/* * Copyright 2021 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. * */ #include "amdgpu_eeprom.h" #include "amdgpu.h" /* AT24CM02 and M24M02-R have a 256-byte write page size. */ #define EEPROM_PAGE_BITS 8 #define EEPROM_PAGE_SIZE (1U << EEPROM_PAGE_BITS) #define EEPROM_PAGE_MASK (EEPROM_PAGE_SIZE - 1) #define EEPROM_OFFSET_SIZE 2 /* EEPROM memory addresses are 19-bits long, which can * be partitioned into 3, 8, 8 bits, for a total of 19. * The upper 3 bits are sent as part of the 7-bit * "Device Type Identifier"--an I2C concept, which for EEPROM devices * is hard-coded as 1010b, indicating that it is an EEPROM * device--this is the wire format, followed by the upper * 3 bits of the 19-bit address, followed by the direction, * followed by two bytes holding the rest of the 16-bits of * the EEPROM memory address. The format on the wire for EEPROM * devices is: 1010XYZD, A15:A8, A7:A0, * Where D is the direction and sequenced out by the hardware. * Bits XYZ are memory address bits 18, 17 and 16. * These bits are compared to how pins 1-3 of the part are connected, * depending on the size of the part, more on that later. * * Note that of this wire format, a client is in control * of, and needs to specify only XYZ, A15:A8, A7:0, bits, * which is exactly the EEPROM memory address, or offset, * in order to address up to 8 EEPROM devices on the I2C bus. * * For instance, a 2-Mbit I2C EEPROM part, addresses all its bytes, * using an 18-bit address, bit 17 to 0 and thus would use all but one bit of * the 19 bits previously mentioned. The designer would then not connect * pins 1 and 2, and pin 3 usually named "A_2" or "E2", would be connected to * either Vcc or GND. This would allow for up to two 2-Mbit parts on * the same bus, where one would be addressable with bit 18 as 1, and * the other with bit 18 of the address as 0. * * For a 2-Mbit part, bit 18 is usually known as the "Chip Enable" or * "Hardware Address Bit". This bit is compared to the load on pin 3 * of the device, described above, and if there is a match, then this * device responds to the command. This way, you can connect two * 2-Mbit EEPROM devices on the same bus, but see one contiguous * memory from 0 to 7FFFFh, where address 0 to 3FFFF is in the device * whose pin 3 is connected to GND, and address 40000 to 7FFFFh is in * the 2nd device, whose pin 3 is connected to Vcc. * * This addressing you encode in the 32-bit "eeprom_addr" below, * namely the 19-bits "XYZ,A15:A0", as a single 19-bit address. For * instance, eeprom_addr = 0x6DA01, is 110_1101_1010_0000_0001, where * XYZ=110b, and A15:A0=DA01h. The XYZ bits become part of the device * address, and the rest of the address bits are sent as the memory * address bytes. * * That is, for an I2C EEPROM driver everything is controlled by * the "eeprom_addr". * * P.S. If you need to write, lock and read the Identification Page, * (M24M02-DR device only, which we do not use), change the "7" to * "0xF" in the macro below, and let the client set bit 20 to 1 in * "eeprom_addr", and set A10 to 0 to write into it, and A10 and A1 to * 1 to lock it permanently. */ #define MAKE_I2C_ADDR(_aa) ((0xA << 3) | (((_aa) >> 16) & 7)) static int __amdgpu_eeprom_xfer(struct i2c_adapter *i2c_adap, u32 eeprom_addr, u8 *eeprom_buf, u16 buf_size, bool read) { u8 eeprom_offset_buf[EEPROM_OFFSET_SIZE]; struct i2c_msg msgs[] = { { .flags = 0, .len = EEPROM_OFFSET_SIZE, .buf = eeprom_offset_buf, }, { .flags = read ? I2C_M_RD : 0, }, }; const u8 *p = eeprom_buf; int r; u16 len; for (r = 0; buf_size > 0; buf_size -= len, eeprom_addr += len, eeprom_buf += len) { /* Set the EEPROM address we want to write to/read from. */ msgs[0].addr = MAKE_I2C_ADDR(eeprom_addr); msgs[1].addr = msgs[0].addr; msgs[0].buf[0] = (eeprom_addr >> 8) & 0xff; msgs[0].buf[1] = eeprom_addr & 0xff; if (!read) { /* Write the maximum amount of data, without * crossing the device's page boundary, as per * its spec. Partial page writes are allowed, * starting at any location within the page, * so long as the page boundary isn't crossed * over (actually the page pointer rolls * over). * * As per the AT24CM02 EEPROM spec, after * writing into a page, the I2C driver should * terminate the transfer, i.e. in * "i2c_transfer()" below, with a STOP * condition, so that the self-timed write * cycle begins. This is implied for the * "i2c_transfer()" abstraction. */ len = min(EEPROM_PAGE_SIZE - (eeprom_addr & EEPROM_PAGE_MASK), (u32)buf_size); } else { /* Reading from the EEPROM has no limitation * on the number of bytes read from the EEPROM * device--they are simply sequenced out. */ len = buf_size; } msgs[1].len = len; msgs[1].buf = eeprom_buf; /* This constitutes a START-STOP transaction. */ r = i2c_transfer(i2c_adap, msgs, ARRAY_SIZE(msgs)); if (r != ARRAY_SIZE(msgs)) break; if (!read) { /* According to EEPROM specs the length of the * self-writing cycle, tWR (tW), is 10 ms. * * TODO: Use polling on ACK, aka Acknowledge * Polling, to minimize waiting for the * internal write cycle to complete, as it is * usually smaller than tWR (tW). */ msleep(10); } } return r < 0 ? r : eeprom_buf - p; } /** * amdgpu_eeprom_xfer -- Read/write from/to an I2C EEPROM device * @i2c_adap: pointer to the I2C adapter to use * @eeprom_addr: EEPROM address from which to read/write * @eeprom_buf: pointer to data buffer to read into/write from * @buf_size: the size of @eeprom_buf * @read: True if reading from the EEPROM, false if writing * * Returns the number of bytes read/written; -errno on error. */ static int amdgpu_eeprom_xfer(struct i2c_adapter *i2c_adap, u32 eeprom_addr, u8 *eeprom_buf, u16 buf_size, bool read) { const struct i2c_adapter_quirks *quirks = i2c_adap->quirks; u16 limit; if (!quirks) limit = 0; else if (read) limit = quirks->max_read_len; else limit = quirks->max_write_len; if (limit == 0) { return __amdgpu_eeprom_xfer(i2c_adap, eeprom_addr, eeprom_buf, buf_size, read); } else if (limit <= EEPROM_OFFSET_SIZE) { dev_err_ratelimited(&i2c_adap->dev, "maddr:0x%04X size:0x%02X:quirk max_%s_len must be > %d", eeprom_addr, buf_size, read ? "read" : "write", EEPROM_OFFSET_SIZE); return -EINVAL; } else { u16 ps; /* Partial size */ int res = 0, r; /* The "limit" includes all data bytes sent/received, * which would include the EEPROM_OFFSET_SIZE bytes. * Account for them here. */ limit -= EEPROM_OFFSET_SIZE; for ( ; buf_size > 0; buf_size -= ps, eeprom_addr += ps, eeprom_buf += ps) { ps = min(limit, buf_size); r = __amdgpu_eeprom_xfer(i2c_adap, eeprom_addr, eeprom_buf, ps, read); if (r < 0) return r; res += r; } return res; } } int amdgpu_eeprom_read(struct i2c_adapter *i2c_adap, u32 eeprom_addr, u8 *eeprom_buf, u16 bytes) { return amdgpu_eeprom_xfer(i2c_adap, eeprom_addr, eeprom_buf, bytes, true); } int amdgpu_eeprom_write(struct i2c_adapter *i2c_adap, u32 eeprom_addr, u8 *eeprom_buf, u16 bytes) { return amdgpu_eeprom_xfer(i2c_adap, eeprom_addr, eeprom_buf, bytes, false); }