_index == 1) {
                /* DSP 1 is a C6713 */
                if (pao->pci.pci_dev->subsystem_device == 0x8700) {
                        /* PLD is located at CE1=0x90000000 */
                        data = boot_loader_read_mem32(pao, dsp_index,
                                0x90000010);
                        if ((data & 0xFF) != 0xAA)
                                return HPI6205_ERROR_DSP_PLD;
                        /* 8713 - LED on */
                        boot_loader_write_mem32(pao, dsp_index, 0x90000000,
                                0x02);
                }
        }
        return 0;
}

/** Transfer data to or from DSP
 nOperation = H620_H620_HIF_SEND_DATA or H620_HIF_GET_DATA
*/
static short hpi6205_transfer_data(struct hpi_adapter_obj *pao, u8 *p_data,
        u32 data_size, int operation)
{
        struct hpi_hw_obj *phw = pao->priv;
        u32 data_transferred = 0;
        u16 err = 0;
        u32 temp2;
        struct bus_master_interface *interface = phw->p_interface_buffer;

        if (!p_data)
                return HPI_ERROR_INVALID_DATA_POINTER;

        data_size &= ~3L;       /* round data_size down to nearest 4 bytes */

        /* make sure state is IDLE */
        if (!wait_dsp_ack(phw, H620_HIF_IDLE, HPI6205_TIMEOUT))
                return HPI_ERROR_DSP_HARDWARE;

        while (data_transferred < data_size) {
                u32 this_copy = data_size - data_transferred;

                if (this_copy > HPI6205_SIZEOF_DATA)
                        this_copy = HPI6205_SIZEOF_DATA;

                if (operation == H620_HIF_SEND_DATA)
                        memcpy((void *)&interface->u.b_data[0],
                                &p_data[data_transferred], this_copy);

                interface->transfer_size_in_bytes = this_copy;

                /* DSP must change this back to nOperation */
                interface->dsp_ack = H620_HIF_IDLE;
                send_dsp_command(phw, operation);

                temp2 = wait_dsp_ack(phw, operation, HPI6205_TIMEOUT);
                HPI_DEBUG_LOG(DEBUG, "spun %d times for data xfer of %d\n",
                        HPI6205_TIMEOUT - temp2, this_copy);

                if (!temp2) {
                        /* timed out */
                        HPI_DEBUG_LOG(ERROR,
                                "Timed out waiting for " "state %d got %d\n",
                                operation, interface->dsp_ack);

                        break;
                }
                if (operation == H620_HIF_GET_DATA)
                        memcpy(&p_data[data_transferred],
                                (void *)&interface->u.b_data[0], this_copy);

                data_transferred += this_copy;
        }
        if (interface->dsp_ack != operation)
                HPI_DEBUG_LOG(DEBUG, "interface->dsp_ack=%d, expected %d\n",
                        interface->dsp_ack, operation);
        /*                      err=HPI_ERROR_DSP_HARDWARE; */

        send_dsp_command(phw, H620_HIF_IDLE);

        return err;
}

/* wait for up to timeout_us microseconds for the DSP
   to signal state by DMA into dwDspAck
*/
static int wait_dsp_ack(struct hpi_hw_obj *phw, int state, int timeout_us)
{
        struct bus_master_interface *interface = phw->p_interface_buffer;
        int t = timeout_us / 4;

        rmb();  /* ensure interface->dsp_ack is up to date */
        while ((interface->dsp_ack != state) && --t) {
                hpios_delay_micro_seconds(4);
                rmb();  /* DSP changes dsp_ack by DMA */
        }

        /*HPI_DEBUG_LOG(VERBOSE, "Spun %d for %d\n", timeout_us/4-t, state); */
        return t * 4;
}

/* set the busmaster interface to cmd, then interrupt the DSP */
static void send_dsp_command(struct hpi_hw_obj *phw, int cmd)
{
        struct bus_master_interface *interface = phw->p_interface_buffer;
        u32 r;

        interface->host_cmd = cmd;
        wmb();  /* DSP gets state by DMA, make sure it is written to memory */
        /* before we interrupt the DSP */
        r = ioread32(phw->prHDCR);
        r |= (u32)C6205_HDCR_DSPINT;
        iowrite32(r, phw->prHDCR);
        r &= ~(u32)C6205_HDCR_DSPINT;
        iowrite32(r, phw->prHDCR);
}

static unsigned int message_count;

static u16 message_response_sequence(struct hpi_adapter_obj *pao,
        struct hpi_message *phm, struct hpi_response *phr)
{
        u32 time_out, time_out2;
        struct hpi_hw_obj *phw = pao->priv;
        struct bus_master_interface *interface = phw->p_interface_buffer;
        u16 err = 0;

        message_count++;
        if (phm->size > sizeof(interface->u)) {
                phr->error = HPI_ERROR_MESSAGE_BUFFER_TOO_SMALL;
                phr->specific_error = sizeof(interface->u);
                phr->size = sizeof(struct hpi_response_header);
                HPI_DEBUG_LOG(ERROR,
                        "message len %d too big for buffer %zd \n", phm->size,
                        sizeof(interface->u));
                return 0;
        }

        /* Assume buffer of type struct bus_master_interface
           is allocated "noncacheable" */

        if (!wait_dsp_ack(phw, H620_HIF_IDLE, HPI6205_TIMEOUT)) {
                HPI_DEBUG_LOG(DEBUG, "timeout waiting for idle\n");
                return HPI6205_ERROR_MSG_RESP_IDLE_TIMEOUT;
        }

        memcpy(&interface->u.message_buffer, phm, phm->size);
        /* signal we want a response */
        send_dsp_command(phw, H620_HIF_GET_RESP);

        time_out2 = wait_dsp_ack(phw, H620_HIF_GET_RESP, HPI6205_TIMEOUT);

        if (!time_out2) {
                HPI_DEBUG_LOG(ERROR,
                        "(%u) Timed out waiting for " "GET_RESP state [%x]\n",
                        message_count, interface->dsp_ack);
        } else {
                HPI_DEBUG_LOG(VERBOSE,
                        "(%u) transition to GET_RESP after %u\n",
                        message_count, HPI6205_TIMEOUT - time_out2);
        }
        /* spin waiting on HIF interrupt flag (end of msg process) */
        time_out = HPI6205_TIMEOUT;

        /* read the result */
        if (time_out) {
                if (interface->u.response_buffer.size <= phr->size)
                        memcpy(phr, &interface->u.response_buffer,
                                interface->u.response_buffer.size);
                else {
                        HPI_DEBUG_LOG(ERROR,
                                "response len %d too big for buffer %d\n",
                                interface->u.response_buffer.size, phr->size);
                        memcpy(phr, &interface->u.response_buffer,
                                sizeof(struct hpi_response_header));
                        phr->error = HPI_ERROR_RESPONSE_BUFFER_TOO_SMALL;
                        phr->specific_error =
                                interface->u.response_buffer.size;
                        phr->size = sizeof(struct hpi_response_header);
                }
        }
        /* set interface back to idle */
        send_dsp_command(phw, H620_HIF_IDLE);

        if (!time_out || !time_out2) {
                HPI_DEBUG_LOG(DEBUG, "something timed out!\n");
                return HPI6205_ERROR_MSG_RESP_TIMEOUT;
        }
        /* special case for adapter close - */
        /* wait for the DSP to indicate it is idle */
        if (phm->function == HPI_ADAPTER_CLOSE) {
                if (!wait_dsp_ack(phw, H620_HIF_IDLE, HPI6205_TIMEOUT)) {
                        HPI_DEBUG_LOG(DEBUG,
                                "Timeout waiting for idle "
                                "(on adapter_close)\n");
                        return HPI6205_ERROR_MSG_RESP_IDLE_TIMEOUT;
                }
        }
        err = hpi_validate_response(phm, phr);
        return err;
}

static void hw_message(struct hpi_adapter_obj *pao, struct hpi_message *phm,
        struct hpi_response *phr)
{

        u16 err = 0;

        hpios_dsplock_lock(pao);

        err = message_response_sequence(pao, phm, phr);

        /* maybe an error response */
        if (err) {
                /* something failed in the HPI/DSP interface */
                if (err >= HPI_ERROR_BACKEND_BASE) {
                        phr->error = HPI_ERROR_DSP_COMMUNICATION;
                        phr->specific_error = err;
                } else {
                        phr->error = err;
                }

                pao->dsp_crashed++;

                /* just the header of the response is valid */
                phr->size = sizeof(struct hpi_response_header);
                goto err;
        } else
                pao->dsp_crashed = 0;

        if (phr->error != 0)    /* something failed in the DSP */
                goto err;

        switch (phm->function) {
        case HPI_OSTREAM_WRITE:
        case HPI_ISTREAM_ANC_WRITE:
                err = hpi6205_transfer_data(pao, phm->u.d.u.data.pb_data,
                        phm->u.d.u.data.data_size, H620_HIF_SEND_DATA);
                break;

        case HPI_ISTREAM_READ:
        case HPI_OSTREAM_ANC_READ:
                err = hpi6205_transfer_data(pao, phm->u.d.u.data.pb_data,
                        phm->u.d.u.data.data_size, H620_HIF_GET_DATA);
                break;

        case HPI_CONTROL_SET_STATE:
                if (phm->object == HPI_OBJ_CONTROLEX
                        && phm->u.cx.attribute == HPI_COBRANET_SET_DATA)
                        err = hpi6205_transfer_data(pao,
                                phm->u.cx.u.cobranet_bigdata.pb_data,
                                phm->u.cx.u.cobranet_bigdata.byte_count,
                                H620_HIF_SEND_DATA);
                break;

        case HPI_CONTROL_GET_STATE:
                if (phm->object == HPI_OBJ_CONTROLEX
                        && phm->u.cx.attribute == HPI_COBRANET_GET_DATA)
                        err = hpi6205_transfer_data(pao,
                                phm->u.cx.u.cobranet_bigdata.pb_data,
                                phr->u.cx.u.cobranet_data.byte_count,
                                H620_HIF_GET_DATA);
                break;
        }
        phr->error = err;

err:
        hpios_dsplock_unlock(pao);

        return;
}