Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Mika Westerberg | 3794 | 69.25% | 7 | 70.00% |
Rajmohan Mani | 1683 | 30.72% | 2 | 20.00% |
Colin Ian King | 2 | 0.04% | 1 | 10.00% |
Total | 5479 | 10 |
// SPDX-License-Identifier: GPL-2.0 /* * USB4 specific functionality * * Copyright (C) 2019, Intel Corporation * Authors: Mika Westerberg <mika.westerberg@linux.intel.com> * Rajmohan Mani <rajmohan.mani@intel.com> */ #include <linux/delay.h> #include <linux/ktime.h> #include "sb_regs.h" #include "tb.h" #define USB4_DATA_DWORDS 16 #define USB4_DATA_RETRIES 3 enum usb4_switch_op { USB4_SWITCH_OP_QUERY_DP_RESOURCE = 0x10, USB4_SWITCH_OP_ALLOC_DP_RESOURCE = 0x11, USB4_SWITCH_OP_DEALLOC_DP_RESOURCE = 0x12, USB4_SWITCH_OP_NVM_WRITE = 0x20, USB4_SWITCH_OP_NVM_AUTH = 0x21, USB4_SWITCH_OP_NVM_READ = 0x22, USB4_SWITCH_OP_NVM_SET_OFFSET = 0x23, USB4_SWITCH_OP_DROM_READ = 0x24, USB4_SWITCH_OP_NVM_SECTOR_SIZE = 0x25, }; enum usb4_sb_target { USB4_SB_TARGET_ROUTER, USB4_SB_TARGET_PARTNER, USB4_SB_TARGET_RETIMER, }; #define USB4_NVM_READ_OFFSET_MASK GENMASK(23, 2) #define USB4_NVM_READ_OFFSET_SHIFT 2 #define USB4_NVM_READ_LENGTH_MASK GENMASK(27, 24) #define USB4_NVM_READ_LENGTH_SHIFT 24 #define USB4_NVM_SET_OFFSET_MASK USB4_NVM_READ_OFFSET_MASK #define USB4_NVM_SET_OFFSET_SHIFT USB4_NVM_READ_OFFSET_SHIFT #define USB4_DROM_ADDRESS_MASK GENMASK(14, 2) #define USB4_DROM_ADDRESS_SHIFT 2 #define USB4_DROM_SIZE_MASK GENMASK(19, 15) #define USB4_DROM_SIZE_SHIFT 15 #define USB4_NVM_SECTOR_SIZE_MASK GENMASK(23, 0) typedef int (*read_block_fn)(void *, unsigned int, void *, size_t); typedef int (*write_block_fn)(void *, const void *, size_t); static int usb4_switch_wait_for_bit(struct tb_switch *sw, u32 offset, u32 bit, u32 value, int timeout_msec) { ktime_t timeout = ktime_add_ms(ktime_get(), timeout_msec); do { u32 val; int ret; ret = tb_sw_read(sw, &val, TB_CFG_SWITCH, offset, 1); if (ret) return ret; if ((val & bit) == value) return 0; usleep_range(50, 100); } while (ktime_before(ktime_get(), timeout)); return -ETIMEDOUT; } static int usb4_switch_op_read_data(struct tb_switch *sw, void *data, size_t dwords) { if (dwords > USB4_DATA_DWORDS) return -EINVAL; return tb_sw_read(sw, data, TB_CFG_SWITCH, ROUTER_CS_9, dwords); } static int usb4_switch_op_write_data(struct tb_switch *sw, const void *data, size_t dwords) { if (dwords > USB4_DATA_DWORDS) return -EINVAL; return tb_sw_write(sw, data, TB_CFG_SWITCH, ROUTER_CS_9, dwords); } static int usb4_switch_op_read_metadata(struct tb_switch *sw, u32 *metadata) { return tb_sw_read(sw, metadata, TB_CFG_SWITCH, ROUTER_CS_25, 1); } static int usb4_switch_op_write_metadata(struct tb_switch *sw, u32 metadata) { return tb_sw_write(sw, &metadata, TB_CFG_SWITCH, ROUTER_CS_25, 1); } static int usb4_do_read_data(u16 address, void *buf, size_t size, read_block_fn read_block, void *read_block_data) { unsigned int retries = USB4_DATA_RETRIES; unsigned int offset; offset = address & 3; address = address & ~3; do { size_t nbytes = min_t(size_t, size, USB4_DATA_DWORDS * 4); unsigned int dwaddress, dwords; u8 data[USB4_DATA_DWORDS * 4]; int ret; dwaddress = address / 4; dwords = ALIGN(nbytes, 4) / 4; ret = read_block(read_block_data, dwaddress, data, dwords); if (ret) { if (ret != -ENODEV && retries--) continue; return ret; } memcpy(buf, data + offset, nbytes); size -= nbytes; address += nbytes; buf += nbytes; } while (size > 0); return 0; } static int usb4_do_write_data(unsigned int address, const void *buf, size_t size, write_block_fn write_next_block, void *write_block_data) { unsigned int retries = USB4_DATA_RETRIES; unsigned int offset; offset = address & 3; address = address & ~3; do { u32 nbytes = min_t(u32, size, USB4_DATA_DWORDS * 4); u8 data[USB4_DATA_DWORDS * 4]; int ret; memcpy(data + offset, buf, nbytes); ret = write_next_block(write_block_data, data, nbytes / 4); if (ret) { if (ret == -ETIMEDOUT) { if (retries--) continue; ret = -EIO; } return ret; } size -= nbytes; address += nbytes; buf += nbytes; } while (size > 0); return 0; } static int usb4_switch_op(struct tb_switch *sw, u16 opcode, u8 *status) { u32 val; int ret; val = opcode | ROUTER_CS_26_OV; ret = tb_sw_write(sw, &val, TB_CFG_SWITCH, ROUTER_CS_26, 1); if (ret) return ret; ret = usb4_switch_wait_for_bit(sw, ROUTER_CS_26, ROUTER_CS_26_OV, 0, 500); if (ret) return ret; ret = tb_sw_read(sw, &val, TB_CFG_SWITCH, ROUTER_CS_26, 1); if (ret) return ret; if (val & ROUTER_CS_26_ONS) return -EOPNOTSUPP; *status = (val & ROUTER_CS_26_STATUS_MASK) >> ROUTER_CS_26_STATUS_SHIFT; return 0; } static bool link_is_usb4(struct tb_port *port) { u32 val; if (!port->cap_usb4) return false; if (tb_port_read(port, &val, TB_CFG_PORT, port->cap_usb4 + PORT_CS_18, 1)) return false; return !(val & PORT_CS_18_TCM); } /** * usb4_switch_setup() - Additional setup for USB4 device * @sw: USB4 router to setup * * USB4 routers need additional settings in order to enable all the * tunneling. This function enables USB and PCIe tunneling if it can be * enabled (e.g the parent switch also supports them). If USB tunneling * is not available for some reason (like that there is Thunderbolt 3 * switch upstream) then the internal xHCI controller is enabled * instead. */ int usb4_switch_setup(struct tb_switch *sw) { struct tb_port *downstream_port; struct tb_switch *parent; bool tbt3, xhci; u32 val = 0; int ret; if (!tb_route(sw)) return 0; ret = tb_sw_read(sw, &val, TB_CFG_SWITCH, ROUTER_CS_6, 1); if (ret) return ret; parent = tb_switch_parent(sw); downstream_port = tb_port_at(tb_route(sw), parent); sw->link_usb4 = link_is_usb4(downstream_port); tb_sw_dbg(sw, "link: %s\n", sw->link_usb4 ? "USB4" : "TBT3"); xhci = val & ROUTER_CS_6_HCI; tbt3 = !(val & ROUTER_CS_6_TNS); tb_sw_dbg(sw, "TBT3 support: %s, xHCI: %s\n", tbt3 ? "yes" : "no", xhci ? "yes" : "no"); ret = tb_sw_read(sw, &val, TB_CFG_SWITCH, ROUTER_CS_5, 1); if (ret) return ret; if (sw->link_usb4 && tb_switch_find_port(parent, TB_TYPE_USB3_DOWN)) { val |= ROUTER_CS_5_UTO; xhci = false; } /* Only enable PCIe tunneling if the parent router supports it */ if (tb_switch_find_port(parent, TB_TYPE_PCIE_DOWN)) { val |= ROUTER_CS_5_PTO; /* * xHCI can be enabled if PCIe tunneling is supported * and the parent does not have any USB3 dowstream * adapters (so we cannot do USB 3.x tunneling). */ if (xhci) val |= ROUTER_CS_5_HCO; } /* TBT3 supported by the CM */ val |= ROUTER_CS_5_C3S; /* Tunneling configuration is ready now */ val |= ROUTER_CS_5_CV; ret = tb_sw_write(sw, &val, TB_CFG_SWITCH, ROUTER_CS_5, 1); if (ret) return ret; return usb4_switch_wait_for_bit(sw, ROUTER_CS_6, ROUTER_CS_6_CR, ROUTER_CS_6_CR, 50); } /** * usb4_switch_read_uid() - Read UID from USB4 router * @sw: USB4 router * @uid: UID is stored here * * Reads 64-bit UID from USB4 router config space. */ int usb4_switch_read_uid(struct tb_switch *sw, u64 *uid) { return tb_sw_read(sw, uid, TB_CFG_SWITCH, ROUTER_CS_7, 2); } static int usb4_switch_drom_read_block(void *data, unsigned int dwaddress, void *buf, size_t dwords) { struct tb_switch *sw = data; u8 status = 0; u32 metadata; int ret; metadata = (dwords << USB4_DROM_SIZE_SHIFT) & USB4_DROM_SIZE_MASK; metadata |= (dwaddress << USB4_DROM_ADDRESS_SHIFT) & USB4_DROM_ADDRESS_MASK; ret = usb4_switch_op_write_metadata(sw, metadata); if (ret) return ret; ret = usb4_switch_op(sw, USB4_SWITCH_OP_DROM_READ, &status); if (ret) return ret; if (status) return -EIO; return usb4_switch_op_read_data(sw, buf, dwords); } /** * usb4_switch_drom_read() - Read arbitrary bytes from USB4 router DROM * @sw: USB4 router * @address: Byte address inside DROM to start reading * @buf: Buffer where the DROM content is stored * @size: Number of bytes to read from DROM * * Uses USB4 router operations to read router DROM. For devices this * should always work but for hosts it may return %-EOPNOTSUPP in which * case the host router does not have DROM. */ int usb4_switch_drom_read(struct tb_switch *sw, unsigned int address, void *buf, size_t size) { return usb4_do_read_data(address, buf, size, usb4_switch_drom_read_block, sw); } static int usb4_set_port_configured(struct tb_port *port, bool configured) { int ret; u32 val; ret = tb_port_read(port, &val, TB_CFG_PORT, port->cap_usb4 + PORT_CS_19, 1); if (ret) return ret; if (configured) val |= PORT_CS_19_PC; else val &= ~PORT_CS_19_PC; return tb_port_write(port, &val, TB_CFG_PORT, port->cap_usb4 + PORT_CS_19, 1); } /** * usb4_switch_configure_link() - Set upstream USB4 link configured * @sw: USB4 router * * Sets the upstream USB4 link to be configured for power management * purposes. */ int usb4_switch_configure_link(struct tb_switch *sw) { struct tb_port *up; if (!tb_route(sw)) return 0; up = tb_upstream_port(sw); return usb4_set_port_configured(up, true); } /** * usb4_switch_unconfigure_link() - Un-set upstream USB4 link configuration * @sw: USB4 router * * Reverse of usb4_switch_configure_link(). */ void usb4_switch_unconfigure_link(struct tb_switch *sw) { struct tb_port *up; if (sw->is_unplugged || !tb_route(sw)) return; up = tb_upstream_port(sw); usb4_set_port_configured(up, false); } /** * usb4_switch_lane_bonding_possible() - Are conditions met for lane bonding * @sw: USB4 router * * Checks whether conditions are met so that lane bonding can be * established with the upstream router. Call only for device routers. */ bool usb4_switch_lane_bonding_possible(struct tb_switch *sw) { struct tb_port *up; int ret; u32 val; up = tb_upstream_port(sw); ret = tb_port_read(up, &val, TB_CFG_PORT, up->cap_usb4 + PORT_CS_18, 1); if (ret) return false; return !!(val & PORT_CS_18_BE); } /** * usb4_switch_set_sleep() - Prepare the router to enter sleep * @sw: USB4 router * * Enables wakes and sets sleep bit for the router. Returns when the * router sleep ready bit has been asserted. */ int usb4_switch_set_sleep(struct tb_switch *sw) { int ret; u32 val; /* Set sleep bit and wait for sleep ready to be asserted */ ret = tb_sw_read(sw, &val, TB_CFG_SWITCH, ROUTER_CS_5, 1); if (ret) return ret; val |= ROUTER_CS_5_SLP; ret = tb_sw_write(sw, &val, TB_CFG_SWITCH, ROUTER_CS_5, 1); if (ret) return ret; return usb4_switch_wait_for_bit(sw, ROUTER_CS_6, ROUTER_CS_6_SLPR, ROUTER_CS_6_SLPR, 500); } /** * usb4_switch_nvm_sector_size() - Return router NVM sector size * @sw: USB4 router * * If the router supports NVM operations this function returns the NVM * sector size in bytes. If NVM operations are not supported returns * %-EOPNOTSUPP. */ int usb4_switch_nvm_sector_size(struct tb_switch *sw) { u32 metadata; u8 status; int ret; ret = usb4_switch_op(sw, USB4_SWITCH_OP_NVM_SECTOR_SIZE, &status); if (ret) return ret; if (status) return status == 0x2 ? -EOPNOTSUPP : -EIO; ret = usb4_switch_op_read_metadata(sw, &metadata); if (ret) return ret; return metadata & USB4_NVM_SECTOR_SIZE_MASK; } static int usb4_switch_nvm_read_block(void *data, unsigned int dwaddress, void *buf, size_t dwords) { struct tb_switch *sw = data; u8 status = 0; u32 metadata; int ret; metadata = (dwords << USB4_NVM_READ_LENGTH_SHIFT) & USB4_NVM_READ_LENGTH_MASK; metadata |= (dwaddress << USB4_NVM_READ_OFFSET_SHIFT) & USB4_NVM_READ_OFFSET_MASK; ret = usb4_switch_op_write_metadata(sw, metadata); if (ret) return ret; ret = usb4_switch_op(sw, USB4_SWITCH_OP_NVM_READ, &status); if (ret) return ret; if (status) return -EIO; return usb4_switch_op_read_data(sw, buf, dwords); } /** * usb4_switch_nvm_read() - Read arbitrary bytes from router NVM * @sw: USB4 router * @address: Starting address in bytes * @buf: Read data is placed here * @size: How many bytes to read * * Reads NVM contents of the router. If NVM is not supported returns * %-EOPNOTSUPP. */ int usb4_switch_nvm_read(struct tb_switch *sw, unsigned int address, void *buf, size_t size) { return usb4_do_read_data(address, buf, size, usb4_switch_nvm_read_block, sw); } static int usb4_switch_nvm_set_offset(struct tb_switch *sw, unsigned int address) { u32 metadata, dwaddress; u8 status = 0; int ret; dwaddress = address / 4; metadata = (dwaddress << USB4_NVM_SET_OFFSET_SHIFT) & USB4_NVM_SET_OFFSET_MASK; ret = usb4_switch_op_write_metadata(sw, metadata); if (ret) return ret; ret = usb4_switch_op(sw, USB4_SWITCH_OP_NVM_SET_OFFSET, &status); if (ret) return ret; return status ? -EIO : 0; } static int usb4_switch_nvm_write_next_block(void *data, const void *buf, size_t dwords) { struct tb_switch *sw = data; u8 status; int ret; ret = usb4_switch_op_write_data(sw, buf, dwords); if (ret) return ret; ret = usb4_switch_op(sw, USB4_SWITCH_OP_NVM_WRITE, &status); if (ret) return ret; return status ? -EIO : 0; } /** * usb4_switch_nvm_write() - Write to the router NVM * @sw: USB4 router * @address: Start address where to write in bytes * @buf: Pointer to the data to write * @size: Size of @buf in bytes * * Writes @buf to the router NVM using USB4 router operations. If NVM * write is not supported returns %-EOPNOTSUPP. */ int usb4_switch_nvm_write(struct tb_switch *sw, unsigned int address, const void *buf, size_t size) { int ret; ret = usb4_switch_nvm_set_offset(sw, address); if (ret) return ret; return usb4_do_write_data(address, buf, size, usb4_switch_nvm_write_next_block, sw); } /** * usb4_switch_nvm_authenticate() - Authenticate new NVM * @sw: USB4 router * * After the new NVM has been written via usb4_switch_nvm_write(), this * function triggers NVM authentication process. If the authentication * is successful the router is power cycled and the new NVM starts * running. In case of failure returns negative errno. */ int usb4_switch_nvm_authenticate(struct tb_switch *sw) { u8 status = 0; int ret; ret = usb4_switch_op(sw, USB4_SWITCH_OP_NVM_AUTH, &status); if (ret) return ret; switch (status) { case 0x0: tb_sw_dbg(sw, "NVM authentication successful\n"); return 0; case 0x1: return -EINVAL; case 0x2: return -EAGAIN; case 0x3: return -EOPNOTSUPP; default: return -EIO; } } /** * usb4_switch_query_dp_resource() - Query availability of DP IN resource * @sw: USB4 router * @in: DP IN adapter * * For DP tunneling this function can be used to query availability of * DP IN resource. Returns true if the resource is available for DP * tunneling, false otherwise. */ bool usb4_switch_query_dp_resource(struct tb_switch *sw, struct tb_port *in) { u8 status; int ret; ret = usb4_switch_op_write_metadata(sw, in->port); if (ret) return false; ret = usb4_switch_op(sw, USB4_SWITCH_OP_QUERY_DP_RESOURCE, &status); /* * If DP resource allocation is not supported assume it is * always available. */ if (ret == -EOPNOTSUPP) return true; else if (ret) return false; return !status; } /** * usb4_switch_alloc_dp_resource() - Allocate DP IN resource * @sw: USB4 router * @in: DP IN adapter * * Allocates DP IN resource for DP tunneling using USB4 router * operations. If the resource was allocated returns %0. Otherwise * returns negative errno, in particular %-EBUSY if the resource is * already allocated. */ int usb4_switch_alloc_dp_resource(struct tb_switch *sw, struct tb_port *in) { u8 status; int ret; ret = usb4_switch_op_write_metadata(sw, in->port); if (ret) return ret; ret = usb4_switch_op(sw, USB4_SWITCH_OP_ALLOC_DP_RESOURCE, &status); if (ret == -EOPNOTSUPP) return 0; else if (ret) return ret; return status ? -EBUSY : 0; } /** * usb4_switch_dealloc_dp_resource() - Releases allocated DP IN resource * @sw: USB4 router * @in: DP IN adapter * * Releases the previously allocated DP IN resource. */ int usb4_switch_dealloc_dp_resource(struct tb_switch *sw, struct tb_port *in) { u8 status; int ret; ret = usb4_switch_op_write_metadata(sw, in->port); if (ret) return ret; ret = usb4_switch_op(sw, USB4_SWITCH_OP_DEALLOC_DP_RESOURCE, &status); if (ret == -EOPNOTSUPP) return 0; else if (ret) return ret; return status ? -EIO : 0; } static int usb4_port_idx(const struct tb_switch *sw, const struct tb_port *port) { struct tb_port *p; int usb4_idx = 0; /* Assume port is primary */ tb_switch_for_each_port(sw, p) { if (!tb_port_is_null(p)) continue; if (tb_is_upstream_port(p)) continue; if (!p->link_nr) { if (p == port) break; usb4_idx++; } } return usb4_idx; } /** * usb4_switch_map_pcie_down() - Map USB4 port to a PCIe downstream adapter * @sw: USB4 router * @port: USB4 port * * USB4 routers have direct mapping between USB4 ports and PCIe * downstream adapters where the PCIe topology is extended. This * function returns the corresponding downstream PCIe adapter or %NULL * if no such mapping was possible. */ struct tb_port *usb4_switch_map_pcie_down(struct tb_switch *sw, const struct tb_port *port) { int usb4_idx = usb4_port_idx(sw, port); struct tb_port *p; int pcie_idx = 0; /* Find PCIe down port matching usb4_port */ tb_switch_for_each_port(sw, p) { if (!tb_port_is_pcie_down(p)) continue; if (pcie_idx == usb4_idx) return p; pcie_idx++; } return NULL; } /** * usb4_switch_map_usb3_down() - Map USB4 port to a USB3 downstream adapter * @sw: USB4 router * @port: USB4 port * * USB4 routers have direct mapping between USB4 ports and USB 3.x * downstream adapters where the USB 3.x topology is extended. This * function returns the corresponding downstream USB 3.x adapter or * %NULL if no such mapping was possible. */ struct tb_port *usb4_switch_map_usb3_down(struct tb_switch *sw, const struct tb_port *port) { int usb4_idx = usb4_port_idx(sw, port); struct tb_port *p; int usb_idx = 0; /* Find USB3 down port matching usb4_port */ tb_switch_for_each_port(sw, p) { if (!tb_port_is_usb3_down(p)) continue; if (usb_idx == usb4_idx) return p; usb_idx++; } return NULL; } /** * usb4_port_unlock() - Unlock USB4 downstream port * @port: USB4 port to unlock * * Unlocks USB4 downstream port so that the connection manager can * access the router below this port. */ int usb4_port_unlock(struct tb_port *port) { int ret; u32 val; ret = tb_port_read(port, &val, TB_CFG_PORT, ADP_CS_4, 1); if (ret) return ret; val &= ~ADP_CS_4_LCK; return tb_port_write(port, &val, TB_CFG_PORT, ADP_CS_4, 1); } static int usb4_port_wait_for_bit(struct tb_port *port, u32 offset, u32 bit, u32 value, int timeout_msec) { ktime_t timeout = ktime_add_ms(ktime_get(), timeout_msec); do { u32 val; int ret; ret = tb_port_read(port, &val, TB_CFG_PORT, offset, 1); if (ret) return ret; if ((val & bit) == value) return 0; usleep_range(50, 100); } while (ktime_before(ktime_get(), timeout)); return -ETIMEDOUT; } static int usb4_port_read_data(struct tb_port *port, void *data, size_t dwords) { if (dwords > USB4_DATA_DWORDS) return -EINVAL; return tb_port_read(port, data, TB_CFG_PORT, port->cap_usb4 + PORT_CS_2, dwords); } static int usb4_port_write_data(struct tb_port *port, const void *data, size_t dwords) { if (dwords > USB4_DATA_DWORDS) return -EINVAL; return tb_port_write(port, data, TB_CFG_PORT, port->cap_usb4 + PORT_CS_2, dwords); } static int usb4_port_sb_read(struct tb_port *port, enum usb4_sb_target target, u8 index, u8 reg, void *buf, u8 size) { size_t dwords = DIV_ROUND_UP(size, 4); int ret; u32 val; if (!port->cap_usb4) return -EINVAL; val = reg; val |= size << PORT_CS_1_LENGTH_SHIFT; val |= (target << PORT_CS_1_TARGET_SHIFT) & PORT_CS_1_TARGET_MASK; if (target == USB4_SB_TARGET_RETIMER) val |= (index << PORT_CS_1_RETIMER_INDEX_SHIFT); val |= PORT_CS_1_PND; ret = tb_port_write(port, &val, TB_CFG_PORT, port->cap_usb4 + PORT_CS_1, 1); if (ret) return ret; ret = usb4_port_wait_for_bit(port, port->cap_usb4 + PORT_CS_1, PORT_CS_1_PND, 0, 500); if (ret) return ret; ret = tb_port_read(port, &val, TB_CFG_PORT, port->cap_usb4 + PORT_CS_1, 1); if (ret) return ret; if (val & PORT_CS_1_NR) return -ENODEV; if (val & PORT_CS_1_RC) return -EIO; return buf ? usb4_port_read_data(port, buf, dwords) : 0; } static int usb4_port_sb_write(struct tb_port *port, enum usb4_sb_target target, u8 index, u8 reg, const void *buf, u8 size) { size_t dwords = DIV_ROUND_UP(size, 4); int ret; u32 val; if (!port->cap_usb4) return -EINVAL; if (buf) { ret = usb4_port_write_data(port, buf, dwords); if (ret) return ret; } val = reg; val |= size << PORT_CS_1_LENGTH_SHIFT; val |= PORT_CS_1_WNR_WRITE; val |= (target << PORT_CS_1_TARGET_SHIFT) & PORT_CS_1_TARGET_MASK; if (target == USB4_SB_TARGET_RETIMER) val |= (index << PORT_CS_1_RETIMER_INDEX_SHIFT); val |= PORT_CS_1_PND; ret = tb_port_write(port, &val, TB_CFG_PORT, port->cap_usb4 + PORT_CS_1, 1); if (ret) return ret; ret = usb4_port_wait_for_bit(port, port->cap_usb4 + PORT_CS_1, PORT_CS_1_PND, 0, 500); if (ret) return ret; ret = tb_port_read(port, &val, TB_CFG_PORT, port->cap_usb4 + PORT_CS_1, 1); if (ret) return ret; if (val & PORT_CS_1_NR) return -ENODEV; if (val & PORT_CS_1_RC) return -EIO; return 0; } static int usb4_port_sb_op(struct tb_port *port, enum usb4_sb_target target, u8 index, enum usb4_sb_opcode opcode, int timeout_msec) { ktime_t timeout; u32 val; int ret; val = opcode; ret = usb4_port_sb_write(port, target, index, USB4_SB_OPCODE, &val, sizeof(val)); if (ret) return ret; timeout = ktime_add_ms(ktime_get(), timeout_msec); do { /* Check results */ ret = usb4_port_sb_read(port, target, index, USB4_SB_OPCODE, &val, sizeof(val)); if (ret) return ret; switch (val) { case 0: return 0; case USB4_SB_OPCODE_ERR: return -EAGAIN; case USB4_SB_OPCODE_ONS: return -EOPNOTSUPP; default: if (val != opcode) return -EIO; break; } } while (ktime_before(ktime_get(), timeout)); return -ETIMEDOUT; } /** * usb4_port_enumerate_retimers() - Send RT broadcast transaction * @port: USB4 port * * This forces the USB4 port to send broadcast RT transaction which * makes the retimers on the link to assign index to themselves. Returns * %0 in case of success and negative errno if there was an error. */ int usb4_port_enumerate_retimers(struct tb_port *port) { u32 val; val = USB4_SB_OPCODE_ENUMERATE_RETIMERS; return usb4_port_sb_write(port, USB4_SB_TARGET_ROUTER, 0, USB4_SB_OPCODE, &val, sizeof(val)); } static inline int usb4_port_retimer_op(struct tb_port *port, u8 index, enum usb4_sb_opcode opcode, int timeout_msec) { return usb4_port_sb_op(port, USB4_SB_TARGET_RETIMER, index, opcode, timeout_msec); } /** * usb4_port_retimer_read() - Read from retimer sideband registers * @port: USB4 port * @index: Retimer index * @reg: Sideband register to read * @buf: Data from @reg is stored here * @size: Number of bytes to read * * Function reads retimer sideband registers starting from @reg. The * retimer is connected to @port at @index. Returns %0 in case of * success, and read data is copied to @buf. If there is no retimer * present at given @index returns %-ENODEV. In any other failure * returns negative errno. */ int usb4_port_retimer_read(struct tb_port *port, u8 index, u8 reg, void *buf, u8 size) { return usb4_port_sb_read(port, USB4_SB_TARGET_RETIMER, index, reg, buf, size); } /** * usb4_port_retimer_write() - Write to retimer sideband registers * @port: USB4 port * @index: Retimer index * @reg: Sideband register to write * @buf: Data that is written starting from @reg * @size: Number of bytes to write * * Writes retimer sideband registers starting from @reg. The retimer is * connected to @port at @index. Returns %0 in case of success. If there * is no retimer present at given @index returns %-ENODEV. In any other * failure returns negative errno. */ int usb4_port_retimer_write(struct tb_port *port, u8 index, u8 reg, const void *buf, u8 size) { return usb4_port_sb_write(port, USB4_SB_TARGET_RETIMER, index, reg, buf, size); } /** * usb4_port_retimer_is_last() - Is the retimer last on-board retimer * @port: USB4 port * @index: Retimer index * * If the retimer at @index is last one (connected directly to the * Type-C port) this function returns %1. If it is not returns %0. If * the retimer is not present returns %-ENODEV. Otherwise returns * negative errno. */ int usb4_port_retimer_is_last(struct tb_port *port, u8 index) { u32 metadata; int ret; ret = usb4_port_retimer_op(port, index, USB4_SB_OPCODE_QUERY_LAST_RETIMER, 500); if (ret) return ret; ret = usb4_port_retimer_read(port, index, USB4_SB_METADATA, &metadata, sizeof(metadata)); return ret ? ret : metadata & 1; } /** * usb4_port_retimer_nvm_sector_size() - Read retimer NVM sector size * @port: USB4 port * @index: Retimer index * * Reads NVM sector size (in bytes) of a retimer at @index. This * operation can be used to determine whether the retimer supports NVM * upgrade for example. Returns sector size in bytes or negative errno * in case of error. Specifically returns %-ENODEV if there is no * retimer at @index. */ int usb4_port_retimer_nvm_sector_size(struct tb_port *port, u8 index) { u32 metadata; int ret; ret = usb4_port_retimer_op(port, index, USB4_SB_OPCODE_GET_NVM_SECTOR_SIZE, 500); if (ret) return ret; ret = usb4_port_retimer_read(port, index, USB4_SB_METADATA, &metadata, sizeof(metadata)); return ret ? ret : metadata & USB4_NVM_SECTOR_SIZE_MASK; } static int usb4_port_retimer_nvm_set_offset(struct tb_port *port, u8 index, unsigned int address) { u32 metadata, dwaddress; int ret; dwaddress = address / 4; metadata = (dwaddress << USB4_NVM_SET_OFFSET_SHIFT) & USB4_NVM_SET_OFFSET_MASK; ret = usb4_port_retimer_write(port, index, USB4_SB_METADATA, &metadata, sizeof(metadata)); if (ret) return ret; return usb4_port_retimer_op(port, index, USB4_SB_OPCODE_NVM_SET_OFFSET, 500); } struct retimer_info { struct tb_port *port; u8 index; }; static int usb4_port_retimer_nvm_write_next_block(void *data, const void *buf, size_t dwords) { const struct retimer_info *info = data; struct tb_port *port = info->port; u8 index = info->index; int ret; ret = usb4_port_retimer_write(port, index, USB4_SB_DATA, buf, dwords * 4); if (ret) return ret; return usb4_port_retimer_op(port, index, USB4_SB_OPCODE_NVM_BLOCK_WRITE, 1000); } /** * usb4_port_retimer_nvm_write() - Write to retimer NVM * @port: USB4 port * @index: Retimer index * @address: Byte address where to start the write * @buf: Data to write * @size: Size in bytes how much to write * * Writes @size bytes from @buf to the retimer NVM. Used for NVM * upgrade. Returns %0 if the data was written successfully and negative * errno in case of failure. Specifically returns %-ENODEV if there is * no retimer at @index. */ int usb4_port_retimer_nvm_write(struct tb_port *port, u8 index, unsigned int address, const void *buf, size_t size) { struct retimer_info info = { .port = port, .index = index }; int ret; ret = usb4_port_retimer_nvm_set_offset(port, index, address); if (ret) return ret; return usb4_do_write_data(address, buf, size, usb4_port_retimer_nvm_write_next_block, &info); } /** * usb4_port_retimer_nvm_authenticate() - Start retimer NVM upgrade * @port: USB4 port * @index: Retimer index * * After the new NVM image has been written via usb4_port_retimer_nvm_write() * this function can be used to trigger the NVM upgrade process. If * successful the retimer restarts with the new NVM and may not have the * index set so one needs to call usb4_port_enumerate_retimers() to * force index to be assigned. */ int usb4_port_retimer_nvm_authenticate(struct tb_port *port, u8 index) { u32 val; /* * We need to use the raw operation here because once the * authentication completes the retimer index is not set anymore * so we do not get back the status now. */ val = USB4_SB_OPCODE_NVM_AUTH_WRITE; return usb4_port_sb_write(port, USB4_SB_TARGET_RETIMER, index, USB4_SB_OPCODE, &val, sizeof(val)); } /** * usb4_port_retimer_nvm_authenticate_status() - Read status of NVM upgrade * @port: USB4 port * @index: Retimer index * @status: Raw status code read from metadata * * This can be called after usb4_port_retimer_nvm_authenticate() and * usb4_port_enumerate_retimers() to fetch status of the NVM upgrade. * * Returns %0 if the authentication status was successfully read. The * completion metadata (the result) is then stored into @status. If * reading the status fails, returns negative errno. */ int usb4_port_retimer_nvm_authenticate_status(struct tb_port *port, u8 index, u32 *status) { u32 metadata, val; int ret; ret = usb4_port_retimer_read(port, index, USB4_SB_OPCODE, &val, sizeof(val)); if (ret) return ret; switch (val) { case 0: *status = 0; return 0; case USB4_SB_OPCODE_ERR: ret = usb4_port_retimer_read(port, index, USB4_SB_METADATA, &metadata, sizeof(metadata)); if (ret) return ret; *status = metadata & USB4_SB_METADATA_NVM_AUTH_WRITE_MASK; return 0; case USB4_SB_OPCODE_ONS: return -EOPNOTSUPP; default: return -EIO; } } static int usb4_port_retimer_nvm_read_block(void *data, unsigned int dwaddress, void *buf, size_t dwords) { const struct retimer_info *info = data; struct tb_port *port = info->port; u8 index = info->index; u32 metadata; int ret; metadata = dwaddress << USB4_NVM_READ_OFFSET_SHIFT; if (dwords < USB4_DATA_DWORDS) metadata |= dwords << USB4_NVM_READ_LENGTH_SHIFT; ret = usb4_port_retimer_write(port, index, USB4_SB_METADATA, &metadata, sizeof(metadata)); if (ret) return ret; ret = usb4_port_retimer_op(port, index, USB4_SB_OPCODE_NVM_READ, 500); if (ret) return ret; return usb4_port_retimer_read(port, index, USB4_SB_DATA, buf, dwords * 4); } /** * usb4_port_retimer_nvm_read() - Read contents of retimer NVM * @port: USB4 port * @index: Retimer index * @address: NVM address (in bytes) to start reading * @buf: Data read from NVM is stored here * @size: Number of bytes to read * * Reads retimer NVM and copies the contents to @buf. Returns %0 if the * read was successful and negative errno in case of failure. * Specifically returns %-ENODEV if there is no retimer at @index. */ int usb4_port_retimer_nvm_read(struct tb_port *port, u8 index, unsigned int address, void *buf, size_t size) { struct retimer_info info = { .port = port, .index = index }; return usb4_do_read_data(address, buf, size, usb4_port_retimer_nvm_read_block, &info); } /** * usb4_usb3_port_max_link_rate() - Maximum support USB3 link rate * @port: USB3 adapter port * * Return maximum supported link rate of a USB3 adapter in Mb/s. * Negative errno in case of error. */ int usb4_usb3_port_max_link_rate(struct tb_port *port) { int ret, lr; u32 val; if (!tb_port_is_usb3_down(port) && !tb_port_is_usb3_up(port)) return -EINVAL; ret = tb_port_read(port, &val, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_4, 1); if (ret) return ret; lr = (val & ADP_USB3_CS_4_MSLR_MASK) >> ADP_USB3_CS_4_MSLR_SHIFT; return lr == ADP_USB3_CS_4_MSLR_20G ? 20000 : 10000; } /** * usb4_usb3_port_actual_link_rate() - Established USB3 link rate * @port: USB3 adapter port * * Return actual established link rate of a USB3 adapter in Mb/s. If the * link is not up returns %0 and negative errno in case of failure. */ int usb4_usb3_port_actual_link_rate(struct tb_port *port) { int ret, lr; u32 val; if (!tb_port_is_usb3_down(port) && !tb_port_is_usb3_up(port)) return -EINVAL; ret = tb_port_read(port, &val, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_4, 1); if (ret) return ret; if (!(val & ADP_USB3_CS_4_ULV)) return 0; lr = val & ADP_USB3_CS_4_ALR_MASK; return lr == ADP_USB3_CS_4_ALR_20G ? 20000 : 10000; } static int usb4_usb3_port_cm_request(struct tb_port *port, bool request) { int ret; u32 val; if (!tb_port_is_usb3_down(port)) return -EINVAL; if (tb_route(port->sw)) return -EINVAL; ret = tb_port_read(port, &val, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_2, 1); if (ret) return ret; if (request) val |= ADP_USB3_CS_2_CMR; else val &= ~ADP_USB3_CS_2_CMR; ret = tb_port_write(port, &val, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_2, 1); if (ret) return ret; /* * We can use val here directly as the CMR bit is in the same place * as HCA. Just mask out others. */ val &= ADP_USB3_CS_2_CMR; return usb4_port_wait_for_bit(port, port->cap_adap + ADP_USB3_CS_1, ADP_USB3_CS_1_HCA, val, 1500); } static inline int usb4_usb3_port_set_cm_request(struct tb_port *port) { return usb4_usb3_port_cm_request(port, true); } static inline int usb4_usb3_port_clear_cm_request(struct tb_port *port) { return usb4_usb3_port_cm_request(port, false); } static unsigned int usb3_bw_to_mbps(u32 bw, u8 scale) { unsigned long uframes; uframes = bw * 512UL << scale; return DIV_ROUND_CLOSEST(uframes * 8000, 1000 * 1000); } static u32 mbps_to_usb3_bw(unsigned int mbps, u8 scale) { unsigned long uframes; /* 1 uframe is 1/8 ms (125 us) -> 1 / 8000 s */ uframes = ((unsigned long)mbps * 1000 * 1000) / 8000; return DIV_ROUND_UP(uframes, 512UL << scale); } static int usb4_usb3_port_read_allocated_bandwidth(struct tb_port *port, int *upstream_bw, int *downstream_bw) { u32 val, bw, scale; int ret; ret = tb_port_read(port, &val, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_2, 1); if (ret) return ret; ret = tb_port_read(port, &scale, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_3, 1); if (ret) return ret; scale &= ADP_USB3_CS_3_SCALE_MASK; bw = val & ADP_USB3_CS_2_AUBW_MASK; *upstream_bw = usb3_bw_to_mbps(bw, scale); bw = (val & ADP_USB3_CS_2_ADBW_MASK) >> ADP_USB3_CS_2_ADBW_SHIFT; *downstream_bw = usb3_bw_to_mbps(bw, scale); return 0; } /** * usb4_usb3_port_allocated_bandwidth() - Bandwidth allocated for USB3 * @port: USB3 adapter port * @upstream_bw: Allocated upstream bandwidth is stored here * @downstream_bw: Allocated downstream bandwidth is stored here * * Stores currently allocated USB3 bandwidth into @upstream_bw and * @downstream_bw in Mb/s. Returns %0 in case of success and negative * errno in failure. */ int usb4_usb3_port_allocated_bandwidth(struct tb_port *port, int *upstream_bw, int *downstream_bw) { int ret; ret = usb4_usb3_port_set_cm_request(port); if (ret) return ret; ret = usb4_usb3_port_read_allocated_bandwidth(port, upstream_bw, downstream_bw); usb4_usb3_port_clear_cm_request(port); return ret; } static int usb4_usb3_port_read_consumed_bandwidth(struct tb_port *port, int *upstream_bw, int *downstream_bw) { u32 val, bw, scale; int ret; ret = tb_port_read(port, &val, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_1, 1); if (ret) return ret; ret = tb_port_read(port, &scale, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_3, 1); if (ret) return ret; scale &= ADP_USB3_CS_3_SCALE_MASK; bw = val & ADP_USB3_CS_1_CUBW_MASK; *upstream_bw = usb3_bw_to_mbps(bw, scale); bw = (val & ADP_USB3_CS_1_CDBW_MASK) >> ADP_USB3_CS_1_CDBW_SHIFT; *downstream_bw = usb3_bw_to_mbps(bw, scale); return 0; } static int usb4_usb3_port_write_allocated_bandwidth(struct tb_port *port, int upstream_bw, int downstream_bw) { u32 val, ubw, dbw, scale; int ret; /* Read the used scale, hardware default is 0 */ ret = tb_port_read(port, &scale, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_3, 1); if (ret) return ret; scale &= ADP_USB3_CS_3_SCALE_MASK; ubw = mbps_to_usb3_bw(upstream_bw, scale); dbw = mbps_to_usb3_bw(downstream_bw, scale); ret = tb_port_read(port, &val, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_2, 1); if (ret) return ret; val &= ~(ADP_USB3_CS_2_AUBW_MASK | ADP_USB3_CS_2_ADBW_MASK); val |= dbw << ADP_USB3_CS_2_ADBW_SHIFT; val |= ubw; return tb_port_write(port, &val, TB_CFG_PORT, port->cap_adap + ADP_USB3_CS_2, 1); } /** * usb4_usb3_port_allocate_bandwidth() - Allocate bandwidth for USB3 * @port: USB3 adapter port * @upstream_bw: New upstream bandwidth * @downstream_bw: New downstream bandwidth * * This can be used to set how much bandwidth is allocated for the USB3 * tunneled isochronous traffic. @upstream_bw and @downstream_bw are the * new values programmed to the USB3 adapter allocation registers. If * the values are lower than what is currently consumed the allocation * is set to what is currently consumed instead (consumed bandwidth * cannot be taken away by CM). The actual new values are returned in * @upstream_bw and @downstream_bw. * * Returns %0 in case of success and negative errno if there was a * failure. */ int usb4_usb3_port_allocate_bandwidth(struct tb_port *port, int *upstream_bw, int *downstream_bw) { int ret, consumed_up, consumed_down, allocate_up, allocate_down; ret = usb4_usb3_port_set_cm_request(port); if (ret) return ret; ret = usb4_usb3_port_read_consumed_bandwidth(port, &consumed_up, &consumed_down); if (ret) goto err_request; /* Don't allow it go lower than what is consumed */ allocate_up = max(*upstream_bw, consumed_up); allocate_down = max(*downstream_bw, consumed_down); ret = usb4_usb3_port_write_allocated_bandwidth(port, allocate_up, allocate_down); if (ret) goto err_request; *upstream_bw = allocate_up; *downstream_bw = allocate_down; err_request: usb4_usb3_port_clear_cm_request(port); return ret; } /** * usb4_usb3_port_release_bandwidth() - Release allocated USB3 bandwidth * @port: USB3 adapter port * @upstream_bw: New allocated upstream bandwidth * @downstream_bw: New allocated downstream bandwidth * * Releases USB3 allocated bandwidth down to what is actually consumed. * The new bandwidth is returned in @upstream_bw and @downstream_bw. * * Returns 0% in success and negative errno in case of failure. */ int usb4_usb3_port_release_bandwidth(struct tb_port *port, int *upstream_bw, int *downstream_bw) { int ret, consumed_up, consumed_down; ret = usb4_usb3_port_set_cm_request(port); if (ret) return ret; ret = usb4_usb3_port_read_consumed_bandwidth(port, &consumed_up, &consumed_down); if (ret) goto err_request; /* * Always keep 1000 Mb/s to make sure xHCI has at least some * bandwidth available for isochronous traffic. */ if (consumed_up < 1000) consumed_up = 1000; if (consumed_down < 1000) consumed_down = 1000; ret = usb4_usb3_port_write_allocated_bandwidth(port, consumed_up, consumed_down); if (ret) goto err_request; *upstream_bw = consumed_up; *downstream_bw = consumed_down; err_request: usb4_usb3_port_clear_cm_request(port); return ret; }
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