Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Timur Tabi | 877 | 45.18% | 7 | 14.58% |
Kim Phillips | 350 | 18.03% | 1 | 2.08% |
Andy Fleming | 209 | 10.77% | 4 | 8.33% |
Esben Haabendal | 160 | 8.24% | 1 | 2.08% |
Claudiu Manoil | 97 | 5.00% | 3 | 6.25% |
Anton Vorontsov | 95 | 4.89% | 6 | 12.50% |
Gerlando Falauto | 49 | 2.52% | 2 | 4.17% |
Gustavo A. R. Silva | 27 | 1.39% | 1 | 2.08% |
Grant C. Likely | 26 | 1.34% | 6 | 12.50% |
Sandeep Gopalpet | 20 | 1.03% | 1 | 2.08% |
Rob Herring | 7 | 0.36% | 3 | 6.25% |
Sebastian Andrzej Siewior | 5 | 0.26% | 1 | 2.08% |
Haiying Wang | 4 | 0.21% | 1 | 2.08% |
Javier Martinez Canillas | 4 | 0.21% | 1 | 2.08% |
Thomas Gleixner | 2 | 0.10% | 1 | 2.08% |
Libo Chen | 1 | 0.05% | 1 | 2.08% |
Stephen Rothwell | 1 | 0.05% | 1 | 2.08% |
Zheng Yongjun | 1 | 0.05% | 1 | 2.08% |
Zhao Qiang | 1 | 0.05% | 1 | 2.08% |
Axel Lin | 1 | 0.05% | 1 | 2.08% |
Baruch Siach | 1 | 0.05% | 1 | 2.08% |
Fabian Frederick | 1 | 0.05% | 1 | 2.08% |
Kenth Eriksson | 1 | 0.05% | 1 | 2.08% |
Lennert Buytenhek | 1 | 0.05% | 1 | 2.08% |
Total | 1941 | 48 |
// SPDX-License-Identifier: GPL-2.0-or-later /* * Freescale PowerQUICC Ethernet Driver -- MIIM bus implementation * Provides Bus interface for MIIM regs * * Author: Andy Fleming <afleming@freescale.com> * Modifier: Sandeep Gopalpet <sandeep.kumar@freescale.com> * * Copyright 2002-2004, 2008-2009 Freescale Semiconductor, Inc. * * Based on gianfar_mii.c and ucc_geth_mii.c (Li Yang, Kim Phillips) */ #include <linux/kernel.h> #include <linux/string.h> #include <linux/errno.h> #include <linux/slab.h> #include <linux/delay.h> #include <linux/module.h> #include <linux/mii.h> #include <linux/of_address.h> #include <linux/of_mdio.h> #include <linux/of_device.h> #include <asm/io.h> #if IS_ENABLED(CONFIG_UCC_GETH) #include <soc/fsl/qe/ucc.h> #endif #include "gianfar.h" #define MIIMIND_BUSY 0x00000001 #define MIIMIND_NOTVALID 0x00000004 #define MIIMCFG_INIT_VALUE 0x00000007 #define MIIMCFG_RESET 0x80000000 #define MII_READ_COMMAND 0x00000001 struct fsl_pq_mii { u32 miimcfg; /* MII management configuration reg */ u32 miimcom; /* MII management command reg */ u32 miimadd; /* MII management address reg */ u32 miimcon; /* MII management control reg */ u32 miimstat; /* MII management status reg */ u32 miimind; /* MII management indication reg */ }; struct fsl_pq_mdio { u8 res1[16]; u32 ieventm; /* MDIO Interrupt event register (for etsec2)*/ u32 imaskm; /* MDIO Interrupt mask register (for etsec2)*/ u8 res2[4]; u32 emapm; /* MDIO Event mapping register (for etsec2)*/ u8 res3[1280]; struct fsl_pq_mii mii; u8 res4[28]; u32 utbipar; /* TBI phy address reg (only on UCC) */ u8 res5[2728]; } __packed; /* Number of microseconds to wait for an MII register to respond */ #define MII_TIMEOUT 1000 struct fsl_pq_mdio_priv { void __iomem *map; struct fsl_pq_mii __iomem *regs; }; /* * Per-device-type data. Each type of device tree node that we support gets * one of these. * * @mii_offset: the offset of the MII registers within the memory map of the * node. Some nodes define only the MII registers, and some define the whole * MAC (which includes the MII registers). * * @get_tbipa: determines the address of the TBIPA register * * @ucc_configure: a special function for extra QE configuration */ struct fsl_pq_mdio_data { unsigned int mii_offset; /* offset of the MII registers */ uint32_t __iomem * (*get_tbipa)(void __iomem *p); void (*ucc_configure)(phys_addr_t start, phys_addr_t end); }; /* * Write value to the PHY at mii_id at register regnum, on the bus attached * to the local interface, which may be different from the generic mdio bus * (tied to a single interface), waiting until the write is done before * returning. This is helpful in programming interfaces like the TBI which * control interfaces like onchip SERDES and are always tied to the local * mdio pins, which may not be the same as system mdio bus, used for * controlling the external PHYs, for example. */ static int fsl_pq_mdio_write(struct mii_bus *bus, int mii_id, int regnum, u16 value) { struct fsl_pq_mdio_priv *priv = bus->priv; struct fsl_pq_mii __iomem *regs = priv->regs; unsigned int timeout; /* Set the PHY address and the register address we want to write */ iowrite32be((mii_id << 8) | regnum, ®s->miimadd); /* Write out the value we want */ iowrite32be(value, ®s->miimcon); /* Wait for the transaction to finish */ timeout = MII_TIMEOUT; while ((ioread32be(®s->miimind) & MIIMIND_BUSY) && timeout) { cpu_relax(); timeout--; } return timeout ? 0 : -ETIMEDOUT; } /* * Read the bus for PHY at addr mii_id, register regnum, and return the value. * Clears miimcom first. * * All PHY operation done on the bus attached to the local interface, which * may be different from the generic mdio bus. This is helpful in programming * interfaces like the TBI which, in turn, control interfaces like on-chip * SERDES and are always tied to the local mdio pins, which may not be the * same as system mdio bus, used for controlling the external PHYs, for eg. */ static int fsl_pq_mdio_read(struct mii_bus *bus, int mii_id, int regnum) { struct fsl_pq_mdio_priv *priv = bus->priv; struct fsl_pq_mii __iomem *regs = priv->regs; unsigned int timeout; u16 value; /* Set the PHY address and the register address we want to read */ iowrite32be((mii_id << 8) | regnum, ®s->miimadd); /* Clear miimcom, and then initiate a read */ iowrite32be(0, ®s->miimcom); iowrite32be(MII_READ_COMMAND, ®s->miimcom); /* Wait for the transaction to finish, normally less than 100us */ timeout = MII_TIMEOUT; while ((ioread32be(®s->miimind) & (MIIMIND_NOTVALID | MIIMIND_BUSY)) && timeout) { cpu_relax(); timeout--; } if (!timeout) return -ETIMEDOUT; /* Grab the value of the register from miimstat */ value = ioread32be(®s->miimstat); dev_dbg(&bus->dev, "read %04x from address %x/%x\n", value, mii_id, regnum); return value; } /* Reset the MIIM registers, and wait for the bus to free */ static int fsl_pq_mdio_reset(struct mii_bus *bus) { struct fsl_pq_mdio_priv *priv = bus->priv; struct fsl_pq_mii __iomem *regs = priv->regs; unsigned int timeout; mutex_lock(&bus->mdio_lock); /* Reset the management interface */ iowrite32be(MIIMCFG_RESET, ®s->miimcfg); /* Setup the MII Mgmt clock speed */ iowrite32be(MIIMCFG_INIT_VALUE, ®s->miimcfg); /* Wait until the bus is free */ timeout = MII_TIMEOUT; while ((ioread32be(®s->miimind) & MIIMIND_BUSY) && timeout) { cpu_relax(); timeout--; } mutex_unlock(&bus->mdio_lock); if (!timeout) { dev_err(&bus->dev, "timeout waiting for MII bus\n"); return -EBUSY; } return 0; } #if IS_ENABLED(CONFIG_GIANFAR) /* * Return the TBIPA address, starting from the address * of the mapped GFAR MDIO registers (struct gfar) * This is mildly evil, but so is our hardware for doing this. * Also, we have to cast back to struct gfar because of * definition weirdness done in gianfar.h. */ static uint32_t __iomem *get_gfar_tbipa_from_mdio(void __iomem *p) { struct gfar __iomem *enet_regs = p; return &enet_regs->tbipa; } /* * Return the TBIPA address, starting from the address * of the mapped GFAR MII registers (gfar_mii_regs[] within struct gfar) */ static uint32_t __iomem *get_gfar_tbipa_from_mii(void __iomem *p) { return get_gfar_tbipa_from_mdio(container_of(p, struct gfar, gfar_mii_regs)); } /* * Return the TBIPAR address for an eTSEC2 node */ static uint32_t __iomem *get_etsec_tbipa(void __iomem *p) { return p; } #endif #if IS_ENABLED(CONFIG_UCC_GETH) /* * Return the TBIPAR address for a QE MDIO node, starting from the address * of the mapped MII registers (struct fsl_pq_mii) */ static uint32_t __iomem *get_ucc_tbipa(void __iomem *p) { struct fsl_pq_mdio __iomem *mdio = container_of(p, struct fsl_pq_mdio, mii); return &mdio->utbipar; } /* * Find the UCC node that controls the given MDIO node * * For some reason, the QE MDIO nodes are not children of the UCC devices * that control them. Therefore, we need to scan all UCC nodes looking for * the one that encompases the given MDIO node. We do this by comparing * physical addresses. The 'start' and 'end' addresses of the MDIO node are * passed, and the correct UCC node will cover the entire address range. * * This assumes that there is only one QE MDIO node in the entire device tree. */ static void ucc_configure(phys_addr_t start, phys_addr_t end) { static bool found_mii_master; struct device_node *np = NULL; if (found_mii_master) return; for_each_compatible_node(np, NULL, "ucc_geth") { struct resource res; const uint32_t *iprop; uint32_t id; int ret; ret = of_address_to_resource(np, 0, &res); if (ret < 0) { pr_debug("fsl-pq-mdio: no address range in node %pOF\n", np); continue; } /* if our mdio regs fall within this UCC regs range */ if ((start < res.start) || (end > res.end)) continue; iprop = of_get_property(np, "cell-index", NULL); if (!iprop) { iprop = of_get_property(np, "device-id", NULL); if (!iprop) { pr_debug("fsl-pq-mdio: no UCC ID in node %pOF\n", np); continue; } } id = be32_to_cpup(iprop); /* * cell-index and device-id for QE nodes are * numbered from 1, not 0. */ if (ucc_set_qe_mux_mii_mng(id - 1) < 0) { pr_debug("fsl-pq-mdio: invalid UCC ID in node %pOF\n", np); continue; } pr_debug("fsl-pq-mdio: setting node UCC%u to MII master\n", id); found_mii_master = true; } } #endif static const struct of_device_id fsl_pq_mdio_match[] = { #if IS_ENABLED(CONFIG_GIANFAR) { .compatible = "fsl,gianfar-tbi", .data = &(struct fsl_pq_mdio_data) { .mii_offset = 0, .get_tbipa = get_gfar_tbipa_from_mii, }, }, { .compatible = "fsl,gianfar-mdio", .data = &(struct fsl_pq_mdio_data) { .mii_offset = 0, .get_tbipa = get_gfar_tbipa_from_mii, }, }, { .type = "mdio", .compatible = "gianfar", .data = &(struct fsl_pq_mdio_data) { .mii_offset = offsetof(struct fsl_pq_mdio, mii), .get_tbipa = get_gfar_tbipa_from_mdio, }, }, { .compatible = "fsl,etsec2-tbi", .data = &(struct fsl_pq_mdio_data) { .mii_offset = offsetof(struct fsl_pq_mdio, mii), .get_tbipa = get_etsec_tbipa, }, }, { .compatible = "fsl,etsec2-mdio", .data = &(struct fsl_pq_mdio_data) { .mii_offset = offsetof(struct fsl_pq_mdio, mii), .get_tbipa = get_etsec_tbipa, }, }, #endif #if IS_ENABLED(CONFIG_UCC_GETH) { .compatible = "fsl,ucc-mdio", .data = &(struct fsl_pq_mdio_data) { .mii_offset = 0, .get_tbipa = get_ucc_tbipa, .ucc_configure = ucc_configure, }, }, { /* Legacy UCC MDIO node */ .type = "mdio", .compatible = "ucc_geth_phy", .data = &(struct fsl_pq_mdio_data) { .mii_offset = 0, .get_tbipa = get_ucc_tbipa, .ucc_configure = ucc_configure, }, }, #endif /* No Kconfig option for Fman support yet */ { .compatible = "fsl,fman-mdio", .data = &(struct fsl_pq_mdio_data) { .mii_offset = 0, /* Fman TBI operations are handled elsewhere */ }, }, {}, }; MODULE_DEVICE_TABLE(of, fsl_pq_mdio_match); static void set_tbipa(const u32 tbipa_val, struct platform_device *pdev, uint32_t __iomem * (*get_tbipa)(void __iomem *), void __iomem *reg_map, struct resource *reg_res) { struct device_node *np = pdev->dev.of_node; uint32_t __iomem *tbipa; bool tbipa_mapped; tbipa = of_iomap(np, 1); if (tbipa) { tbipa_mapped = true; } else { tbipa_mapped = false; tbipa = (*get_tbipa)(reg_map); /* * Add consistency check to make sure TBI is contained within * the mapped range (not because we would get a segfault, * rather to catch bugs in computing TBI address). Print error * message but continue anyway. */ if ((void *)tbipa > reg_map + resource_size(reg_res) - 4) dev_err(&pdev->dev, "invalid register map (should be at least 0x%04zx to contain TBI address)\n", ((void *)tbipa - reg_map) + 4); } iowrite32be(be32_to_cpu(tbipa_val), tbipa); if (tbipa_mapped) iounmap(tbipa); } static int fsl_pq_mdio_probe(struct platform_device *pdev) { const struct of_device_id *id = of_match_device(fsl_pq_mdio_match, &pdev->dev); const struct fsl_pq_mdio_data *data; struct device_node *np = pdev->dev.of_node; struct resource res; struct device_node *tbi; struct fsl_pq_mdio_priv *priv; struct mii_bus *new_bus; int err; if (!id) { dev_err(&pdev->dev, "Failed to match device\n"); return -ENODEV; } data = id->data; dev_dbg(&pdev->dev, "found %s compatible node\n", id->compatible); new_bus = mdiobus_alloc_size(sizeof(*priv)); if (!new_bus) return -ENOMEM; priv = new_bus->priv; new_bus->name = "Freescale PowerQUICC MII Bus"; new_bus->read = &fsl_pq_mdio_read; new_bus->write = &fsl_pq_mdio_write; new_bus->reset = &fsl_pq_mdio_reset; err = of_address_to_resource(np, 0, &res); if (err < 0) { dev_err(&pdev->dev, "could not obtain address information\n"); goto error; } snprintf(new_bus->id, MII_BUS_ID_SIZE, "%pOFn@%llx", np, (unsigned long long)res.start); priv->map = of_iomap(np, 0); if (!priv->map) { err = -ENOMEM; goto error; } /* * Some device tree nodes represent only the MII registers, and * others represent the MAC and MII registers. The 'mii_offset' field * contains the offset of the MII registers inside the mapped register * space. */ if (data->mii_offset > resource_size(&res)) { dev_err(&pdev->dev, "invalid register map\n"); err = -EINVAL; goto error; } priv->regs = priv->map + data->mii_offset; new_bus->parent = &pdev->dev; platform_set_drvdata(pdev, new_bus); if (data->get_tbipa) { for_each_child_of_node(np, tbi) { if (of_node_is_type(tbi, "tbi-phy")) { dev_dbg(&pdev->dev, "found TBI PHY node %pOFP\n", tbi); break; } } if (tbi) { const u32 *prop = of_get_property(tbi, "reg", NULL); if (!prop) { dev_err(&pdev->dev, "missing 'reg' property in node %pOF\n", tbi); err = -EBUSY; goto error; } set_tbipa(*prop, pdev, data->get_tbipa, priv->map, &res); } } if (data->ucc_configure) data->ucc_configure(res.start, res.end); err = of_mdiobus_register(new_bus, np); if (err) { dev_err(&pdev->dev, "cannot register %s as MDIO bus\n", new_bus->name); goto error; } return 0; error: if (priv->map) iounmap(priv->map); kfree(new_bus); return err; } static int fsl_pq_mdio_remove(struct platform_device *pdev) { struct device *device = &pdev->dev; struct mii_bus *bus = dev_get_drvdata(device); struct fsl_pq_mdio_priv *priv = bus->priv; mdiobus_unregister(bus); iounmap(priv->map); mdiobus_free(bus); return 0; } static struct platform_driver fsl_pq_mdio_driver = { .driver = { .name = "fsl-pq_mdio", .of_match_table = fsl_pq_mdio_match, }, .probe = fsl_pq_mdio_probe, .remove = fsl_pq_mdio_remove, }; module_platform_driver(fsl_pq_mdio_driver); MODULE_LICENSE("GPL");
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