#ifdef USE_SSUSB_QMU #include "mu3d_hal_osal.h" #define _MTK_QMU_DRV_EXT_ #include "mu3d_hal_qmu_drv.h" #undef _MTK_QMU_DRV_EXT_ #include "mu3d_hal_usb_drv.h" #include "mu3d_hal_hw.h" /** * get_bd - get a null bd * @args - arg1: dir, arg2: ep number */ PBD get_bd(USB_DIR dir, DEV_UINT32 num) { PBD ptr; if (dir == USB_RX) { ptr = (PBD) Rx_bd_List[num].pNext; os_printk(K_DEBUG, "%s Rx_bd_List[%d].pNext=%p\n", __func__, num, (Rx_bd_List[num].pNext)); if ((Rx_bd_List[num].pNext + 1) < Rx_bd_List[num].pEnd) Rx_bd_List[num].pNext++; else Rx_bd_List[num].pNext = Rx_bd_List[num].pStart; } else { ptr = (PBD) Tx_bd_List[num].pNext; os_printk(K_DEBUG, "%s Tx_gpd_List[%d].pNext=%p\n", __func__, num, (Tx_bd_List[num].pNext)); Tx_bd_List[num].pNext++; Tx_bd_List[num].pNext = Tx_bd_List[num].pNext + AT_BD_EXT_LEN; if (Tx_bd_List[num].pNext >= Tx_bd_List[num].pEnd) Tx_bd_List[num].pNext = Tx_bd_List[num].pStart; } return ptr; } /** * get_bd - get a null gpd * @args - arg1: dir, arg2: ep number */ PGPD get_gpd(USB_DIR dir, DEV_UINT32 num) { PGPD ptr; if (dir == USB_RX) { ptr = Rx_gpd_List[num].pNext; /* qmu_printk(K_DEBUG, "[RX]""GPD List[%d]->Next=%p\n", num, Rx_gpd_List[num].pNext); */ Rx_gpd_List[num].pNext = Rx_gpd_List[num].pNext + (AT_GPD_EXT_LEN / sizeof(TGPD) + 1); /* qmu_printk(K_DEBUG, "[Rx]""GPD List[%d]->Start=%p, Next=%p, End=%p\n", */ /* num, Rx_gpd_List[num].pStart, Rx_gpd_List[num].pNext, Rx_gpd_List[num].pEnd); */ if (Rx_gpd_List[num].pNext >= Rx_gpd_List[num].pEnd) Rx_gpd_List[num].pNext = Rx_gpd_List[num].pStart; } else { ptr = Tx_gpd_List[num].pNext; /* qmu_printk(K_DEBUG, "[TX]""GPD List[%d]->Next=%p\n", num, Tx_gpd_List[num].pNext); */ /* * Here is really tricky. * The size of a GPD is 16 bytes. But the cache line size is 64B. * If all GPDs are allocated continiously. * When doing invalidating the cache. The size of 64B from the specified address would flush to * the physical memory. This action may cause that other GPDs corrupted, like HWO=1 when receiving * QMU Done interrupt. Current workaround is that let a GPD as 64 bytes. So the next * GPD is behind 64bytes. */ Tx_gpd_List[num].pNext = Tx_gpd_List[num].pNext + (AT_GPD_EXT_LEN / sizeof(TGPD) + 1); /* qmu_printk(K_DEBUG, "[TX]""GPD List[%d]->Start=%p, pNext=%p, pEnd=%p\n", */ /* num, Tx_gpd_List[num].pStart, Tx_gpd_List[num].pNext, Tx_gpd_List[num].pEnd); */ if (Tx_gpd_List[num].pNext >= Tx_gpd_List[num].pEnd) Tx_gpd_List[num].pNext = Tx_gpd_List[num].pStart; } return ptr; } /** * get_bd - align gpd ptr to target ptr * @args - arg1: dir, arg2: ep number, arg3: target ptr */ void gpd_ptr_align(USB_DIR dir, DEV_UINT32 num, PGPD ptr) { DEV_UINT32 run_next; run_next = true; /* qmu_printk(K_DEBUG,"%s %d, EP%d, ptr=%p\n", __func__, dir, num, ptr); */ while (run_next) { if (ptr == get_gpd(dir, num)) run_next = false; } } /** * bd_virt_to_phys - map bd virtual address to physical address * @args - arg1: virtual address, arg2: dir, arg3: ep number * @return - physical address */ dma_addr_t bd_virt_to_phys(void *vaddr, USB_DIR dir, DEV_UINT32 num) { uintptr_t ptr; if (dir == USB_RX) ptr = rx_bd_map[num].p_desc_dma; else ptr = tx_bd_map[num].p_desc_dma; os_printk(K_DEBUG, "%s %s[%d]phys=%lx<->virt=%p\n", __func__, ((dir == USB_RX) ? "RX" : "TX"), num, ptr, vaddr); return (dma_addr_t) ptr; } /** * bd_phys_to_virt - map bd physical address to virtual address * @args - arg1: physical address, arg2: dir, arg3: ep number * @return - virtual address */ void *bd_phys_to_virt(void *paddr, USB_DIR dir, DEV_UINT32 num) { void *ptr; os_printk(K_DEBUG, "bd_phys_to_virt paddr=%p, num=%d\n", paddr, num); if (dir == USB_RX) ptr = rx_bd_map[num].p_desc; else ptr = tx_bd_map[num].p_desc; /*os_printk(K_DEBUG,"%s %s[%d]phys=%p<->virt=%p\n", __func__, \ ((dir==USB_RX)?"RX":"TX"), num , paddr, ptr); */ return ptr; } /** * mu3d_hal_gpd_virt_to_phys - map gpd virtual address to physical address * @args - arg1: virtual address, arg2: dir, arg3: ep number * @return - physical address */ dma_addr_t mu3d_hal_gpd_virt_to_phys(void *vaddr, USB_DIR dir, DEV_UINT32 num) { uintptr_t ptr; if (dir == USB_RX) ptr = rx_gpd_map[num].p_desc_dma + (dma_addr_t) (vaddr - rx_gpd_map[num].p_desc); else ptr = tx_gpd_map[num].p_desc_dma + (dma_addr_t) (vaddr - tx_gpd_map[num].p_desc); os_printk(K_DEBUG, "%s %s[%d]phys=%lx<->virt=%p\n", __func__, ((dir == USB_RX) ? "RX" : "TX"), num, ptr, vaddr); return (dma_addr_t) ptr; } /** * gpd_phys_to_virt - map gpd physical address to virtual address * @args - arg1: physical address, arg2: dir, arg3: ep number * @return - virtual address */ void *gpd_phys_to_virt(void *paddr, USB_DIR dir, DEV_UINT32 num) { void *ptr; /* os_printk(K_DEBUG,"%s paddr=%p, num=%d\n", __func__, paddr, num); */ if (dir == USB_RX) { /*os_printk(K_DEBUG, "%s Rx_gpd_Offset[%d]=0x%08X\n", __func__, num, \ Rx_gpd_Offset[num]); */ ptr = (void *)((uintptr_t) rx_gpd_map[num].p_desc + (uintptr_t) (paddr - rx_gpd_map[num].p_desc_dma)); } else { /*os_printk(K_DEBUG,"%s Tx_gpd_Offset[%d]=0x%08X\n", __func__, num, \ Tx_gpd_Offset[num]); */ ptr = (void *)((uintptr_t) tx_gpd_map[num].p_desc + (uintptr_t) (paddr - tx_gpd_map[num].p_desc_dma)); } /*os_printk(K_DEBUG,"%s %s[%d]phys=%p<->virt=%p\n", __func__, \ ((dir==USB_RX)?"RX":"TX"), num , paddr, ptr); */ return ptr; } /** * init_bd_list - initialize bd management list * @args - arg1: dir, arg2: ep number, arg3: bd virtual addr, arg4: bd ioremap addr, arg5: bd number */ void init_bd_list(USB_DIR dir, int num, PBD ptr, dma_addr_t io_ptr, DEV_UINT32 size) { if (dir == USB_RX) { Rx_bd_List[num].pStart = ptr; Rx_bd_List[num].pEnd = (PBD) (ptr + size); rx_bd_map[num].p_desc = (void *)ptr; rx_bd_map[num].p_desc_dma = io_ptr; ptr++; Rx_bd_List[num].pNext = ptr; os_printk(K_DEBUG, "Rx_bd_List[%d].pStart=%p, pNext=%p, pEnd=%p\n", num, Rx_bd_List[num].pStart, Rx_bd_List[num].pNext, Rx_bd_List[num].pEnd); os_printk(K_DEBUG, "rx_bd_map[%d] vir=%p dma=%08llx\n", num, rx_bd_map[num].p_desc, (unsigned long long)rx_bd_map[num].p_desc_dma); os_printk(K_DEBUG, "vir=%p dma=%08llx\n", ptr, (unsigned long long)io_ptr); } else { Tx_bd_List[num].pStart = ptr; Tx_bd_List[num].pEnd = (PBD) ((DEV_UINT8 *) (ptr + size) + AT_BD_EXT_LEN * size); tx_bd_map[num].p_desc = (void *)ptr; tx_bd_map[num].p_desc_dma = io_ptr; ptr++; Tx_bd_List[num].pNext = (PBD) ((DEV_UINT8 *) ptr + AT_BD_EXT_LEN); os_printk(K_DEBUG, "Tx_bd_List[%d].pStart=%p, pNext=%p, pEnd=%p\n", num, Tx_bd_List[num].pStart, Tx_bd_List[num].pNext, Tx_bd_List[num].pEnd); os_printk(K_DEBUG, "tx_bd_map[%d] vir=%p dma=%08llx\n", num, tx_bd_map[num].p_desc, (unsigned long long)tx_bd_map[num].p_desc_dma); os_printk(K_DEBUG, "vir=%p, dma=%08llx\n", ptr, (unsigned long long)io_ptr); } } /** * init_gpd_list - initialize gpd management list * @args - arg1: dir, arg2: ep number, arg3: gpd virtual addr, arg4: gpd ioremap addr, arg5: gpd number */ void init_gpd_list(USB_DIR dir, int num, PGPD ptr, dma_addr_t io_ptr, DEV_UINT32 size) { if (dir == USB_RX) { Rx_gpd_List[num].pStart = ptr; Rx_gpd_List[num].pEnd = (PGPD) ((DEV_UINT8 *) (ptr + size) + AT_GPD_EXT_LEN * size); rx_gpd_map[num].p_desc = (void *)ptr; rx_gpd_map[num].p_desc_dma = io_ptr; ptr++; Rx_gpd_List[num].pNext = (PGPD) ((DEV_UINT8 *) ptr + AT_GPD_EXT_LEN); qmu_printk(K_INFO, "Rx_gpd_List[%d].pStart=%p, pNext=%p, pEnd=%p\n", num, Rx_gpd_List[num].pStart, Rx_gpd_List[num].pNext, Rx_gpd_List[num].pEnd); qmu_printk(K_INFO, "rx_gpd_map[%d] vir=%p dma=%08llx\n", num, rx_gpd_map[num].p_desc, (unsigned long long)rx_gpd_map[num].p_desc_dma); qmu_printk(K_INFO, "vir=%p, dma=%08llx\n", ptr, (unsigned long long)io_ptr); } else { Tx_gpd_List[num].pStart = ptr; Tx_gpd_List[num].pEnd = (PGPD) ((DEV_UINT8 *) (ptr + size) + AT_GPD_EXT_LEN * size); tx_gpd_map[num].p_desc = (void *)ptr; tx_gpd_map[num].p_desc_dma = io_ptr; ptr++; Tx_gpd_List[num].pNext = (PGPD) ((DEV_UINT8 *) ptr + AT_GPD_EXT_LEN); qmu_printk(K_INFO, "Tx_gpd_List[%d].pStart=%p, pNext=%p, pEnd=%p\n", num, Tx_gpd_List[num].pStart, Tx_gpd_List[num].pNext, Tx_gpd_List[num].pEnd); qmu_printk(K_INFO, "tx_gpd_map[%d] vir=%p dma=%08llx\n", num, tx_gpd_map[num].p_desc, (unsigned long long)tx_gpd_map[num].p_desc_dma); qmu_printk(K_INFO, "vir=%p, dma=%08llx\n", ptr, (unsigned long long)io_ptr); } } /** * free_gpd - free gpd management list * @args - arg1: dir, arg2: ep number */ void free_gpd(USB_DIR dir, int num) { if (dir == USB_RX) { os_memset(Rx_gpd_List[num].pStart, 0, MAX_GPD_NUM * (sizeof(TGPD) + AT_GPD_EXT_LEN)); } else { os_memset(Tx_gpd_List[num].pStart, 0, MAX_GPD_NUM * (sizeof(TGPD) + AT_GPD_EXT_LEN)); } } /** * mu3d_hal_alloc_qmu_mem - allocate gpd and bd memory for all ep * */ /* USBIF */ static dma_addr_t Tx_gpd_ioptr[15]; static dma_addr_t Rx_gpd_ioptr[15]; void _ex_mu3d_hal_free_qmu_mem(struct device *dev) { DEV_UINT32 i; DEV_UINT32 size = (sizeof(TGPD) + AT_GPD_EXT_LEN) * MAX_GPD_NUM; qmu_printk(K_INFO, "_ex_mu3d_hal_free_qmu_mem +\n"); /*TODO:dma_free_coherent() is needed if _ex_mu3d_hal_alloc_qmu_mem() would be called more than once */ for (i = 1; i <= MAX_QMU_EP; i++) { #if 0 kfree(Rx_gpd_head[i]); kfree(Tx_gpd_head[i]); #else dma_free_coherent(dev, size, Rx_gpd_head[i], Rx_gpd_ioptr[i]); dma_free_coherent(dev, size, Tx_gpd_head[i], Tx_gpd_ioptr[i]); #endif } qmu_printk(K_INFO, "_ex_mu3d_hal_free_qmu_mem -\n"); } void _ex_mu3d_hal_alloc_qmu_mem(struct device *dev) { DEV_UINT32 i, size; TGPD *ptr; dma_addr_t io_ptr; dma_addr_t dma_handle; /*TODO: dma_pool_alloc() is an alternative choice once the memory size is a concern */ for (i = 1; i <= MAX_QMU_EP; i++) { /* Allocate Rx GPD */ size = (sizeof(TGPD) + AT_GPD_EXT_LEN) * MAX_GPD_NUM; ptr = (TGPD *) dma_alloc_coherent(dev, size, &dma_handle, GFP_KERNEL); memset(ptr, 0, size); Rx_gpd_ioptr[i] = io_ptr = dma_handle; init_gpd_list(USB_RX, i, ptr, io_ptr, MAX_GPD_NUM); Rx_gpd_end[i] = ptr; qmu_printk(K_INFO, "ALLOC RX GPD End [%d] Virtual Mem=%p, DMA addr=%08llx\n", i, Rx_gpd_end[i], (unsigned long long)io_ptr); TGPD_CLR_FLAGS_HWO(Rx_gpd_end[i]); Rx_gpd_head[i] = Rx_gpd_last[i] = Rx_gpd_end[i]; qmu_printk(K_INFO, "RQSAR[%d]=%08llx\n", i, (unsigned long long)mu3d_hal_gpd_virt_to_phys(Rx_gpd_end[i], USB_RX, i)); /* Allocate Tx GPD */ size = (sizeof(TGPD) + AT_GPD_EXT_LEN) * MAX_GPD_NUM; ptr = (TGPD *) dma_alloc_coherent(dev, size, &dma_handle, GFP_KERNEL); memset(ptr, 0, size); Tx_gpd_ioptr[i] = io_ptr = dma_handle; init_gpd_list(USB_TX, i, ptr, io_ptr, MAX_GPD_NUM); Tx_gpd_end[i] = ptr; qmu_printk(K_INFO, "ALLOC TX GPD End [%d] Virtual Mem=%p, DMA addr=%08llx\n", i, Tx_gpd_end[i], (unsigned long long)io_ptr); TGPD_CLR_FLAGS_HWO(Tx_gpd_end[i]); Tx_gpd_head[i] = Tx_gpd_last[i] = Tx_gpd_end[i]; qmu_printk(K_INFO, "TQSAR[%d]=%08llx\n", i, (unsigned long long)mu3d_hal_gpd_virt_to_phys(Tx_gpd_end[i], USB_TX, i)); } } void mu3d_hal_free_qmu_mem(void) { DEV_UINT32 i; for (i = 1; i <= MAX_QMU_EP; i++) { kfree(Rx_gpd_head[i]); kfree(Tx_gpd_head[i]); kfree(Rx_bd_List[i].pStart); kfree(Tx_bd_List[i].pStart); } } void mu3d_hal_alloc_qmu_mem(void) { DEV_UINT32 i, size; TGPD *ptr; dma_addr_t io_ptr; TBD *bptr; dma_addr_t io_bptr; for (i = 1; i <= MAX_QMU_EP; i++) { /* Allocate Tx GPD */ size = sizeof(TGPD); size *= MAX_GPD_NUM; ptr = (TGPD *) os_mem_alloc(size); os_memset(ptr, 0, size); io_ptr = dma_map_single(NULL, ptr, size, DMA_TO_DEVICE); init_gpd_list(USB_RX, i, ptr, io_ptr, MAX_GPD_NUM); Rx_gpd_end[i] = ptr; os_printk(K_DEBUG, "ALLOC RX GPD End [%d] Virtual Mem=%p, DMA addr=%08llx\n", i, Rx_gpd_end[i], (unsigned long long)io_ptr); /* os_memset(Rx_gpd_end[i], 0 , sizeof(TGPD)); */ TGPD_CLR_FLAGS_HWO(Rx_gpd_end[i]); Rx_gpd_head[i] = Rx_gpd_last[i] = Rx_gpd_end[i]; os_printk(K_DEBUG, "RQSAR[%d]=%08llx\n", i, (unsigned long long)mu3d_hal_gpd_virt_to_phys(Rx_gpd_end[i], USB_RX, i)); /* Allocate Rx GPD */ size = sizeof(TGPD); size += AT_GPD_EXT_LEN; size *= MAX_GPD_NUM; ptr = (TGPD *) os_mem_alloc(size); os_memset(ptr, 0, size); io_ptr = dma_map_single(NULL, ptr, size, DMA_TO_DEVICE); init_gpd_list(USB_TX, i, ptr, io_ptr, MAX_GPD_NUM); Tx_gpd_end[i] = ptr; os_printk(K_DEBUG, "ALLOC TX GPD End [%d] Virtual Mem=%p, DMA addr=%08llx\n", i, Tx_gpd_end[i], (unsigned long long)io_ptr); TGPD_CLR_FLAGS_HWO(Tx_gpd_end[i]); Tx_gpd_head[i] = Tx_gpd_last[i] = Tx_gpd_end[i]; os_printk(K_DEBUG, "TQSAR[%d]=%08llx\n", i, (unsigned long long)mu3d_hal_gpd_virt_to_phys(Tx_gpd_end[i], USB_TX, i)); /* Allocate Tx BD */ size = (sizeof(TBD)); size *= MAX_BD_NUM; bptr = (TBD *) os_mem_alloc(size); os_memset(bptr, 0, size); io_bptr = dma_map_single(NULL, bptr, size, DMA_TO_DEVICE); init_bd_list(USB_RX, i, bptr, io_bptr, MAX_BD_NUM); /* Allocate Rx BD */ size = (sizeof(TBD)); size += AT_BD_EXT_LEN; size *= MAX_BD_NUM; bptr = (TBD *) os_mem_alloc(size); os_memset(bptr, 0, size); io_bptr = dma_map_single(NULL, bptr, size, DMA_TO_DEVICE); init_bd_list(USB_TX, i, bptr, io_bptr, MAX_BD_NUM); } } /** * mu3d_hal_init_qmu - initialize qmu * */ void _ex_mu3d_hal_init_qmu(void) { DEV_UINT32 i; DEV_UINT32 QCR = 0; /* Initialize QMU Tx/Rx start address. */ for (i = 1; i <= MAX_QMU_EP; i++) { qmu_printk(K_INFO, "==EP[%d]==Start addr RXQ=0x%08lx, TXQ=0x%08lx\n", i, (uintptr_t) mu3d_hal_gpd_virt_to_phys(Rx_gpd_head[i], USB_RX, i), (uintptr_t) mu3d_hal_gpd_virt_to_phys(Tx_gpd_head[i], USB_TX, i)); QCR |= QMU_RX_EN(i); QCR |= QMU_TX_EN(i); os_writel(USB_QMU_RQSAR(i), mu3d_hal_gpd_virt_to_phys(Rx_gpd_head[i], USB_RX, i)); os_writel(USB_QMU_TQSAR(i), mu3d_hal_gpd_virt_to_phys(Tx_gpd_head[i], USB_TX, i)); Tx_gpd_end[i] = Tx_gpd_last[i] = Tx_gpd_head[i]; Rx_gpd_end[i] = Rx_gpd_last[i] = Rx_gpd_head[i]; gpd_ptr_align(USB_TX, i, Tx_gpd_end[i]); gpd_ptr_align(USB_RX, i, Rx_gpd_end[i]); } /* Enable QMU interrupt. */ os_writel(U3D_QIESR1, TXQ_EMPTY_IESR | TXQ_CSERR_IESR | TXQ_LENERR_IESR | RXQ_EMPTY_IESR | RXQ_CSERR_IESR | RXQ_LENERR_IESR | RXQ_ZLPERR_IESR); os_writel(U3D_EPIESR, EP0ISR); } void mu3d_hal_init_qmu(void) { DEV_UINT32 i; DEV_UINT32 QCR = 0; /* Initialize QMU Tx/Rx start address. */ for (i = 1; i <= MAX_QMU_EP; i++) { os_printk(K_DEBUG, "==EP[%d]==Start addr RXQ=0x%08lx, TXQ=0x%08lx\n", i, (uintptr_t) mu3d_hal_gpd_virt_to_phys(Rx_gpd_head[i], USB_RX, i), (uintptr_t) mu3d_hal_gpd_virt_to_phys(Tx_gpd_head[i], USB_TX, i)); QCR |= QMU_RX_EN(i); QCR |= QMU_TX_EN(i); os_writel(USB_QMU_RQSAR(i), mu3d_hal_gpd_virt_to_phys(Rx_gpd_head[i], USB_RX, i)); os_writel(USB_QMU_TQSAR(i), mu3d_hal_gpd_virt_to_phys(Tx_gpd_head[i], USB_TX, i)); Tx_gpd_end[i] = Tx_gpd_last[i] = Tx_gpd_head[i]; Rx_gpd_end[i] = Rx_gpd_last[i] = Rx_gpd_head[i]; gpd_ptr_align(USB_TX, i, Tx_gpd_end[i]); gpd_ptr_align(USB_RX, i, Rx_gpd_end[i]); } /* Enable QMU Tx/Rx. */ os_writel(U3D_QGCSR, QCR); os_writel(U3D_QIESR0, QCR); /* Enable QMU interrupt. */ os_writel(U3D_QIESR1, TXQ_EMPTY_IESR | TXQ_CSERR_IESR | TXQ_LENERR_IESR | RXQ_EMPTY_IESR | RXQ_CSERR_IESR | RXQ_LENERR_IESR | RXQ_ZLPERR_IESR); os_writel(U3D_EPIESR, EP0ISR); } /** * mu3d_hal_cal_checksum - calculate check sum * @args - arg1: data buffer, arg2: data length */ noinline DEV_UINT8 mu3d_hal_cal_checksum(DEV_UINT8 *data, DEV_INT32 len) { DEV_UINT8 *uDataPtr, ckSum; DEV_INT32 i; *(data + 1) = 0x0; uDataPtr = data; ckSum = 0; /* For ALPS01572117, we found calculated QMU check sum is wrong. (Dump memory value directly.) */ /* After check this function, we did not find any flaw. Still cannot find how to get this wrong value. */ /* Maybe it is a memory corruption or complier problem. Add "noinline" and "mb();" to prevent this problem. */ mb(); for (i = 0; i < len; i++) ckSum += *(uDataPtr + i); return 0xFF - ckSum; } /** * mu3d_hal_resume_qmu - resume qmu function * @args - arg1: ep number, arg2: dir */ void mu3d_hal_resume_qmu(DEV_INT32 q_num, USB_DIR dir) { if (dir == USB_TX) { /* qmu_printk(K_DEBUG, "%s EP%d CSR=%x, CPR=%x\n", __func__, q_num, os_readl(USB_QMU_TQCSR(q_num)), os_readl(USB_QMU_TQCPR(q_num))); */ os_writel(USB_QMU_TQCSR(q_num), QMU_Q_RESUME); if (!os_readl(USB_QMU_TQCSR(q_num))) { qmu_printk(K_WARNIN, "[ERROR]" "%s TQCSR[%d]=%x\n", __func__, q_num, os_readl(USB_QMU_TQCSR(q_num))); os_writel(USB_QMU_TQCSR(q_num), QMU_Q_RESUME); qmu_printk(K_WARNIN, "[ERROR]" "%s TQCSR[%d]=%x\n", __func__, q_num, os_readl(USB_QMU_TQCSR(q_num))); } } else if (dir == USB_RX) { os_writel(USB_QMU_RQCSR(q_num), QMU_Q_RESUME); if (!os_readl(USB_QMU_RQCSR(q_num))) { qmu_printk(K_WARNIN, "[ERROR]" "%s RQCSR[%d]=%x\n", __func__, q_num, os_readl(USB_QMU_RQCSR(q_num))); os_writel(USB_QMU_RQCSR(q_num), QMU_Q_RESUME); qmu_printk(K_WARNIN, "[ERROR]" "%s RQCSR[%d]=%x\n", __func__, q_num, os_readl(USB_QMU_RQCSR(q_num))); } } else { qmu_printk(K_ERR, "%s wrong direction!!!\n", __func__); BUG_ON(1); } } /** * mu3d_hal_prepare_tx_gpd - prepare tx gpd/bd * @args - arg1: gpd address, arg2: data buffer address, arg3: data length, arg4: ep number, * arg5: with bd or not, arg6: write hwo bit or not, arg7: write ioc bit or not */ TGPD *_ex_mu3d_hal_prepare_tx_gpd(TGPD *gpd, dma_addr_t pBuf, DEV_UINT32 data_len, DEV_UINT8 ep_num, DEV_UINT8 _is_bdp, DEV_UINT8 isHWO, DEV_UINT8 ioc, DEV_UINT8 bps, DEV_UINT8 zlp) { qmu_printk(K_DEBUG, "[TX]" "%s gpd=%p, epnum=%d, len=%d, zlp=%d, size(TGPD)=%lld, pBuf=%08lx\n", __func__, gpd, ep_num, data_len, zlp, (u64) sizeof(TGPD), (unsigned long)pBuf); /*Set actual data point to "DATA Buffer" */ TGPD_SET_DATA(gpd, (unsigned long)pBuf); /*Clear "BDP(Buffer Descriptor Present)" flag */ TGPD_CLR_FORMAT_BDP(gpd); /* * "Data Buffer Length" = * 0 (If data length > GPD buffer length, use BDs), * data_len (If data length < GPD buffer length, only use GPD) */ TGPD_SET_BUF_LEN(gpd, data_len); /*"GPD extension length" = 0. Does not use GPD EXT!! */ TGPD_SET_EXT_LEN(gpd, 0); if (zlp) TGPD_SET_FORMAT_ZLP(gpd); else TGPD_CLR_FORMAT_ZLP(gpd); /*Default: bps=false */ TGPD_CLR_FORMAT_BPS(gpd); /*Default: ioc=true */ TGPD_SET_FORMAT_IOC(gpd); /*Get the next GPD */ Tx_gpd_end[ep_num] = get_gpd(USB_TX, ep_num); qmu_printk(K_DEBUG, "[TX]" "Tx_gpd_end[%d]=%p\n", ep_num, Tx_gpd_end[ep_num]); /*Initialize the new GPD */ memset(Tx_gpd_end[ep_num], 0, sizeof(TGPD) + AT_GPD_EXT_LEN); /*Clear "HWO(Hardware Own)" flag */ TGPD_CLR_FLAGS_HWO(Tx_gpd_end[ep_num]); /*Set "Next GDP pointer" as the next GPD */ TGPD_SET_NEXT(gpd, (unsigned long)mu3d_hal_gpd_virt_to_phys(Tx_gpd_end[ep_num], USB_TX, ep_num)); /*Default: isHWO=true */ TGPD_SET_CHKSUM(gpd, CHECKSUM_LENGTH); /*Set GPD Checksum */ TGPD_SET_FLAGS_HWO(gpd); /*Set HWO flag */ return gpd; } TGPD *mu3d_hal_prepare_tx_gpd(TGPD *gpd, dma_addr_t pBuf, DEV_UINT32 data_len, DEV_UINT8 ep_num, DEV_UINT8 _is_bdp, DEV_UINT8 isHWO, DEV_UINT8 ioc, DEV_UINT8 bps, DEV_UINT8 zlp) { DEV_UINT32 offset; DEV_INT32 i; DEV_INT32 bd_num; DEV_UINT32 length; TBD *bd_next; TBD *bd_head; TBD *bd; DEV_UINT8 *pBuffer; /*If data length is less than the GPD buffer size, just use GPD */ /* if (data_len <= GPD_BUF_SIZE) { */ /* _is_bdp = 0; */ /* } */ os_printk(K_INFO, "%s gpd=%p, epnum=%d, len=%d, _is_bdp=%d\n", __func__, gpd, ep_num, data_len, _is_bdp); if (!_is_bdp) { /*Set actual data point to "DATA Buffer" */ TGPD_SET_DATA(gpd, (unsigned long)pBuf); /*Clear "BDP(Buffer Descriptor Present)" flag */ TGPD_CLR_FORMAT_BDP(gpd); } else { /*Get the first BD */ bd_head = (TBD *) get_bd(USB_TX, ep_num); os_printk(K_INFO, "bd_head=x%p\n", bd_head); bd = bd_head; os_memset(bd, 0, sizeof(TBD)); /*Date length for transfer */ length = data_len; /*Point of data buffer */ pBuffer = (DEV_UINT8 *) (uintptr_t) (pBuf); /*The size of BD buffer */ offset = BD_BUF_SIZE; /*Count how many BD this transfer need. */ bd_num = (!(length % offset)) ? (length / offset) : ((length / offset) + 1); os_printk(K_INFO, "bd_num=%d\n", bd_num); /*If the size of BD buffer is bigger than the length of actual transfer, use the actual length */ if (offset > length) offset = length; /*Insert data into each BD */ for (i = 0; i < bd_num; i++) { os_printk(K_INFO, "bd[%d]=%p\n", i, bd); if (i == (bd_num - 1)) { /*The last BD */ TBD_SET_EXT_LEN(bd, 0); /*"BD Extension Length" = 0. Does not use BD EXT!! */ TBD_SET_BUF_LEN(bd, length); /*"Data Buffer Length" = the rest of data length */ /*Store the data pointer to "Data Buffer" */ TBD_SET_DATA(bd, (unsigned long)pBuffer); TBD_SET_FLAGS_EOL(bd); /*Set "EOL" */ TBD_SET_NEXT(bd, 0); /*Set "Next BD pointer" = 0 */ TBD_SET_CHKSUM(bd, CHECKSUM_LENGTH); /*Set "BD Checksum" */ /*Flush the data of BD struct to device */ dma_sync_single_for_device(NULL, bd_virt_to_phys(bd, USB_RX, ep_num), sizeof(TBD), DMA_BIDIRECTIONAL); /*There is no data left to be transferred by GPD */ /* data_len=length; */ data_len = 0; /*There is no data left to insert BD */ length = 0; } else { TBD_SET_EXT_LEN(bd, 0); /*"BD Extension length" = 0. Does not use BD EXT!! */ TBD_SET_BUF_LEN(bd, offset); /*"Data Buffer Length" = the MAX BD transfer size */ /*Store the data pointer to "Data Buffer" */ TBD_SET_DATA(bd, (unsigned long)pBuffer); TBD_CLR_FLAGS_EOL(bd); /*Clear "EOL" */ /*Get the next BD */ bd_next = (TBD *) get_bd(USB_TX, ep_num); os_memset(bd_next, 0, sizeof(TBD)); /*Set "Next BD pointer" as the next BD */ TBD_SET_NEXT(bd, (unsigned long)bd_virt_to_phys(bd_next, USB_TX, ep_num)); TBD_SET_CHKSUM(bd, CHECKSUM_LENGTH); /*Set BD Checksum */ /*Flush the data of BD struct to device */ dma_sync_single_for_device(NULL, bd_virt_to_phys(bd, USB_RX, ep_num), sizeof(TBD), DMA_BIDIRECTIONAL); /*Calculate the left data length */ length -= offset; /*Move to pointer of buffer */ pBuffer += offset; /*Move to next BD */ bd = bd_next; } } /*Set the BD pointer into "BD Pointer" at GPD */ TGPD_SET_DATA(gpd, (unsigned long)bd_virt_to_phys(bd_head, USB_TX, ep_num)); /*Set "BDP(Buffer Descriptor Present)" flag */ TGPD_SET_FORMAT_BDP(gpd); } os_printk(K_INFO, "%s GPD data_length=%d\n", __func__, data_len); /* * "Data Buffer Length" = * 0 (If data length > GPD buffer length, use BDs), * data_len (If data length < GPD buffer length, only use GPD) */ TGPD_SET_BUF_LEN(gpd, data_len); /*"GPD extension length" = 0. Does not use GPD EXT!! */ TGPD_SET_EXT_LEN(gpd, 0); /*Default: zlp=false, except type=ISOC */ if (zlp) TGPD_SET_FORMAT_ZLP(gpd); else TGPD_CLR_FORMAT_ZLP(gpd); /*Default: bps=false */ if (bps) TGPD_SET_FORMAT_BPS(gpd); else TGPD_CLR_FORMAT_BPS(gpd); /*Default: ioc=true */ if (ioc) TGPD_SET_FORMAT_IOC(gpd); else TGPD_CLR_FORMAT_IOC(gpd); /*Get the next GPD */ Tx_gpd_end[ep_num] = get_gpd(USB_TX, ep_num); os_printk(K_INFO, "Tx_gpd_end[%d]=%p\n", ep_num, Tx_gpd_end[ep_num]); /*Initialize the new GPD */ os_memset(Tx_gpd_end[ep_num], 0, sizeof(TGPD)); /*Clear "HWO(Hardware Own)" flag */ TGPD_CLR_FLAGS_HWO(Tx_gpd_end[ep_num]); /*Set "Next GDP pointer" as the next GPD */ TGPD_SET_NEXT(gpd, (unsigned long)mu3d_hal_gpd_virt_to_phys(Tx_gpd_end[ep_num], USB_TX, ep_num)); /*Default: isHWO=true */ if (isHWO) { TGPD_SET_CHKSUM(gpd, CHECKSUM_LENGTH); /*Set GPD Checksum */ TGPD_SET_FLAGS_HWO(gpd); /*Set HWO flag */ } else { TGPD_CLR_FLAGS_HWO(gpd); TGPD_SET_CHKSUM_HWO(gpd, CHECKSUM_LENGTH); } /*Flush the data of GPD struct to device */ dma_sync_single_for_device(NULL, mu3d_hal_gpd_virt_to_phys(gpd, USB_TX, ep_num), sizeof(TGPD), DMA_BIDIRECTIONAL); #if defined(USB_RISC_CACHE_ENABLED) os_flushinvalidateDcache(); #endif return gpd; } static inline int check_next_gpd(TGPD *gpd, TGPD *next_gpd) { if (((uintptr_t) next_gpd - (uintptr_t) gpd) == 0x40) return 1; else if (((uintptr_t) gpd - (uintptr_t) next_gpd) == 0x7c0) return 1; /*UNNECESSARY_ELSE*/ qmu_printk(K_ERR, "[RX]" "%p <-> %p\n", gpd, next_gpd); return 0; } /** * mu3d_hal_prepare_rx_gpd - prepare rx gpd/bd * @args - arg1: gpd address, arg2: data buffer address, arg3: data length, * arg4: ep number, arg5: with bd or not, arg6: write hwo bit or not, arg7: write ioc bit or not */ TGPD *_ex_mu3d_hal_prepare_rx_gpd(TGPD *gpd, dma_addr_t pBuf, DEV_UINT32 data_len, DEV_UINT8 ep_num, DEV_UINT8 _is_bdp, DEV_UINT8 isHWO, DEV_UINT8 ioc, DEV_UINT8 bps, DEV_UINT32 cMaxPacketSize) { qmu_printk(K_DEBUG, "[RX]" "%s gpd=%p, epnum=%d, len=%d, pBuf=%08lx\n", __func__, gpd, ep_num, data_len, (unsigned long)pBuf); /*Set actual data point to "DATA Buffer" */ TGPD_SET_DATA(gpd, (unsigned long)pBuf); /*Clear "BDP(Buffer Descriptor Present)" flag */ TGPD_CLR_FORMAT_BDP(gpd); /* * Set "Allow Data Buffer Length" = * 0 (If data length > GPD buffer length, use BDs), * data_len (If data length < GPD buffer length, only use GPD) */ TGPD_SET_DataBUF_LEN(gpd, data_len); /*Set "Transferred Data Length" = 0 */ TGPD_SET_BUF_LEN(gpd, 0); /*Default: bps=false */ TGPD_CLR_FORMAT_BPS(gpd); /*Default: ioc=true */ TGPD_SET_FORMAT_IOC(gpd); /*Get the next GPD */ Rx_gpd_end[ep_num] = get_gpd(USB_RX, ep_num); qmu_printk(K_DEBUG, "[RX]" "Rx_gpd_end[%d]=%p gpd=%p\n", ep_num, Rx_gpd_end[ep_num], gpd); /* BUG_ON(!check_next_gpd(gpd, Rx_gpd_end[ep_num])); */ /*Initialize the new GPD */ memset(Rx_gpd_end[ep_num], 0, sizeof(TGPD) + AT_GPD_EXT_LEN); /*Clear "HWO(Hardware Own)" flag */ TGPD_CLR_FLAGS_HWO(Rx_gpd_end[ep_num]); /*Set Next GDP pointer to the next GPD */ TGPD_SET_NEXT(gpd, (unsigned long)mu3d_hal_gpd_virt_to_phys(Rx_gpd_end[ep_num], USB_RX, ep_num)); /*Default: isHWO=true */ TGPD_SET_CHKSUM(gpd, CHECKSUM_LENGTH); /*Set GPD Checksum */ TGPD_SET_FLAGS_HWO(gpd); /*Set HWO flag */ /* os_printk(K_DEBUG,"Rx gpd info { HWO %d, Next_GPD %x ,DataBufferLength %d, */ /* DataBuffer %x, Recived Len %d, Endpoint %d, TGL %d, ZLP %d}\n", */ /* (DEV_UINT32)TGPD_GET_FLAG(gpd), (DEV_UINT32)TGPD_GET_NEXT(gpd), */ /* (DEV_UINT32)TGPD_GET_DataBUF_LEN(gpd), (DEV_UINT32)TGPD_GET_DATA(gpd), */ /* (DEV_UINT32)TGPD_GET_BUF_LEN(gpd), (DEV_UINT32)TGPD_GET_EPaddr(gpd), */ /* (DEV_UINT32)TGPD_GET_TGL(gpd), (DEV_UINT32)TGPD_GET_ZLP(gpd)); */ return gpd; } TGPD *mu3d_hal_prepare_rx_gpd(TGPD *gpd, dma_addr_t pBuf, DEV_UINT32 data_len, DEV_UINT8 ep_num, DEV_UINT8 _is_bdp, DEV_UINT8 isHWO, DEV_UINT8 ioc, DEV_UINT8 bps, DEV_UINT32 cMaxPacketSize) { DEV_UINT32 offset; DEV_INT32 i; DEV_INT32 bd_num; DEV_UINT32 length; TBD *bd_next; TBD *bd_head; TBD *bd; DEV_UINT8 *pBuffer; /*If data length is less than the GPD buffer size, just use GPD */ if (data_len < GPD_BUF_SIZE) _is_bdp = 0; os_printk(K_INFO, "%s gpd=%p, epnum=%d, len=%d, _is_bdp=%d, maxp=%d\n", __func__, gpd, ep_num, data_len, _is_bdp, cMaxPacketSize); if (!_is_bdp) { /*Set actual data point to "DATA Buffer" */ TGPD_SET_DATA(gpd, (unsigned long)pBuf); /*Clear "BDP(Buffer Descriptor Present)" flag */ TGPD_CLR_FORMAT_BDP(gpd); } else { /*Get the first BD */ bd_head = (TBD *) get_bd(USB_RX, ep_num); os_printk(K_INFO, "bd_head=x%p\n", bd_head); bd = bd_head; os_memset(bd, 0, sizeof(TBD)); /*Date length for transfer */ length = data_len; /*Point of data buffer */ pBuffer = (DEV_UINT8 *) (uintptr_t) (pBuf); /*The size of BD buffer */ offset = BD_BUF_SIZE; /*Count how many BD this transfer need. */ bd_num = (!(length % offset)) ? (length / offset) : ((length / offset) + 1); os_printk(K_INFO, "%s bd_num=%d\n", __func__, bd_num); /*Insert data into each BD */ for (i = 0; i < bd_num; i++) { os_printk(K_INFO, "%s bd[%d]=%p\n", __func__, i, bd); if (i == (bd_num - 1)) { TBD_SET_BUF_LEN(bd, 0); /*Set "Transferred Data Length" = 0 */ /*The last one's data buffer lengnth must be precise, or the GPD will never * done unless ZLP or short packet. */ /*"Allow Data Buffer Length" = the rest of data length* */ length = (!(length % cMaxPacketSize)) ? (length) : ((length / cMaxPacketSize) + 1) * cMaxPacketSize; TBD_SET_DataBUF_LEN(bd, length); /*Store the data pointer to "Data Buffer" */ TBD_SET_DATA(bd, (unsigned long)pBuffer); TBD_SET_FLAGS_EOL(bd); /*Set "EOL" */ TBD_SET_NEXT(bd, 0); /*Set "Next BD pointer" = 0 */ TBD_SET_CHKSUM(bd, CHECKSUM_LENGTH); /*Set "BD Checksum" */ /*Flush the data of BD struct to device */ dma_sync_single_for_device(NULL, bd_virt_to_phys(bd, USB_RX, ep_num), sizeof(TBD), DMA_BIDIRECTIONAL); break; } /*WARNING:UNNECESSARY_ELSE: else is not generally useful after a break or return*/ /*else*/ { TBD_SET_BUF_LEN(bd, 0); /*Set "Transferred Data Length" = 0 */ /*"Allow Data Buffer Length" = the MAX BD transfer size */ TBD_SET_DataBUF_LEN(bd, offset); /*Store the data pointer to "Data Buffer" */ TBD_SET_DATA(bd, (unsigned long)pBuffer); TBD_CLR_FLAGS_EOL(bd); /*Clear "EOL" */ /*Get the next BD */ bd_next = (TBD *) get_bd(USB_RX, ep_num); os_memset(bd_next, 0, sizeof(TBD)); /*Set "Next BD pointer" as the next BD */ TBD_SET_NEXT(bd, (unsigned long)bd_virt_to_phys(bd_next, USB_RX, ep_num)); TBD_SET_CHKSUM(bd, CHECKSUM_LENGTH); /*Set BD Checksum */ /*Flush the data of BD struct to device */ dma_sync_single_for_device(NULL, bd_virt_to_phys(bd, USB_RX, ep_num), sizeof(TBD), DMA_BIDIRECTIONAL); /*Calculate the left data length */ length -= offset; /*Move to pointer of buffer */ pBuffer += offset; /*Move to next BD */ bd = bd_next; } } /*Set the BD pointer into "BD Pointer" at GPD */ TGPD_SET_DATA(gpd, (unsigned long)bd_virt_to_phys(bd_head, USB_RX, ep_num)); /*Set "BDP(Buffer Descriptor Present)" flag */ TGPD_SET_FORMAT_BDP(gpd); } os_printk(K_INFO, "%s GPD data_length=%d\n", __func__, data_len); /* * Set "Allow Data Buffer Length" = * 0 (If data length > GPD buffer length, use BDs), * data_len (If data length < GPD buffer length, only use GPD) */ TGPD_SET_DataBUF_LEN(gpd, data_len); /* TGPD_SET_DataBUF_LEN(gpd, gpd_buf_size); */ /*Set "Transferred Data Length" = 0 */ TGPD_SET_BUF_LEN(gpd, 0); /*Default: bps=false */ if (bps) TGPD_SET_FORMAT_BPS(gpd); else TGPD_CLR_FORMAT_BPS(gpd); /*Default: ioc=true */ if (ioc) TGPD_SET_FORMAT_IOC(gpd); else TGPD_CLR_FORMAT_IOC(gpd); /*Get the next GPD */ Rx_gpd_end[ep_num] = get_gpd(USB_RX, ep_num); os_printk(K_INFO, "%s Rx_gpd_end[%d]=%p\n", __func__, ep_num, Tx_gpd_end[ep_num]); /*Initialize the new GPD */ os_memset(Rx_gpd_end[ep_num], 0, sizeof(TGPD)); /*Clear "HWO(Hardware Own)" flag */ TGPD_CLR_FLAGS_HWO(Rx_gpd_end[ep_num]); /*Set Next GDP pointer to the next GPD */ TGPD_SET_NEXT(gpd, (unsigned long)mu3d_hal_gpd_virt_to_phys(Rx_gpd_end[ep_num], USB_RX, ep_num)); /*Default: isHWO=true */ if (isHWO) { TGPD_SET_CHKSUM(gpd, CHECKSUM_LENGTH); /*Set GPD Checksum */ TGPD_SET_FLAGS_HWO(gpd); /*Set HWO flag */ } else { TGPD_CLR_FLAGS_HWO(gpd); TGPD_SET_CHKSUM_HWO(gpd, CHECKSUM_LENGTH); } /* os_printk(K_DEBUG,"Rx gpd info { HWO %d, Next_GPD %x ,DataBufferLength %d, * DataBuffer %x, Recived Len %d, Endpoint %d, TGL %d, ZLP %d}\n", */ /* (DEV_UINT32)TGPD_GET_FLAG(gpd), (DEV_UINT32)TGPD_GET_NEXT(gpd), */ /* (DEV_UINT32)TGPD_GET_DataBUF_LEN(gpd), (DEV_UINT32)TGPD_GET_DATA(gpd), */ /* (DEV_UINT32)TGPD_GET_BUF_LEN(gpd), (DEV_UINT32)TGPD_GET_EPaddr(gpd), */ /* (DEV_UINT32)TGPD_GET_TGL(gpd), (DEV_UINT32)TGPD_GET_ZLP(gpd)); */ /*Flush the data of GPD struct to device */ dma_sync_single_for_device(NULL, mu3d_hal_gpd_virt_to_phys(gpd, USB_RX, ep_num), sizeof(TGPD), DMA_BIDIRECTIONAL); return gpd; } /* * mu3d_hal_insert_transfer_gpd - insert new gpd/bd * @args - arg1: ep number, arg2: dir, arg3: data buffer, arg4: data length, * arg5: write hwo bit or not, arg6: write ioc bit or not */ void _ex_mu3d_hal_insert_transfer_gpd(DEV_INT32 ep_num, USB_DIR dir, dma_addr_t buf, DEV_UINT32 count, DEV_UINT8 isHWO, DEV_UINT8 ioc, DEV_UINT8 bps, DEV_UINT8 zlp, DEV_UINT32 maxp) { TGPD *gpd; if (dir == USB_TX) { gpd = Tx_gpd_end[ep_num]; _ex_mu3d_hal_prepare_tx_gpd(gpd, buf, count, ep_num, IS_BDP, isHWO, ioc, bps, zlp); } else if (dir == USB_RX) { gpd = Rx_gpd_end[ep_num]; _ex_mu3d_hal_prepare_rx_gpd(gpd, buf, count, ep_num, IS_BDP, isHWO, ioc, bps, maxp); } } void mu3d_hal_insert_transfer_gpd(DEV_INT32 ep_num, USB_DIR dir, dma_addr_t buf, DEV_UINT32 count, DEV_UINT8 isHWO, DEV_UINT8 ioc, DEV_UINT8 bps, DEV_UINT8 zlp, DEV_UINT32 maxp) { TGPD *gpd; if (dir == USB_TX) { gpd = Tx_gpd_end[ep_num]; /* os_printk(K_INFO,"TX gpd :%x\n", (unsigned int)gpd); */ mu3d_hal_prepare_tx_gpd(gpd, buf, count, ep_num, IS_BDP, isHWO, ioc, bps, zlp); } else if (dir == USB_RX) { gpd = Rx_gpd_end[ep_num]; /* os_printk(K_INFO,"RX gpd :%x\n",(unsigned int)gpd); */ mu3d_hal_prepare_rx_gpd(gpd, buf, count, ep_num, IS_BDP, isHWO, ioc, bps, maxp); } } /** * mu3d_hal_start_qmu - start qmu function (QMU flow : * mu3d_hal_init_qmu ->mu3d_hal_start_qmu -> mu3d_hal_insert_transfer_gpd -> mu3d_hal_resume_qmu) * @args - arg1: ep number, arg2: dir */ void mu3d_hal_start_qmu(DEV_INT32 Q_num, USB_DIR dir) { DEV_UINT32 QCR; DEV_UINT32 txcsr; if (dir == USB_TX) { txcsr = USB_ReadCsr32(U3D_TX1CSR0, Q_num) & 0xFFFEFFFF; USB_WriteCsr32(U3D_TX1CSR0, Q_num, txcsr | TX_DMAREQEN); QCR = os_readl(U3D_QCR0); os_writel(U3D_QCR0, QCR | QMU_TX_CS_EN(Q_num)); #if (TXZLP == HW_MODE) QCR = os_readl(U3D_QCR1); os_writel(U3D_QCR1, QCR & ~QMU_TX_ZLP(Q_num)); QCR = os_readl(U3D_QCR2); os_writel(U3D_QCR2, QCR | QMU_TX_ZLP(Q_num)); #elif (TXZLP == GPD_MODE) QCR = os_readl(U3D_QCR1); os_writel(U3D_QCR1, QCR | QMU_TX_ZLP(Q_num)); #endif os_writel(U3D_QEMIESR, os_readl(U3D_QEMIESR) | QMU_TX_EMPTY(Q_num)); os_writel(U3D_TQERRIESR0, QMU_TX_LEN_ERR(Q_num) | QMU_TX_CS_ERR(Q_num)); qmu_printk(K_INFO, "USB_QMU_TQCSR:0x%08X\n", os_readl(USB_QMU_TQCSR(Q_num))); if (os_readl(USB_QMU_TQCSR(Q_num)) & QMU_Q_ACTIVE) { qmu_printk(K_INFO, "Tx %d Active Now!\n", Q_num); return; } os_writel(USB_QMU_TQCSR(Q_num), QMU_Q_START); qmu_printk(K_INFO, "USB_QMU_TQCSR:0x%08X\n", os_readl(USB_QMU_TQCSR(Q_num))); } else if (dir == USB_RX) { USB_WriteCsr32(U3D_RX1CSR0, Q_num, USB_ReadCsr32(U3D_RX1CSR0, Q_num) | (RX_DMAREQEN)); QCR = os_readl(U3D_QCR0); os_writel(U3D_QCR0, QCR | QMU_RX_CS_EN(Q_num)); #ifdef CFG_RX_ZLP_EN QCR = os_readl(U3D_QCR3); os_writel(U3D_QCR3, QCR | QMU_RX_ZLP(Q_num)); #else QCR = os_readl(U3D_QCR3); os_writel(U3D_QCR3, QCR & ~(QMU_RX_ZLP(Q_num))); #endif #ifdef CFG_RX_COZ_EN QCR = os_readl(U3D_QCR3); os_writel(U3D_QCR3, QCR | QMU_RX_COZ(Q_num)); #else QCR = os_readl(U3D_QCR3); os_writel(U3D_QCR3, QCR & ~(QMU_RX_COZ(Q_num))); #endif os_writel(U3D_QEMIESR, os_readl(U3D_QEMIESR) | QMU_RX_EMPTY(Q_num)); os_writel(U3D_RQERRIESR0, QMU_RX_LEN_ERR(Q_num) | QMU_RX_CS_ERR(Q_num)); os_writel(U3D_RQERRIESR1, QMU_RX_EP_ERR(Q_num) | QMU_RX_ZLP_ERR(Q_num)); qmu_printk(K_INFO, "USB_QMU_RQCSR:0x%08X\n", os_readl(USB_QMU_RQCSR(Q_num))); if (os_readl(USB_QMU_RQCSR(Q_num)) & QMU_Q_ACTIVE) { qmu_printk(K_INFO, "Rx %d Active Now!\n", Q_num); return; } os_writel(USB_QMU_RQCSR(Q_num), QMU_Q_START); qmu_printk(K_INFO, "USB_QMU_RQCSR:0x%08X\n", os_readl(USB_QMU_RQCSR(Q_num))); } #if (CHECKSUM_TYPE == CS_16B) os_writel(U3D_QCR0, os_readl(U3D_QCR0) | CS16B_EN); #else os_writel(U3D_QCR0, os_readl(U3D_QCR0) & ~CS16B_EN); #endif } /** * mu3d_hal_stop_qmu - stop qmu function (after qmu stop, fifo should be flushed) * @args - arg1: ep number, arg2: dir */ void mu3d_hal_stop_qmu(DEV_INT32 q_num, USB_DIR dir) { if (dir == USB_TX) { if (!(os_readl(USB_QMU_TQCSR(q_num)) & (QMU_Q_ACTIVE))) { qmu_printk(K_CRIT, "Tx%d inActive Now!\n", q_num); return; } os_writel(USB_QMU_TQCSR(q_num), QMU_Q_STOP); mb(); if (wait_for_value(USB_QMU_TQCSR(q_num), QMU_Q_ACTIVE, 0, 10, 100) == RET_SUCCESS) qmu_printk(K_CRIT, "Tx%d stop Now! CSR=0x%x\n", q_num, os_readl(USB_QMU_TQCSR(q_num))); else { qmu_printk(K_CRIT, "Tx%d UNSTOPABLE!! CSR=0x%x\n", q_num, os_readl(USB_QMU_TQCSR(q_num))); WARN_ON(1); } } else if (dir == USB_RX) { if (!(os_readl(USB_QMU_RQCSR(q_num)) & QMU_Q_ACTIVE)) { qmu_printk(K_CRIT, "Rx%d inActive Now!\n", q_num); return; } os_writel(USB_QMU_RQCSR(q_num), QMU_Q_STOP); mb(); if (wait_for_value(USB_QMU_RQCSR(q_num), QMU_Q_ACTIVE, 0, 10, 100) == RET_SUCCESS) qmu_printk(K_CRIT, "Rx%d stop Now! CSR=0x%x\n", q_num, os_readl(USB_QMU_RQCSR(q_num))); else { qmu_printk(K_CRIT, "Rx%d UNSTOPABLE!! CSR=0x%x\n", q_num, os_readl(USB_QMU_RQCSR(q_num))); WARN_ON(1); } } } /** * mu3d_hal_send_stall - send stall * @args - arg1: ep number, arg2: dir */ void mu3d_hal_send_stall(DEV_INT32 q_num, USB_DIR dir) { if (dir == USB_TX) { USB_WriteCsr32(U3D_TX1CSR0, q_num, USB_ReadCsr32(U3D_TX1CSR0, q_num) | TX_SENDSTALL); while (!(USB_ReadCsr32(U3D_TX1CSR0, q_num) & TX_SENTSTALL)) ; USB_WriteCsr32(U3D_TX1CSR0, q_num, USB_ReadCsr32(U3D_TX1CSR0, q_num) | TX_SENTSTALL); USB_WriteCsr32(U3D_TX1CSR0, q_num, USB_ReadCsr32(U3D_TX1CSR0, q_num) & ~TX_SENDSTALL); } else if (dir == USB_RX) { USB_WriteCsr32(U3D_RX1CSR0, q_num, USB_ReadCsr32(U3D_RX1CSR0, q_num) | RX_SENDSTALL); while (!(USB_ReadCsr32(U3D_RX1CSR0, q_num) & RX_SENTSTALL)) ; USB_WriteCsr32(U3D_RX1CSR0, q_num, USB_ReadCsr32(U3D_RX1CSR0, q_num) | RX_SENTSTALL); USB_WriteCsr32(U3D_RX1CSR0, q_num, USB_ReadCsr32(U3D_RX1CSR0, q_num) & ~RX_SENDSTALL); } os_printk(K_CRIT, "%s %s-EP[%d] sent stall\n", __func__, ((dir == USB_TX) ? "TX" : "RX"), q_num); } /** * mu3d_hal_restart_qmu - clear toggle(or sequence) number and start qmu * @args - arg1: ep number, arg2: dir */ void mu3d_hal_restart_qmu(DEV_INT32 q_num, USB_DIR dir) { DEV_UINT32 ep_rst; qmu_printk(K_CRIT, "%s : Reset %s-EP[%d]\n", __func__, ((dir == USB_TX) ? "TX" : "RX"), q_num); if (dir == USB_TX) { ep_rst = BIT16 << q_num; os_writel(U3D_EP_RST, ep_rst); os_ms_delay(1); os_writel(U3D_EP_RST, 0); } else { ep_rst = 1 << q_num; os_writel(U3D_EP_RST, ep_rst); os_ms_delay(1); os_writel(U3D_EP_RST, 0); } mu3d_hal_start_qmu(q_num, dir); } /** * flush_qmu - stop qmu and align qmu start ptr t0 current ptr * @args - arg1: ep number, arg2: dir */ void _ex_mu3d_hal_flush_qmu(DEV_INT32 Q_num, USB_DIR dir) { TGPD *gpd_current; qmu_printk(K_CRIT, "%s flush QMU %s-EP[%d]\n", __func__, ((dir == USB_TX) ? "TX" : "RX"), Q_num); if (dir == USB_TX) { /*Stop QMU */ mu3d_hal_stop_qmu(Q_num, USB_TX); /*Get TX Queue Current Pointer Register */ /* QMU GPD address --> CPU DMA address */ gpd_current = (TGPD *) (uintptr_t) (os_readl(USB_QMU_TQCPR(Q_num))); /*If gpd_current = 0, it means QMU has not yet to execute GPD in QMU. */ if (!gpd_current) { /*Get TX Queue Starting Address Register */ /* QMU GPD address --> CPU DMA address */ gpd_current = (TGPD *) (uintptr_t) (os_readl(USB_QMU_TQSAR(Q_num))); } /* * Even if the GPD pointer got from SAR is corrupted. We should use the head of GPD list. * We know that Tx_gpd_head[Q_num] is always correct. */ if (!gpd_current) { gpd_current = Tx_gpd_head[Q_num]; qmu_printk(K_CRIT, "gpd is null, so use the head of GPD list %p\n", gpd_current); } else { /*Switch physical to virtual address */ qmu_printk(K_CRIT, "gpd_current(P) %p\n", gpd_current); gpd_current = gpd_phys_to_virt((void *)gpd_current, USB_TX, Q_num); qmu_printk(K_CRIT, "gpd_current(V) %p\n", (void *)gpd_current); } /*Reset the TX GPD list state */ Tx_gpd_end[Q_num] = Tx_gpd_last[Q_num] = gpd_current; gpd_ptr_align(dir, Q_num, Tx_gpd_end[Q_num]); free_gpd(dir, Q_num); /*FIXME: Do not know why... */ os_writel(USB_QMU_TQSAR(Q_num), mu3d_hal_gpd_virt_to_phys(Tx_gpd_last[Q_num], USB_TX, Q_num)); qmu_printk(K_ERR, "USB_QMU_TQSAR %x\n", os_readl(USB_QMU_TQSAR(Q_num))); } else if (dir == USB_RX) { /*Stop QMU */ mu3d_hal_stop_qmu(Q_num, USB_RX); /*Get RX Queue Current Pointer Register */ /* QMU GPD address --> CPU DMA address */ gpd_current = (TGPD *) (uintptr_t) (os_readl(USB_QMU_RQCPR(Q_num))); if (!gpd_current) { /*Get RX Queue Starting Address Register */ /* QMU GPD address --> CPU DMA address */ gpd_current = (TGPD *) (uintptr_t) (os_readl(USB_QMU_RQSAR(Q_num))); } /* * Even if the GPD pointer got from SAR is corrupted. We should use the head of GPD list. * We know that Rx_gpd_head[Q_num] is always correct. */ if (!gpd_current) { gpd_current = Rx_gpd_head[Q_num]; qmu_printk(K_CRIT, "gpd is null, so use the head of GPD list %p\n", gpd_current); } else { /*Switch physical to virtual address */ qmu_printk(K_CRIT, "gpd_current(P) %p\n", gpd_current); gpd_current = gpd_phys_to_virt((void *)gpd_current, USB_RX, Q_num); qmu_printk(K_CRIT, "gpd_current(V) %p\n", (void *)gpd_current); } /*Reset the RX GPD list state */ Rx_gpd_end[Q_num] = Rx_gpd_last[Q_num] = gpd_current; gpd_ptr_align(dir, Q_num, Rx_gpd_end[Q_num]); free_gpd(dir, Q_num); /*FIXME: Do not know why... */ os_writel(USB_QMU_RQSAR(Q_num), mu3d_hal_gpd_virt_to_phys(Rx_gpd_end[Q_num], USB_RX, Q_num)); qmu_printk(K_ERR, "USB_QMU_RQSAR %x\n", os_readl(USB_QMU_RQSAR(Q_num))); } } void mu3d_hal_flush_qmu(DEV_INT32 Q_num, USB_DIR dir) { TGPD *gpd_current; struct USB_REQ *req = mu3d_hal_get_req(Q_num, dir); os_printk(K_CRIT, "%s flush QMU %s\n", __func__, ((dir == USB_TX) ? "TX" : "RX")); if (dir == USB_TX) { /*Stop QMU */ mu3d_hal_stop_qmu(Q_num, USB_TX); /*Get TX Queue Current Pointer Register */ /* QMU GPD address --> CPU DMA address */ gpd_current = (TGPD *) (uintptr_t) (os_readl(USB_QMU_TQCPR(Q_num))); /*If gpd_current = 0, it means QMU has not yet to execute GPD in QMU. */ if (!gpd_current) { /*Get TX Queue Starting Address Register */ /* QMU GPD address --> CPU DMA address */ gpd_current = (TGPD *) (uintptr_t) (os_readl(USB_QMU_TQSAR(Q_num))); } /*Switch physical to virtual address */ os_printk(K_CRIT, "gpd_current(P) %p\n", gpd_current); gpd_current = gpd_phys_to_virt(gpd_current, USB_TX, Q_num); os_printk(K_CRIT, "gpd_current(V) %p\n", gpd_current); /*Reset the TX GPD list state */ Tx_gpd_end[Q_num] = Tx_gpd_last[Q_num] = gpd_current; gpd_ptr_align(dir, Q_num, Tx_gpd_end[Q_num]); free_gpd(dir, Q_num); /*FIXME: Do not know why... */ os_writel(USB_QMU_TQSAR(Q_num), mu3d_hal_gpd_virt_to_phys(Tx_gpd_last[Q_num], USB_TX, Q_num)); os_printk(K_ERR, "USB_QMU_TQSAR %x\n", os_readl(USB_QMU_TQSAR(Q_num))); req->complete = true; /* os_printk(K_ERR,"TxQ %d Flush Now!\n", Q_num); */ } else if (dir == USB_RX) { /*Stop QMU */ mu3d_hal_stop_qmu(Q_num, USB_RX); /*Get RX Queue Current Pointer Register */ /* QMU GPD address --> CPU DMA address */ gpd_current = (TGPD *) (uintptr_t) (os_readl(USB_QMU_RQCPR(Q_num))); if (!gpd_current) { /*Get RX Queue Starting Address Register */ /* QMU GPD address --> CPU DMA address */ gpd_current = (TGPD *) (uintptr_t) (os_readl(USB_QMU_RQSAR(Q_num))); } /*Switch physical to virtual address */ os_printk(K_CRIT, "gpd_current(P) %p\n", gpd_current); gpd_current = gpd_phys_to_virt(gpd_current, USB_RX, Q_num); os_printk(K_CRIT, "gpd_current(V) %p\n", gpd_current); /*Reset the RX GPD list state */ Rx_gpd_end[Q_num] = Rx_gpd_last[Q_num] = gpd_current; gpd_ptr_align(dir, Q_num, Rx_gpd_end[Q_num]); free_gpd(dir, Q_num); /*FIXME: Do not know why... */ os_writel(USB_QMU_RQSAR(Q_num), mu3d_hal_gpd_virt_to_phys(Rx_gpd_end[Q_num], USB_RX, Q_num)); os_printk(K_ERR, "USB_QMU_RQSAR %x\n", os_readl(USB_QMU_RQSAR(Q_num))); req->complete = true; /* os_printk(K_ERR,"RxQ %d Flush Now!\n", Q_num); */ } } #endif