static void dump_xor(void)
{
mvOsPrintf(" CHANNEL_ARBITER_REG %08x\n",
MV_REG_READ(XOR_CHANNEL_ARBITER_REG(1)));
mvOsPrintf(" CONFIG_REG %08x\n",
MV_REG_READ(XOR_CONFIG_REG(1, XOR_CHAN(0))));
mvOsPrintf(" ACTIVATION_REG %08x\n",
MV_REG_READ(XOR_ACTIVATION_REG(1, XOR_CHAN(0))));
mvOsPrintf(" CAUSE_REG %08x\n",
MV_REG_READ(XOR_CAUSE_REG(1)));
mvOsPrintf(" MASK_REG %08x\n",
MV_REG_READ(XOR_MASK_REG(1)));
mvOsPrintf(" ERROR_CAUSE_REG %08x\n",
MV_REG_READ(XOR_ERROR_CAUSE_REG(1)));
mvOsPrintf(" ERROR_ADDR_REG %08x\n",
MV_REG_READ(XOR_ERROR_ADDR_REG(1)));
mvOsPrintf(" NEXT_DESC_PTR_REG %08x\n",
MV_REG_READ(XOR_NEXT_DESC_PTR_REG(1, XOR_CHAN(0))));
mvOsPrintf(" CURR_DESC_PTR_REG %08x\n",
MV_REG_READ(XOR_CURR_DESC_PTR_REG(1, XOR_CHAN(0))));
mvOsPrintf(" BYTE_COUNT_REG %08x\n\n",
MV_REG_READ(XOR_BYTE_COUNT_REG(1, XOR_CHAN(0))));
mvOsPrintf(" %08x\n\n", XOR_WINDOW_CTRL_REG(1, XOR_CHAN(0))) ;
mvOsPrintf(" XOR_WINDOW_CTRL_REG %08x\n\n",
MV_REG_READ(XOR_WINDOW_CTRL_REG(1, XOR_CHAN(0)))) ;
}
void
print_xor_regs(int chan)
{
printk(" XOR_CHANNEL_ARBITER_REG %08x\n", MV_REG_READ(XOR_CHANNEL_ARBITER_REG));
printk(" XOR_CONFIG_REG %08x\n", MV_REG_READ(XOR_CONFIG_REG(chan)));
printk(" XOR_ACTIVATION_REG %08x\n", MV_REG_READ(XOR_ACTIVATION_REG(chan)));
printk(" XOR_CAUSE_REG %08x\n", MV_REG_READ(XOR_CAUSE_REG));
printk(" XOR_MASK_REG %08x\n", MV_REG_READ(XOR_MASK_REG));
printk(" XOR_ERROR_CAUSE_REG %08x\n", MV_REG_READ(XOR_ERROR_CAUSE_REG));
printk(" XOR_ERROR_ADDR_REG %08x\n", MV_REG_READ(XOR_ERROR_ADDR_REG));
printk(" XOR_NEXT_DESC_PTR_REG %08x\n", MV_REG_READ(XOR_NEXT_DESC_PTR_REG(chan)));
printk(" XOR_CURR_DESC_PTR_REG %08x\n", MV_REG_READ(XOR_CURR_DESC_PTR_REG(chan)));
printk(" XOR_BYTE_COUNT_REG %08x\n", MV_REG_READ(XOR_BYTE_COUNT_REG(chan)));
}
void setXorDesc(void)
{
unsigned int mode;
eth_xor_desc = mvOsMalloc(sizeof(MV_XOR_DESC) + XEXDPR_DST_PTR_DMA_MASK + 32);
eth_xor_desc = (MV_XOR_DESC *)MV_ALIGN_UP((MV_U32)eth_xor_desc, XEXDPR_DST_PTR_DMA_MASK+1);
eth_xor_desc_phys_addr = mvOsIoVirtToPhys(NULL, eth_xor_desc);
mvSysXorInit();
mode = MV_REG_READ(XOR_CONFIG_REG(1, XOR_CHAN(0)));
mode &= ~XEXCR_OPERATION_MODE_MASK;
mode |= XEXCR_OPERATION_MODE_DMA;
MV_REG_WRITE(XOR_CONFIG_REG(1, XOR_CHAN(0)), mode);
MV_REG_WRITE(XOR_NEXT_DESC_PTR_REG(1, XOR_CHAN(0)), eth_xor_desc_phys_addr);
dump_xor();
}
static inline
struct eth_pbuf *eth_l2fw_copy_packet_withXor(struct eth_pbuf *pRxPktInfo)
{
struct bm_pool *pool;
struct eth_pbuf *pTxPktInfo;
pool = &mv_eth_pool[pRxPktInfo->pool];
pTxPktInfo = mv_eth_pool_get(pool);
if (pTxPktInfo == NULL) {
mvOsPrintf("pTxPktInfo == NULL in %s\n", __func__);
return NULL;
}
/* sync between giga and XOR to avoid errors (like checksum errors in TX)
when working with IOCC */
mvOsCacheIoSync();
eth_xor_desc->srcAdd0 = pRxPktInfo->physAddr + pRxPktInfo->offset + MV_ETH_MH_SIZE + 30;
eth_xor_desc->phyDestAdd = pTxPktInfo->physAddr + pTxPktInfo->offset + MV_ETH_MH_SIZE + 30;
eth_xor_desc->byteCnt = pRxPktInfo->bytes - 30;
eth_xor_desc->phyNextDescPtr = 0;
eth_xor_desc->status = BIT31;
/* we had changed only the first part of eth_xor_desc, so flush only one
line of cache */
mvOsCacheLineFlush(NULL, eth_xor_desc);
MV_REG_WRITE(XOR_NEXT_DESC_PTR_REG(1, XOR_CHAN(0)), eth_xor_desc_phys_addr);
MV_REG_WRITE(XOR_ACTIVATION_REG(1, XOR_CHAN(0)), XEXACTR_XESTART_MASK);
mvOsCacheLineInv(NULL, pRxPktInfo->pBuf + pRxPktInfo->offset);
l2fw_copy_mac(pRxPktInfo, pTxPktInfo);
mvOsCacheLineFlush(NULL, pTxPktInfo->pBuf + pTxPktInfo->offset);
/* Update TxPktInfo */
pTxPktInfo->bytes = pRxPktInfo->bytes;
return pTxPktInfo;
}
/*
* mv_xor_transfer - Transfer data from source to destination on one of
* three modes (XOR,CRC32,DMA)
*
* DESCRIPTION:
* This function initiates XOR channel, according to function parameters,
* in order to perform XOR or CRC32 or DMA transaction.
* To gain maximum performance the user is asked to keep the following
* restrictions:
* 1) Selected engine is available (not busy).
* 1) This module does not take into consideration CPU MMU issues.
* In order for the XOR engine to access the appropreate source
* and destination, address parameters must be given in system
* physical mode.
* 2) This API does not take care of cache coherency issues. The source,
* destination and in case of chain the descriptor list are assumed
* to be cache coherent.
* 4) Parameters validity. For example, does size parameter exceeds
* maximum byte count of descriptor mode (16M or 64K).
*
* INPUT:
* chan - XOR channel number. See MV_XOR_CHANNEL enumerator.
* xor_type - One of three: XOR, CRC32 and DMA operations.
* xor_chain_ptr - address of chain pointer
*
* OUTPUT:
* None.
*
* RETURS:
* MV_BAD_PARAM if parameters to function invalid, MV_OK otherwise.
*
*/
int mv_xor_transfer(u32 chan, int xor_type, u32 xor_chain_ptr)
{
u32 tmp;
/* Parameter checking */
if (chan >= MV_XOR_MAX_CHAN) {
debug("%s: ERR. Invalid chan num %d\n", __func__, chan);
return MV_BAD_PARAM;
}
if (MV_ACTIVE == mv_xor_state_get(chan)) {
debug("%s: ERR. Channel is already active\n", __func__);
return MV_BUSY;
}
if (0x0 == xor_chain_ptr) {
debug("%s: ERR. xor_chain_ptr is NULL pointer\n", __func__);
return MV_BAD_PARAM;
}
/* Read configuration register and mask the operation mode field */
tmp = reg_read(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)));
tmp &= ~XEXCR_OPERATION_MODE_MASK;
switch (xor_type) {
case MV_XOR:
if (0 != (xor_chain_ptr & XEXDPR_DST_PTR_XOR_MASK)) {
debug("%s: ERR. Invalid chain pointer (bits [5:0] must be cleared)\n",
__func__);
return MV_BAD_PARAM;
}
/* Set the operation mode to XOR */
tmp |= XEXCR_OPERATION_MODE_XOR;
break;
case MV_DMA:
if (0 != (xor_chain_ptr & XEXDPR_DST_PTR_DMA_MASK)) {
debug("%s: ERR. Invalid chain pointer (bits [4:0] must be cleared)\n",
__func__);
return MV_BAD_PARAM;
}
/* Set the operation mode to DMA */
tmp |= XEXCR_OPERATION_MODE_DMA;
break;
case MV_CRC32:
if (0 != (xor_chain_ptr & XEXDPR_DST_PTR_CRC_MASK)) {
debug("%s: ERR. Invalid chain pointer (bits [4:0] must be cleared)\n",
__func__);
return MV_BAD_PARAM;
}
/* Set the operation mode to CRC32 */
tmp |= XEXCR_OPERATION_MODE_CRC;
break;
default:
return MV_BAD_PARAM;
}
/* Write the operation mode to the register */
reg_write(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)), tmp);
/*
* Update the NextDescPtr field in the XOR Engine [0..1] Next Descriptor
* Pointer Register (XExNDPR)
*/
reg_write(XOR_NEXT_DESC_PTR_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
xor_chain_ptr);
/* Start transfer */
reg_bit_set(XOR_ACTIVATION_REG(XOR_UNIT(chan), XOR_CHAN(chan)),
XEXACTR_XESTART_MASK);
return MV_OK;
}
/*******************************************************************************
* mvXorTransfer - Transfer data from source to destination on one of
* three modes (XOR,CRC32,DMA)
*
* DESCRIPTION:
* This function initiates XOR channel, according to function parameters,
* in order to perform XOR or CRC32 or DMA transaction.
* To gain maximum performance the user is asked to keep the following
* restrictions:
* 1) Selected engine is available (not busy).
* 1) This module does not take into consideration CPU MMU issues.
* In order for the XOR engine to access the appropreate source
* and destination, address parameters must be given in system
* physical mode.
* 2) This API does not take care of cache coherency issues. The source,
* destination and in case of chain the descriptor list are assumed
* to be cache coherent.
* 4) Parameters validity. For example, does size parameter exceeds
* maximum byte count of descriptor mode (16M or 64K).
*
* INPUT:
* chan - XOR channel number. See MV_XOR_CHANNEL enumerator.
* xorType - One of three: XOR, CRC32 and DMA operations.
* xorChainPtr - address of chain pointer
*
* OUTPUT:
* None.
*
* RETURS:
* MV_BAD_PARAM if parameters to function invalid, MV_OK otherwise.
*
*******************************************************************************/
MV_STATUS mvXorTransfer(MV_U32 chan, MV_XOR_TYPE xorType, MV_U32 xorChainPtr)
{
MV_U32 temp;
/* Parameter checking */
if (chan >= MV_XOR_MAX_CHAN) {
DB(mvOsPrintf("%s: ERR. Invalid chan num %d\n", __func__, chan));
return MV_BAD_PARAM;
}
if (MV_ACTIVE == mvXorStateGet(chan)) {
DB(mvOsPrintf("%s: ERR. Channel is already active\n", __func__));
return MV_BUSY;
}
if (0x0 == xorChainPtr) {
DB(mvOsPrintf("%s: ERR. xorChainPtr is NULL pointer\n", __func__));
return MV_BAD_PARAM;
}
/* read configuration register and mask the operation mode field */
temp = MV_REG_READ(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)));
temp &= ~XEXCR_OPERATION_MODE_MASK;
switch (xorType) {
case MV_XOR:
if (0 != (xorChainPtr & XEXDPR_DST_PTR_XOR_MASK)) {
DB(mvOsPrintf("%s: ERR. Invalid chain pointer (bits [5:0] must "
"be cleared)\n", __func__));
return MV_BAD_PARAM;
}
/* set the operation mode to XOR */
temp |= XEXCR_OPERATION_MODE_XOR;
break;
case MV_DMA:
if (0 != (xorChainPtr & XEXDPR_DST_PTR_DMA_MASK)) {
DB(mvOsPrintf("%s: ERR. Invalid chain pointer (bits [4:0] must "
"be cleared)\n", __func__));
return MV_BAD_PARAM;
}
/* set the operation mode to DMA */
temp |= XEXCR_OPERATION_MODE_DMA;
break;
case MV_CRC32:
if (0 != (xorChainPtr & XEXDPR_DST_PTR_CRC_MASK)) {
DB(mvOsPrintf("%s: ERR. Invalid chain pointer (bits [4:0] must "
"be cleared)\n", __func__));
return MV_BAD_PARAM;
}
/* set the operation mode to CRC32 */
temp |= XEXCR_OPERATION_MODE_CRC;
break;
default:
return MV_BAD_PARAM;
}
/* write the operation mode to the register */
MV_REG_WRITE(XOR_CONFIG_REG(XOR_UNIT(chan), XOR_CHAN(chan)), temp);
/* update the NextDescPtr field in the XOR Engine [0..1] Next Descriptor
Pointer Register (XExNDPR) */
MV_REG_WRITE(XOR_NEXT_DESC_PTR_REG(XOR_UNIT(chan), XOR_CHAN(chan)), xorChainPtr);
/* start transfer */
MV_REG_BIT_SET(XOR_ACTIVATION_REG(XOR_UNIT(chan), XOR_CHAN(chan)), XEXACTR_XESTART_MASK);
return MV_OK;
}
