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w5100.cpp
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w5100.cpp
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/****************************************************************************************************************************
w5100.cpp - Driver for W5x00
EthernetWebServer is a library for the Ethernet shields to run WebServer
Based on and modified from ESP8266 https://github.com/esp8266/Arduino/releases
Built by Khoi Hoang https://github.com/khoih-prog/EthernetWebServer
Licensed under MIT license
Version: 1.0.9
Copyright 2018 Paul Stoffregen
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 AUTHORS OR COPYRIGHT
HOLDERS 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.
Version Modified By Date Comments
------- ----------- ---------- -----------
1.0.0 K Hoang 13/02/2020 Initial coding for Arduino Mega, Teensy, etc to support Ethernetx libraries
1.0.1 K Hoang 20/02/2020 Add support to lambda functions
1.0.2 K Hoang 20/02/2020 Add support to UIPEthernet library for ENC28J60
1.0.3 K Hoang 23/02/2020 Add support to SAM DUE / SAMD21 boards
1.0.4 K Hoang 16/04/2020 Add support to SAMD51 boards
1.0.5 K Hoang 24/04/2020 Add support to nRF52 boards, such as AdaFruit Feather nRF52832, nRF52840 Express, BlueFruit Sense,
Itsy-Bitsy nRF52840 Express, Metro nRF52840 Express, NINA_B30_ublox, etc.
More Custom Ethernet libraries supported such as Ethernet2, Ethernet3, EthernetLarge
1.0.6 K Hoang 27/04/2020 Add support to ESP32/ESP8266 boards
1.0.7 K Hoang 30/04/2020 Add ENC28J60 support to ESP32/ESP8266 boards
1.0.8 K Hoang 12/05/2020 Fix W5x00 support for ESP8266 boards.
1.0.9 K Hoang 15/05/2020 Add EthernetWrapper.h for easier W5x00 support as well as more Ethernet libs in the future.
*****************************************************************************************************************************/
#include <Arduino.h>
#include "Ethernet.h"
#include "w5100.h"
#define W5100_DEBUG 1
/***************************************************/
/** Default SS pin setting **/
/***************************************************/
// If variant.h or other headers specifically define the
// default SS pin for ethernet, use it.
#if defined(PIN_SPI_SS_ETHERNET_LIB)
#define SS_PIN_DEFAULT PIN_SPI_SS_ETHERNET_LIB
//KH
#warning w5100.cpp Use PIN_SPI_SS_ETHERNET_LIB defined, change SS_PIN_DEFAULT to PIN_SPI_SS_ETHERNET_LIB
// MKR boards default to pin 5 for MKR ETH
// Pins 8-10 are MOSI/SCK/MISO on MRK, so don't use pin 10
#elif defined(USE_ARDUINO_MKR_PIN_LAYOUT) || defined(ARDUINO_SAMD_MKRZERO) || defined(ARDUINO_SAMD_MKR1000) || defined(ARDUINO_SAMD_MKRFox1200) || defined(ARDUINO_SAMD_MKRGSM1400) || defined(ARDUINO_SAMD_MKRWAN1300)
#define SS_PIN_DEFAULT 5
//KH
#warning w5100.cpp Use MKR, change SS_PIN_DEFAULT to 5
// For boards using AVR, assume shields with SS on pin 10
// will be used. This allows for Arduino Mega (where
// SS is pin 53) and Arduino Leonardo (where SS is pin 17)
// to work by default with Arduino Ethernet Shield R2 & R3.
#elif defined(__AVR__)
#define SS_PIN_DEFAULT 10
//KH
#warning w5100.cpp Use __AVR__, change SS_PIN_DEFAULT to 10
// If variant.h or other headers define these names
// use them if none of the other cases match
#elif defined(PIN_SPI_SS)
#if defined(__SAMD21G18A__)
//10 - 2 (6 conflict) all not OK for Nano 33 IoT !!! SPI corrupted???
#warning w5100.cpp Use __SAMD21G18A__, change SS_PIN_DEFAULT to 10
#define SS_PIN_DEFAULT 10
#else
#define SS_PIN_DEFAULT PIN_SPI_SS
//KH
#warning w5100.cpp Use PIN_SPI_SS defined, change SS_PIN_DEFAULT to PIN_SPI_SS
#endif
#elif defined(CORE_SS0_PIN)
#define SS_PIN_DEFAULT CORE_SS0_PIN
//KH
#warning w5100.cpp Use CORE_SS0_PIN defined, change SS_PIN_DEFAULT to CORE_SS0_PIN
//KH for ESP32
#elif defined(ESP32)
//pin SS already defined in ESP32 as pin 5, don't use this as conflict with SPIFFS, EEPROM, etc.
// Use in GPIO22
#warning w5100.cpp Use ESP32, change SS_PIN_DEFAULT to GPIO22, MOSI(23), MISO(19), SCK(18)
#define SS_PIN_DEFAULT 22 //SS
///////
//KH for ESP8266
#elif defined(ESP8266)
//pin SS already defined in ESP8266 as pin 15. Conflict => Move to pin GPIO4 (D2)
#warning w5100.cpp Use ESP8266, change SS_PIN_DEFAULT to SS(4), MOSI(13), MISO(12), SCK(14)
#define SS_PIN_DEFAULT D2 // GPIO4, SS
///////
// As a final fallback, use pin 10
#else
#define SS_PIN_DEFAULT 10
//KH
#warning w5100.cpp Use fallback, change SS_PIN_DEFAULT to 10
#endif
// W5100 controller instance
uint8_t W5100Class::chip = 0;
uint8_t W5100Class::CH_BASE_MSB;
uint8_t W5100Class::ss_pin = SS_PIN_DEFAULT;
#ifdef ETHERNET_LARGE_BUFFERS
uint16_t W5100Class::SSIZE = 2048;
uint16_t W5100Class::SMASK = 0x07FF;
#endif
W5100Class W5100;
// pointers and bitmasks for optimized SS pin
#if defined(__AVR__)
volatile uint8_t * W5100Class::ss_pin_reg;
uint8_t W5100Class::ss_pin_mask;
#elif defined(__MK20DX128__) || defined(__MK20DX256__) || defined(__MK66FX1M0__) || defined(__MK64FX512__)
volatile uint8_t * W5100Class::ss_pin_reg;
#elif defined(__IMXRT1062__)
volatile uint32_t * W5100Class::ss_pin_reg;
uint32_t W5100Class::ss_pin_mask;
#elif defined(__MKL26Z64__)
volatile uint8_t * W5100Class::ss_pin_reg;
uint8_t W5100Class::ss_pin_mask;
#elif defined(__SAM3X8E__) || defined(__SAM3A8C__) || defined(__SAM3A4C__)
volatile uint32_t * W5100Class::ss_pin_reg;
uint32_t W5100Class::ss_pin_mask;
#elif defined(__PIC32MX__)
volatile uint32_t * W5100Class::ss_pin_reg;
uint32_t W5100Class::ss_pin_mask;
#elif defined(ARDUINO_ARCH_ESP8266)
volatile uint32_t * W5100Class::ss_pin_reg;
uint32_t W5100Class::ss_pin_mask;
#elif defined(__SAMD21G18A__)
volatile uint32_t * W5100Class::ss_pin_reg;
uint32_t W5100Class::ss_pin_mask;
#warning w5100.cpp Use __SAMD21G18A__
#endif
// KH
uint8_t W5100Class::init(uint8_t socketNumbers, uint8_t new_ss_pin)
{
uint8_t i;
if (initialized) return 1;
// Many Ethernet shields have a CAT811 or similar reset chip
// connected to W5100 or W5200 chips. The W5200 will not work at
// all, and may even drive its MISO pin, until given an active low
// reset pulse! The CAT811 has a 240 ms typical pulse length, and
// a 400 ms worst case maximum pulse length. MAX811 has a worst
// case maximum 560 ms pulse length. This delay is meant to wait
// until the reset pulse is ended. If your hardware has a shorter
// reset time, this can be edited or removed.
delay(560);
//W5100Class::ss_pin = new_ss_pin;
#if ( W5100_DEBUG > 0 )
//KH
Serial.print("\nW5100 init, using SS_PIN_DEFAULT = ");
Serial.print(SS_PIN_DEFAULT);
Serial.print(", new ss_pin = ");
Serial.print(new_ss_pin);
Serial.print(", W5100Class::ss_pin = ");
Serial.println(W5100Class::ss_pin);
#endif
SPI.begin();
initSS();
resetSS();
// From #define SPI_ETHERNET_SETTINGS SPISettings(14000000, MSBFIRST, SPI_MODE0)
SPI.beginTransaction(SPI_ETHERNET_SETTINGS);
// Attempt W5200 detection first, because W5200 does not properly
// reset its SPI state when CS goes high (inactive). Communication
// from detecting the other chips can leave the W5200 in a state
// where it won't recover, unless given a reset pulse.
if (isW5200())
{
CH_BASE_MSB = 0x40;
#ifdef ETHERNET_LARGE_BUFFERS
#if MAX_SOCK_NUM <= 1
SSIZE = 16384;
#elif MAX_SOCK_NUM <= 2
SSIZE = 8192;
#elif MAX_SOCK_NUM <= 4
SSIZE = 4096;
#else
SSIZE = 2048;
#endif
SMASK = SSIZE - 1;
#endif
for (i=0; i<MAX_SOCK_NUM; i++)
{
writeSnRX_SIZE(i, SSIZE >> 10);
writeSnTX_SIZE(i, SSIZE >> 10);
}
for (; i<8; i++)
{
writeSnRX_SIZE(i, 0);
writeSnTX_SIZE(i, 0);
}
#if ( W5100_DEBUG > 0 )
Serial.print("W5100::init: W5200, SSIZE =");
Serial.println(SSIZE);
#endif
// Try W5500 next. Wiznet finally seems to have implemented
// SPI well with this chip. It appears to be very resilient,
// so try it after the fragile W5200
} else if (isW5500())
{
CH_BASE_MSB = 0x10;
#ifdef ETHERNET_LARGE_BUFFERS
#if MAX_SOCK_NUM <= 1
SSIZE = 16384;
#elif MAX_SOCK_NUM <= 2
SSIZE = 8192;
#elif MAX_SOCK_NUM <= 4
SSIZE = 4096;
#else
SSIZE = 2048;
#endif
SMASK = SSIZE - 1;
for (i=0; i<MAX_SOCK_NUM; i++)
{
writeSnRX_SIZE(i, SSIZE >> 10);
writeSnTX_SIZE(i, SSIZE >> 10);
}
for (; i<8; i++)
{
writeSnRX_SIZE(i, 0);
writeSnTX_SIZE(i, 0);
}
#endif
#if ( W5100_DEBUG > 0 )
Serial.print("W5100::init: W5500, SSIZE =");
Serial.println(SSIZE);
#endif
// Try W5100 last. This simple chip uses fixed 4 byte frames
// for every 8 bit access. Terribly inefficient, but so simple
// it recovers from "hearing" unsuccessful W5100 or W5200
// communication. W5100 is also the only chip without a VERSIONR
// register for identification, so we check this last.
} else if (isW5100())
{
CH_BASE_MSB = 0x04;
#ifdef ETHERNET_LARGE_BUFFERS
#if MAX_SOCK_NUM <= 1
SSIZE = 8192;
writeTMSR(0x03);
writeRMSR(0x03);
#else
SSIZE = 4096;
writeTMSR(0x0A);
writeRMSR(0x0A);
#endif
SMASK = SSIZE - 1;
#else
writeTMSR(0x55);
writeRMSR(0x55);
#endif
#if ( W5100_DEBUG > 0 )
Serial.print("W5100::init: W5100, SSIZE =");
Serial.println(SSIZE);
#endif
// No hardware seems to be present. Or it could be a W5200
// that's heard other SPI communication if its chip select
// pin wasn't high when a SD card or other SPI chip was used.
}
else
{
#if ( W5100_DEBUG > 0 )
Serial.println("no chip :-(");
#endif
chip = 0;
SPI.endTransaction();
return 0; // no known chip is responding :-(
}
SPI.endTransaction();
initialized = true;
return 1; // successful init
}
// Soft reset the Wiznet chip, by writing to its MR register reset bit
uint8_t W5100Class::softReset(void)
{
uint16_t count=0;
#if ( W5100_DEBUG > 1 )
Serial.println("Wiznet soft reset");
#endif
// write to reset bit
writeMR(0x80);
// then wait for soft reset to complete
do
{
uint8_t mr = readMR();
#if ( W5100_DEBUG > 2 )
Serial.print("mr=");
Serial.println(mr, HEX);
#endif
if (mr == 0)
return 1;
delay(1);
} while (++count < 20);
return 0;
}
uint8_t W5100Class::isW5100(void)
{
chip = 51;
#if ( W5100_DEBUG > 1 )
Serial.println("W5100.cpp: detect W5100 chip");
#endif
if (!softReset())
return 0;
writeMR(0x10);
if (readMR() != 0x10)
return 0;
writeMR(0x12);
if (readMR() != 0x12)
return 0;
writeMR(0x00);
if (readMR() != 0x00)
return 0;
#if ( W5100_DEBUG > 1 )
Serial.println("chip is W5100");
#endif
return 1;
}
uint8_t W5100Class::isW5200(void)
{
chip = 52;
#if ( W5100_DEBUG > 1 )
Serial.println("W5100.cpp: detect W5200 chip");
#endif
if (!softReset())
return 0;
writeMR(0x08);
if (readMR() != 0x08)
return 0;
writeMR(0x10);
if (readMR() != 0x10)
return 0;
writeMR(0x00);
if (readMR() != 0x00)
return 0;
int ver = readVERSIONR_W5200();
#if ( W5100_DEBUG > 1 )
Serial.print("version=");
Serial.println(ver);
#endif
if (ver != 3)
return 0;
#if ( W5100_DEBUG > 1 )
Serial.println("chip is W5200");
#endif
return 1;
}
uint8_t W5100Class::isW5500(void)
{
chip = 55;
#if ( W5100_DEBUG > 1 )
Serial.println("W5100.cpp: detect W5500 chip");
#endif
if (!softReset())
return 0;
writeMR(0x08);
if (readMR() != 0x08)
return 0;
writeMR(0x10);
if (readMR() != 0x10)
return 0;
writeMR(0x00);
if (readMR() != 0x00)
return 0;
int ver = readVERSIONR_W5500();
#if ( W5100_DEBUG > 1 )
Serial.print("version=");
Serial.println(ver);
#endif
if (ver != 4)
return 0;
#if ( W5100_DEBUG > 1 )
Serial.println("chip is W5500");
#endif
return 1;
}
W5100Linkstatus W5100Class::getLinkStatus()
{
uint8_t phystatus;
// KH
if (!initialized) return UNKNOWN;
switch (chip)
{
case 52:
SPI.beginTransaction(SPI_ETHERNET_SETTINGS);
phystatus = readPSTATUS_W5200();
SPI.endTransaction();
if (phystatus & 0x20)
return LINK_ON;
return LINK_OFF;
case 55:
SPI.beginTransaction(SPI_ETHERNET_SETTINGS);
phystatus = readPHYCFGR_W5500();
SPI.endTransaction();
if (phystatus & 0x01)
return LINK_ON;
return LINK_OFF;
default:
return UNKNOWN;
}
}
uint16_t W5100Class::write(uint16_t addr, const uint8_t *buf, uint16_t len)
{
uint8_t cmd[8];
if (chip == 51)
{
for (uint16_t i=0; i<len; i++)
{
setSS();
SPI.transfer(0xF0);
SPI.transfer(addr >> 8);
SPI.transfer(addr & 0xFF);
addr++;
SPI.transfer(buf[i]);
resetSS();
}
}
else if (chip == 52)
{
setSS();
cmd[0] = addr >> 8;
cmd[1] = addr & 0xFF;
cmd[2] = ((len >> 8) & 0x7F) | 0x80;
cmd[3] = len & 0xFF;
SPI.transfer(cmd, 4);
#ifdef SPI_HAS_TRANSFER_BUF
SPI.transfer(buf, NULL, len);
#else
// TODO: copy 8 bytes at a time to cmd[] and block transfer
for (uint16_t i=0; i < len; i++)
{
SPI.transfer(buf[i]);
}
#endif
resetSS();
}
else
{
// chip == 55
setSS();
if (addr < 0x100)
{
// common registers 00nn
cmd[0] = 0;
cmd[1] = addr & 0xFF;
cmd[2] = 0x04;
}
else if (addr < 0x8000)
{
// socket registers 10nn, 11nn, 12nn, 13nn, etc
cmd[0] = 0;
cmd[1] = addr & 0xFF;
cmd[2] = ((addr >> 3) & 0xE0) | 0x0C;
}
else if (addr < 0xC000)
{
// transmit buffers 8000-87FF, 8800-8FFF, 9000-97FF, etc
// 10## #nnn nnnn nnnn
cmd[0] = addr >> 8;
cmd[1] = addr & 0xFF;
#if defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 1
cmd[2] = 0x14; // 16K buffers
#elif defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 2
cmd[2] = ((addr >> 8) & 0x20) | 0x14; // 8K buffers
#elif defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 4
cmd[2] = ((addr >> 7) & 0x60) | 0x14; // 4K buffers
#else
cmd[2] = ((addr >> 6) & 0xE0) | 0x14; // 2K buffers
#endif
}
else
{
// receive buffers
cmd[0] = addr >> 8;
cmd[1] = addr & 0xFF;
#if defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 1
cmd[2] = 0x1C; // 16K buffers
#elif defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 2
cmd[2] = ((addr >> 8) & 0x20) | 0x1C; // 8K buffers
#elif defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 4
cmd[2] = ((addr >> 7) & 0x60) | 0x1C; // 4K buffers
#else
cmd[2] = ((addr >> 6) & 0xE0) | 0x1C; // 2K buffers
#endif
}
if (len <= 5)
{
for (uint8_t i=0; i < len; i++)
{
cmd[i + 3] = buf[i];
}
SPI.transfer(cmd, len + 3);
}
else
{
SPI.transfer(cmd, 3);
#ifdef SPI_HAS_TRANSFER_BUF
SPI.transfer(buf, NULL, len);
#else
// TODO: copy 8 bytes at a time to cmd[] and block transfer
for (uint16_t i=0; i < len; i++)
{
SPI.transfer(buf[i]);
}
#endif
}
resetSS();
}
return len;
}
uint16_t W5100Class::read(uint16_t addr, uint8_t *buf, uint16_t len)
{
uint8_t cmd[4];
if (chip == 51)
{
for (uint16_t i=0; i < len; i++)
{
setSS();
#if 1
SPI.transfer(0x0F);
SPI.transfer(addr >> 8);
SPI.transfer(addr & 0xFF);
addr++;
buf[i] = SPI.transfer(0);
#else
cmd[0] = 0x0F;
cmd[1] = addr >> 8;
cmd[2] = addr & 0xFF;
cmd[3] = 0;
SPI.transfer(cmd, 4); // TODO: why doesn't this work?
buf[i] = cmd[3];
addr++;
#endif
resetSS();
}
}
else if (chip == 52)
{
setSS();
cmd[0] = addr >> 8;
cmd[1] = addr & 0xFF;
cmd[2] = (len >> 8) & 0x7F;
cmd[3] = len & 0xFF;
SPI.transfer(cmd, 4);
memset(buf, 0, len);
SPI.transfer(buf, len);
resetSS();
}
else
{
// chip == 55
setSS();
if (addr < 0x100)
{
// common registers 00nn
cmd[0] = 0;
cmd[1] = addr & 0xFF;
cmd[2] = 0x00;
}
else if (addr < 0x8000)
{
// socket registers 10nn, 11nn, 12nn, 13nn, etc
cmd[0] = 0;
cmd[1] = addr & 0xFF;
cmd[2] = ((addr >> 3) & 0xE0) | 0x08;
}
else if (addr < 0xC000)
{
// transmit buffers 8000-87FF, 8800-8FFF, 9000-97FF, etc
// 10## #nnn nnnn nnnn
cmd[0] = addr >> 8;
cmd[1] = addr & 0xFF;
#if defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 1
cmd[2] = 0x10; // 16K buffers
#elif defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 2
cmd[2] = ((addr >> 8) & 0x20) | 0x10; // 8K buffers
#elif defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 4
cmd[2] = ((addr >> 7) & 0x60) | 0x10; // 4K buffers
#else
cmd[2] = ((addr >> 6) & 0xE0) | 0x10; // 2K buffers
#endif
} else
{
// receive buffers
cmd[0] = addr >> 8;
cmd[1] = addr & 0xFF;
#if defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 1
cmd[2] = 0x18; // 16K buffers
#elif defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 2
cmd[2] = ((addr >> 8) & 0x20) | 0x18; // 8K buffers
#elif defined(ETHERNET_LARGE_BUFFERS) && MAX_SOCK_NUM <= 4
cmd[2] = ((addr >> 7) & 0x60) | 0x18; // 4K buffers
#else
cmd[2] = ((addr >> 6) & 0xE0) | 0x18; // 2K buffers
#endif
}
SPI.transfer(cmd, 3);
memset(buf, 0, len);
SPI.transfer(buf, len);
resetSS();
}
return len;
}
void W5100Class::execCmdSn(SOCKET s, SockCMD _cmd)
{
// Send command to socket
writeSnCR(s, _cmd);
// Wait for command to complete
while (readSnCR(s)) ;
}