Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Chunfeng Yun | 5062 | 99.86% | 34 | 87.18% |
Ben Dooks | 3 | 0.06% | 1 | 2.56% |
Greg Kroah-Hartman | 2 | 0.04% | 2 | 5.13% |
Lee Jones | 1 | 0.02% | 1 | 2.56% |
Sudip Mukherjee | 1 | 0.02% | 1 | 2.56% |
Total | 5069 | 39 |
// SPDX-License-Identifier: GPL-2.0 /* * mtu3_core.c - hardware access layer and gadget init/exit of * MediaTek usb3 Dual-Role Controller Driver * * Copyright (C) 2016 MediaTek Inc. * * Author: Chunfeng Yun <chunfeng.yun@mediatek.com> */ #include <linux/dma-mapping.h> #include <linux/kernel.h> #include <linux/module.h> #include <linux/of_address.h> #include <linux/of_irq.h> #include <linux/platform_device.h> #include "mtu3.h" #include "mtu3_dr.h" #include "mtu3_debug.h" #include "mtu3_trace.h" static int ep_fifo_alloc(struct mtu3_ep *mep, u32 seg_size) { struct mtu3_fifo_info *fifo = mep->fifo; u32 num_bits = DIV_ROUND_UP(seg_size, MTU3_EP_FIFO_UNIT); u32 start_bit; /* ensure that @mep->fifo_seg_size is power of two */ num_bits = roundup_pow_of_two(num_bits); if (num_bits > fifo->limit) return -EINVAL; mep->fifo_seg_size = num_bits * MTU3_EP_FIFO_UNIT; num_bits = num_bits * (mep->slot + 1); start_bit = bitmap_find_next_zero_area(fifo->bitmap, fifo->limit, 0, num_bits, 0); if (start_bit >= fifo->limit) return -EOVERFLOW; bitmap_set(fifo->bitmap, start_bit, num_bits); mep->fifo_size = num_bits * MTU3_EP_FIFO_UNIT; mep->fifo_addr = fifo->base + MTU3_EP_FIFO_UNIT * start_bit; dev_dbg(mep->mtu->dev, "%s fifo:%#x/%#x, start_bit: %d\n", __func__, mep->fifo_seg_size, mep->fifo_size, start_bit); return mep->fifo_addr; } static void ep_fifo_free(struct mtu3_ep *mep) { struct mtu3_fifo_info *fifo = mep->fifo; u32 addr = mep->fifo_addr; u32 bits = mep->fifo_size / MTU3_EP_FIFO_UNIT; u32 start_bit; if (unlikely(addr < fifo->base || bits > fifo->limit)) return; start_bit = (addr - fifo->base) / MTU3_EP_FIFO_UNIT; bitmap_clear(fifo->bitmap, start_bit, bits); mep->fifo_size = 0; mep->fifo_seg_size = 0; dev_dbg(mep->mtu->dev, "%s size:%#x/%#x, start_bit: %d\n", __func__, mep->fifo_seg_size, mep->fifo_size, start_bit); } /* enable/disable U3D SS function */ static inline void mtu3_ss_func_set(struct mtu3 *mtu, bool enable) { /* If usb3_en==0, LTSSM will go to SS.Disable state */ if (enable) mtu3_setbits(mtu->mac_base, U3D_USB3_CONFIG, USB3_EN); else mtu3_clrbits(mtu->mac_base, U3D_USB3_CONFIG, USB3_EN); dev_dbg(mtu->dev, "USB3_EN = %d\n", !!enable); } /* set/clear U3D HS device soft connect */ static inline void mtu3_hs_softconn_set(struct mtu3 *mtu, bool enable) { if (enable) { mtu3_setbits(mtu->mac_base, U3D_POWER_MANAGEMENT, SOFT_CONN | SUSPENDM_ENABLE); } else { mtu3_clrbits(mtu->mac_base, U3D_POWER_MANAGEMENT, SOFT_CONN | SUSPENDM_ENABLE); } dev_dbg(mtu->dev, "SOFTCONN = %d\n", !!enable); } /* only port0 of U2/U3 supports device mode */ static int mtu3_device_enable(struct mtu3 *mtu) { void __iomem *ibase = mtu->ippc_base; u32 check_clk = 0; mtu3_clrbits(ibase, U3D_SSUSB_IP_PW_CTRL2, SSUSB_IP_DEV_PDN); if (mtu->u3_capable) { check_clk = SSUSB_U3_MAC_RST_B_STS; mtu3_clrbits(ibase, SSUSB_U3_CTRL(0), (SSUSB_U3_PORT_DIS | SSUSB_U3_PORT_PDN | SSUSB_U3_PORT_HOST_SEL)); } mtu3_clrbits(ibase, SSUSB_U2_CTRL(0), (SSUSB_U2_PORT_DIS | SSUSB_U2_PORT_PDN | SSUSB_U2_PORT_HOST_SEL)); if (mtu->ssusb->dr_mode == USB_DR_MODE_OTG) { mtu3_setbits(ibase, SSUSB_U2_CTRL(0), SSUSB_U2_PORT_OTG_SEL); if (mtu->u3_capable) mtu3_setbits(ibase, SSUSB_U3_CTRL(0), SSUSB_U3_PORT_DUAL_MODE); } return ssusb_check_clocks(mtu->ssusb, check_clk); } static void mtu3_device_disable(struct mtu3 *mtu) { void __iomem *ibase = mtu->ippc_base; if (mtu->u3_capable) mtu3_setbits(ibase, SSUSB_U3_CTRL(0), (SSUSB_U3_PORT_DIS | SSUSB_U3_PORT_PDN)); mtu3_setbits(ibase, SSUSB_U2_CTRL(0), SSUSB_U2_PORT_DIS | SSUSB_U2_PORT_PDN); if (mtu->ssusb->dr_mode == USB_DR_MODE_OTG) { mtu3_clrbits(ibase, SSUSB_U2_CTRL(0), SSUSB_U2_PORT_OTG_SEL); if (mtu->u3_capable) mtu3_clrbits(ibase, SSUSB_U3_CTRL(0), SSUSB_U3_PORT_DUAL_MODE); } mtu3_setbits(ibase, U3D_SSUSB_IP_PW_CTRL2, SSUSB_IP_DEV_PDN); } static void mtu3_dev_power_on(struct mtu3 *mtu) { void __iomem *ibase = mtu->ippc_base; mtu3_clrbits(ibase, U3D_SSUSB_IP_PW_CTRL2, SSUSB_IP_DEV_PDN); if (mtu->u3_capable) mtu3_clrbits(ibase, SSUSB_U3_CTRL(0), SSUSB_U3_PORT_PDN); mtu3_clrbits(ibase, SSUSB_U2_CTRL(0), SSUSB_U2_PORT_PDN); } static void mtu3_dev_power_down(struct mtu3 *mtu) { void __iomem *ibase = mtu->ippc_base; if (mtu->u3_capable) mtu3_setbits(ibase, SSUSB_U3_CTRL(0), SSUSB_U3_PORT_PDN); mtu3_setbits(ibase, SSUSB_U2_CTRL(0), SSUSB_U2_PORT_PDN); mtu3_setbits(ibase, U3D_SSUSB_IP_PW_CTRL2, SSUSB_IP_DEV_PDN); } /* reset U3D's device module. */ static void mtu3_device_reset(struct mtu3 *mtu) { void __iomem *ibase = mtu->ippc_base; mtu3_setbits(ibase, U3D_SSUSB_DEV_RST_CTRL, SSUSB_DEV_SW_RST); udelay(1); mtu3_clrbits(ibase, U3D_SSUSB_DEV_RST_CTRL, SSUSB_DEV_SW_RST); } static void mtu3_intr_status_clear(struct mtu3 *mtu) { void __iomem *mbase = mtu->mac_base; /* Clear EP0 and Tx/Rx EPn interrupts status */ mtu3_writel(mbase, U3D_EPISR, ~0x0); /* Clear U2 USB common interrupts status */ mtu3_writel(mbase, U3D_COMMON_USB_INTR, ~0x0); /* Clear U3 LTSSM interrupts status */ mtu3_writel(mbase, U3D_LTSSM_INTR, ~0x0); /* Clear speed change interrupt status */ mtu3_writel(mbase, U3D_DEV_LINK_INTR, ~0x0); /* Clear QMU interrupt status */ mtu3_writel(mbase, U3D_QISAR0, ~0x0); } /* disable all interrupts */ static void mtu3_intr_disable(struct mtu3 *mtu) { /* Disable level 1 interrupts */ mtu3_writel(mtu->mac_base, U3D_LV1IECR, ~0x0); /* Disable endpoint interrupts */ mtu3_writel(mtu->mac_base, U3D_EPIECR, ~0x0); mtu3_intr_status_clear(mtu); } /* enable system global interrupt */ static void mtu3_intr_enable(struct mtu3 *mtu) { void __iomem *mbase = mtu->mac_base; u32 value; /*Enable level 1 interrupts (BMU, QMU, MAC3, DMA, MAC2, EPCTL) */ value = BMU_INTR | QMU_INTR | MAC3_INTR | MAC2_INTR | EP_CTRL_INTR; mtu3_writel(mbase, U3D_LV1IESR, value); /* Enable U2 common USB interrupts */ value = SUSPEND_INTR | RESUME_INTR | RESET_INTR; mtu3_writel(mbase, U3D_COMMON_USB_INTR_ENABLE, value); if (mtu->u3_capable) { /* Enable U3 LTSSM interrupts */ value = HOT_RST_INTR | WARM_RST_INTR | ENTER_U3_INTR | EXIT_U3_INTR; mtu3_writel(mbase, U3D_LTSSM_INTR_ENABLE, value); } /* Enable QMU interrupts. */ value = TXQ_CSERR_INT | TXQ_LENERR_INT | RXQ_CSERR_INT | RXQ_LENERR_INT | RXQ_ZLPERR_INT; mtu3_writel(mbase, U3D_QIESR1, value); /* Enable speed change interrupt */ mtu3_writel(mbase, U3D_DEV_LINK_INTR_ENABLE, SSUSB_DEV_SPEED_CHG_INTR); } static void mtu3_set_speed(struct mtu3 *mtu, enum usb_device_speed speed) { void __iomem *mbase = mtu->mac_base; if (speed > mtu->max_speed) speed = mtu->max_speed; switch (speed) { case USB_SPEED_FULL: /* disable U3 SS function */ mtu3_clrbits(mbase, U3D_USB3_CONFIG, USB3_EN); /* disable HS function */ mtu3_clrbits(mbase, U3D_POWER_MANAGEMENT, HS_ENABLE); break; case USB_SPEED_HIGH: mtu3_clrbits(mbase, U3D_USB3_CONFIG, USB3_EN); /* HS/FS detected by HW */ mtu3_setbits(mbase, U3D_POWER_MANAGEMENT, HS_ENABLE); break; case USB_SPEED_SUPER: mtu3_setbits(mbase, U3D_POWER_MANAGEMENT, HS_ENABLE); mtu3_clrbits(mtu->ippc_base, SSUSB_U3_CTRL(0), SSUSB_U3_PORT_SSP_SPEED); break; case USB_SPEED_SUPER_PLUS: mtu3_setbits(mbase, U3D_POWER_MANAGEMENT, HS_ENABLE); mtu3_setbits(mtu->ippc_base, SSUSB_U3_CTRL(0), SSUSB_U3_PORT_SSP_SPEED); break; default: dev_err(mtu->dev, "invalid speed: %s\n", usb_speed_string(speed)); return; } mtu->speed = speed; dev_dbg(mtu->dev, "set speed: %s\n", usb_speed_string(speed)); } /* CSR registers will be reset to default value if port is disabled */ static void mtu3_csr_init(struct mtu3 *mtu) { void __iomem *mbase = mtu->mac_base; if (mtu->u3_capable) { /* disable LGO_U1/U2 by default */ mtu3_clrbits(mbase, U3D_LINK_POWER_CONTROL, SW_U1_REQUEST_ENABLE | SW_U2_REQUEST_ENABLE); /* enable accept LGO_U1/U2 link command from host */ mtu3_setbits(mbase, U3D_LINK_POWER_CONTROL, SW_U1_ACCEPT_ENABLE | SW_U2_ACCEPT_ENABLE); /* device responses to u3_exit from host automatically */ mtu3_clrbits(mbase, U3D_LTSSM_CTRL, SOFT_U3_EXIT_EN); /* automatically build U2 link when U3 detect fail */ mtu3_setbits(mbase, U3D_USB2_TEST_MODE, U2U3_AUTO_SWITCH); /* auto clear SOFT_CONN when clear USB3_EN if work as HS */ mtu3_setbits(mbase, U3D_U3U2_SWITCH_CTRL, SOFTCON_CLR_AUTO_EN); } /* delay about 0.1us from detecting reset to send chirp-K */ mtu3_clrbits(mbase, U3D_LINK_RESET_INFO, WTCHRP_MSK); /* enable automatical HWRW from L1 */ mtu3_setbits(mbase, U3D_POWER_MANAGEMENT, LPM_HRWE); } /* reset: u2 - data toggle, u3 - SeqN, flow control status etc */ static void mtu3_ep_reset(struct mtu3_ep *mep) { struct mtu3 *mtu = mep->mtu; u32 rst_bit = EP_RST(mep->is_in, mep->epnum); mtu3_setbits(mtu->mac_base, U3D_EP_RST, rst_bit); mtu3_clrbits(mtu->mac_base, U3D_EP_RST, rst_bit); } /* set/clear the stall and toggle bits for non-ep0 */ void mtu3_ep_stall_set(struct mtu3_ep *mep, bool set) { struct mtu3 *mtu = mep->mtu; void __iomem *mbase = mtu->mac_base; u8 epnum = mep->epnum; u32 csr; if (mep->is_in) { /* TX */ csr = mtu3_readl(mbase, MU3D_EP_TXCR0(epnum)) & TX_W1C_BITS; if (set) csr |= TX_SENDSTALL; else csr = (csr & (~TX_SENDSTALL)) | TX_SENTSTALL; mtu3_writel(mbase, MU3D_EP_TXCR0(epnum), csr); } else { /* RX */ csr = mtu3_readl(mbase, MU3D_EP_RXCR0(epnum)) & RX_W1C_BITS; if (set) csr |= RX_SENDSTALL; else csr = (csr & (~RX_SENDSTALL)) | RX_SENTSTALL; mtu3_writel(mbase, MU3D_EP_RXCR0(epnum), csr); } if (!set) { mtu3_ep_reset(mep); mep->flags &= ~MTU3_EP_STALL; } else { mep->flags |= MTU3_EP_STALL; } dev_dbg(mtu->dev, "%s: %s\n", mep->name, set ? "SEND STALL" : "CLEAR STALL, with EP RESET"); } void mtu3_dev_on_off(struct mtu3 *mtu, int is_on) { if (mtu->u3_capable && mtu->speed >= USB_SPEED_SUPER) mtu3_ss_func_set(mtu, is_on); else mtu3_hs_softconn_set(mtu, is_on); dev_info(mtu->dev, "gadget (%s) pullup D%s\n", usb_speed_string(mtu->speed), is_on ? "+" : "-"); } void mtu3_start(struct mtu3 *mtu) { void __iomem *mbase = mtu->mac_base; dev_dbg(mtu->dev, "%s devctl 0x%x\n", __func__, mtu3_readl(mbase, U3D_DEVICE_CONTROL)); mtu3_dev_power_on(mtu); mtu3_csr_init(mtu); mtu3_set_speed(mtu, mtu->speed); /* Initialize the default interrupts */ mtu3_intr_enable(mtu); mtu->is_active = 1; if (mtu->softconnect) mtu3_dev_on_off(mtu, 1); } void mtu3_stop(struct mtu3 *mtu) { dev_dbg(mtu->dev, "%s\n", __func__); mtu3_intr_disable(mtu); if (mtu->softconnect) mtu3_dev_on_off(mtu, 0); mtu->is_active = 0; mtu3_dev_power_down(mtu); } static void mtu3_dev_suspend(struct mtu3 *mtu) { if (!mtu->is_active) return; mtu3_intr_disable(mtu); mtu3_dev_power_down(mtu); } static void mtu3_dev_resume(struct mtu3 *mtu) { if (!mtu->is_active) return; mtu3_dev_power_on(mtu); mtu3_intr_enable(mtu); } /* for non-ep0 */ int mtu3_config_ep(struct mtu3 *mtu, struct mtu3_ep *mep, int interval, int burst, int mult) { void __iomem *mbase = mtu->mac_base; bool gen2cp = mtu->gen2cp; int epnum = mep->epnum; u32 csr0, csr1, csr2; int fifo_sgsz, fifo_addr; int num_pkts; fifo_addr = ep_fifo_alloc(mep, mep->maxp); if (fifo_addr < 0) { dev_err(mtu->dev, "alloc ep fifo failed(%d)\n", mep->maxp); return -ENOMEM; } fifo_sgsz = ilog2(mep->fifo_seg_size); dev_dbg(mtu->dev, "%s fifosz: %x(%x/%x)\n", __func__, fifo_sgsz, mep->fifo_seg_size, mep->fifo_size); if (mep->is_in) { csr0 = TX_TXMAXPKTSZ(mep->maxp); csr0 |= TX_DMAREQEN; num_pkts = (burst + 1) * (mult + 1) - 1; csr1 = TX_SS_BURST(burst) | TX_SLOT(mep->slot); csr1 |= TX_MAX_PKT(gen2cp, num_pkts) | TX_MULT(gen2cp, mult); csr2 = TX_FIFOADDR(fifo_addr >> 4); csr2 |= TX_FIFOSEGSIZE(fifo_sgsz); switch (mep->type) { case USB_ENDPOINT_XFER_BULK: csr1 |= TX_TYPE(TYPE_BULK); break; case USB_ENDPOINT_XFER_ISOC: csr1 |= TX_TYPE(TYPE_ISO); csr2 |= TX_BINTERVAL(interval); break; case USB_ENDPOINT_XFER_INT: csr1 |= TX_TYPE(TYPE_INT); csr2 |= TX_BINTERVAL(interval); break; } /* Enable QMU Done interrupt */ mtu3_setbits(mbase, U3D_QIESR0, QMU_TX_DONE_INT(epnum)); mtu3_writel(mbase, MU3D_EP_TXCR0(epnum), csr0); mtu3_writel(mbase, MU3D_EP_TXCR1(epnum), csr1); mtu3_writel(mbase, MU3D_EP_TXCR2(epnum), csr2); dev_dbg(mtu->dev, "U3D_TX%d CSR0:%#x, CSR1:%#x, CSR2:%#x\n", epnum, mtu3_readl(mbase, MU3D_EP_TXCR0(epnum)), mtu3_readl(mbase, MU3D_EP_TXCR1(epnum)), mtu3_readl(mbase, MU3D_EP_TXCR2(epnum))); } else { csr0 = RX_RXMAXPKTSZ(mep->maxp); csr0 |= RX_DMAREQEN; num_pkts = (burst + 1) * (mult + 1) - 1; csr1 = RX_SS_BURST(burst) | RX_SLOT(mep->slot); csr1 |= RX_MAX_PKT(gen2cp, num_pkts) | RX_MULT(gen2cp, mult); csr2 = RX_FIFOADDR(fifo_addr >> 4); csr2 |= RX_FIFOSEGSIZE(fifo_sgsz); switch (mep->type) { case USB_ENDPOINT_XFER_BULK: csr1 |= RX_TYPE(TYPE_BULK); break; case USB_ENDPOINT_XFER_ISOC: csr1 |= RX_TYPE(TYPE_ISO); csr2 |= RX_BINTERVAL(interval); break; case USB_ENDPOINT_XFER_INT: csr1 |= RX_TYPE(TYPE_INT); csr2 |= RX_BINTERVAL(interval); break; } /*Enable QMU Done interrupt */ mtu3_setbits(mbase, U3D_QIESR0, QMU_RX_DONE_INT(epnum)); mtu3_writel(mbase, MU3D_EP_RXCR0(epnum), csr0); mtu3_writel(mbase, MU3D_EP_RXCR1(epnum), csr1); mtu3_writel(mbase, MU3D_EP_RXCR2(epnum), csr2); dev_dbg(mtu->dev, "U3D_RX%d CSR0:%#x, CSR1:%#x, CSR2:%#x\n", epnum, mtu3_readl(mbase, MU3D_EP_RXCR0(epnum)), mtu3_readl(mbase, MU3D_EP_RXCR1(epnum)), mtu3_readl(mbase, MU3D_EP_RXCR2(epnum))); } dev_dbg(mtu->dev, "csr0:%#x, csr1:%#x, csr2:%#x\n", csr0, csr1, csr2); dev_dbg(mtu->dev, "%s: %s, fifo-addr:%#x, fifo-size:%#x(%#x/%#x)\n", __func__, mep->name, mep->fifo_addr, mep->fifo_size, fifo_sgsz, mep->fifo_seg_size); return 0; } /* for non-ep0 */ void mtu3_deconfig_ep(struct mtu3 *mtu, struct mtu3_ep *mep) { void __iomem *mbase = mtu->mac_base; int epnum = mep->epnum; if (mep->is_in) { mtu3_writel(mbase, MU3D_EP_TXCR0(epnum), 0); mtu3_writel(mbase, MU3D_EP_TXCR1(epnum), 0); mtu3_writel(mbase, MU3D_EP_TXCR2(epnum), 0); mtu3_setbits(mbase, U3D_QIECR0, QMU_TX_DONE_INT(epnum)); } else { mtu3_writel(mbase, MU3D_EP_RXCR0(epnum), 0); mtu3_writel(mbase, MU3D_EP_RXCR1(epnum), 0); mtu3_writel(mbase, MU3D_EP_RXCR2(epnum), 0); mtu3_setbits(mbase, U3D_QIECR0, QMU_RX_DONE_INT(epnum)); } mtu3_ep_reset(mep); ep_fifo_free(mep); dev_dbg(mtu->dev, "%s: %s\n", __func__, mep->name); } /* * Two scenarios: * 1. when device IP supports SS, the fifo of EP0, TX EPs, RX EPs * are separated; * 2. when supports only HS, the fifo is shared for all EPs, and * the capability registers of @EPNTXFFSZ or @EPNRXFFSZ indicate * the total fifo size of non-ep0, and ep0's is fixed to 64B, * so the total fifo size is 64B + @EPNTXFFSZ; * Due to the first 64B should be reserved for EP0, non-ep0's fifo * starts from offset 64 and are divided into two equal parts for * TX or RX EPs for simplification. */ static void get_ep_fifo_config(struct mtu3 *mtu) { struct mtu3_fifo_info *tx_fifo; struct mtu3_fifo_info *rx_fifo; u32 fifosize; if (mtu->separate_fifo) { fifosize = mtu3_readl(mtu->mac_base, U3D_CAP_EPNTXFFSZ); tx_fifo = &mtu->tx_fifo; tx_fifo->base = 0; tx_fifo->limit = fifosize / MTU3_EP_FIFO_UNIT; bitmap_zero(tx_fifo->bitmap, MTU3_FIFO_BIT_SIZE); fifosize = mtu3_readl(mtu->mac_base, U3D_CAP_EPNRXFFSZ); rx_fifo = &mtu->rx_fifo; rx_fifo->base = 0; rx_fifo->limit = fifosize / MTU3_EP_FIFO_UNIT; bitmap_zero(rx_fifo->bitmap, MTU3_FIFO_BIT_SIZE); mtu->slot = MTU3_U3_IP_SLOT_DEFAULT; } else { fifosize = mtu3_readl(mtu->mac_base, U3D_CAP_EPNTXFFSZ); tx_fifo = &mtu->tx_fifo; tx_fifo->base = MTU3_U2_IP_EP0_FIFO_SIZE; tx_fifo->limit = (fifosize / MTU3_EP_FIFO_UNIT) >> 1; bitmap_zero(tx_fifo->bitmap, MTU3_FIFO_BIT_SIZE); rx_fifo = &mtu->rx_fifo; rx_fifo->base = tx_fifo->base + tx_fifo->limit * MTU3_EP_FIFO_UNIT; rx_fifo->limit = tx_fifo->limit; bitmap_zero(rx_fifo->bitmap, MTU3_FIFO_BIT_SIZE); mtu->slot = MTU3_U2_IP_SLOT_DEFAULT; } dev_dbg(mtu->dev, "%s, TX: base-%d, limit-%d; RX: base-%d, limit-%d\n", __func__, tx_fifo->base, tx_fifo->limit, rx_fifo->base, rx_fifo->limit); } static void mtu3_ep0_setup(struct mtu3 *mtu) { u32 maxpacket = mtu->g.ep0->maxpacket; u32 csr; dev_dbg(mtu->dev, "%s maxpacket: %d\n", __func__, maxpacket); csr = mtu3_readl(mtu->mac_base, U3D_EP0CSR); csr &= ~EP0_MAXPKTSZ_MSK; csr |= EP0_MAXPKTSZ(maxpacket); csr &= EP0_W1C_BITS; mtu3_writel(mtu->mac_base, U3D_EP0CSR, csr); /* Enable EP0 interrupt */ mtu3_writel(mtu->mac_base, U3D_EPIESR, EP0ISR | SETUPENDISR); } static int mtu3_mem_alloc(struct mtu3 *mtu) { void __iomem *mbase = mtu->mac_base; struct mtu3_ep *ep_array; int in_ep_num, out_ep_num; u32 cap_epinfo; int ret; int i; cap_epinfo = mtu3_readl(mbase, U3D_CAP_EPINFO); in_ep_num = CAP_TX_EP_NUM(cap_epinfo); out_ep_num = CAP_RX_EP_NUM(cap_epinfo); dev_info(mtu->dev, "fifosz/epnum: Tx=%#x/%d, Rx=%#x/%d\n", mtu3_readl(mbase, U3D_CAP_EPNTXFFSZ), in_ep_num, mtu3_readl(mbase, U3D_CAP_EPNRXFFSZ), out_ep_num); /* one for ep0, another is reserved */ mtu->num_eps = min(in_ep_num, out_ep_num) + 1; ep_array = kcalloc(mtu->num_eps * 2, sizeof(*ep_array), GFP_KERNEL); if (ep_array == NULL) return -ENOMEM; mtu->ep_array = ep_array; mtu->in_eps = ep_array; mtu->out_eps = &ep_array[mtu->num_eps]; /* ep0 uses in_eps[0], out_eps[0] is reserved */ mtu->ep0 = mtu->in_eps; mtu->ep0->mtu = mtu; mtu->ep0->epnum = 0; for (i = 1; i < mtu->num_eps; i++) { struct mtu3_ep *mep = mtu->in_eps + i; mep->fifo = &mtu->tx_fifo; mep = mtu->out_eps + i; mep->fifo = &mtu->rx_fifo; } get_ep_fifo_config(mtu); ret = mtu3_qmu_init(mtu); if (ret) kfree(mtu->ep_array); return ret; } static void mtu3_mem_free(struct mtu3 *mtu) { mtu3_qmu_exit(mtu); kfree(mtu->ep_array); } static void mtu3_regs_init(struct mtu3 *mtu) { void __iomem *mbase = mtu->mac_base; /* be sure interrupts are disabled before registration of ISR */ mtu3_intr_disable(mtu); mtu3_csr_init(mtu); /* U2/U3 detected by HW */ mtu3_writel(mbase, U3D_DEVICE_CONF, 0); /* vbus detected by HW */ mtu3_clrbits(mbase, U3D_MISC_CTRL, VBUS_FRC_EN | VBUS_ON); /* use new QMU format when HW version >= 0x1003 */ if (mtu->gen2cp) mtu3_writel(mbase, U3D_QFCR, ~0x0); } static irqreturn_t mtu3_link_isr(struct mtu3 *mtu) { void __iomem *mbase = mtu->mac_base; enum usb_device_speed udev_speed; u32 maxpkt = 64; u32 link; u32 speed; link = mtu3_readl(mbase, U3D_DEV_LINK_INTR); link &= mtu3_readl(mbase, U3D_DEV_LINK_INTR_ENABLE); mtu3_writel(mbase, U3D_DEV_LINK_INTR, link); /* W1C */ dev_dbg(mtu->dev, "=== LINK[%x] ===\n", link); if (!(link & SSUSB_DEV_SPEED_CHG_INTR)) return IRQ_NONE; speed = SSUSB_DEV_SPEED(mtu3_readl(mbase, U3D_DEVICE_CONF)); switch (speed) { case MTU3_SPEED_FULL: udev_speed = USB_SPEED_FULL; /*BESLCK = 4 < BESLCK_U3 = 10 < BESLDCK = 15 */ mtu3_writel(mbase, U3D_USB20_LPM_PARAMETER, LPM_BESLDCK(0xf) | LPM_BESLCK(4) | LPM_BESLCK_U3(0xa)); mtu3_setbits(mbase, U3D_POWER_MANAGEMENT, LPM_BESL_STALL | LPM_BESLD_STALL); break; case MTU3_SPEED_HIGH: udev_speed = USB_SPEED_HIGH; /*BESLCK = 4 < BESLCK_U3 = 10 < BESLDCK = 15 */ mtu3_writel(mbase, U3D_USB20_LPM_PARAMETER, LPM_BESLDCK(0xf) | LPM_BESLCK(4) | LPM_BESLCK_U3(0xa)); mtu3_setbits(mbase, U3D_POWER_MANAGEMENT, LPM_BESL_STALL | LPM_BESLD_STALL); break; case MTU3_SPEED_SUPER: udev_speed = USB_SPEED_SUPER; maxpkt = 512; break; case MTU3_SPEED_SUPER_PLUS: udev_speed = USB_SPEED_SUPER_PLUS; maxpkt = 512; break; default: udev_speed = USB_SPEED_UNKNOWN; break; } dev_dbg(mtu->dev, "%s: %s\n", __func__, usb_speed_string(udev_speed)); mtu3_dbg_trace(mtu->dev, "link speed %s", usb_speed_string(udev_speed)); mtu->g.speed = udev_speed; mtu->g.ep0->maxpacket = maxpkt; mtu->ep0_state = MU3D_EP0_STATE_SETUP; mtu->connected = !!(udev_speed != USB_SPEED_UNKNOWN); if (udev_speed == USB_SPEED_UNKNOWN) { mtu3_gadget_disconnect(mtu); pm_runtime_put(mtu->dev); } else { pm_runtime_get(mtu->dev); mtu3_ep0_setup(mtu); } return IRQ_HANDLED; } static irqreturn_t mtu3_u3_ltssm_isr(struct mtu3 *mtu) { void __iomem *mbase = mtu->mac_base; u32 ltssm; ltssm = mtu3_readl(mbase, U3D_LTSSM_INTR); ltssm &= mtu3_readl(mbase, U3D_LTSSM_INTR_ENABLE); mtu3_writel(mbase, U3D_LTSSM_INTR, ltssm); /* W1C */ dev_dbg(mtu->dev, "=== LTSSM[%x] ===\n", ltssm); trace_mtu3_u3_ltssm_isr(ltssm); if (ltssm & (HOT_RST_INTR | WARM_RST_INTR)) mtu3_gadget_reset(mtu); if (ltssm & VBUS_FALL_INTR) { mtu3_ss_func_set(mtu, false); mtu3_gadget_reset(mtu); } if (ltssm & VBUS_RISE_INTR) mtu3_ss_func_set(mtu, true); if (ltssm & EXIT_U3_INTR) mtu3_gadget_resume(mtu); if (ltssm & ENTER_U3_INTR) mtu3_gadget_suspend(mtu); return IRQ_HANDLED; } static irqreturn_t mtu3_u2_common_isr(struct mtu3 *mtu) { void __iomem *mbase = mtu->mac_base; u32 u2comm; u2comm = mtu3_readl(mbase, U3D_COMMON_USB_INTR); u2comm &= mtu3_readl(mbase, U3D_COMMON_USB_INTR_ENABLE); mtu3_writel(mbase, U3D_COMMON_USB_INTR, u2comm); /* W1C */ dev_dbg(mtu->dev, "=== U2COMM[%x] ===\n", u2comm); trace_mtu3_u2_common_isr(u2comm); if (u2comm & SUSPEND_INTR) mtu3_gadget_suspend(mtu); if (u2comm & RESUME_INTR) mtu3_gadget_resume(mtu); if (u2comm & RESET_INTR) mtu3_gadget_reset(mtu); return IRQ_HANDLED; } static irqreturn_t mtu3_irq(int irq, void *data) { struct mtu3 *mtu = (struct mtu3 *)data; unsigned long flags; u32 level1; spin_lock_irqsave(&mtu->lock, flags); /* U3D_LV1ISR is RU */ level1 = mtu3_readl(mtu->mac_base, U3D_LV1ISR); level1 &= mtu3_readl(mtu->mac_base, U3D_LV1IER); if (level1 & EP_CTRL_INTR) mtu3_link_isr(mtu); if (level1 & MAC2_INTR) mtu3_u2_common_isr(mtu); if (level1 & MAC3_INTR) mtu3_u3_ltssm_isr(mtu); if (level1 & BMU_INTR) mtu3_ep0_isr(mtu); if (level1 & QMU_INTR) mtu3_qmu_isr(mtu); spin_unlock_irqrestore(&mtu->lock, flags); return IRQ_HANDLED; } static void mtu3_check_params(struct mtu3 *mtu) { /* device's u3 port (port0) is disabled */ if (mtu->u3_capable && (mtu->ssusb->u3p_dis_msk & BIT(0))) mtu->u3_capable = 0; /* check the max_speed parameter */ switch (mtu->max_speed) { case USB_SPEED_FULL: case USB_SPEED_HIGH: case USB_SPEED_SUPER: case USB_SPEED_SUPER_PLUS: break; default: dev_err(mtu->dev, "invalid max_speed: %s\n", usb_speed_string(mtu->max_speed)); fallthrough; case USB_SPEED_UNKNOWN: /* default as SSP */ mtu->max_speed = USB_SPEED_SUPER_PLUS; break; } if (!mtu->u3_capable && (mtu->max_speed > USB_SPEED_HIGH)) mtu->max_speed = USB_SPEED_HIGH; mtu->speed = mtu->max_speed; dev_info(mtu->dev, "max_speed: %s\n", usb_speed_string(mtu->max_speed)); } static int mtu3_hw_init(struct mtu3 *mtu) { u32 value; int ret; value = mtu3_readl(mtu->ippc_base, U3D_SSUSB_IP_TRUNK_VERS); mtu->hw_version = IP_TRUNK_VERS(value); mtu->gen2cp = !!(mtu->hw_version >= MTU3_TRUNK_VERS_1003); value = mtu3_readl(mtu->ippc_base, U3D_SSUSB_IP_DEV_CAP); mtu->u3_capable = !!SSUSB_IP_DEV_U3_PORT_NUM(value); /* usb3 ip uses separate fifo */ mtu->separate_fifo = mtu->u3_capable; dev_info(mtu->dev, "IP version 0x%x(%s IP)\n", mtu->hw_version, mtu->u3_capable ? "U3" : "U2"); mtu3_check_params(mtu); mtu3_device_reset(mtu); ret = mtu3_device_enable(mtu); if (ret) { dev_err(mtu->dev, "device enable failed %d\n", ret); return ret; } ret = mtu3_mem_alloc(mtu); if (ret) return -ENOMEM; mtu3_regs_init(mtu); return 0; } static void mtu3_hw_exit(struct mtu3 *mtu) { mtu3_device_disable(mtu); mtu3_mem_free(mtu); } /* * we set 32-bit DMA mask by default, here check whether the controller * supports 36-bit DMA or not, if it does, set 36-bit DMA mask. */ static int mtu3_set_dma_mask(struct mtu3 *mtu) { struct device *dev = mtu->dev; bool is_36bit = false; int ret = 0; u32 value; value = mtu3_readl(mtu->mac_base, U3D_MISC_CTRL); if (value & DMA_ADDR_36BIT) { is_36bit = true; ret = dma_set_mask_and_coherent(dev, DMA_BIT_MASK(36)); /* If set 36-bit DMA mask fails, fall back to 32-bit DMA mask */ if (ret) { is_36bit = false; ret = dma_set_mask_and_coherent(dev, DMA_BIT_MASK(32)); } } dev_info(dev, "dma mask: %s bits\n", is_36bit ? "36" : "32"); return ret; } int ssusb_gadget_init(struct ssusb_mtk *ssusb) { struct device *dev = ssusb->dev; struct platform_device *pdev = to_platform_device(dev); struct mtu3 *mtu = NULL; int ret = -ENOMEM; mtu = devm_kzalloc(dev, sizeof(struct mtu3), GFP_KERNEL); if (mtu == NULL) return -ENOMEM; mtu->irq = platform_get_irq_byname_optional(pdev, "device"); if (mtu->irq < 0) { if (mtu->irq == -EPROBE_DEFER) return mtu->irq; /* for backward compatibility */ mtu->irq = platform_get_irq(pdev, 0); if (mtu->irq < 0) return mtu->irq; } dev_info(dev, "irq %d\n", mtu->irq); mtu->mac_base = devm_platform_ioremap_resource_byname(pdev, "mac"); if (IS_ERR(mtu->mac_base)) { dev_err(dev, "error mapping memory for dev mac\n"); return PTR_ERR(mtu->mac_base); } spin_lock_init(&mtu->lock); mtu->dev = dev; mtu->ippc_base = ssusb->ippc_base; ssusb->mac_base = mtu->mac_base; ssusb->u3d = mtu; mtu->ssusb = ssusb; mtu->max_speed = usb_get_maximum_speed(dev); dev_dbg(dev, "mac_base=0x%p, ippc_base=0x%p\n", mtu->mac_base, mtu->ippc_base); ret = mtu3_hw_init(mtu); if (ret) { dev_err(dev, "mtu3 hw init failed:%d\n", ret); return ret; } ret = mtu3_set_dma_mask(mtu); if (ret) { dev_err(dev, "mtu3 set dma_mask failed:%d\n", ret); goto dma_mask_err; } ret = devm_request_threaded_irq(dev, mtu->irq, NULL, mtu3_irq, IRQF_ONESHOT, dev_name(dev), mtu); if (ret) { dev_err(dev, "request irq %d failed!\n", mtu->irq); goto irq_err; } /* power down device IP for power saving by default */ mtu3_stop(mtu); ret = mtu3_gadget_setup(mtu); if (ret) { dev_err(dev, "mtu3 gadget init failed:%d\n", ret); goto gadget_err; } ssusb_dev_debugfs_init(ssusb); dev_dbg(dev, " %s() done...\n", __func__); return 0; gadget_err: device_init_wakeup(dev, false); dma_mask_err: irq_err: mtu3_hw_exit(mtu); ssusb->u3d = NULL; dev_err(dev, " %s() fail...\n", __func__); return ret; } void ssusb_gadget_exit(struct ssusb_mtk *ssusb) { struct mtu3 *mtu = ssusb->u3d; mtu3_gadget_cleanup(mtu); device_init_wakeup(ssusb->dev, false); mtu3_hw_exit(mtu); } bool ssusb_gadget_ip_sleep_check(struct ssusb_mtk *ssusb) { struct mtu3 *mtu = ssusb->u3d; /* host only, should wait for ip sleep */ if (!mtu) return true; /* device is started and pullup D+, ip can sleep */ if (mtu->is_active && mtu->softconnect) return true; /* ip can't sleep if not pullup D+ when support device mode */ return false; } int ssusb_gadget_suspend(struct ssusb_mtk *ssusb, pm_message_t msg) { struct mtu3 *mtu = ssusb->u3d; if (!mtu->gadget_driver) return 0; if (mtu->connected) return -EBUSY; mtu3_dev_suspend(mtu); synchronize_irq(mtu->irq); return 0; } int ssusb_gadget_resume(struct ssusb_mtk *ssusb, pm_message_t msg) { struct mtu3 *mtu = ssusb->u3d; if (!mtu->gadget_driver) return 0; mtu3_dev_resume(mtu); return 0; }
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