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2 Commits
master ... doublebuf

Author SHA1 Message Date
Ondřej Hruška 4a041485fb
broken things buuuu
6 years ago
Ondřej Hruška af70cd7488
Fix for double buffered USB and other cummulative fixes
6 years ago
114 changed files with 372 additions and 12463 deletions
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Show Stats
  1. 4
      .gitignore
  2. 6
      .gitmodules
  3. 61
      CMakeLists.txt
  4. 111
      Drivers/STM32F0xx_HAL_Driver/Src/stm32f0xx_hal_pcd.c
  5. 1
      GexCore
  6. 129
      GexUnits/1wire/_ow_api.c
  7. 18
      GexUnits/1wire/_ow_commands.h
  8. 59
      GexUnits/1wire/_ow_init.c
  9. 60
      GexUnits/1wire/_ow_internal.h
  10. 223
      GexUnits/1wire/_ow_low_level.c
  11. 84
      GexUnits/1wire/_ow_low_level.h
  12. 129
      GexUnits/1wire/_ow_search.c
  13. 83
      GexUnits/1wire/_ow_search.h
  14. 68
      GexUnits/1wire/_ow_settings.c
  15. 246
      GexUnits/1wire/unit_1wire.c
  16. 79
      GexUnits/1wire/unit_1wire.h
  17. 700
      GexUnits/adc/_adc_core.c
  18. 269
      GexUnits/adc/_adc_init.c
  19. 161
      GexUnits/adc/_adc_internal.h
  20. 117
      GexUnits/adc/_adc_settings.c
  21. 428
      GexUnits/adc/unit_adc.c
  22. 15
      GexUnits/adc/unit_adc.h
  23. 84
      GexUnits/dac/_dac_api.c
  24. 392
      GexUnits/dac/_dac_core.c
  25. 144
      GexUnits/dac/_dac_init.c
  26. 111
      GexUnits/dac/_dac_internal.h
  27. 131
      GexUnits/dac/_dac_settings.c
  28. 166
      GexUnits/dac/unit_dac.c
  29. 16
      GexUnits/dac/unit_dac.h
  30. 71
      GexUnits/din/_din_api.c
  31. 80
      GexUnits/din/_din_exti.c
  32. 139
      GexUnits/din/_din_init.c
  33. 65
      GexUnits/din/_din_internal.h
  34. 118
      GexUnits/din/_din_settings.c
  35. 94
      GexUnits/din/unit_din.c
  36. 42
      GexUnits/din/unit_din.h
  37. 173
      GexUnits/dout/_dout_api.c
  38. 71
      GexUnits/dout/_dout_init.c
  39. 54
      GexUnits/dout/_dout_internal.h
  40. 82
      GexUnits/dout/_dout_settings.c
  41. 66
      GexUnits/dout/unit_dout.c
  42. 71
      GexUnits/dout/unit_dout.h
  43. 11
      GexUnits/fcap/_fcap_api.c
  44. 461
      GexUnits/fcap/_fcap_core.c
  45. 147
      GexUnits/fcap/_fcap_init.c
  46. 117
      GexUnits/fcap/_fcap_internal.h
  47. 114
      GexUnits/fcap/_fcap_settings.c
  48. 322
      GexUnits/fcap/unit_fcap.c
  49. 16
      GexUnits/fcap/unit_fcap.h
  50. 123
      GexUnits/i2c/_i2c_api.c
  51. 160
      GexUnits/i2c/_i2c_init.c
  52. 51
      GexUnits/i2c/_i2c_internal.h
  53. 103
      GexUnits/i2c/_i2c_settings.c
  54. 88
      GexUnits/i2c/unit_i2c.c
  55. 76
      GexUnits/i2c/unit_i2c.h
  56. 53
      GexUnits/neopixel/_npx_api.c
  57. 58
      GexUnits/neopixel/_npx_init.c
  58. 52
      GexUnits/neopixel/_npx_internal.h
  59. 61
      GexUnits/neopixel/_npx_settings.c
  60. 76
      GexUnits/neopixel/unit_neopixel.c
  61. 53
      GexUnits/neopixel/unit_neopixel.h
  62. 83
      GexUnits/neopixel/ws2812.c
  63. 37
      GexUnits/neopixel/ws2812.h
  64. 64
      GexUnits/pwmdim/_pwmdim_api.c
  65. 170
      GexUnits/pwmdim/_pwmdim_init.c
  66. 65
      GexUnits/pwmdim/_pwmdim_internal.h
  67. 89
      GexUnits/pwmdim/_pwmdim_settings.c
  68. 69
      GexUnits/pwmdim/unit_pwmdim.c
  69. 16
      GexUnits/pwmdim/unit_pwmdim.h
  70. 110
      GexUnits/sipo/_sipo_api.c
  71. 113
      GexUnits/sipo/_sipo_init.c
  72. 120
      GexUnits/sipo/_sipo_internal.h
  73. 116
      GexUnits/sipo/_sipo_settings.c
  74. 73
      GexUnits/sipo/unit_sipo.c
  75. 16
      GexUnits/sipo/unit_sipo.h
  76. 103
      GexUnits/spi/_spi_api.c
  77. 195
      GexUnits/spi/_spi_init.c
  78. 59
      GexUnits/spi/_spi_internal.h
  79. 141
      GexUnits/spi/_spi_settings.c
  80. 84
      GexUnits/spi/unit_spi.c
  81. 63
      GexUnits/spi/unit_spi.h
  82. 2
      GexUnits/template/!README.TXT
  83. 11
      GexUnits/template/_tpl_api.c
  84. 49
      GexUnits/template/_tpl_init.c
  85. 46
      GexUnits/template/_tpl_internal.h
  86. 58
      GexUnits/template/_tpl_settings.c
  87. 23
      GexUnits/template/install.sh
  88. 57
      GexUnits/template/unit_tpl.c
  89. 16
      GexUnits/template/unit_tpl.h
  90. 11
      GexUnits/touch/_touch_api.c
  91. 217
      GexUnits/touch/_touch_core.c
  92. 221
      GexUnits/touch/_touch_init.c
  93. 95
      GexUnits/touch/_touch_internal.h
  94. 187
      GexUnits/touch/_touch_settings.c
  95. 136
      GexUnits/touch/unit_touch.c
  96. 16
      GexUnits/touch/unit_touch.h
  97. 57
      GexUnits/units_manifest.h
  98. 56
      GexUnits/usart/_usart_api.c
  99. 444
      GexUnits/usart/_usart_dmas.c
  100. 344
      GexUnits/usart/_usart_init.c
  101. Some files were not shown because too many files have changed in this diff Show More

4
.gitignore vendored
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@ -1,6 +1,3 @@
# The customized build.mk file
build.mk
# Prerequisites
*.d
*.tmp
@ -87,4 +84,3 @@ cmake-build-*
/main.flash.map
/disassembly.lst
/main.ram.map
build/*

6
.gitmodules vendored
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@ -1,3 +1,3 @@
[submodule "GexCore"]
path = GexCore
url = https://git.ondrovo.com/gex/gex-core.git
[submodule "User"]
path = User
url = git@github.com:MightyPork/gex-core

61
CMakeLists.txt
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@ -1,6 +1,3 @@
# This is a dummy CmakeLists.txt file for CLion.
# It does not work, don't even try.
cmake_minimum_required(VERSION 3.9)
project(GEX_F072)
@ -21,24 +18,8 @@ add_definitions(
-DVERBOSE_HARDFAULT=1
-DUSE_STACK_MONITOR=1
-DUSE_DEBUG_UART=1
-DGEX_PLAT_F072_ZERO
-DGEX_PLAT_F072_DISCOVERY
-DHAL_TSC_MODULE_ENABLED
-DENABLE_UNIT_1WIRE=1
-DENABLE_UNIT_ADC=1
-DENABLE_UNIT_DAC=1
-DENABLE_UNIT_DIGITAL_IN=1
-DENABLE_UNIT_DIGITAL_OUT=1
-DENABLE_UNIT_FCAP=1
-DENABLE_UNIT_I2C=1
-DENABLE_UNIT_NEOPIXEL=1
-DENABLE_UNIT_SIMPLE_PWM=1
-DENABLE_UNIT_SIPO=1
-DENABLE_UNIT_SPI=1
-DENABLE_UNIT_TEMPLATE=1
-DENABLE_UNIT_TEST=1
-DENABLE_UNIT_TOUCH=1
-DENABLE_UNIT_USART=1
)
FILE(GLOB_RECURSE SOURCE_FILES
@ -47,10 +28,8 @@ FILE(GLOB_RECURSE SOURCE_FILES
Drivers/*.h
Middlewares/*.c
Middlewares/*.h
GexCore/*.c
GexCore/*.h
GexUnits/*.c
GexUnits/*.h
User/*.c
User/*.h
Src/*.c
Src/*.h
)
@ -66,18 +45,18 @@ include_directories(
Drivers/STM32F0xx_HAL_Driver/Inc/Legacy
# USB Library
GexCore/USB/STM32_USB_Device_Library/Core/Inc
User/USB/STM32_USB_Device_Library/Core/Inc
# USB Device Classes
GexCore/USB/STM32_USB_Device_Library/Class/AUDIO/Inc
GexCore/USB/STM32_USB_Device_Library/Class/CDC/Inc
GexCore/USB/STM32_USB_Device_Library/Class/CustomHID/Inc
GexCore/USB/STM32_USB_Device_Library/Class/DFU/Inc
GexCore/USB/STM32_USB_Device_Library/Class/HID/Inc
GexCore/USB/STM32_USB_Device_Library/Class/MSC/Inc
GexCore/USB/STM32_USB_Device_Library/Class/MSC_CDC
User/USB/STM32_USB_Device_Library/Class/AUDIO/Inc
User/USB/STM32_USB_Device_Library/Class/CDC/Inc
User/USB/STM32_USB_Device_Library/Class/CustomHID/Inc
User/USB/STM32_USB_Device_Library/Class/DFU/Inc
User/USB/STM32_USB_Device_Library/Class/HID/Inc
User/USB/STM32_USB_Device_Library/Class/MSC/Inc
User/USB/STM32_USB_Device_Library/Class/MSC_CDC
# Other vendor libraries
GexCore/USB/STM32_TouchSensing_Library/inc
User/USB/STM32_TouchSensing_Library/inc
# FreeRTOS
Middlewares/Third_Party/FreeRTOS/Source/CMSIS_RTOS
@ -86,15 +65,15 @@ include_directories(
Middlewares/Third_Party/FreeRTOS/Source/portable/GCC/ARM_CM0
# Application
GexCore
GexCore/USB
GexCore/utils
GexCore/TinyFrame
GexCore/framework
GexCore/platform
GexCore/tasks
User
User/USB
User/utils
User/TinyFrame
User/framework
User/platform
User/tasks
User/units
Inc
GexUnits
)
add_executable(main ${SOURCE_FILES})

111
Drivers/STM32F0xx_HAL_Driver/Src/stm32f0xx_hal_pcd.c
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@ -70,12 +70,24 @@
*/
/* Includes ------------------------------------------------------------------*/
#include <utils/hexdump.h>
#include "stm32f0xx_hal.h"
#include "stdbool.h"
/** @addtogroup STM32F0xx_HAL_Driver
* @{
*/
static inline void dbgShowTog(PCD_HandleTypeDef *hpcd, bool strobe)
{
PCD_EPTypeDef *ep = &hpcd->IN_ep[2];
uint32_t v = (GPIOB->ODR & ~0b111);
if ((PCD_GET_ENDPOINT(hpcd->Instance, ep->num)& USB_EP_DTOG_TX) == USB_EP_DTOG_TX) v |= 1;
if ((PCD_GET_ENDPOINT(hpcd->Instance, ep->num)& USB_EP_DTOG_RX) == USB_EP_DTOG_RX) v |= 2;
GPIOB->ODR = v;
}
#ifdef HAL_PCD_MODULE_ENABLED
#if defined(STM32F042x6) || defined(STM32F048xx) || defined(STM32F072xB) || defined(STM32F078xx) || defined(STM32F070xB)|| defined(STM32F070x6)
@ -738,12 +750,16 @@ HAL_StatusTypeDef HAL_PCD_EP_Open(PCD_HandleTypeDef *hpcd, uint8_t ep_addr, uint
/* Clear the data toggle bits for the endpoint IN/OUT*/
PCD_CLEAR_RX_DTOG(hpcd->Instance, ep->num)
PCD_CLEAR_TX_DTOG(hpcd->Instance, ep->num)
PCD_RX_DTOG(hpcd->Instance, ep->num);
/* Configure DISABLE status for the Endpoint*/
PCD_SET_EP_TX_STATUS(hpcd->Instance, ep->num, USB_EP_TX_DIS)
PCD_SET_EP_RX_STATUS(hpcd->Instance, ep->num, USB_EP_RX_DIS)
}
}
}
dbgShowTog(hpcd, false);
__HAL_UNLOCK(hpcd);
return ret;
@ -903,12 +919,12 @@ HAL_StatusTypeDef HAL_PCD_EP_Transmit(PCD_HandleTypeDef *hpcd, uint8_t ep_addr,
ep->xfer_count = 0U;
ep->is_in = 1U;
ep->num = ep_addr & 0x7FU;
/*Multi packet transfer*/
if (ep->xfer_len > ep->maxpacket)
{
len=ep->maxpacket;
ep->xfer_len-=len;
ep->xfer_len-=len;
}
else
{
@ -925,23 +941,25 @@ HAL_StatusTypeDef HAL_PCD_EP_Transmit(PCD_HandleTypeDef *hpcd, uint8_t ep_addr,
else
{
/*Write the data to the USB endpoint*/
if ((PCD_GET_ENDPOINT(hpcd->Instance, ep->num)& USB_EP_DTOG_TX) == USB_EP_DTOG_TX)
if ((PCD_GET_ENDPOINT(hpcd->Instance, ep->num)& USB_EP_DTOG_RX) == USB_EP_DTOG_RX)
{
/*Set the Double buffer counter for pmabuffer1*/
PCD_SET_EP_DBUF1_CNT(hpcd->Instance, ep->num, ep->is_in, len)
pmabuffer = ep->pmaaddr1;
/*Set the Double buffer counter for pmabuffer0*/
PCD_SET_EP_DBUF0_CNT(hpcd->Instance, ep->num, ep->is_in, len)
pmabuffer = ep->pmaaddr0;
}
else
{
/*Set the Double buffer counter for pmabuffer0*/
PCD_SET_EP_DBUF0_CNT(hpcd->Instance, ep->num, ep->is_in, len)
pmabuffer = ep->pmaaddr0;
/*Set the Double buffer counter for pmabuffer1*/
PCD_SET_EP_DBUF1_CNT(hpcd->Instance, ep->num, ep->is_in, len)
pmabuffer = ep->pmaaddr1;
}
PCD_WritePMA(hpcd->Instance, ep->xfer_buff, pmabuffer, len);
PCD_WritePMA(hpcd->Instance, ep->xfer_buff, pmabuffer, (uint16_t) len);
PCD_FreeUserBuffer(hpcd->Instance, ep->num, ep->is_in)
}
dbgShowTog(hpcd, false);
PCD_SET_EP_TX_STATUS(hpcd->Instance, ep->num, USB_EP_TX_VALID)
return HAL_OK;
@ -1121,8 +1139,6 @@ PCD_StateTypeDef HAL_PCD_GetState(PCD_HandleTypeDef *hpcd)
* @}
*/
#pragma GCC push_options //GEX addition
#pragma GCC optimize ("O2")
/** @addtogroup PCD_Private_Functions
* @{
*/
@ -1181,7 +1197,6 @@ void PCD_ReadPMA(USB_TypeDef *USBx, uint8_t *pbUsrBuf, uint16_t wPMABufAddr, ui
*pbUsrBuf++ = ((temp >> 0) & 0xFF);
}
}
#pragma GCC pop_options //GEX addition
/**
* @brief This function handles PCD Endpoint interrupt request.
@ -1195,10 +1210,14 @@ static HAL_StatusTypeDef PCD_EP_ISR_Handler(PCD_HandleTypeDef *hpcd)
uint8_t EPindex;
__IO uint16_t wIstr;
__IO uint16_t wEPVal = 0U;
GPIOB->ODR |= 4;
for(volatile i=0;i<20;i++);
GPIOB->ODR &= ~4;
/* stay in loop while pending interrupts */
while (((wIstr = hpcd->Instance->ISTR) & USB_ISTR_CTR) != 0U)
{
/* extract highest priority endpoint number */
EPindex = (uint8_t)(wIstr & USB_ISTR_EP_ID);
@ -1338,15 +1357,19 @@ static HAL_StatusTypeDef PCD_EP_ISR_Handler(PCD_HandleTypeDef *hpcd)
/* clear int flag */
PCD_CLEAR_TX_EP_CTR(hpcd->Instance, EPindex);
/* IN double Buffering*/
// This function is full of strange code that causes the double buffered mode to not work
#define WANT_HAL_BUGS 0
#if WANT_HAL_BUGS
/* IN double Buffering*/
if (ep->doublebuffer == 0U)
{
ep->xfer_count = PCD_GET_EP_TX_CNT(hpcd->Instance, ep->num);
// if (ep->xfer_count != 0)
// {
// PCD_WritePMA(hpcd->Instance, ep->xfer_buff, ep->pmaadress, ep->xfer_count); // GEX FIX
// }
if (ep->xfer_count != 0)
{
PCD_WritePMA(hpcd->Instance, ep->xfer_buff, ep->pmaadress, ep->xfer_count);
}
}
else
{
@ -1368,13 +1391,50 @@ static HAL_StatusTypeDef PCD_EP_ISR_Handler(PCD_HandleTypeDef *hpcd)
PCD_WritePMA(hpcd->Instance, ep->xfer_buff, ep->pmaaddr1, ep->xfer_count);
}
}
PCD_FreeUserBuffer(hpcd->Instance, ep->num, PCD_EP_DBUF_IN)
PCD_FreeUserBuffer(hpcd->Instance, ep->num, PCD_EP_DBUF_IN)
}
/*multi-packet on the NON control IN endpoint*/
// ep->xfer_count = PCD_GET_EP_TX_CNT(hpcd->Instance, ep->num); // GEX FIX
ep->xfer_count = PCD_GET_EP_TX_CNT(hpcd->Instance, ep->num);
#else
uint8_t tmpbuf[64];
/* IN double Buffering*/
if (ep->doublebuffer == 0U)
{
ep->xfer_count = PCD_GET_EP_TX_CNT(hpcd->Instance, ep->num);
}
else
{
// NOTE: DTOG is inverted by the device at the end of a transaction
if ((PCD_GET_ENDPOINT(hpcd->Instance, ep->num)& USB_EP_DTOG_TX) == USB_EP_DTOG_TX)
{
/*read from endpoint BUF0Addr buffer*/
ep->xfer_count = PCD_GET_EP_DBUF0_CNT(hpcd->Instance, ep->num);
// PCD_ReadPMA(hpcd->Instance, tmpbuf, ep->pmaaddr0, ep->xfer_count);
// hexDump("buf0", tmpbuf, ep->xfer_count);
}
else
{
/*read from endpoint BUF1Addr buffer*/
ep->xfer_count = PCD_GET_EP_DBUF1_CNT(hpcd->Instance, ep->num);
// PCD_ReadPMA(hpcd->Instance, tmpbuf, ep->pmaaddr1, ep->xfer_count);
// hexDump("buf1", tmpbuf, ep->xfer_count);
}
}
#endif
// dbg("ISR: ep %02x Xferd %db, remain %d", ep->num, ep->xfer_count, ep->xfer_len);
ep->xfer_buff+=ep->xfer_count;
/* Zero Length Packet? */
if(ep->num==2) dbgShowTog(hpcd, true);
/* Zero Length Packet? <- what? */
if (ep->xfer_len == 0U)
{
/* TX COMPLETE */
@ -1382,6 +1442,7 @@ static HAL_StatusTypeDef PCD_EP_ISR_Handler(PCD_HandleTypeDef *hpcd)
}
else
{
trap("multipart!");
HAL_PCD_EP_Transmit(hpcd, ep->num, ep->xfer_buff, ep->xfer_len);
}
}

1
GexCore

@ -1 +0,0 @@
Subproject commit 3d3d74f3817e89a8c3ce2cb36501ad292b6ddc85

129
GexUnits/1wire/_ow_api.c
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@ -1,129 +0,0 @@
//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_1wire.h"
// 1WIRE master
#define OW_INTERNAL
#include "_ow_internal.h"
#include "_ow_commands.h"
#include "_ow_low_level.h"
/* Check presence of any devices on the bus */
error_t UU_1WIRE_CheckPresence(Unit *unit, bool *presence)
{
CHECK_TYPE(unit, &UNIT_1WIRE);
// reset
*presence = ow_reset(unit);
return E_SUCCESS;
}
/* Read address of a lone device on the bus */
error_t UU_1WIRE_ReadAddress(Unit *unit, uint64_t *address)
{
CHECK_TYPE(unit, &UNIT_1WIRE);
*address = 0;
if (!ow_reset(unit)) return E_HW_TIMEOUT;
// command
ow_write_u8(unit, OW_ROM_READ);
// read the ROM code
*address = ow_read_u64(unit);
const uint8_t *addr_as_bytes = (void*)address;
if (0 != ow_checksum(addr_as_bytes, 8)) {
*address = 0;
return E_CHECKSUM_MISMATCH; // checksum mismatch
}
return E_SUCCESS;
}
/* Write bytes to a device */
error_t UU_1WIRE_Write(Unit *unit, uint64_t address, const uint8_t *buff, uint32_t len)
{
CHECK_TYPE(unit, &UNIT_1WIRE);
if (!ow_reset(unit)) return E_HW_TIMEOUT;
// MATCH_ROM+addr, or SKIP_ROM
if (address != 0) {
ow_write_u8(unit, OW_ROM_MATCH);
ow_write_u64(unit, address);
} else {
ow_write_u8(unit, OW_ROM_SKIP);
}
// write the payload;
for (uint32_t i = 0; i < len; i++) {
ow_write_u8(unit, *buff++);
}
return E_SUCCESS;
}
/* Write a request to a device and read a response */
error_t UU_1WIRE_Read(Unit *unit, uint64_t address,
const uint8_t *request_buff, uint32_t request_len,
uint8_t *response_buff, uint32_t response_len, bool check_crc)
{
CHECK_TYPE(unit, &UNIT_1WIRE);
if (!ow_reset(unit)) return E_HW_TIMEOUT;
uint8_t *rb = response_buff;
// MATCH_ROM+addr, or SKIP_ROM
if (address != 0) {
ow_write_u8(unit, OW_ROM_MATCH);
ow_write_u64(unit, address);
} else {
ow_write_u8(unit, OW_ROM_SKIP);
}
// write the payload;
for (uint32_t i = 0; i < request_len; i++) {
ow_write_u8(unit, *request_buff++);
}
// read the requested number of bytes
for (uint32_t i = 0; i < response_len; i++) {
*rb++ = ow_read_u8(unit);
}
if (check_crc) {
if (0 != ow_checksum(response_buff, response_len)) {
return E_CHECKSUM_MISMATCH;
}
}
return E_SUCCESS;
}
/* Perform the search algorithm (start or continue) */
error_t UU_1WIRE_Search(Unit *unit, bool with_alarm, bool restart,
uint64_t *buffer, uint32_t capacity, uint32_t *real_count,
bool *have_more)
{
CHECK_TYPE(unit, &UNIT_1WIRE);
struct priv *priv = unit->data;
if (restart) {
uint8_t search_cmd = (uint8_t) (with_alarm ? OW_ROM_ALM_SEARCH : OW_ROM_SEARCH);
ow_search_init(unit, search_cmd, true);
}
*real_count = ow_search_run(unit, (ow_romcode_t *) buffer, capacity);
// resolve the code
switch (priv->searchState.status) {
case OW_SEARCH_MORE:
*have_more = priv->searchState.status == OW_SEARCH_MORE;
case OW_SEARCH_DONE:
return E_SUCCESS;
case OW_SEARCH_FAILED:
return priv->searchState.error;
}
return E_INTERNAL_ERROR;
}

18
GexUnits/1wire/_ow_commands.h
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@ -1,18 +0,0 @@
//
// Created by MightyPork on 2018/01/29.
//
#ifndef GEX_F072_OW_COMMANDS_H
#define GEX_F072_OW_COMMANDS_H
#ifndef OW_INTERNAL
#error bad include!
#endif
#define OW_ROM_SEARCH 0xF0
#define OW_ROM_READ 0x33
#define OW_ROM_MATCH 0x55
#define OW_ROM_SKIP 0xCC
#define OW_ROM_ALM_SEARCH 0xEC
#endif //GEX_F072_OW_COMMANDS_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define OW_INTERNAL
#include "_ow_internal.h"
/** Allocate data structure and set defaults */
error_t OW_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
// some defaults
priv->pin_number = 0;
priv->port_name = 'A';
priv->parasitic = false;
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t OW_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
// --- Parse config ---
priv->ll_pin = hw_pin2ll(priv->pin_number, &suc);
priv->port = hw_port2periph(priv->port_name, &suc);
Resource rsc = rsc_portpin2rsc(priv->port_name, priv->pin_number, &suc);
if (!suc) return E_BAD_CONFIG;
// --- Claim resources ---
TRY(rsc_claim(unit, rsc));
// --- Init hardware ---
LL_GPIO_SetPinMode(priv->port, priv->ll_pin, LL_GPIO_MODE_OUTPUT);
LL_GPIO_SetPinOutputType(priv->port, priv->ll_pin, LL_GPIO_OUTPUT_PUSHPULL);
LL_GPIO_SetPinSpeed(priv->port, priv->ll_pin, LL_GPIO_SPEED_FREQ_HIGH);
LL_GPIO_SetPinPull(priv->port, priv->ll_pin, LL_GPIO_PULL_UP); // pull-up for OD state
return E_SUCCESS;
}
/** Tear down the unit */
void OW_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// Release all resources
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/01/29.
//
#ifndef GEX_F072_OW_INTERNAL_H
#define GEX_F072_OW_INTERNAL_H
#ifndef OW_INTERNAL
#error bad include!
#endif
#include "_ow_search.h"
/** Private data structure */
struct priv {
char port_name;
uint8_t pin_number;
bool parasitic;
GPIO_TypeDef *port;
uint32_t ll_pin;
TimerHandle_t busyWaitTimer; // timer used to wait for ds1820 measurement completion
bool busy; // flag used when the timer is running
uint32_t busyStart;
TF_ID busyRequestId;
struct ow_search_state searchState;
};
/** Load from a binary buffer stored in Flash */
void OW_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void OW_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t OW_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void OW_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Allocate data structure and set defaults */
error_t OW_preInit(Unit *unit);
/** Finalize unit set-up */
error_t OW_init(Unit *unit);
/** Tear down the unit */
void OW_deInit(Unit *unit);
/** Callback for the FreeRTOS timer used to wait for device ready */
void OW_TimerCb(TimerHandle_t xTimer);
// ------------------------------------------------------------------------
#endif //GEX_F072_OW_INTERNAL_H

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GexUnits/1wire/_ow_low_level.c
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//
// Created by MightyPork on 2018/01/29.
//
// 1-Wire unit low level functions
//
#include "platform.h"
#define OW_INTERNAL
#include "_ow_internal.h"
#include "_ow_low_level.h"
static inline uint8_t crc8_bits(uint8_t data)
{
uint8_t crc = 0;
if(data & 1) crc ^= 0x5e;
if(data & 2) crc ^= 0xbc;
if(data & 4) crc ^= 0x61;
if(data & 8) crc ^= 0xc2;
if(data & 0x10) crc ^= 0x9d;
if(data & 0x20) crc ^= 0x23;
if(data & 0x40) crc ^= 0x46;
if(data & 0x80) crc ^= 0x8c;
return crc;
}
static uint8_t crc8_add(uint8_t cksum, uint8_t byte)
{
return crc8_bits(byte ^ cksum);
}
uint8_t ow_checksum(const uint8_t *buff, uint32_t len)
{
uint8_t cksum = 0;
for(uint32_t i = 0; i < len; i++) {
cksum = crc8_add(cksum, buff[i]);
}
return cksum;
}
// ----------------------------------------------
static inline void ow_pull_high(Unit *unit)
{
struct priv *priv = unit->data;
LL_GPIO_SetOutputPin(priv->port, priv->ll_pin);
LL_GPIO_SetPinMode(priv->port, priv->ll_pin, LL_GPIO_MODE_OUTPUT);
}
static inline void ow_pull_low(Unit *unit)
{
struct priv *priv = unit->data;
LL_GPIO_ResetOutputPin(priv->port, priv->ll_pin);
LL_GPIO_SetPinMode(priv->port, priv->ll_pin, LL_GPIO_MODE_OUTPUT);
}
static inline void ow_release_line(Unit *unit)
{
struct priv *priv = unit->data;
LL_GPIO_SetPinMode(priv->port, priv->ll_pin, LL_GPIO_MODE_INPUT);
}
static inline bool ow_sample_line(Unit *unit)
{
struct priv *priv = unit->data;
return (bool) LL_GPIO_IsInputPinSet(priv->port, priv->ll_pin);
}
/**
* Reset the 1-wire bus
*/
bool ow_reset(Unit *unit)
{
ow_pull_low(unit);
PTIM_MicroDelay(500);
bool presence;
vPortEnterCritical();
{
// Strong pull-up (for parasitive power)
ow_pull_high(unit);
PTIM_MicroDelay(2);
// switch to open-drain
ow_release_line(unit);
PTIM_MicroDelay(118);
presence = !ow_sample_line(unit);
}
vPortExitCritical();
PTIM_MicroDelay(130);
return presence;
}
/**
* Write a bit to the 1-wire bus
*/
void ow_write_bit(Unit *unit, bool bit)
{
vPortEnterCritical();
{
// start mark
ow_pull_low(unit);
PTIM_MicroDelay(2);
if (bit) ow_pull_high(unit);
PTIM_MicroDelay(70);
// Strong pull-up (for parasitive power)
ow_pull_high(unit);
}
vPortExitCritical();
PTIM_MicroDelay(2);
}
/**
* Read a bit from the 1-wire bus
*/
bool ow_read_bit(Unit *unit)
{
bool bit;
vPortEnterCritical();
{
// start mark
ow_pull_low(unit);
PTIM_MicroDelay(2);
ow_release_line(unit);
PTIM_MicroDelay(20);
bit = ow_sample_line(unit);
}
vPortExitCritical();
PTIM_MicroDelay(40);
return bit;
}
/**
* Write a byte to the 1-wire bus
*/
void ow_write_u8(Unit *unit, uint8_t byte)
{
for (int i = 0; i < 8; i++) {
ow_write_bit(unit, 0 != (byte & (1 << i)));
}
}
/**
* Write a halfword to the 1-wire bus
*/
void ow_write_u16(Unit *unit, uint16_t halfword)
{
ow_write_u8(unit, (uint8_t) (halfword & 0xFF));
ow_write_u8(unit, (uint8_t) ((halfword >> 8) & 0xFF));
}
/**
* Write a word to the 1-wire bus
*/
void ow_write_u32(Unit *unit, uint32_t word)
{
ow_write_u16(unit, (uint16_t) (word));
ow_write_u16(unit, (uint16_t) (word >> 16));
}
/**
* Write a doubleword to the 1-wire bus
*/
void ow_write_u64(Unit *unit, uint64_t dword)
{
ow_write_u32(unit, (uint32_t) (dword));
ow_write_u32(unit, (uint32_t) (dword >> 32));
}
/**
* Read a byte form the 1-wire bus
*/
uint8_t ow_read_u8(Unit *unit)
{
uint8_t buf = 0;
for (int i = 0; i < 8; i++) {
buf |= (1 & ow_read_bit(unit)) << i;
}
return buf;
}
/**
* Read a halfword form the 1-wire bus
*/
uint16_t ow_read_u16(Unit *unit)
{
uint16_t acu = 0;
acu |= ow_read_u8(unit);
acu |= ow_read_u8(unit) << 8;
return acu;
}
/**
* Read a word form the 1-wire bus
*/
uint32_t ow_read_u32(Unit *unit)
{
uint32_t acu = 0;
acu |= ow_read_u16(unit);
acu |= (uint32_t)ow_read_u16(unit) << 16;
return acu;
}
/**
* Read a doubleword form the 1-wire bus
*/
uint64_t ow_read_u64(Unit *unit)
{
uint64_t acu = 0;
acu |= ow_read_u32(unit);
acu |= (uint64_t)ow_read_u32(unit) << 32;
return acu;
}

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GexUnits/1wire/_ow_low_level.h
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//
// Created by MightyPork on 2018/02/01.
//
#ifndef GEX_F072_OW_LOW_LEVEL_H
#define GEX_F072_OW_LOW_LEVEL_H
#ifndef OW_INTERNAL
#error bad include!
#endif
#include "platform.h"
#include "unit_base.h"
#include "_ow_low_level.h"
/**
* Compute a 1-wire type checksum.
* If the buffer includes the checksum, the result should be 0.
*
* (this function may be used externally, or you can delete the implementation
* from the c file if another implementation is already available)
*
* @param[in] buf - buffer of bytes to verify
* @param[in] len - buffer length
* @return checksum
*/
uint8_t ow_checksum(const uint8_t *buf, uint32_t len);
/**
* Reset the 1-wire bus
*/
bool ow_reset(Unit *unit);
/**
* Write a bit to the 1-wire bus
*/
void ow_write_bit(Unit *unit, bool bit);
/**
* Read a bit from the 1-wire bus
*/
bool ow_read_bit(Unit *unit);
/**
* Write a byte to the 1-wire bus
*/
void ow_write_u8(Unit *unit, uint8_t byte);
/**
* Write a halfword to the 1-wire bus
*/
void ow_write_u16(Unit *unit, uint16_t halfword);
/**
* Write a word to the 1-wire bus
*/
void ow_write_u32(Unit *unit, uint32_t word);
/**
* Write a doubleword to the 1-wire bus
*/
void ow_write_u64(Unit *unit, uint64_t dword);
/**
* Read a byte form the 1-wire bus
*/
uint8_t ow_read_u8(Unit *unit);
/**
* Read a halfword form the 1-wire bus
*/
uint16_t ow_read_u16(Unit *unit);
/**
* Read a word form the 1-wire bus
*/
uint32_t ow_read_u32(Unit *unit);
/**
* Read a doubleword form the 1-wire bus
*/
uint64_t ow_read_u64(Unit *unit);
#endif //GEX_F072_OW_LOW_LEVEL_H

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GexUnits/1wire/_ow_search.c
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//
// Created by MightyPork on 2018/02/01.
//
#include "platform.h"
#include "unit_1wire.h"
#define OW_INTERNAL
#include "_ow_search.h"
#include "_ow_internal.h"
#include "_ow_low_level.h"
#include "_ow_commands.h"
void ow_search_init(Unit *unit, uint8_t command, bool test_checksums)
{
if (unit->driver != &UNIT_1WIRE)
trap("Wrong unit type - %s", unit->driver->name);
assert_param(command == OW_ROM_SEARCH || command == OW_ROM_ALM_SEARCH);
struct priv *priv = unit->data;
struct ow_search_state *state = &priv->searchState;
state->prev_last_fork = 64;
memset(state->prev_code, 0, 8);
state->status = OW_SEARCH_MORE;
state->error = E_SUCCESS;
state->command = command;
state->first = true;
state->test_checksums = test_checksums;
}
uint32_t ow_search_run(Unit *unit, ow_romcode_t *codes, uint32_t capacity)
{
if (unit->driver != &UNIT_1WIRE)
trap("Wrong unit type - %s", unit->driver->name);
assert_param(codes);
struct priv *priv = unit->data;
struct ow_search_state *state = &priv->searchState;
if (state->status != OW_SEARCH_MORE) return 0;
uint32_t found_devices = 0;
while (found_devices < capacity) {
uint8_t index = 0;
ow_romcode_t code = {};
int8_t last_fork = -1;
// Start a new transaction. Devices respond to reset
if (!ow_reset(unit)) {
state->status = OW_SEARCH_FAILED;
state->error = E_HW_TIMEOUT;
goto done;
}
// Send the search command (SEARCH_ROM, SEARCH_ALARM)
ow_write_u8(unit, state->command);
uint8_t *code_byte = &code[0];
bool p, n;
while (index != 64) {
// Read a bit and its complement
p = ow_read_bit(unit);
n = ow_read_bit(unit);
if (!p && !n) {
// A fork: there are devices on the bus with different bit value
// (the bus is open-drain, in both cases one device pulls it low)
if ((found_devices > 0 || !state->first) && index < state->prev_last_fork) {
// earlier than the last fork, take the same turn as before
p = ow_code_getbit(state->prev_code, index);
if (!p) last_fork = index; // remember for future runs, 1 not explored yet
}
else if (index == state->prev_last_fork) {
p = 1; // both forks are now exhausted
}
else { // a new fork
last_fork = index;
}
}
else if (p && n) {
// No devices left connected - this doesn't normally happen
state->status = OW_SEARCH_FAILED;
state->error = E_BUS_FAULT;
goto done;
}
// All devices have a matching bit here, or it was resolved in a fork
if (p) *code_byte |= (1 << (index & 7));
ow_write_bit(unit, p);
index++;
if((index & 7) == 0) {
code_byte++;
}
}
memcpy(state->prev_code, code, 8);
if (state->test_checksums) {
if (0 != ow_checksum(code, 8)) {
state->status = OW_SEARCH_FAILED;
state->error = E_CHECKSUM_MISMATCH;
goto done;
}
}
// Record a found address
memcpy(codes[found_devices], code, 8);
found_devices++;
// Stop condition
if (last_fork == -1) {
state->status = OW_SEARCH_DONE;
goto done;
}
state->prev_last_fork = last_fork;
}
done:
state->first = false;
return found_devices;
}

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GexUnits/1wire/_ow_search.h
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//
// Created by MightyPork on 2018/02/01.
//
#ifndef GEX_F072_OW_SEARCH_H
#define GEX_F072_OW_SEARCH_H
#ifndef OW_INTERNAL
#error bad include!
#endif
#include <stdint.h>
#include <stdbool.h>
#include "unit_base.h"
// --------------------------------------------------------------------------------------
/**
* Data type holding a romcode
*/
typedef uint8_t ow_romcode_t[8];
/**
* Get a single bit from a romcode
*/
#define ow_code_getbit(code, index) (bool)((code)[(index) >> 3] & (1 << ((index) & 7)))
/**
* Convert to unsigned 64-bit integer
* (works only on little-endian systems - eg. OK on x86/x86_64, not on PowerPC)
*/
#define ow_romcode_to_u64(code) (*((uint64_t *) (void *)(code)))
/**
* States of the search algorithm
*/
enum ow_search_result {
OW_SEARCH_DONE = 0,
OW_SEARCH_MORE = 1,
OW_SEARCH_FAILED = 2,
};
/**
* Internal state of the search algorithm.
* Check status to see if more remain to be read or an error occurred.
*/
struct ow_search_state {
int8_t prev_last_fork;
ow_romcode_t prev_code;
uint8_t command;
enum ow_search_result status;
bool first;
bool test_checksums;
error_t error;
};
/**
* Init the search algorithm state structure
*
* @param[out] state - inited struct
* @param[in] command - command to send for requesting the search (e.g. SEARCH_ROM)
* @param[in] test_checksums - verify checksums of all read romcodes
*/
void ow_search_init(Unit *unit, uint8_t command, bool test_checksums);
/**
* Perform a search of the 1-wire bus, with a state struct pre-inited
* using ow_search_init().
*
* Romcodes are stored in the provided array in a numerically ascending order.
*
* This function may be called repeatedly to retrieve more addresses than could fit
* in the address buffer.
*
* @param[in,out] state - search state, used for multiple calls with limited buffer size
* @param[out] codes - buffer for found romcodes
* @param[in] capacity - buffer capacity
* @return number of romcodes found. Search status is stored in `state->status`,
* possible error code in `status->error`
*/
uint32_t ow_search_run(Unit *unit, ow_romcode_t *codes, uint32_t capacity);
#endif //GEX_F072_OW_SEARCH_H

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GexUnits/1wire/_ow_settings.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define OW_INTERNAL
#include "_ow_internal.h"
/** Load from a binary buffer stored in Flash */
void OW_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->port_name = pp_char(pp);
priv->pin_number = pp_u8(pp);
priv->parasitic = pp_bool(pp);
}
/** Write to a binary buffer for storing in Flash */
void OW_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
pb_char(pb, priv->port_name);
pb_u8(pb, priv->pin_number);
pb_bool(pb, priv->parasitic);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t OW_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "pin")) {
suc = cfg_portpin_parse(value, &priv->port_name, &priv->pin_number);
}
else if (streq(key, "parasitic")) {
priv->parasitic = cfg_bool_parse(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void OW_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Data pin");
iw_entry(iw, "pin", "%c%d", priv->port_name, priv->pin_number);
iw_comment(iw, "Parasitic (bus-powered) mode");
iw_entry_s(iw, "parasitic", str_yn(priv->parasitic));
}

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GexUnits/1wire/unit_1wire.c
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//
// Created by MightyPork on 2018/01/29.
//
#include "comm/messages.h"
#include "unit_base.h"
#include "unit_1wire.h"
// 1WIRE master
#define OW_INTERNAL
#include "_ow_internal.h"
#include "_ow_low_level.h"
/** Callback for sending a poll_ready success / failure report */
static void OW_TimerRespCb(Job *job)
{
Unit *unit = job->unit;
assert_param(unit);
struct priv *priv = unit->data;
bool success = (bool) job->data1;
if (success) {
com_respond_ok(priv->busyRequestId);
} else {
com_respond_error(priv->busyRequestId, E_HW_TIMEOUT);
}
priv->busy = false;
}
/**
* 1-Wire timer callback, used for the 'wait_ready' function.
*
* - In parasitic mode, this is a simple 750ms wait, after which a SUCCESS response is sent.
* - In 3-wire mode, the callback is fired periodically and performs a Read operation on the bus.
* The unit responds with 0 while the operation is ongoing. On receiving 1 a SUCCESS response is sent.
* The polling is abandoned after a timeout, sending a TIMEOUT response.
*
* @param xTimer
*/
void OW_tickHandler(Unit *unit)
{
struct priv *priv = unit->data;
if(!priv->busy) {
dbg("ow tick should be disabled now!");
return;
}
if (priv->parasitic) {
// this is the end of the 750ms measurement time
goto halt_ok;
} else {
bool ready = ow_read_bit(unit);
if (ready) {
goto halt_ok;
}
uint32_t time = PTIM_GetTime();
if (time - priv->busyStart > 1000) {
unit->tick_interval = 0;
unit->_tick_cnt = 0;
Job j = {
.unit = unit,
.data1 = 0, // failure
.cb = OW_TimerRespCb,
};
scheduleJob(&j);
}
}
return;
halt_ok:
unit->tick_interval = 0;
unit->_tick_cnt = 0;
Job j = {
.unit = unit,
.data1 = 1, // success
.cb = OW_TimerRespCb,
};
scheduleJob(&j);
}
enum PinCmd_ {
CMD_CHECK_PRESENCE = 0, // simply tests that any devices are attached
CMD_SEARCH_ADDR = 1, // perform a scan of the bus, retrieving all found device ROMs
CMD_SEARCH_ALARM = 2, // like normal scan, but retrieve only devices with alarm
CMD_SEARCH_CONTINUE = 3, // continue the previously started scan, retrieving more devices
CMD_READ_ADDR = 4, // read the ROM code from a single device (for single-device bus)
CMD_WRITE = 10, // write multiple bytes using the SKIP_ROM command
CMD_READ = 11, // write multiple bytes using a ROM address
CMD_POLL_FOR_1 = 20,
};
/** Handle a request message */
static error_t OW_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
struct priv *priv = unit->data;
bool presence;
uint64_t addr;
uint32_t remain;
const uint8_t *tail;
if (priv->busy) return E_BUSY;
bool with_alarm = false;
bool search_reset = false;
switch (command) {
/**
* This is the delay function for DS1820 measurements.
*
* Parasitic: Returns success after the required 750ms
* Non-parasitic: Returns SUCCESS after device responds '1', HW_TIMEOUT after 1s
*/
case CMD_POLL_FOR_1:
// This can't be exposed via the UU API, due to being async
unit->_tick_cnt = 0;
unit->tick_interval = 750;
if (priv->parasitic) {
unit->tick_interval = 750;
} else {
unit->tick_interval = 10;
}
priv->busy = true;
priv->busyStart = PTIM_GetTime();
priv->busyRequestId = frame_id;
return E_SUCCESS; // We will respond when the timer expires
/** Search devices with alarm. No payload, restarts the search. */
case CMD_SEARCH_ALARM:
with_alarm = true;
// fall-through
/** Search all devices. No payload, restarts the search. */
case CMD_SEARCH_ADDR:
search_reset = true;
// fall-through
/** Continue a previously begun search. */
case CMD_SEARCH_CONTINUE:;
uint32_t found_count = 0;
bool have_more = false;
if (!search_reset && priv->searchState.status != OW_SEARCH_MORE) {
dbg("Search not ongoing!");
return E_PROTOCOL_BREACH;
}
TRY(UU_1WIRE_Search(unit, with_alarm, search_reset,
(void *) unit_tmp512, UNIT_TMP_LEN/8, &found_count,
&have_more));
// use multipart to avoid allocating extra buffer
uint8_t status_code = (uint8_t) have_more;
TF_Msg msg = {
.frame_id = frame_id,
.type = MSG_SUCCESS,
.len = (TF_LEN) (found_count * 8 + 1),
};
TF_Respond_Multipart(comm, &msg);
TF_Multipart_Payload(comm, &status_code, 1);
// the codes are back-to-back stored inside the buffer, we send it directly
// (it's already little-endian, as if built by PayloadBuilder)
TF_Multipart_Payload(comm, (uint8_t *) unit_tmp512, found_count * 8);
TF_Multipart_Close(comm);
return E_SUCCESS;
/** Simply check presence of any devices on the bus. Responds with SUCCESS or HW_TIMEOUT */
case CMD_CHECK_PRESENCE:
TRY(UU_1WIRE_CheckPresence(unit, &presence));
com_respond_u8(frame_id, (uint8_t) presence);
return E_SUCCESS;
/** Read address of the single device on the bus - returns u64 */
case CMD_READ_ADDR:
TRY(UU_1WIRE_ReadAddress(unit, &addr));
// build response
PayloadBuilder pb = pb_start(unit_tmp512, UNIT_TMP_LEN, NULL);
pb_u64(&pb, addr);
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
/**
* Write payload to the bus, no confirmation (unless requested).
*
* Payload:
* addr:u64, rest:write_data
* if addr is 0, use SKIP_ROM
*/
case CMD_WRITE:
addr = pp_u64(pp);
tail = pp_tail(pp, &remain);
TRY(UU_1WIRE_Write(unit, addr, tail, remain));
return E_SUCCESS;
/**
* Write and read.
*
* Payload:
* addr:u64, read_len:u16, rest:write_data
* if addr is 0, use SKIP_ROM
*/
case CMD_READ:
addr = pp_u64(pp);
uint16_t rcount = pp_u16(pp);
bool test_crc = pp_bool(pp);
tail = pp_tail(pp, &remain);
TRY(UU_1WIRE_Read(unit, addr,
tail, remain,
(uint8_t *) unit_tmp512, rcount,
test_crc));
// build response
com_respond_buf(frame_id, MSG_SUCCESS, (uint8_t *) unit_tmp512, rcount);
return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_1WIRE = {
.name = "1WIRE",
.description = "1-Wire master",
// Settings
.preInit = OW_preInit,
.cfgLoadBinary = OW_loadBinary,
.cfgWriteBinary = OW_writeBinary,
.cfgLoadIni = OW_loadIni,
.cfgWriteIni = OW_writeIni,
// Init
.init = OW_init,
.deInit = OW_deInit,
// Function
.handleRequest = OW_handleRequest,
.updateTick = OW_tickHandler,
};

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//
// Created by MightyPork on 2018/01/02.
//
// Dallas 1-Wire master unit
//
#ifndef GEX_F072_UNIT_1WIRE_H
#define GEX_F072_UNIT_1WIRE_H
#include "unit.h"
extern const UnitDriver UNIT_1WIRE;
/**
* Check if there are any units present on the bus
*
* @param[in,out] unit
* @param[out] presence - any devices present
* @return success
*/
error_t UU_1WIRE_CheckPresence(Unit *unit, bool *presence);
/**
* Read a device's address (use only with a single device attached)
*
* @param[in,out] unit
* @param[out] address - the device's address, 0 on error or CRC mismatch
* @return success
*/
error_t UU_1WIRE_ReadAddress(Unit *unit, uint64_t *address);
/**
* Write bytes to a device / devices
*
* @param[in,out] unit
* @param[in] address - device address, 0 to skip match (single device or broadcast)
* @param[in] buff - bytes to write
* @param[in] len - buffer length
* @return success
*/
error_t UU_1WIRE_Write(Unit *unit, uint64_t address, const uint8_t *buff, uint32_t len);
/**
* Read bytes from a device / devices, first writing a query
*
* @param[in,out] unit
* @param[in] address - device address, 0 to skip match (single device ONLY!)
* @param[in] request_buff - bytes to write before reading a response
* @param[in] request_len - number of bytes to write
* @param[out] response_buff - buffer for storing the read response
* @param[in] response_len - number of bytes to read
* @param[in] check_crc - verify CRC
* @return success
*/
error_t UU_1WIRE_Read(Unit *unit, uint64_t address,
const uint8_t *request_buff, uint32_t request_len,
uint8_t *response_buff, uint32_t response_len, bool check_crc);
/**
* Perform a ROM search operation.
* The algorithm is on a depth-first search without backtracking,
* taking advantage of the open-drain topology.
*
* This function either starts the search, or continues it.
*
* @param[in,out] unit
* @param[in] with_alarm - true to match only devices in alarm state
* @param[in] restart - true to restart the search (search from the lowest address)
* @param[out] buffer - buffer for storing found addresses
* @param[in] capacity - buffer capacity in address entries (8 bytes)
* @param[out] real_count - real number of found addresses (for which the CRC matched)
* @param[out] have_more - flag indicating there are more devices to be found
* @return success
*/
error_t UU_1WIRE_Search(Unit *unit, bool with_alarm, bool restart,
uint64_t *buffer, uint32_t capacity, uint32_t *real_count,
bool *have_more);
#endif //GEX_F072_UNIT_1WIRE_H

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//
// Created by MightyPork on 2018/02/04.
//
// The core functionality of the ADC unit is defined here.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_adc.h"
#define ADC_INTERNAL
#include "_adc_internal.h"
#define DMA_POS(priv) ((priv)->buf_itemcount - (priv)->DMA_CHx->CNDTR)
/**
* Async job to send a chunk of the DMA buffer to PC.
* This can't be done directly because the interrupt couldn't wait for the TinyFrame mutex.
*
* unit - unit
* data1 - start index
* data2 - number of samples to send
* data3 - bit flags: 0x80 if this is the last sample and we should close
* 0x01 if this was the TC interrupt (otherwise it's HT)
*/
static void UADC_JobSendBlockChunk(Job *job)
{
Unit *unit = job->unit;
struct priv *priv = unit->data;
const uint32_t start = job->data1;
const uint32_t count = job->data2;
const bool close = (bool) (job->data3 & 0x80);
const bool tc = (bool) (job->data3 & 0x01);
const TF_TYPE type = close ? EVT_CAPT_DONE : EVT_CAPT_MORE;
TF_Msg msg = {
.frame_id = priv->stream_frame_id,
.len = (TF_LEN) (1 /*seq*/ + count * sizeof(uint16_t)),
.type = type,
};
assert_param(true == TF_Respond_Multipart(comm, &msg));
TF_Multipart_Payload(comm, &priv->stream_serial, 1);
TF_Multipart_Payload(comm, (uint8_t *) (priv->dma_buffer + start), count * sizeof(uint16_t));
TF_Multipart_Close(comm);
// Clear the "busy" flags - those are checked in the DMA ISR to detect overrun
if (tc) priv->tc_pending = false;
else priv->ht_pending = false;
priv->stream_serial++;
}
/**
* Async job to send the trigger header.
* The header includes info about the trigger + the pre-trigger buffer.
*
* data1 - index in the DMA buffer at which the captured data willl start
* data2 - edge type - 1 rise, 2 fall, 3 forced
* timestamp - event stamp
* unit - unit
*/
static void UADC_JobSendTriggerCaptureHeader(Job *job)
{
Unit *unit = job->unit;
struct priv *priv = unit->data;
EventReport er = {
.unit = unit,
.type = EVT_CAPT_START,
.timestamp = job->timestamp,
.length = (priv->pretrig_len + ((priv->pretrig_len > 0)?1:0)) * // see below why +1
priv->nb_channels *
sizeof(uint16_t) +
4 /*pretrig len*/ +
1 /*edge*/ +
1 /* seq */
};
uint32_t index_trigd = job->data1;
uint8_t edge = (uint8_t) job->data2;
EventReport_Start(&er);
priv->stream_frame_id = er.sent_msg_id;
{
// preamble
uint8_t buf[6];
PayloadBuilder pb = pb_start(buf, 6, NULL);
pb_u32(&pb, priv->pretrig_len);
pb_u8(&pb, edge);
pb_u8(&pb, priv->stream_serial++); // This is the serial counter for the first chunk
// (containing the pre-trigger, or empty if no pretrig configured)
EventReport_PB(&pb);
if (priv->pretrig_len > 0) {
// pretrig
// +1 because we want pretrig 0 to exactly start with the triggering sample
uint32_t pretrig_remain = (priv->pretrig_len + 1) * priv->nb_channels;
assert_param(index_trigd <= priv->buf_itemcount);
// this is one past the last entry of the triggering capture group
if (pretrig_remain > index_trigd) {
// used items in the wrap-around part of the buffer
uint32_t items_from_end = pretrig_remain - index_trigd;
assert_param(priv->buf_itemcount - items_from_end >= index_trigd);
EventReport_Data((uint8_t *) &priv->dma_buffer[priv->buf_itemcount - items_from_end],
items_from_end * sizeof(uint16_t));
assert_param(items_from_end <= pretrig_remain);
pretrig_remain -= items_from_end;
}
assert_param(pretrig_remain <= index_trigd);
EventReport_Data((uint8_t *) &priv->dma_buffer[index_trigd - pretrig_remain],
pretrig_remain * sizeof(uint16_t));
}
}
EventReport_End();
}
/**
* Async job to notify about end of stream
*/
static void UADC_JobSendEndOfStreamMsg(Job *job)
{
TF_Msg msg = {
.type = EVT_CAPT_DONE,
.frame_id = (TF_ID) job->data1
};
TF_Respond(comm, &msg);
}
/**
* Schedule sending a event report to the PC that the current stream has ended.
* The client library should handle this appropriately.
*/
void UADC_ReportEndOfStream(Unit *unit)
{
struct priv *priv = unit->data;
Job j = {
.unit = unit,
.data1 = priv->stream_frame_id, // copy the ID, it may be invalid by the time the cb gets executed
.cb = UADC_JobSendEndOfStreamMsg
};
scheduleJob(&j);
}
/**
* This is a helper function for the ADC DMA interrupt for handing the different interrupt types (half / full transfer).
* It sends the part of the buffer that was just captured via an async job, or aborts on overrun.
*
* It's split off here to allow calling it for the different flags without repeating code.
*
* @param unit
* @param tc - true if this is the TC interrupt, else HT
*/
static void handle_httc(Unit *unit, bool tc)
{
struct priv *priv = unit->data;
uint32_t start = priv->stream_startpos;
uint32_t end;
const bool ht = !tc;
const bool m_trigd = priv->opmode == ADC_OPMODE_TRIGD;
const bool m_stream = priv->opmode == ADC_OPMODE_STREAM;
const bool m_fixcpt = priv->opmode == ADC_OPMODE_BLCAP;
if (ht) {
end = (priv->buf_itemcount >> 1); // div2
}
else {
end = priv->buf_itemcount;
}
if (start != end) { // this sometimes happened after a trigger, may be unnecessary now
if (end < start) {
// this was a trap for a bug with missed TC irq, it's hopefully fixed now
trap("end < start! %d < %d, tc %d", (int)end, (int)start, (int)tc);
}
uint32_t sgcount = (end - start) / priv->nb_channels;
if (m_trigd || m_fixcpt) {
sgcount = MIN(priv->trig_stream_remain, sgcount);
priv->trig_stream_remain -= sgcount;
}
// Check for the closing condition
const bool close = !m_stream && priv->trig_stream_remain == 0;
if ((tc && priv->tc_pending) || (ht && priv->ht_pending)) {
dbg("(!) ADC DMA not handled in time, abort capture");
UADC_SwitchMode(unit, ADC_OPMODE_EMERGENCY_SHUTDOWN);
return;
}
// Here we set the tc/ht pending flags for detecting overrun
Job j = {
.unit = unit,
.data1 = start,
.data2 = sgcount * priv->nb_channels,
.data3 = (uint32_t) (close*0x80) | (tc*1), // bitfields to indicate what's happening
.cb = UADC_JobSendBlockChunk
};
if (tc)
priv->tc_pending = true;
else
priv->ht_pending = true;
if (!scheduleJob(&j)) {
// Abort if we can't queue - the stream would tear and we'd hog the system with error messages
UADC_SwitchMode(unit, ADC_OPMODE_EMERGENCY_SHUTDOWN);
return;
}
if (close) {
// If auto-arm is enabled, we need to re-arm again.
// However, EOS irq is disabled during the capture so the trigger edge detection would
// work on stale data from before this trigger. We have to wait for the next full
// conversion (EOS) before arming.
UADC_SwitchMode(unit, (priv->auto_rearm && m_trigd) ? ADC_OPMODE_REARM_PENDING : ADC_OPMODE_IDLE);
}
}
// Advance the starting position
if (tc) {
priv->stream_startpos = 0;
}
else {
priv->stream_startpos = priv->buf_itemcount >> 1; // div2
}
}
/**
* IRQ handler for the DMA flags.
*
* We handle flags:
* TC - transfer complete
* HT - half transfer
* TE - transfer error (this should never happen unless there's a bug)
*
* The buffer works in a circular mode, so we always handle the previous half
* or what of it should be sent (if capture started somewhere inside).
*
* @param arg - the unit, passed via the irq dispatcher
*/
void UADC_DMA_Handler(void *arg)
{
Unit *unit = arg;
struct priv *priv = unit->data;
// First thing, grab the flags. They may change during the function.
// Working on the live register might cause race conditions.
const uint32_t isrsnapshot = priv->DMAx->ISR;
if (priv->opmode == ADC_OPMODE_UNINIT) {
// the IRQ occured while switching mode, clear flags and do nothing else
LL_DMA_ClearFlag_HT(priv->DMAx, priv->dma_chnum);
LL_DMA_ClearFlag_TC(priv->DMAx, priv->dma_chnum);
LL_DMA_ClearFlag_TE(priv->DMAx, priv->dma_chnum);
return;
}
if (LL_DMA_IsActiveFlag_G(isrsnapshot, priv->dma_chnum)) {
// we have some flags set - check which
const bool tc = LL_DMA_IsActiveFlag_TC(isrsnapshot, priv->dma_chnum);
const bool ht = LL_DMA_IsActiveFlag_HT(isrsnapshot, priv->dma_chnum);
const bool te = LL_DMA_IsActiveFlag_TE(isrsnapshot, priv->dma_chnum);
if (ht) LL_DMA_ClearFlag_HT(priv->DMAx, priv->dma_chnum);
if (tc) LL_DMA_ClearFlag_TC(priv->DMAx, priv->dma_chnum);
if (te) {
// this shouldn't happen - error
adc_dbg("ADC DMA TE!");
LL_DMA_ClearFlag_TE(priv->DMAx, priv->dma_chnum);
return;
}
// check what mode we're in
const bool m_trigd = priv->opmode == ADC_OPMODE_TRIGD;
const bool m_stream = priv->opmode == ADC_OPMODE_STREAM;
const bool m_fixcpt = priv->opmode == ADC_OPMODE_BLCAP;
if (m_trigd || m_stream || m_fixcpt) {
const uint32_t half = (uint32_t) (priv->buf_itemcount >> 1); // div2
if (ht && tc) {
// dual event interrupt - may happen if we missed both and they were pending after
// interrupts became enabled again (this can happen due to the EOS or other higher prio irq's)
if (priv->stream_startpos > half) {
handle_httc(unit, true); // TC
handle_httc(unit, false); // HT
} else {
handle_httc(unit, false); // HT
handle_httc(unit, true); // TC
}
} else {
if (ht && priv->stream_startpos > half) {
// We missed the TC interrupt while e.g. setting up the stream / interrupt. catch up!
// This fixes a bug with "negative size" for report.
handle_httc(unit, true); // TC
}
handle_httc(unit, tc);
}
} else {
// This shouldn't happen, the interrupt should be disabled in this opmode
dbg("(!) not streaming, ADC DMA IT should be disabled");
}
}
}
/**
* End of measurement group interrupt handler.
* This interrupt records the measured values and checks for trigger.
*
* @param arg - unit, passed b y irq dispatcher
*/
void UADC_ADC_EOS_Handler(void *arg)
{
Unit *unit = arg;
struct priv *priv = unit->data;
const bool can_average = priv->cfg.enable_averaging &&
priv->real_frequency_int < UADC_MAX_FREQ_FOR_AVERAGING;
// Normally
uint64_t timestamp = 0;
if (priv->opmode == ADC_OPMODE_ARMED) {
timestamp = PTIM_GetMicrotime();
}
LL_ADC_ClearFlag_EOS(priv->ADCx);
if (priv->opmode == ADC_OPMODE_UNINIT) {
goto exit;
}
uint32_t dmapos = DMA_POS(priv);
// Wait for the DMA to complete copying the last sample
// XXX
// experiments revealed this was actually a bug somewhere else and DMA
// is quick enough so we don't have to worry about this
#if 0
uint32_t err = (dmapos % priv->nb_channels);
if (err != 0) {
GPIOC->BSRR = 0x02;
hw_wait_while(((dmapos = DMA_POS(priv)) % priv->nb_channels) != 0, 10);
GPIOC->BRR = 0x02;
}
#endif
// wrap dmapos to be past the last sample, even if outside the buffer
// - so we can subtract nb_channels
uint32_t sample_pos;
if (dmapos == 0) {
sample_pos = (uint32_t) (priv->buf_itemcount);
} else {
sample_pos = dmapos;
}
sample_pos -= priv->nb_channels;
uint16_t val;
#if 1
for (uint32_t j = 0; j < priv->nb_channels; j++) {
const uint8_t i = priv->channel_nums[j];
val = priv->dma_buffer[sample_pos+j];
if (can_average) {
priv->averaging_bins[i] =
priv->averaging_bins[i] * (1.0f - priv->avg_factor_as_float) +
((float) val) * priv->avg_factor_as_float;
}
priv->last_samples[i] = val;
}
#else
for (uint8_t i = 0; i < 18; i++) {
if (channels_mask & (1 << i)) {
val = priv->dma_buffer[sample_pos+cnt];
cnt++;
if (can_average) {
priv->averaging_bins[i] =
priv->averaging_bins[i] * (1.0f - priv->avg_factor_as_float) +
((float) val) * priv->avg_factor_as_float;
}
priv->last_samples[i] = val;
}
}
#endif
switch (priv->opmode) {
// Triggering condition test
case ADC_OPMODE_ARMED:
val = priv->last_samples[priv->trigger_source];
if ((priv->trig_prev_level < priv->trig_level) &&
val >= priv->trig_level &&
(bool) (priv->trig_edge & 0b01)) {
// Rising edge
UADC_HandleTrigger(unit, 0b01, timestamp);
}
else if ((priv->trig_prev_level > priv->trig_level) &&
val <= priv->trig_level &&
(bool) (priv->trig_edge & 0b10)) {
// Falling edge
UADC_HandleTrigger(unit, 0b10, timestamp);
}
priv->trig_prev_level = val;
break;
// auto-rearm was waiting for the next sample
case ADC_OPMODE_REARM_PENDING:
if (!priv->auto_rearm) {
// It looks like the flag was cleared by DISARM before we got a new sample.
// Let's just switch to IDLE
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
} else {
// Re-arming for a new trigger
UADC_SwitchMode(unit, ADC_OPMODE_ARMED);
}
default:
break;
}
exit:
return;
}
/**
* Handle a detected trigger - start capture if we're not in hold-off
*
* @param unit
* @param edge_type - edge type, is included in the report
* @param timestamp - event time
*/
void UADC_HandleTrigger(Unit *unit, uint8_t edge_type, uint64_t timestamp)
{
struct priv *priv = unit->data;
if (priv->opmode == ADC_OPMODE_UNINIT) return;
if (priv->trig_holdoff != 0 && priv->trig_holdoff_remain > 0) {
// Trig discarded due to holdoff
return;
}
if (priv->trig_holdoff > 0) {
priv->trig_holdoff_remain = priv->trig_holdoff;
// Start the tick
unit->tick_interval = 1;
unit->_tick_cnt = 1;
}
priv->stream_startpos = DMA_POS(priv);
priv->trig_stream_remain = priv->trig_len;
priv->stream_serial = 0;
// This func may be called from the EOS interrupt, so it's safer to send the header message asynchronously
Job j = {
.unit = unit,
.timestamp = timestamp,
.data1 = priv->stream_startpos,
.data2 = edge_type,
.cb = UADC_JobSendTriggerCaptureHeader
};
scheduleJob(&j);
UADC_SwitchMode(unit, ADC_OPMODE_TRIGD);
}
/**
* Abort ongoing capture.
*/
void UADC_AbortCapture(Unit *unit)
{
struct priv *priv = unit->data;
const enum uadc_opmode old_opmode = priv->opmode;
priv->auto_rearm = false;
if (old_opmode == ADC_OPMODE_BLCAP ||
old_opmode == ADC_OPMODE_STREAM ||
old_opmode == ADC_OPMODE_TRIGD) {
UADC_ReportEndOfStream(unit);
}
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
}
/**
* Start a manual block capture.
*
* @param unit
* @param len - number of samples (groups)
* @param frame_id - TF session to re-use for the report (client has a listener set up)
*/
void UADC_StartBlockCapture(Unit *unit, uint32_t len, TF_ID frame_id)
{
struct priv *priv = unit->data;
if (priv->opmode == ADC_OPMODE_UNINIT) return;
priv->stream_frame_id = frame_id;
priv->stream_startpos = DMA_POS(priv);
priv->trig_stream_remain = len;
priv->stream_serial = 0;
UADC_SwitchMode(unit, ADC_OPMODE_BLCAP);
}
/**
* Start a stream
*
* @param frame_id - TF session to re-use for the frames (client has a listener set up)
*/
void UADC_StartStream(Unit *unit, TF_ID frame_id)
{
struct priv *priv = unit->data;
if (priv->opmode == ADC_OPMODE_UNINIT) return;
priv->stream_frame_id = frame_id;
UADC_SwitchMode(unit, ADC_OPMODE_STREAM);
}
/**
* End a stream by user request.
*/
void UADC_StopStream(Unit *unit)
{
struct priv *priv = unit->data;
if (priv->opmode == ADC_OPMODE_UNINIT) return;
UADC_ReportEndOfStream(unit);
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
}
/**
* Handle unit update tick - expire the trigger hold-off.
* We also check for the emergency shutdown condition and clear it.
*/
void UADC_updateTick(Unit *unit)
{
struct priv *priv = unit->data;
// Recover from shutdown after a delay
if (priv->opmode == ADC_OPMODE_EMERGENCY_SHUTDOWN) {
adc_dbg("ADC recovering from emergency shutdown");
UADC_ReportEndOfStream(unit);
LL_TIM_EnableCounter(priv->TIMx);
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
unit->tick_interval = 0;
return;
}
if (priv->trig_holdoff_remain > 0) {
priv->trig_holdoff_remain--;
if (priv->trig_holdoff_remain == 0) {
unit->tick_interval = 0;
unit->_tick_cnt = 0;
}
}
}
/**
* Switch the ADC operational mode.
*
* @param unit
* @param new_mode - mode to set
*/
void UADC_SwitchMode(Unit *unit, enum uadc_opmode new_mode)
{
struct priv *priv = unit->data;
const enum uadc_opmode old_mode = priv->opmode;
if (new_mode == old_mode) return; // nothing to do
// if un-itied, can go only to IDLE
assert_param((old_mode != ADC_OPMODE_UNINIT) || (new_mode == ADC_OPMODE_IDLE));
priv->opmode = ADC_OPMODE_UNINIT;
if (new_mode == ADC_OPMODE_UNINIT) {
adc_dbg("ADC switch -> UNINIT");
// Stop the DMA, timer and disable ADC - this is called before tearing down the unit
LL_TIM_DisableCounter(priv->TIMx);
LL_ADC_ClearFlag_EOS(priv->ADCx);
LL_ADC_DisableIT_EOS(priv->ADCx);
// Switch off the ADC
if (LL_ADC_IsEnabled(priv->ADCx)) {
// Cancel ongoing conversion
if (LL_ADC_REG_IsConversionOngoing(priv->ADCx)) {
LL_ADC_REG_StopConversion(priv->ADCx);
hw_wait_while(LL_ADC_REG_IsStopConversionOngoing(priv->ADCx), 100);
}
LL_ADC_Disable(priv->ADCx);
hw_wait_while(LL_ADC_IsDisableOngoing(priv->ADCx), 100);
}
LL_DMA_DisableChannel(priv->DMAx, priv->dma_chnum);
LL_DMA_DisableIT_HT(priv->DMAx, priv->dma_chnum);
LL_DMA_DisableIT_TC(priv->DMAx, priv->dma_chnum);
LL_DMA_ClearFlag_HT(priv->DMAx, priv->dma_chnum);
LL_DMA_ClearFlag_TC(priv->DMAx, priv->dma_chnum);
}
else if (new_mode == ADC_OPMODE_IDLE || new_mode == ADC_OPMODE_REARM_PENDING) {
// IDLE and ARMED are identical with the exception that the trigger condition is not checked
// ARMED can be only entered from IDLE, thus we do the init only here.
priv->tc_pending = false;
priv->ht_pending = false;
// In IDLE, we don't need the DMA interrupts
LL_DMA_ClearFlag_HT(priv->DMAx, priv->dma_chnum);
LL_DMA_ClearFlag_TC(priv->DMAx, priv->dma_chnum);
LL_DMA_DisableIT_HT(priv->DMAx, priv->dma_chnum);
LL_DMA_DisableIT_TC(priv->DMAx, priv->dma_chnum);
// Use End Of Sequence to recover results for averaging from the DMA buffer and DR
LL_ADC_ClearFlag_EOS(priv->ADCx);
LL_ADC_EnableIT_EOS(priv->ADCx);
if (old_mode == ADC_OPMODE_UNINIT) {
// Nothing is started yet - this is the only way to leave UNINIT
LL_ADC_Enable(priv->ADCx);
LL_DMA_EnableChannel(priv->DMAx, priv->dma_chnum);
LL_TIM_EnableCounter(priv->TIMx);
LL_ADC_REG_StartConversion(priv->ADCx);
}
}
else if (new_mode == ADC_OPMODE_EMERGENCY_SHUTDOWN) {
adc_dbg("ADC switch -> EMERGENCY_STOP");
// Emergency shutdown is used when the job queue overflows and the stream is torn
// This however doesn't help in the case when user sets such a high frequency
// that the whole app becomes unresponsive due to the completion ISR, need to verify the value manually.
LL_DMA_ClearFlag_HT(priv->DMAx, priv->dma_chnum);
LL_DMA_ClearFlag_TC(priv->DMAx, priv->dma_chnum);
LL_DMA_DisableIT_HT(priv->DMAx, priv->dma_chnum);
LL_DMA_DisableIT_TC(priv->DMAx, priv->dma_chnum);
LL_TIM_DisableCounter(priv->TIMx);
UADC_SetSampleRate(unit, 10000); // fallback to a known safe value
LL_ADC_ClearFlag_EOS(priv->ADCx);
LL_ADC_DisableIT_EOS(priv->ADCx);
unit->tick_interval = 0;
unit->_tick_cnt = 250; // 1-off
}
else if (new_mode == ADC_OPMODE_ARMED) {
adc_dbg("ADC switch -> ARMED");
assert_param(old_mode == ADC_OPMODE_IDLE || old_mode == ADC_OPMODE_REARM_PENDING);
// avoid firing immediately by the value jumping across the scale
priv->trig_prev_level = priv->last_samples[priv->trigger_source];
}
else if (new_mode == ADC_OPMODE_TRIGD || new_mode == ADC_OPMODE_STREAM || new_mode == ADC_OPMODE_BLCAP) {
adc_dbg("ADC switch -> CAPTURE");
assert_param(old_mode == ADC_OPMODE_ARMED || old_mode == ADC_OPMODE_IDLE);
// during the capture, we disallow direct readout and averaging to reduce overhead
LL_ADC_DisableIT_EOS(priv->ADCx);
// Enable the DMA buffer interrupts
// we must first clear the flags, otherwise it will cause WEIRD bugs in the handler
LL_DMA_ClearFlag_HT(priv->DMAx, priv->dma_chnum);
LL_DMA_ClearFlag_TC(priv->DMAx, priv->dma_chnum);
// those must be as close as possible to the enabling
// if not trig'd, we don't care for lost samples before (this could cause a DMA irq miss / ht/tc mismatch with the startpos)
if (new_mode != ADC_OPMODE_TRIGD) {
priv->stream_startpos = DMA_POS(priv);
priv->stream_serial = 0;
}
LL_DMA_EnableIT_HT(priv->DMAx, priv->dma_chnum);
LL_DMA_EnableIT_TC(priv->DMAx, priv->dma_chnum);
}
priv->opmode = new_mode;
}

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//
// Created by MightyPork on 2018/02/03.
//
// ADC unit init and de-init functions
//
#include "platform.h"
#include "unit_base.h"
#define ADC_INTERNAL
#include "_adc_internal.h"
/** Allocate data structure and set defaults */
error_t UADC_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
priv->cfg.channels = 1<<16; // Tsense by default - always available, easy testing
priv->cfg.sample_time = 0b010; // 13.5c - good enough and the default 0b00 value really is useless
priv->cfg.frequency = 1000;
priv->cfg.buffer_size = 256; // in half-words
priv->cfg.averaging_factor = 500; // 0.5
priv->cfg.enable_averaging = true;
priv->opmode = ADC_OPMODE_UNINIT;
return E_SUCCESS;
}
/** Configure frequency */
error_t UADC_SetSampleRate(Unit *unit, uint32_t hertz)
{
struct priv *priv = unit->data;
uint16_t presc;
uint32_t count;
if (!hw_solve_timer(PLAT_APB1_HZ, hertz, true, &presc, &count, &priv->real_frequency)) {
dbg("Failed to resolve timer params.");
return E_BAD_VALUE;
}
adc_dbg("Frequency error %d ppm, presc %d, count %d",
(int) lrintf(1000000.0f * ((priv->real_frequency - hertz) / (float) hertz)),
(int) presc, (int) count);
LL_TIM_SetPrescaler(priv->TIMx, (uint32_t) (presc - 1));
LL_TIM_SetAutoReload(priv->TIMx, count - 1);
priv->real_frequency_int = hertz;
return E_SUCCESS;
}
/**
* Set up the ADC DMA.
* This is split to its own function because it's also called when the user adjusts the
* enabled channels and we need to re-configure it.
*
* @param unit
*/
void UADC_SetupDMA(Unit *unit)
{
struct priv *priv = unit->data;
adc_dbg("Setting up DMA");
{
uint32_t itemcount = priv->nb_channels * (priv->cfg.buffer_size / (priv->nb_channels));
if (itemcount % 2 == 1) itemcount -= priv->nb_channels; // ensure the count is even
priv->buf_itemcount = itemcount;
adc_dbg("DMA item count is %d (%d bytes), There are %d samples per group.",
(int)priv->buf_itemcount,
(int)(priv->buf_itemcount * sizeof(uint16_t)),
(int)priv->nb_channels);
{
LL_DMA_InitTypeDef init;
LL_DMA_StructInit(&init);
init.Direction = LL_DMA_DIRECTION_PERIPH_TO_MEMORY;
init.Mode = LL_DMA_MODE_CIRCULAR;
init.NbData = itemcount;
init.PeriphOrM2MSrcAddress = (uint32_t) &priv->ADCx->DR;
init.PeriphOrM2MSrcDataSize = LL_DMA_PDATAALIGN_HALFWORD;
init.PeriphOrM2MSrcIncMode = LL_DMA_PERIPH_NOINCREMENT;
init.MemoryOrM2MDstAddress = (uint32_t) priv->dma_buffer;
init.MemoryOrM2MDstDataSize = LL_DMA_MDATAALIGN_HALFWORD;
init.MemoryOrM2MDstIncMode = LL_DMA_MEMORY_INCREMENT;
assert_param(SUCCESS == LL_DMA_Init(priv->DMAx, priv->dma_chnum, &init));
}
// LL_DMA_EnableChannel(priv->DMAx, priv->dma_chnum); // this is done in the switch mode func now
}
}
/** Finalize unit set-up */
error_t UADC_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
// Written for F072 which has only one ADC
TRY(rsc_claim(unit, R_ADC1));
TRY(rsc_claim(unit, R_DMA1_1));
TRY(rsc_claim(unit, R_TIM15));
priv->DMAx = DMA1;
priv->DMA_CHx = DMA1_Channel1;
priv->dma_chnum = 1;
priv->ADCx = ADC1;
priv->ADCx_Common = ADC1_COMMON;
priv->TIMx = TIM15;
// ----------------------- CONFIGURE PINS --------------------------
{
// Claim and configure all analog pins
priv->nb_channels = 0;
for (uint8_t i = 0; i <= UADC_MAX_CHANNEL; i++) {
if (priv->cfg.channels & (1UL << i)) {
priv->channel_nums[priv->nb_channels] = (uint8_t) i;
priv->nb_channels++;
do {
char c;
uint8_t num;
if (i <= 7) {
c = 'A';
num = i;
}
else if (i <= 9) {
c = 'B';
num = (uint8_t) (i - 8);
}
else if (i <= 15) {
c = 'C';
num = (uint8_t) (i - 10);
}
else {
break;
}
TRY(rsc_claim_pin(unit, c, num));
uint32_t ll_pin = hw_pin2ll(num, &suc);
GPIO_TypeDef *port = hw_port2periph(c, &suc);
assert_param(suc);
LL_GPIO_SetPinPull(port, ll_pin, LL_GPIO_PULL_NO);
LL_GPIO_SetPinMode(port, ll_pin, LL_GPIO_MODE_ANALOG);
} while (0);
}
}
if (priv->nb_channels == 0) {
dbg("Need at least 1 channel");
return E_BAD_CONFIG;
}
// ensure some minimal space is available
if (priv->cfg.buffer_size < priv->nb_channels * 2) {
dbg("Insufficient buf size");
return E_BAD_CONFIG;
}
}
// ---------------- Alloc the buffer ----------------------
adc_dbg("Allocating buffer of size %d half-words", (int)priv->cfg.buffer_size);
priv->dma_buffer = calloc_ck(priv->cfg.buffer_size, sizeof(uint16_t));
if (NULL == priv->dma_buffer) return E_OUT_OF_MEM;
assert_param(((uint32_t) priv->dma_buffer & 3) == 0); // must be aligned
// ------------------- ENABLE CLOCKS --------------------------
{
// enable peripherals clock
hw_periph_clock_enable(priv->ADCx);
hw_periph_clock_enable(priv->TIMx);
// DMA and GPIO clocks are enabled on startup automatically
}
// ------------------- CONFIGURE THE TIMER --------------------------
adc_dbg("Setting up TIMER");
{
TRY(UADC_SetSampleRate(unit, priv->cfg.frequency));
LL_TIM_EnableARRPreload(priv->TIMx);
LL_TIM_EnableUpdateEvent(priv->TIMx);
LL_TIM_SetTriggerOutput(priv->TIMx, LL_TIM_TRGO_UPDATE);
LL_TIM_GenerateEvent_UPDATE(priv->TIMx); // load the prescaller value
}
// --------------------- CONFIGURE THE ADC ---------------------------
adc_dbg("Setting up ADC");
{
// Calibrate the ADC
adc_dbg("Wait for calib");
LL_ADC_StartCalibration(priv->ADCx);
while (LL_ADC_IsCalibrationOnGoing(priv->ADCx)) {}
adc_dbg("ADC calibrated.");
// Let's just enable the internal channels always - makes toggling them on-line easier
LL_ADC_SetCommonPathInternalCh(priv->ADCx_Common, LL_ADC_PATH_INTERNAL_VREFINT | LL_ADC_PATH_INTERNAL_TEMPSENSOR);
LL_ADC_SetDataAlignment(priv->ADCx, LL_ADC_DATA_ALIGN_RIGHT);
LL_ADC_SetResolution(priv->ADCx, LL_ADC_RESOLUTION_12B);
LL_ADC_REG_SetDMATransfer(priv->ADCx, LL_ADC_REG_DMA_TRANSFER_UNLIMITED);
// configure channels
priv->channels_mask = priv->cfg.channels;
priv->ADCx->CHSELR = priv->channels_mask;
LL_ADC_REG_SetTriggerSource(priv->ADCx, LL_ADC_REG_TRIG_EXT_TIM15_TRGO);
LL_ADC_SetSamplingTimeCommonChannels(priv->ADCx, LL_ADC_SAMPLETIMES[priv->cfg.sample_time]);
// will be enabled when switching to INIT mode
}
// --------------------- CONFIGURE DMA -------------------------------
UADC_SetupDMA(unit);
// prepare the avg factor float for the ISR
if (priv->cfg.averaging_factor > 1000) priv->cfg.averaging_factor = 1000; // normalize
priv->avg_factor_as_float = priv->cfg.averaging_factor/1000.0f;
adc_dbg("ADC peripherals configured.");
irqd_attach(priv->DMA_CHx, UADC_DMA_Handler, unit);
irqd_attach(priv->ADCx, UADC_ADC_EOS_Handler, unit);
adc_dbg("irqs attached");
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
adc_dbg("ADC done");
return E_SUCCESS;
}
/** Tear down the unit */
void UADC_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// de-init peripherals
if (unit->status == E_SUCCESS ) {
UADC_SwitchMode(unit, ADC_OPMODE_UNINIT);
//LL_ADC_DeInit(priv->ADCx);
LL_ADC_CommonDeInit(priv->ADCx_Common);
LL_TIM_DeInit(priv->TIMx);
irqd_detach(priv->DMA_CHx, UADC_DMA_Handler);
irqd_detach(priv->ADCx, UADC_ADC_EOS_Handler);
LL_DMA_DeInit(priv->DMAx, priv->dma_chnum);
}
// free buffer if not NULL
free_ck(priv->dma_buffer);
// Release all resources, deinit pins
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
// Defines and prototypes used internally by the ADC unit.
//
#ifndef GEX_F072_ADC_INTERNAL_H
#define GEX_F072_ADC_INTERNAL_H
#ifndef ADC_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
//#define adc_dbg dbg
#define adc_dbg(...) do {} while(0)
#define UADC_MAX_FREQ_FOR_AVERAGING 20000
#define UADC_MAX_CHANNEL 17
enum uadc_opmode {
ADC_OPMODE_UNINIT, //!< Not yet switched to any mode
ADC_OPMODE_IDLE, //!< Idle. Allows immediate value readout and averaging.
ADC_OPMODE_REARM_PENDING, //!< Idle, waiting for the next sample to re-arm (auto trigger).
ADC_OPMODE_ARMED, //!< Armed for a trigger. Direct access and averaging are disabled.
ADC_OPMODE_TRIGD, //!< Triggered, sending pre-trigger and streaming captured data.
ADC_OPMODE_BLCAP, //!< Capture of fixed length without a trigger
ADC_OPMODE_STREAM, //!< Unlimited capture
ADC_OPMODE_EMERGENCY_SHUTDOWN, //!< Used when the buffers overrun to safely transition to IDLE after a delay
};
enum uadc_event {
EVT_CAPT_START = 50, //!< Capture start (used in event in the first frame when trigger is detected)
EVT_CAPT_MORE = 51, //!< Capture data payload (used as TYPE for all capture types)
EVT_CAPT_DONE = 52, //!< End of trig'd or block capture payload (last frame with data),
//!< or a farewell message after closing stream using abort(), in this case without data.
};
/** Private data structure */
struct priv {
struct {
uint32_t channels; //!< bit flags (will be recorded in order 0-15)
uint8_t sample_time; //!< 0-7 (corresponds to 1.5-239.5 cycles) - time for the sampling capacitor to charge
uint32_t frequency; //!< Timer frequency in Hz. Note: not all frequencies can be achieved accurately
uint32_t buffer_size; //!< Buffer size in bytes (count 2 bytes per channel per measurement) - faster sampling freq needs bigger buffer
uint16_t averaging_factor; //!< Exponential averaging factor 0-1000
bool enable_averaging;
} cfg;
// Peripherals
ADC_TypeDef *ADCx; //!< The ADC peripheral used
ADC_Common_TypeDef *ADCx_Common; //!< The ADC common control block
TIM_TypeDef *TIMx; //!< ADC timing timer instance
DMA_TypeDef *DMAx; //!< DMA isnatnce used
uint8_t dma_chnum; //!< DMA channel number
DMA_Channel_TypeDef *DMA_CHx; //!< DMA channel instance
uint8_t channel_nums[18];
// Live config
float real_frequency;
uint32_t real_frequency_int;
uint32_t channels_mask; //!< channels bitfield including tsense and vref
float avg_factor_as_float;
uint16_t *dma_buffer; //!< malloc'd buffer for the samples
uint8_t nb_channels; //!< nbr of enabled adc channels
uint32_t buf_itemcount; //!< real size of the buffer in samples (adjusted to fit 2x whole multiple of sample group)
// Trigger state
uint32_t trig_stream_remain; //!< Counter of samples remaining to be sent in the post-trigger stream
uint16_t trig_holdoff_remain; //!< Tmp counter for the currently active hold-off
uint16_t trig_prev_level; //!< Value of the previous sample, used to detect trigger edge
uint32_t stream_startpos; //!< Byte offset in the DMA buffer where the next capture for a stream should start.
//!< Updated in TH/TC and on trigger (after the preceding data is sent as a pretrig buffer)
enum uadc_opmode opmode; //!< OpMode (state machine state)
float averaging_bins[18]; //!< Averaging buffers, enough space to accommodate all channels (16 external + 2 internal)
uint16_t last_samples[18]; //!< If averaging is disabled, the last captured sample is stored here.
// Trigger config
uint8_t trigger_source; //!< number of the pin selected as a trigger source
uint32_t pretrig_len; //!< Pre-trigger length, nbr of historical samples to report when trigger occurs
uint32_t trig_len; //!< Trigger length, nbr of samples to report AFTER a trigger occurs
uint16_t trig_level; //!< Triggering level in LSB
uint8_t trig_edge; //!< Which edge we want to trigger on. 1-rising, 2-falling, 3-both
bool auto_rearm; //!< Flag that the trigger should be re-armed after the stream finishes
uint16_t trig_holdoff; //!< Trigger hold-off time, set when configuring the trigger
TF_ID stream_frame_id; //!< Session ID for multi-part stream (response or report)
uint8_t stream_serial; //!< Serial nr of a stream frame
bool tc_pending;
bool ht_pending;
};
/** Allocate data structure and set defaults */
error_t UADC_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void UADC_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void UADC_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UADC_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void UADC_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t UADC_init(Unit *unit);
/** Tear down the unit */
void UADC_deInit(Unit *unit);
/** Configure DMA (buffer count etc) */
void UADC_SetupDMA(Unit *unit);
// ------------------------------------------------------------------------
/** DMA half/complete handler */
void UADC_DMA_Handler(void *arg);
/** ADC eod of sequence handler */
void UADC_ADC_EOS_Handler(void *arg);
/** Switch to a different opmode */
void UADC_SwitchMode(Unit *unit, enum uadc_opmode new_mode);
/** Handle trigger - process pre-trigger and start streaming the requested number of samples */
void UADC_HandleTrigger(Unit *unit, uint8_t edge_type, uint64_t timestamp);
/** Handle a periodic tick - expiring the hold-off */
void UADC_updateTick(Unit *unit);
/** Send a end-of-stream message to PC's stream listener so it can shut down. */
void UADC_ReportEndOfStream(Unit *unit);
/** Start a block capture */
void UADC_StartBlockCapture(Unit *unit, uint32_t len, TF_ID frame_id);
/** Start stream */
void UADC_StartStream(Unit *unit, TF_ID frame_id);
/** End stream */
void UADC_StopStream(Unit *unit);
/** Configure frequency */
error_t UADC_SetSampleRate(Unit *unit, uint32_t hertz);
/** Abort capture */
void UADC_AbortCapture(Unit *unit);
#endif //GEX_F072_ADC_INTERNAL_H

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//
// Created by MightyPork on 2018/02/03.
//
// ADC unit settings reading / parsing
//
#include "platform.h"
#include "unit_base.h"
#define ADC_INTERNAL
#include "_adc_internal.h"
/** Load from a binary buffer stored in Flash */
void UADC_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->cfg.channels = pp_u32(pp);
priv->cfg.sample_time = pp_u8(pp);
priv->cfg.frequency = pp_u32(pp);
priv->cfg.buffer_size = pp_u32(pp);
priv->cfg.averaging_factor = pp_u16(pp);
if (version >= 1) {
priv->cfg.enable_averaging = pp_bool(pp);
}
}
/** Write to a binary buffer for storing in Flash */
void UADC_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 1); // version
pb_u32(pb, priv->cfg.channels);
pb_u8(pb, priv->cfg.sample_time);
pb_u32(pb, priv->cfg.frequency);
pb_u32(pb, priv->cfg.buffer_size);
pb_u16(pb, priv->cfg.averaging_factor);
pb_bool(pb, priv->cfg.enable_averaging);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UADC_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "channels")) {
priv->cfg.channels = cfg_pinmask_parse_32(value, &suc);
}
else if (streq(key, "sample_time")) {
priv->cfg.sample_time = cfg_u8_parse(value, &suc);
if (priv->cfg.sample_time > 7) return E_BAD_VALUE;
}
else if (streq(key, "frequency")) {
priv->cfg.frequency = cfg_u32_parse(value, &suc);
}
else if (streq(key, "buffer_size")) {
priv->cfg.buffer_size = cfg_u32_parse(value, &suc);
}
else if (streq(key, "avg_factor")) {
priv->cfg.averaging_factor = cfg_u16_parse(value, &suc);
if (priv->cfg.averaging_factor > 1000) return E_BAD_VALUE;
}
else if (streq(key, "averaging")) {
priv->cfg.enable_averaging = cfg_bool_parse(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void UADC_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Enabled channels, comma separated");
iw_comment(iw, " 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17");
iw_comment(iw, "A0 A1 A2 A3 A4 A5 A6 A7 B0 B1 C0 C1 C2 C3 C4 C5 Tsens Vref");
iw_entry_s(iw, "channels", cfg_pinmask_encode(priv->cfg.channels, unit_tmp512, true));
iw_cmt_newline(iw);
iw_comment(iw, "Sampling time (0-7)");
iw_entry_d(iw, "sample_time", priv->cfg.sample_time);
iw_comment(iw, "Sampling frequency (Hz)");
iw_entry_d(iw, "frequency", priv->cfg.frequency);
iw_cmt_newline(iw);
iw_comment(iw, "Sample buffer size");
iw_comment(iw, "- shared by all enabled channels");
iw_comment(iw, "- defines the maximum pre-trigger size (divide by # of channels)");
iw_comment(iw, "- captured data is sent in half-buffer chunks");
iw_comment(iw, "- buffer overrun aborts the data capture");
iw_entry_d(iw, "buffer_size", priv->cfg.buffer_size);
iw_cmt_newline(iw);
iw_comment(iw, "Enable continuous sampling with averaging");
iw_comment(iw, "Caution: This can cause DAC output glitches");
iw_entry_s(iw, "averaging", str_yn(priv->cfg.enable_averaging));
iw_comment(iw, "Exponential averaging coefficient (permil, range 0-1000 ~ 0.000-1.000)");
iw_comment(iw, "- used formula: y[t]=(1-k)*y[t-1]+k*u[t]");
iw_comment(iw, "- not available when a capture is running");
iw_entry_d(iw, "avg_factor", priv->cfg.averaging_factor);
}

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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_adc.h"
#define ADC_INTERNAL
#include "_adc_internal.h"
// ------------------------------------------------------------------------
enum AdcCmd_ {
CMD_READ_RAW = 0,
CMD_READ_SMOOTHED = 1,
CMD_READ_CAL_CONSTANTS = 2,
CMD_GET_ENABLED_CHANNELS = 10,
CMD_GET_SAMPLE_RATE = 11,
CMD_SETUP_TRIGGER = 20,
CMD_ARM = 21,
CMD_DISARM = 22,
CMD_ABORT = 23, // abort any ongoing capture or stream
CMD_FORCE_TRIGGER = 24,
CMD_BLOCK_CAPTURE = 25,
CMD_STREAM_START = 26,
CMD_STREAM_STOP = 27,
CMD_SET_SMOOTHING_FACTOR = 28,
CMD_SET_SAMPLE_RATE = 29,
CMD_ENABLE_CHANNELS = 30,
CMD_SET_SAMPLE_TIME = 31,
};
/** Handle a request message */
static error_t UADC_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
struct priv *priv = unit->data;
PayloadBuilder pb = pb_start(unit_tmp512, UNIT_TMP_LEN, NULL);
switch (command) {
/**
* Get enabled channels.
* Response: bytes with indices of enabled channels, ascending order.
*/
case CMD_GET_ENABLED_CHANNELS:
for (uint8_t i = 0; i < 18; i++) {
if (priv->channels_mask & (1 << i)) {
pb_u8(&pb, i);
}
}
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
/**
* Set the sample rate in Hz
* plad: hz:u32
*/
case CMD_SET_SAMPLE_RATE:
{
uint32_t freq = pp_u32(pp);
if (freq == 0) return E_BAD_VALUE;
TRY(UADC_SetSampleRate(unit, freq));
}
// Pass through - send back the obtained sample rate
/**
* Read the real used frequency, expressed as float.
* May differ from the configured or requested value due to prescaller limitations.
*/
case CMD_GET_SAMPLE_RATE:
pb_u32(&pb, priv->real_frequency_int);
pb_float(&pb, priv->real_frequency);
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
/**
* Set smoothing factor 0-1000.
* pld: u16:factor
*/
case CMD_SET_SMOOTHING_FACTOR:
{
uint16_t fac = pp_u16(pp);
if (fac > 1000) return E_BAD_VALUE;
priv->avg_factor_as_float = fac / 1000.0f;
}
return E_SUCCESS;
/**
* Set sample time
* pld: u8:0-7
*/
case CMD_SET_SAMPLE_TIME:
{
uint8_t tim = pp_u8(pp);
if (tim > 7) return E_BAD_VALUE;
UADC_SwitchMode(unit, ADC_OPMODE_UNINIT);
{
LL_ADC_SetSamplingTimeCommonChannels(priv->ADCx, LL_ADC_SAMPLETIMES[tim]);
}
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
}
return E_SUCCESS;
/** Read ADC calibration constants */
case CMD_READ_CAL_CONSTANTS:
{
pb_u16(&pb, *VREFINT_CAL_ADDR); // VREFINT_CAL
pb_u16(&pb, VREFINT_CAL_VREF); // Vref pin voltage during calibration (usually bonded to Vdd)
pb_u16(&pb, *TEMPSENSOR_CAL1_ADDR); // TEMPSENSOR_CAL1
pb_u16(&pb, *TEMPSENSOR_CAL2_ADDR); // TEMPSENSOR_CAL2
pb_u8(&pb, TEMPSENSOR_CAL1_TEMP); // temperature for CAL1
pb_u8(&pb, TEMPSENSOR_CAL2_TEMP); // temperature for CAL2
pb_u16(&pb, TEMPSENSOR_CAL_VREFANALOG); // VREFINT_CAL_VREF - Vref pin voltage during calibration (usually bonded to Vdd)
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
}
return E_SUCCESS;
/**
* Enable channels. The channels must've been configured in the settings (except ch 16 and 17 which are available always)
* pld: u32: bitmap of channels
*/
case CMD_ENABLE_CHANNELS:
{
uint32_t new_channels = pp_u32(pp);
// this tears down the peripherals sufficiently so we can re-configure them. Going back to IDLE re-inits this
UADC_SwitchMode(unit, ADC_OPMODE_UNINIT);
uint32_t illegal_channels = new_channels & ~(priv->cfg.channels | (1<<16) | (1<<17)); // 16 and 17 may be enabled always
if (illegal_channels != 0) {
com_respond_str(MSG_ERROR, frame_id, "Some requested channels not available");
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
return E_FAILURE;
}
uint8_t nb_channels = 0;
// count the enabled channels
for(int i = 0; i < 32; i++) {
if (new_channels & (1<<i)) {
priv->channel_nums[nb_channels] = (uint8_t) i;
nb_channels++;
}
}
if (nb_channels == 0) {
com_respond_str(MSG_ERROR, frame_id, "Need at least 1 channel");
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
return E_FAILURE;
}
if (priv->cfg.buffer_size < nb_channels * 2) {
com_respond_str(MSG_ERROR, frame_id, "Insufficient buf size");
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
return E_BAD_CONFIG;
}
priv->nb_channels = nb_channels;
priv->ADCx->CHSELR = new_channels; // apply it to the ADC
priv->channels_mask = new_channels;
UADC_SetupDMA(unit);
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
}
return E_SUCCESS;
/**
* Read raw values from the last measurement.
* Response: interleaved (u8:channel, u16:value) for all channels
*/
case CMD_READ_RAW:
if(priv->opmode != ADC_OPMODE_IDLE && priv->opmode != ADC_OPMODE_ARMED) {
return E_BUSY;
}
for (uint8_t i = 0; i < 18; i++) {
if (priv->channels_mask & (1 << i)) {
pb_u16(&pb, priv->last_samples[i]);
}
}
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
/**
* Read smoothed values.
* Response: interleaved (u8:channel, f32:value) for all channels
*/
case CMD_READ_SMOOTHED:
if(priv->opmode != ADC_OPMODE_IDLE && priv->opmode != ADC_OPMODE_ARMED) {
return E_BUSY;
}
if (! priv->cfg.enable_averaging) {
com_respond_str(MSG_ERROR, frame_id, "Averaging disabled");
return E_FAILURE;
}
if (priv->real_frequency_int > UADC_MAX_FREQ_FOR_AVERAGING) {
com_respond_str(MSG_ERROR, frame_id, "Too fast for averaging");
return E_FAILURE;
}
for (uint8_t i = 0; i < 18; i++) {
if (priv->channels_mask & (1 << i)) {
pb_float(&pb, priv->averaging_bins[i]);
}
}
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
/**
* Configure a trigger. This is legal only if the current state is IDLE or ARMED (will re-arm).
*
* Payload:
* u8 - source channel
* u16 - triggering level
* u8 - edge to trigger on: 1-rising, 2-falling, 3-both
* u16 - pre-trigger samples count
* u32 - post-trigger samples count
* u16 - trigger hold-off in ms (dead time after firing, before it cna fire again if armed)
* u8(bool) - auto re-arm after firing and completing the capture
*/
case CMD_SETUP_TRIGGER:
adc_dbg("> Setup trigger");
if (priv->opmode != ADC_OPMODE_IDLE &&
priv->opmode != ADC_OPMODE_ARMED &&
priv->opmode != ADC_OPMODE_REARM_PENDING) {
return E_BUSY;
}
{
const uint8_t source = pp_u8(pp);
const uint16_t level = pp_u16(pp);
const uint8_t edge = pp_u8(pp);
const uint32_t pretrig = pp_u32(pp);
const uint32_t count = pp_u32(pp);
const uint16_t holdoff = pp_u16(pp);
const bool auto_rearm = pp_bool(pp);
if (source > UADC_MAX_CHANNEL) {
com_respond_str(MSG_ERROR, frame_id, "Invalid trig source");
return E_FAILURE;
}
if (0 == (priv->channels_mask & (1 << source))) {
com_respond_str(MSG_ERROR, frame_id, "Channel not enabled");
return E_FAILURE;
}
if (level > 4095) {
com_respond_str(MSG_ERROR, frame_id, "Level out of range (0-4095)");
return E_FAILURE;
}
if (edge == 0 || edge > 3) {
com_respond_str(MSG_ERROR, frame_id, "Bad edge");
return E_FAILURE;
}
// XXX the max size may be too much
const uint32_t max_pretrig = (priv->buf_itemcount / priv->nb_channels);
if (pretrig > max_pretrig) {
com_respond_snprintf(frame_id, MSG_ERROR,
"Pretrig too large (max %d)", (int) max_pretrig);
return E_FAILURE;
}
priv->trigger_source = source;
priv->trig_level = level;
priv->trig_prev_level = priv->last_samples[source];
priv->trig_edge = edge;
priv->pretrig_len = pretrig;
priv->trig_len = count;
priv->trig_holdoff = holdoff;
priv->auto_rearm = auto_rearm;
}
return E_SUCCESS;
/**
* Arm (permissible only if idle and the trigger is configured)
*/
case CMD_ARM:
adc_dbg("> Arm");
uint8_t sticky = pp_u8(pp);
if(priv->opmode == ADC_OPMODE_ARMED || priv->opmode == ADC_OPMODE_REARM_PENDING) {
// We are armed or will re-arm promptly, act like the call succeeded
// The auto flag is set regardless
} else {
if (priv->opmode != ADC_OPMODE_IDLE) {
return E_BUSY; // capture in progress
}
if (priv->trig_len == 0) {
com_respond_str(MSG_ERROR, frame_id, "Trigger not configured.");
return E_FAILURE;
}
UADC_SwitchMode(unit, ADC_OPMODE_ARMED);
}
if (sticky != 255) {
priv->auto_rearm = (bool)sticky;
}
return E_SUCCESS;
/**
* Dis-arm. Permissible only when idle or armed.
* Switches to idle.
*/
case CMD_DISARM:
adc_dbg("> Disarm");
priv->auto_rearm = false;
if(priv->opmode == ADC_OPMODE_IDLE) {
return E_SUCCESS; // already idle, success - no work to do
}
// capture in progress
if (priv->opmode != ADC_OPMODE_ARMED &&
priv->opmode != ADC_OPMODE_REARM_PENDING) {
// Capture in progress, we already cleared auto rearm, so we're done for now
// auto_rearm is checked in the EOS isr and if cleared, does not re-arm.
return E_SUCCESS;
}
UADC_SwitchMode(unit, ADC_OPMODE_IDLE);
return E_SUCCESS;
/**
* Abort any ongoing capture and dis-arm.
*/
case CMD_ABORT:;
adc_dbg("> Abort capture");
UADC_AbortCapture(unit);
return E_SUCCESS;
/**
* Force a trigger (complete with pre-trigger capture and hold-off)
* The reported edge will be 0b11, here meaning "manual trigger"
*/
case CMD_FORCE_TRIGGER:
adc_dbg("> Force trigger");
// This is similar to block capture, but includes the pre-trig buffer and has fixed size based on trigger config
// FORCE is useful for checking if the trigger is set up correctly
if (priv->opmode != ADC_OPMODE_ARMED &&
priv->opmode != ADC_OPMODE_IDLE &&
priv->opmode != ADC_OPMODE_REARM_PENDING) return E_BUSY;
if (priv->trig_len == 0) {
com_respond_str(MSG_ERROR, frame_id, "Trigger not configured.");
return E_FAILURE;
}
UADC_HandleTrigger(unit, 0b11, PTIM_GetMicrotime());
return E_SUCCESS;
/**
* Start a block capture (like manual trigger, but without pre-trigger and arming)
*
* Payload:
* u32 - sample count (for each channel)
*/
case CMD_BLOCK_CAPTURE:
adc_dbg("> Block cpt");
if (priv->opmode != ADC_OPMODE_ARMED &&
priv->opmode != ADC_OPMODE_REARM_PENDING &&
priv->opmode != ADC_OPMODE_IDLE) return E_BUSY;
uint32_t count = pp_u32(pp);
UADC_StartBlockCapture(unit, count, frame_id);
return E_SUCCESS;
/**
* Start streaming (like block capture, but unlimited)
* The stream can be terminated by the stop command.
*/
case CMD_STREAM_START:
adc_dbg("> Stream ON");
if (priv->opmode != ADC_OPMODE_ARMED &&
priv->opmode != ADC_OPMODE_REARM_PENDING &&
priv->opmode != ADC_OPMODE_IDLE) return E_BUSY;
UADC_StartStream(unit, frame_id);
return E_SUCCESS;
/**
* Stop a stream.
*/
case CMD_STREAM_STOP:
adc_dbg("> Stream OFF");
if (priv->opmode != ADC_OPMODE_STREAM) {
com_respond_str(MSG_ERROR, frame_id, "Not streaming");
return E_FAILURE;
}
UADC_StopStream(unit);
return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_ADC = {
.name = "ADC",
.description = "Analog/digital converter",
// Settings
.preInit = UADC_preInit,
.cfgLoadBinary = UADC_loadBinary,
.cfgWriteBinary = UADC_writeBinary,
.cfgLoadIni = UADC_loadIni,
.cfgWriteIni = UADC_writeIni,
// Init
.init = UADC_init,
.deInit = UADC_deInit,
// Function
.handleRequest = UADC_handleRequest,
.updateTick = UADC_updateTick,
};

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//
// Created by MightyPork on 2017/11/25.
//
// ADC unit with several DSO-like features, like triggering, pre-trigger, block capture,
// streaming, smoothing...
//
#ifndef U_TPL_H
#define U_TPL_H
#include "unit.h"
extern const UnitDriver UNIT_ADC;
#endif //U_TPL_H

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GexUnits/dac/_dac_api.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_dac.h"
#define DAC_INTERNAL
#include "_dac_internal.h"
/**
* Re-configure the
* @param unit
*/
void UDAC_Reconfigure(Unit *unit)
{
struct priv *priv = unit->data;
// back-up IT state
bool IT_enabled = (bool) LL_TIM_IsEnabledIT_UPDATE(priv->TIMx);
if (IT_enabled) {
LL_TIM_DisableIT_UPDATE(priv->TIMx);
}
// ...
DAC->CR &= ~(DAC_CR_EN1 | DAC_CR_EN2);
uint32_t CR = 0;
if (priv->cfg.ch[0].enable) {
CR |=
(priv->cfg.ch[0].buffered ? 0 : DAC_CR_BOFF1) |
(priv->ch[0].noise_type << DAC_CR_WAVE1_Pos) |
(priv->ch[0].noise_level & 0xF) << DAC_CR_MAMP1_Pos |
DAC_CR_TEN1 |
(0b111 << DAC_CR_TSEL1_Pos); // software trigger;
CR |= DAC_CR_EN1;
}
if (priv->cfg.ch[1].enable) {
CR |=
(priv->cfg.ch[1].buffered ? 0 : DAC_CR_BOFF2) |
(priv->ch[1].noise_type << DAC_CR_WAVE2_Pos) |
(priv->ch[1].noise_level & 0xF) << DAC_CR_MAMP2_Pos |
DAC_CR_TEN2 |
(0b111 << DAC_CR_TSEL2_Pos); // software trigger
CR |= DAC_CR_EN2;
}
DAC->CR = CR;
// ...
if (IT_enabled) {
LL_TIM_EnableIT_UPDATE(priv->TIMx);
}
}
error_t UDAC_SetFreq(Unit *unit, int channel, float freq)
{
struct priv *priv = unit->data;
priv->ch[channel].increment = (uint32_t) roundf(25.0f * freq * UDAC_VALUE_COUNT * // FIXME constant seems derived from the divide ...?
((float)UDAC_TIM_FREQ_DIVIDER / PLAT_AHB_MHZ)
);
// dbg("Ch %d: Computed increment: %d", channel+1, (int)priv->ch[channel].increment);
return E_SUCCESS;
}
void UDAC_ToggleTimerIfNeeded(Unit *unit)
{
struct priv *priv = unit->data;
if (priv->ch[0].waveform == UDAC_WAVE_DC && priv->ch[1].waveform == UDAC_WAVE_DC) {
LL_TIM_DisableCounter(priv->TIMx);
// manually call the interrupt function to update the level
UDAC_HandleIT(unit);
} else {
LL_TIM_EnableCounter(priv->TIMx);
}
}

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GexUnits/dac/_dac_core.c
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//
// Created by MightyPork on 2018/03/10.
//
#include "platform.h"
#include "unit_dac.h"
#define DAC_INTERNAL
#include "_dac_internal.h"
#pragma GCC push_options
#pragma GCC optimize ("O2")
void UDAC_HandleIT(void *arg)
{
Unit *unit = arg;
struct priv *priv = unit->data;
LL_TIM_ClearFlag_UPDATE(priv->TIMx);
// TODO optimize to allow faster update speed
uint16_t vals[2];
for (int i = 0; i < 2; i++) {
struct udac_channel_live *const ch = &priv->ch[i];
if (ch->waveform == UDAC_WAVE_DC) {
// skip the whole counter thing for DC
vals[i] = ch->dc_level;
continue;
}
ch->counter += ch->increment;
const uint16_t index = (uint16_t) (ch->counter >> UDAC_INDEX_SHIFT);
switch (ch->waveform) {
case UDAC_WAVE_SINE: {
const uint32_t phase = index >> (UDAC_INDEX_WIDTH - 2);
uint32_t pos = (uint32_t) index & (((1<<(UDAC_INDEX_WIDTH - 2)) - 1));
if (phase & 0b01) {
// 2nd and 4th quarter (01, 11)
pos = (UDAC_VALUE_COUNT/4 - 1) - pos;
}
uint32_t value;
/* unpack */
const uint32_t nthbyte = (pos * 3) / 2;
const uint8_t topbyte = LUT_sine_8192_quad_packed[nthbyte];
const uint8_t botbyte = LUT_sine_8192_quad_packed[nthbyte + 1];
if (pos & 1) {
// odd index
value = (uint32_t) (((topbyte & 0xF) << 8) | botbyte);
}
else {
value = (uint32_t) ((topbyte << 4) | ((botbyte & 0xF0) >> 4));
}
/* end unpack -> value */
if (phase & 0b10) {
// 3rd and 4th quarter (10, 11)
value = 2047 - value;
}
else {
// 1st and 2nd quarter (00, 01)
value = 2048 + value;
}
vals[i] = (uint16_t) value;
break;
}
case UDAC_WAVE_RECTANGLE:
if (index < ch->rectangle_ontime) {
vals[i] = ch->rectangle_high;
} else {
vals[i] = ch->rectangle_low;
}
break;
case UDAC_WAVE_SAWTOOTH_UP:
vals[i] = (uint16_t) (index / 2); // for 8192 steps, this will produce 0-4095
break;
case UDAC_WAVE_SAWTOOTH_DOWN:
vals[i] = (uint16_t) (4095 - (index / 2)); // for 8192 steps, this will produce 0-4095
break;
case UDAC_WAVE_TRIANGLE: {
if (index < 4096) {
vals[i] = index;
}
else {
vals[i] = (uint16_t) (8191 - index);
}
break;
}
default:
vals[i] = 0; // this shouldn't happen
break;
} // end select waveform
} // end for 0,1
DAC->DHR12RD = (vals[1] << 16) | vals[0];
// Trigger a conversion
DAC->SWTRIGR = (DAC_SWTR_CH1 | DAC_SWTR_CH2);
}
#pragma GCC pop_options
/**
* This is the first 1/4 of a 12-bit sine wave sampled in 8192 points, each two points packed into three bytes (saves 1/4 of space used by uint16_t's)
* The array holds 2048 data points which can be easily offset / flipped to cover the entire waveform.
*
* |<-->|
* _---_
* / \
* / \
* /---------\---------/
* \ /
* \_ _/
* ---
*/
#if 0 // this is rail to rail, but the dac doesn't work well at the rails and it gets flattened
const uint8_t LUT_sine_8192_quad_packed[] = {
0x00, 0x00, 0x02, 0x00, 0x30, 0x05, 0x00, 0x60, 0x08, 0x00, 0x90, 0x0B, 0x00, 0xD0, 0x0E, 0x01, 0x00, 0x11, 0x01, 0x30, 0x14, 0x01, 0x60, 0x18,
0x01, 0x90, 0x1B, 0x01, 0xC0, 0x1E, 0x01, 0xF0, 0x21, 0x02, 0x30, 0x24, 0x02, 0x60, 0x27, 0x02, 0x90, 0x2A, 0x02, 0xC0, 0x2E, 0x02, 0xF0, 0x31,
0x03, 0x20, 0x34, 0x03, 0x50, 0x37, 0x03, 0x90, 0x3A, 0x03, 0xC0, 0x3D, 0x03, 0xF0, 0x40, 0x04, 0x20, 0x43, 0x04, 0x50, 0x47, 0x04, 0x80, 0x4A,
0x04, 0xB0, 0x4D, 0x04, 0xE0, 0x50, 0x05, 0x20, 0x53, 0x05, 0x50, 0x56, 0x05, 0x80, 0x59, 0x05, 0xB0, 0x5D, 0x05, 0xE0, 0x60, 0x06, 0x10, 0x63,
0x06, 0x40, 0x66, 0x06, 0x80, 0x69, 0x06, 0xB0, 0x6C, 0x06, 0xE0, 0x6F, 0x07, 0x10, 0x73, 0x07, 0x40, 0x76, 0x07, 0x70, 0x79, 0x07, 0xA0, 0x7C,
0x07, 0xE0, 0x7F, 0x08, 0x10, 0x82, 0x08, 0x40, 0x85, 0x08, 0x70, 0x88, 0x08, 0xA0, 0x8C, 0x08, 0xD0, 0x8F, 0x09, 0x00, 0x92, 0x09, 0x30, 0x95,
0x09, 0x70, 0x98, 0x09, 0xA0, 0x9B, 0x09, 0xD0, 0x9E, 0x0A, 0x00, 0xA2, 0x0A, 0x30, 0xA5, 0x0A, 0x60, 0xA8, 0x0A, 0x90, 0xAB, 0x0A, 0xC0, 0xAE,
0x0B, 0x00, 0xB1, 0x0B, 0x30, 0xB4, 0x0B, 0x60, 0xB7, 0x0B, 0x90, 0xBB, 0x0B, 0xC0, 0xBE, 0x0B, 0xF0, 0xC1, 0x0C, 0x20, 0xC4, 0x0C, 0x60, 0xC7,
0x0C, 0x90, 0xCA, 0x0C, 0xC0, 0xCD, 0x0C, 0xF0, 0xD0, 0x0D, 0x20, 0xD4, 0x0D, 0x50, 0xD7, 0x0D, 0x80, 0xDA, 0x0D, 0xB0, 0xDD, 0x0D, 0xF0, 0xE0,
0x0E, 0x20, 0xE3, 0x0E, 0x50, 0xE6, 0x0E, 0x80, 0xE9, 0x0E, 0xB0, 0xED, 0x0E, 0xE0, 0xF0, 0x0F, 0x10, 0xF3, 0x0F, 0x40, 0xF6, 0x0F, 0x70, 0xF9,
0x0F, 0xB0, 0xFC, 0x0F, 0xE0, 0xFF, 0x10, 0x11, 0x02, 0x10, 0x41, 0x05, 0x10, 0x71, 0x09, 0x10, 0xA1, 0x0C, 0x10, 0xD1, 0x0F, 0x11, 0x01, 0x12,
0x11, 0x31, 0x15, 0x11, 0x71, 0x18, 0x11, 0xA1, 0x1B, 0x11, 0xD1, 0x1E, 0x12, 0x01, 0x21, 0x12, 0x31, 0x25, 0x12, 0x61, 0x28, 0x12, 0x91, 0x2B,
0x12, 0xC1, 0x2E, 0x12, 0xF1, 0x31, 0x13, 0x31, 0x34, 0x13, 0x61, 0x37, 0x13, 0x91, 0x3A, 0x13, 0xC1, 0x3D, 0x13, 0xF1, 0x41, 0x14, 0x21, 0x44,
0x14, 0x51, 0x47, 0x14, 0x81, 0x4A, 0x14, 0xB1, 0x4D, 0x14, 0xE1, 0x50, 0x15, 0x21, 0x53, 0x15, 0x51, 0x56, 0x15, 0x81, 0x59, 0x15, 0xB1, 0x5C,
0x15, 0xE1, 0x60, 0x16, 0x11, 0x63, 0x16, 0x41, 0x66, 0x16, 0x71, 0x69, 0x16, 0xA1, 0x6C, 0x16, 0xD1, 0x6F, 0x17, 0x11, 0x72, 0x17, 0x41, 0x75,
0x17, 0x71, 0x78, 0x17, 0xA1, 0x7B, 0x17, 0xD1, 0x7E, 0x18, 0x01, 0x81, 0x18, 0x31, 0x85, 0x18, 0x61, 0x88, 0x18, 0x91, 0x8B, 0x18, 0xC1, 0x8E,
0x18, 0xF1, 0x91, 0x19, 0x21, 0x94, 0x19, 0x61, 0x97, 0x19, 0x91, 0x9A, 0x19, 0xC1, 0x9D, 0x19, 0xF1, 0xA0, 0x1A, 0x21, 0xA3, 0x1A, 0x51, 0xA6,
0x1A, 0x81, 0xA9, 0x1A, 0xB1, 0xAD, 0x1A, 0xE1, 0xB0, 0x1B, 0x11, 0xB3, 0x1B, 0x41, 0xB6, 0x1B, 0x71, 0xB9, 0x1B, 0xA1, 0xBC, 0x1B, 0xD1, 0xBF,
0x1C, 0x11, 0xC2, 0x1C, 0x41, 0xC5, 0x1C, 0x71, 0xC8, 0x1C, 0xA1, 0xCB, 0x1C, 0xD1, 0xCE, 0x1D, 0x01, 0xD1, 0x1D, 0x31, 0xD4, 0x1D, 0x61, 0xD7,
0x1D, 0x91, 0xDB, 0x1D, 0xC1, 0xDE, 0x1D, 0xF1, 0xE1, 0x1E, 0x21, 0xE4, 0x1E, 0x51, 0xE7, 0x1E, 0x81, 0xEA, 0x1E, 0xB1, 0xED, 0x1E, 0xE1, 0xF0,
0x1F, 0x11, 0xF3, 0x1F, 0x41, 0xF6, 0x1F, 0x71, 0xF9, 0x1F, 0xB1, 0xFC, 0x1F, 0xE1, 0xFF, 0x20, 0x12, 0x02, 0x20, 0x42, 0x05, 0x20, 0x72, 0x08,
0x20, 0xA2, 0x0B, 0x20, 0xD2, 0x0E, 0x21, 0x02, 0x11, 0x21, 0x32, 0x14, 0x21, 0x62, 0x17, 0x21, 0x92, 0x1A, 0x21, 0xC2, 0x1D, 0x21, 0xF2, 0x20,
0x22, 0x22, 0x23, 0x22, 0x52, 0x26, 0x22, 0x82, 0x2A, 0x22, 0xB2, 0x2D, 0x22, 0xE2, 0x30, 0x23, 0x12, 0x33, 0x23, 0x42, 0x36, 0x23, 0x72, 0x39,
0x23, 0xA2, 0x3C, 0x23, 0xD2, 0x3F, 0x24, 0x02, 0x42, 0x24, 0x32, 0x45, 0x24, 0x62, 0x48, 0x24, 0x92, 0x4B, 0x24, 0xC2, 0x4E, 0x24, 0xF2, 0x51,
0x25, 0x22, 0x54, 0x25, 0x52, 0x57, 0x25, 0x82, 0x5A, 0x25, 0xB2, 0x5D, 0x25, 0xE2, 0x60, 0x26, 0x12, 0x63, 0x26, 0x42, 0x66, 0x26, 0x72, 0x69,
0x26, 0xA2, 0x6C, 0x26, 0xD2, 0x6F, 0x27, 0x02, 0x72, 0x27, 0x32, 0x75, 0x27, 0x62, 0x78, 0x27, 0x92, 0x7B, 0x27, 0xC2, 0x7E, 0x27, 0xF2, 0x81,
0x28, 0x22, 0x84, 0x28, 0x52, 0x87, 0x28, 0x82, 0x8A, 0x28, 0xB2, 0x8D, 0x28, 0xE2, 0x90, 0x29, 0x12, 0x92, 0x29, 0x42, 0x95, 0x29, 0x72, 0x98,
0x29, 0xA2, 0x9B, 0x29, 0xD2, 0x9E, 0x2A, 0x02, 0xA1, 0x2A, 0x32, 0xA4, 0x2A, 0x62, 0xA7, 0x2A, 0x92, 0xAA, 0x2A, 0xC2, 0xAD, 0x2A, 0xF2, 0xB0,
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0x79, 0xF7, 0xA0, 0x7A, 0x07, 0xA1, 0x7A, 0x17, 0xA2, 0x7A, 0x27, 0xA3, 0x7A, 0x37, 0xA4, 0x7A, 0x47, 0xA5, 0x7A, 0x57, 0xA5, 0x7A, 0x67, 0xA6,
0x7A, 0x77, 0xA7, 0x7A, 0x87, 0xA8, 0x7A, 0x97, 0xA9, 0x7A, 0xA7, 0xAA, 0x7A, 0xA7, 0xAB, 0x7A, 0xB7, 0xAC, 0x7A, 0xC7, 0xAD, 0x7A, 0xD7, 0xAE,
0x7A, 0xE7, 0xAE, 0x7A, 0xF7, 0xAF, 0x7B, 0x07, 0xB0, 0x7B, 0x17, 0xB1, 0x7B, 0x17, 0xB2, 0x7B, 0x27, 0xB3, 0x7B, 0x37, 0xB4, 0x7B, 0x47, 0xB4,
0x7B, 0x57, 0xB5, 0x7B, 0x67, 0xB6, 0x7B, 0x77, 0xB7, 0x7B, 0x77, 0xB8, 0x7B, 0x87, 0xB9, 0x7B, 0x97, 0xB9, 0x7B, 0xA7, 0xBA, 0x7B, 0xB7, 0xBB,
0x7B, 0xB7, 0xBC, 0x7B, 0xC7, 0xBD, 0x7B, 0xD7, 0xBD, 0x7B, 0xE7, 0xBE, 0x7B, 0xF7, 0xBF, 0x7B, 0xF7, 0xC0, 0x7C, 0x07, 0xC1, 0x7C, 0x17, 0xC1,
0x7C, 0x27, 0xC2, 0x7C, 0x27, 0xC3, 0x7C, 0x37, 0xC4, 0x7C, 0x47, 0xC4, 0x7C, 0x57, 0xC5, 0x7C, 0x57, 0xC6, 0x7C, 0x67, 0xC7, 0x7C, 0x77, 0xC7,
0x7C, 0x87, 0xC8, 0x7C, 0x87, 0xC9, 0x7C, 0x97, 0xC9, 0x7C, 0xA7, 0xCA, 0x7C, 0xA7, 0xCB, 0x7C, 0xB7, 0xCC, 0x7C, 0xC7, 0xCC, 0x7C, 0xD7, 0xCD,
0x7C, 0xD7, 0xCE, 0x7C, 0xE7, 0xCE, 0x7C, 0xF7, 0xCF, 0x7C, 0xF7, 0xD0, 0x7D, 0x07, 0xD0, 0x7D, 0x17, 0xD1, 0x7D, 0x17, 0xD2, 0x7D, 0x27, 0xD2,
0x7D, 0x37, 0xD3, 0x7D, 0x37, 0xD4, 0x7D, 0x47, 0xD4, 0x7D, 0x57, 0xD5, 0x7D, 0x57, 0xD5, 0x7D, 0x67, 0xD6, 0x7D, 0x67, 0xD7, 0x7D, 0x77, 0xD7,
0x7D, 0x87, 0xD8, 0x7D, 0x87, 0xD9, 0x7D, 0x97, 0xD9, 0x7D, 0x97, 0xDA, 0x7D, 0xA7, 0xDA, 0x7D, 0xB7, 0xDB, 0x7D, 0xB7, 0xDC, 0x7D, 0xC7, 0xDC,
0x7D, 0xC7, 0xDD, 0x7D, 0xD7, 0xDD, 0x7D, 0xE7, 0xDE, 0x7D, 0xE7, 0xDE, 0x7D, 0xF7, 0xDF, 0x7D, 0xF7, 0xE0, 0x7E, 0x07, 0xE0, 0x7E, 0x07, 0xE1,
0x7E, 0x17, 0xE1, 0x7E, 0x17, 0xE2, 0x7E, 0x27, 0xE2, 0x7E, 0x27, 0xE3, 0x7E, 0x37, 0xE3, 0x7E, 0x37, 0xE4, 0x7E, 0x47, 0xE4, 0x7E, 0x57, 0xE5,
0x7E, 0x57, 0xE5, 0x7E, 0x67, 0xE6, 0x7E, 0x67, 0xE6, 0x7E, 0x67, 0xE7, 0x7E, 0x77, 0xE7, 0x7E, 0x77, 0xE8, 0x7E, 0x87, 0xE8, 0x7E, 0x87, 0xE9,
0x7E, 0x97, 0xE9, 0x7E, 0x97, 0xEA, 0x7E, 0xA7, 0xEA, 0x7E, 0xA7, 0xEA, 0x7E, 0xB7, 0xEB, 0x7E, 0xB7, 0xEB, 0x7E, 0xC7, 0xEC, 0x7E, 0xC7, 0xEC,
0x7E, 0xC7, 0xED, 0x7E, 0xD7, 0xED, 0x7E, 0xD7, 0xED, 0x7E, 0xE7, 0xEE, 0x7E, 0xE7, 0xEE, 0x7E, 0xE7, 0xEF, 0x7E, 0xF7, 0xEF, 0x7E, 0xF7, 0xEF,
0x7F, 0x07, 0xF0, 0x7F, 0x07, 0xF0, 0x7F, 0x07, 0xF1, 0x7F, 0x17, 0xF1, 0x7F, 0x17, 0xF1, 0x7F, 0x17, 0xF2, 0x7F, 0x27, 0xF2, 0x7F, 0x27, 0xF2,
0x7F, 0x37, 0xF3, 0x7F, 0x37, 0xF3, 0x7F, 0x37, 0xF3, 0x7F, 0x47, 0xF4, 0x7F, 0x47, 0xF4, 0x7F, 0x47, 0xF4, 0x7F, 0x57, 0xF5, 0x7F, 0x57, 0xF5,
0x7F, 0x57, 0xF5, 0x7F, 0x57, 0xF6, 0x7F, 0x67, 0xF6, 0x7F, 0x67, 0xF6, 0x7F, 0x67, 0xF6, 0x7F, 0x77, 0xF7, 0x7F, 0x77, 0xF7, 0x7F, 0x77, 0xF7,
0x7F, 0x77, 0xF8, 0x7F, 0x87, 0xF8, 0x7F, 0x87, 0xF8, 0x7F, 0x87, 0xF8, 0x7F, 0x87, 0xF9, 0x7F, 0x97, 0xF9, 0x7F, 0x97, 0xF9, 0x7F, 0x97, 0xF9,
0x7F, 0x97, 0xFA, 0x7F, 0xA7, 0xFA, 0x7F, 0xA7, 0xFA, 0x7F, 0xA7, 0xFA, 0x7F, 0xA7, 0xFA, 0x7F, 0xB7, 0xFB, 0x7F, 0xB7, 0xFB, 0x7F, 0xB7, 0xFB,
0x7F, 0xB7, 0xFB, 0x7F, 0xB7, 0xFB, 0x7F, 0xC7, 0xFC, 0x7F, 0xC7, 0xFC, 0x7F, 0xC7, 0xFC, 0x7F, 0xC7, 0xFC, 0x7F, 0xC7, 0xFC, 0x7F, 0xC7, 0xFC,
0x7F, 0xD7, 0xFD, 0x7F, 0xD7, 0xFD, 0x7F, 0xD7, 0xFD, 0x7F, 0xD7, 0xFD, 0x7F, 0xD7, 0xFD, 0x7F, 0xD7, 0xFD, 0x7F, 0xD7, 0xFD, 0x7F, 0xD7, 0xFE,
0x7F, 0xE7, 0xFE, 0x7F, 0xE7, 0xFE, 0x7F, 0xE7, 0xFE, 0x7F, 0xE7, 0xFE, 0x7F, 0xE7, 0xFE, 0x7F, 0xE7, 0xFE, 0x7F, 0xE7, 0xFE, 0x7F, 0xE7, 0xFE,
0x7F, 0xE7, 0xFE, 0x7F, 0xE7, 0xFE, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF,
0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF, 0x7F, 0xF7, 0xFF,
};
#else
// range 2000
const uint8_t LUT_sine_8192_quad_packed[3072] = {
0x00, 0x00, 0x02, 0x00, 0x30, 0x05, 0x00, 0x60, 0x08, 0x00, 0x90, 0x0B, 0x00, 0xC0, 0x0E, 0x00, 0xF0, 0x11, 0x01, 0x20, 0x14, 0x01, 0x50, 0x17,
0x01, 0x90, 0x1A, 0x01, 0xC0, 0x1D, 0x01, 0xF0, 0x20, 0x02, 0x20, 0x23, 0x02, 0x50, 0x26, 0x02, 0x80, 0x29, 0x02, 0xB0, 0x2C, 0x02, 0xE0, 0x30,
0x03, 0x10, 0x33, 0x03, 0x40, 0x36, 0x03, 0x70, 0x39, 0x03, 0xA0, 0x3C, 0x03, 0xD0, 0x3F, 0x04, 0x00, 0x42, 0x04, 0x30, 0x45, 0x04, 0x70, 0x48,
0x04, 0xA0, 0x4B, 0x04, 0xD0, 0x4E, 0x05, 0x00, 0x51, 0x05, 0x30, 0x54, 0x05, 0x60, 0x57, 0x05, 0x90, 0x5A, 0x05, 0xC0, 0x5E, 0x05, 0xF0, 0x61,
0x06, 0x20, 0x64, 0x06, 0x50, 0x67, 0x06, 0x80, 0x6A, 0x06, 0xB0, 0x6D, 0x06, 0xE0, 0x70, 0x07, 0x10, 0x73, 0x07, 0x50, 0x76, 0x07, 0x80, 0x79,
0x07, 0xB0, 0x7C, 0x07, 0xE0, 0x7F, 0x08, 0x10, 0x82, 0x08, 0x40, 0x85, 0x08, 0x70, 0x88, 0x08, 0xA0, 0x8B, 0x08, 0xD0, 0x8F, 0x09, 0x00, 0x92,
0x09, 0x30, 0x95, 0x09, 0x60, 0x98, 0x09, 0x90, 0x9B, 0x09, 0xC0, 0x9E, 0x09, 0xF0, 0xA1, 0x0A, 0x20, 0xA4, 0x0A, 0x50, 0xA7, 0x0A, 0x90, 0xAA,
0x0A, 0xC0, 0xAD, 0x0A, 0xF0, 0xB0, 0x0B, 0x20, 0xB3, 0x0B, 0x50, 0xB6, 0x0B, 0x80, 0xB9, 0x0B, 0xB0, 0xBC, 0x0B, 0xE0, 0xBF, 0x0C, 0x10, 0xC3,
0x0C, 0x40, 0xC6, 0x0C, 0x70, 0xC9, 0x0C, 0xA0, 0xCC, 0x0C, 0xD0, 0xCF, 0x0D, 0x00, 0xD2, 0x0D, 0x30, 0xD5, 0x0D, 0x60, 0xD8, 0x0D, 0x90, 0xDB,
0x0D, 0xC0, 0xDE, 0x0D, 0xF0, 0xE1, 0x0E, 0x30, 0xE4, 0x0E, 0x60, 0xE7, 0x0E, 0x90, 0xEA, 0x0E, 0xC0, 0xED, 0x0E, 0xF0, 0xF0, 0x0F, 0x20, 0xF3,
0x0F, 0x50, 0xF6, 0x0F, 0x80, 0xF9, 0x0F, 0xB0, 0xFC, 0x0F, 0xE0, 0xFF, 0x10, 0x11, 0x03, 0x10, 0x41, 0x06, 0x10, 0x71, 0x09, 0x10, 0xA1, 0x0C,
0x10, 0xD1, 0x0F, 0x11, 0x01, 0x12, 0x11, 0x31, 0x15, 0x11, 0x61, 0x18, 0x11, 0x91, 0x1B, 0x11, 0xC1, 0x1E, 0x11, 0xF1, 0x21, 0x12, 0x21, 0x24,
0x12, 0x51, 0x27, 0x12, 0x81, 0x2A, 0x12, 0xC1, 0x2D, 0x12, 0xF1, 0x30, 0x13, 0x21, 0x33, 0x13, 0x51, 0x36, 0x13, 0x81, 0x39, 0x13, 0xB1, 0x3C,
0x13, 0xE1, 0x3F, 0x14, 0x11, 0x42, 0x14, 0x41, 0x45, 0x14, 0x71, 0x48, 0x14, 0xA1, 0x4B, 0x14, 0xD1, 0x4E, 0x15, 0x01, 0x51, 0x15, 0x31, 0x54,
0x15, 0x61, 0x57, 0x15, 0x91, 0x5A, 0x15, 0xC1, 0x5D, 0x15, 0xF1, 0x60, 0x16, 0x21, 0x64, 0x16, 0x51, 0x67, 0x16, 0x81, 0x6A, 0x16, 0xB1, 0x6D,
0x16, 0xE1, 0x70, 0x17, 0x11, 0x73, 0x17, 0x41, 0x76, 0x17, 0x71, 0x79, 0x17, 0xA1, 0x7C, 0x17, 0xD1, 0x7F, 0x18, 0x01, 0x82, 0x18, 0x31, 0x85,
0x18, 0x61, 0x88, 0x18, 0x91, 0x8B, 0x18, 0xC1, 0x8E, 0x18, 0xF1, 0x91, 0x19, 0x21, 0x94, 0x19, 0x51, 0x97, 0x19, 0x81, 0x9A, 0x19, 0xB1, 0x9D,
0x19, 0xE1, 0xA0, 0x1A, 0x11, 0xA3, 0x1A, 0x41, 0xA6, 0x1A, 0x71, 0xA9, 0x1A, 0xA1, 0xAC, 0x1A, 0xD1, 0xAF, 0x1B, 0x01, 0xB2, 0x1B, 0x31, 0xB5,
0x1B, 0x61, 0xB8, 0x1B, 0x91, 0xBB, 0x1B, 0xC1, 0xBE, 0x1B, 0xF1, 0xC1, 0x1C, 0x21, 0xC4, 0x1C, 0x51, 0xC7, 0x1C, 0x81, 0xCA, 0x1C, 0xB1, 0xCD,
0x1C, 0xE1, 0xD0, 0x1D, 0x11, 0xD3, 0x1D, 0x41, 0xD6, 0x1D, 0x71, 0xD9, 0x1D, 0xA1, 0xDC, 0x1D, 0xD1, 0xDF, 0x1E, 0x01, 0xE1, 0x1E, 0x31, 0xE4,
0x1E, 0x61, 0xE7, 0x1E, 0x91, 0xEA, 0x1E, 0xC1, 0xED, 0x1E, 0xF1, 0xF0, 0x1F, 0x21, 0xF3, 0x1F, 0x51, 0xF6, 0x1F, 0x81, 0xF9, 0x1F, 0xB1, 0xFC,
0x1F, 0xE1, 0xFF, 0x20, 0x12, 0x02, 0x20, 0x42, 0x05, 0x20, 0x72, 0x08, 0x20, 0xA2, 0x0B, 0x20, 0xD2, 0x0E, 0x21, 0x02, 0x11, 0x21, 0x22, 0x14,
0x21, 0x52, 0x17, 0x21, 0x82, 0x1A, 0x21, 0xB2, 0x1D, 0x21, 0xE2, 0x20, 0x22, 0x12, 0x23, 0x22, 0x42, 0x26, 0x22, 0x72, 0x29, 0x22, 0xA2, 0x2C,
0x22, 0xD2, 0x2F, 0x23, 0x02, 0x31, 0x23, 0x32, 0x34, 0x23, 0x62, 0x37, 0x23, 0x92, 0x3A, 0x23, 0xC2, 0x3D, 0x23, 0xF2, 0x40, 0x24, 0x22, 0x43,
0x24, 0x52, 0x46, 0x24, 0x82, 0x49, 0x24, 0xA2, 0x4C, 0x24, 0xD2, 0x4F, 0x25, 0x02, 0x52, 0x25, 0x32, 0x55, 0x25, 0x62, 0x58, 0x25, 0x92, 0x5B,
0x25, 0xC2, 0x5D, 0x25, 0xF2, 0x60, 0x26, 0x22, 0x63, 0x26, 0x52, 0x66, 0x26, 0x82, 0x69, 0x26, 0xB2, 0x6C, 0x26, 0xE2, 0x6F, 0x27, 0x02, 0x72,
0x27, 0x32, 0x75, 0x27, 0x62, 0x78, 0x27, 0x92, 0x7B, 0x27, 0xC2, 0x7E, 0x27, 0xF2, 0x80, 0x28, 0x22, 0x83, 0x28, 0x52, 0x86, 0x28, 0x82, 0x89,
0x28, 0xB2, 0x8C, 0x28, 0xE2, 0x8F, 0x29, 0x02, 0x92, 0x29, 0x32, 0x95, 0x29, 0x62, 0x98, 0x29, 0x92, 0x9B, 0x29, 0xC2, 0x9D, 0x29, 0xF2, 0xA0,
0x2A, 0x22, 0xA3, 0x2A, 0x52, 0xA6, 0x2A, 0x82, 0xA9, 0x2A, 0xA2, 0xAC, 0x2A, 0xD2, 0xAF, 0x2B, 0x02, 0xB2, 0x2B, 0x32, 0xB5, 0x2B, 0x62, 0xB7,
0x2B, 0x92, 0xBA, 0x2B, 0xC2, 0xBD, 0x2B, 0xF2, 0xC0, 0x2C, 0x12, 0xC3, 0x2C, 0x42, 0xC6, 0x2C, 0x72, 0xC9, 0x2C, 0xA2, 0xCB, 0x2C, 0xD2, 0xCE,
0x2D, 0x02, 0xD1, 0x2D, 0x32, 0xD4, 0x2D, 0x62, 0xD7, 0x2D, 0x82, 0xDA, 0x2D, 0xB2, 0xDD, 0x2D, 0xE2, 0xE0, 0x2E, 0x12, 0xE2, 0x2E, 0x42, 0xE5,
0x2E, 0x72, 0xE8, 0x2E, 0x92, 0xEB, 0x2E, 0xC2, 0xEE, 0x2E, 0xF2, 0xF1, 0x2F, 0x22, 0xF3, 0x2F, 0x52, 0xF6, 0x2F, 0x82, 0xF9, 0x2F, 0xB2, 0xFC,
0x2F, 0xD2, 0xFF, 0x30, 0x03, 0x02, 0x30, 0x33, 0x04, 0x30, 0x63, 0x07, 0x30, 0x93, 0x0A, 0x30, 0xC3, 0x0D, 0x30, 0xE3, 0x10, 0x31, 0x13, 0x13,
0x31, 0x43, 0x15, 0x31, 0x73, 0x18, 0x31, 0xA3, 0x1B, 0x31, 0xC3, 0x1E, 0x31, 0xF3, 0x21, 0x32, 0x23, 0x23, 0x32, 0x53, 0x26, 0x32, 0x83, 0x29,
0x32, 0xA3, 0x2C, 0x32, 0xD3, 0x2F, 0x33, 0x03, 0x31, 0x33, 0x33, 0x34, 0x33, 0x63, 0x37, 0x33, 0x83, 0x3A, 0x33, 0xB3, 0x3D, 0x33, 0xE3, 0x3F,
0x34, 0x13, 0x42, 0x34, 0x43, 0x45, 0x34, 0x63, 0x48, 0x34, 0x93, 0x4B, 0x34, 0xC3, 0x4D, 0x34, 0xF3, 0x50, 0x35, 0x23, 0x53, 0x35, 0x43, 0x56,
0x35, 0x73, 0x58, 0x35, 0xA3, 0x5B, 0x35, 0xD3, 0x5E, 0x35, 0xF3, 0x61, 0x36, 0x23, 0x64, 0x36, 0x53, 0x66, 0x36, 0x83, 0x69, 0x36, 0xA3, 0x6C,
0x36, 0xD3, 0x6F, 0x37, 0x03, 0x71, 0x37, 0x33, 0x74, 0x37, 0x53, 0x77, 0x37, 0x83, 0x7A, 0x37, 0xB3, 0x7C, 0x37, 0xE3, 0x7F, 0x38, 0x03, 0x82,
0x38, 0x33, 0x85, 0x38, 0x63, 0x87, 0x38, 0x93, 0x8A, 0x38, 0xB3, 0x8D, 0x38, 0xE3, 0x90, 0x39, 0x13, 0x92, 0x39, 0x43, 0x95, 0x39, 0x63, 0x98,
0x39, 0x93, 0x9A, 0x39, 0xC3, 0x9D, 0x39, 0xF3, 0xA0, 0x3A, 0x13, 0xA3, 0x3A, 0x43, 0xA5, 0x3A, 0x73, 0xA8, 0x3A, 0x93, 0xAB, 0x3A, 0xC3, 0xAD,
0x3A, 0xF3, 0xB0, 0x3B, 0x13, 0xB3, 0x3B, 0x43, 0xB6, 0x3B, 0x73, 0xB8, 0x3B, 0xA3, 0xBB, 0x3B, 0xC3, 0xBE, 0x3B, 0xF3, 0xC0, 0x3C, 0x23, 0xC3,
0x3C, 0x43, 0xC6, 0x3C, 0x73, 0xC8, 0x3C, 0xA3, 0xCB, 0x3C, 0xC3, 0xCE, 0x3C, 0xF3, 0xD0, 0x3D, 0x23, 0xD3, 0x3D, 0x43, 0xD6, 0x3D, 0x73, 0xD8,
0x3D, 0xA3, 0xDB, 0x3D, 0xC3, 0xDE, 0x3D, 0xF3, 0xE0, 0x3E, 0x23, 0xE3, 0x3E, 0x43, 0xE6, 0x3E, 0x73, 0xE8, 0x3E, 0xA3, 0xEB, 0x3E, 0xC3, 0xEE,
0x3E, 0xF3, 0xF0, 0x3F, 0x23, 0xF3, 0x3F, 0x43, 0xF6, 0x3F, 0x73, 0xF8, 0x3F, 0xA3, 0xFB, 0x3F, 0xC3, 0xFE, 0x3F, 0xF4, 0x00, 0x40, 0x24, 0x03,
0x40, 0x44, 0x06, 0x40, 0x74, 0x08, 0x40, 0x94, 0x0B, 0x40, 0xC4, 0x0D, 0x40, 0xF4, 0x10, 0x41, 0x14, 0x13, 0x41, 0x44, 0x15, 0x41, 0x74, 0x18,
0x41, 0x94, 0x1A, 0x41, 0xC4, 0x1D, 0x41, 0xE4, 0x20, 0x42, 0x14, 0x22, 0x42, 0x44, 0x25, 0x42, 0x64, 0x28, 0x42, 0x94, 0x2A, 0x42, 0xB4, 0x2D,
0x42, 0xE4, 0x2F, 0x43, 0x14, 0x32, 0x43, 0x34, 0x34, 0x43, 0x64, 0x37, 0x43, 0x84, 0x3A, 0x43, 0xB4, 0x3C, 0x43, 0xE4, 0x3F, 0x44, 0x04, 0x41,
0x44, 0x34, 0x44, 0x44, 0x54, 0x47, 0x44, 0x84, 0x49, 0x44, 0xA4, 0x4C, 0x44, 0xD4, 0x4E, 0x44, 0xF4, 0x51, 0x45, 0x24, 0x53, 0x45, 0x54, 0x56,
0x45, 0x74, 0x58, 0x45, 0xA4, 0x5B, 0x45, 0xC4, 0x5E, 0x45, 0xF4, 0x60, 0x46, 0x14, 0x63, 0x46, 0x44, 0x65, 0x46, 0x64, 0x68, 0x46, 0x94, 0x6A,
0x46, 0xB4, 0x6D, 0x46, 0xE4, 0x6F, 0x47, 0x14, 0x72, 0x47, 0x34, 0x74, 0x47, 0x64, 0x77, 0x47, 0x84, 0x79, 0x47, 0xB4, 0x7C, 0x47, 0xD4, 0x7E,
0x48, 0x04, 0x81, 0x48, 0x24, 0x83, 0x48, 0x54, 0x86, 0x48, 0x74, 0x88, 0x48, 0xA4, 0x8B, 0x48, 0xC4, 0x8D, 0x48, 0xF4, 0x90, 0x49, 0x14, 0x92,
0x49, 0x44, 0x95, 0x49, 0x64, 0x97, 0x49, 0x94, 0x9A, 0x49, 0xB4, 0x9C, 0x49, 0xE4, 0x9F, 0x4A, 0x04, 0xA1, 0x4A, 0x24, 0xA4, 0x4A, 0x54, 0xA6,
0x4A, 0x74, 0xA9, 0x4A, 0xA4, 0xAB, 0x4A, 0xC4, 0xAE, 0x4A, 0xF4, 0xB0, 0x4B, 0x14, 0xB2, 0x4B, 0x44, 0xB5, 0x4B, 0x64, 0xB7, 0x4B, 0x94, 0xBA,
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};
#endif

144
GexUnits/dac/_dac_init.c
Unescape View File

@ -1,144 +0,0 @@
//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define DAC_INTERNAL
#include "_dac_internal.h"
/** Allocate data structure and set defaults */
error_t UDAC_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
for (int i = 0; i < 2; i++) {
priv->cfg.ch[i].buffered = true;
priv->cfg.ch[i].enable = true;
priv->cfg.ch[i].noise_level = 2;
priv->cfg.ch[i].noise_type = NOISE_NONE;
priv->ch[i].waveform = UDAC_WAVE_DC;
priv->ch[i].dc_level = 2047;
priv->ch[i].rectangle_ontime = 4096; // half
priv->ch[i].rectangle_high = 4095;
priv->ch[i].rectangle_low = 0;
priv->ch[i].counter = 0;
priv->ch[i].increment = 0; // stopped
priv->ch[i].phase = 0;
}
UDAC_SetFreq(unit, 0, 1000);
UDAC_SetFreq(unit, 1, 1000);
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t UDAC_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
// copy noise config
priv->ch[0].noise_type = priv->cfg.ch[0].noise_type;
priv->ch[0].noise_level = priv->cfg.ch[0].noise_level;
priv->ch[1].noise_type = priv->cfg.ch[1].noise_type;
priv->ch[1].noise_level = priv->cfg.ch[1].noise_level;
// this may change for different devices
const Resource r_ch1 = R_PA4;
const Resource r_ch2 = R_PA5;
TRY(rsc_claim(unit, R_TIM6));
priv->TIMx = TIM6;
const bool e1 = priv->cfg.ch[0].enable;
const bool e2 = priv->cfg.ch[1].enable;
if (e1) {
TRY(rsc_claim(unit, r_ch1));
}
if (e2) {
TRY(rsc_claim(unit, r_ch2));
}
TRY(rsc_claim(unit, R_DAC1));
hw_periph_clock_enable(DAC1);
hw_periph_clock_enable(priv->TIMx);
GPIO_TypeDef *port;
uint32_t ll;
if (e1) {
assert_param(hw_pinrsc2ll(r_ch1, &port, &ll));
LL_GPIO_SetPinMode(port, ll, LL_GPIO_MODE_ANALOG);
}
if (e2) {
assert_param(hw_pinrsc2ll(r_ch1, &port, &ll));
LL_GPIO_SetPinMode(port, ll, LL_GPIO_MODE_ANALOG);
}
uint16_t presc = 1;
// presets... TODO pick the highest useable one (or find a new one)
#if UDAC_TIM_FREQ_DIVIDER == 1
uint32_t count = PLAT_AHB_MHZ;
#elif UDAC_TIM_FREQ_DIVIDER == 2
uint32_t count = PLAT_AHB_MHZ * 2;
#elif UDAC_TIM_FREQ_DIVIDER == 4
uint32_t count = PLAT_AHB_MHZ * 4;
#elif UDAC_TIM_FREQ_DIVIDER == 8
uint32_t count = PLAT_AHB_MHZ * 8;
#else
#error "bad freq"
#endif
// dbg("Presc %d, count %d", (int)presc, (int)count);
LL_TIM_SetPrescaler(priv->TIMx, (uint32_t) (presc - 1));
LL_TIM_SetAutoReload(priv->TIMx, count - 1);
LL_TIM_EnableARRPreload(priv->TIMx);
LL_TIM_GenerateEvent_UPDATE(priv->TIMx);
LL_TIM_ClearFlag_UPDATE(priv->TIMx); // prevent irq right after enabling
irqd_attach(priv->TIMx, UDAC_HandleIT, unit);
LL_TIM_EnableIT_UPDATE(priv->TIMx);
UDAC_Reconfigure(unit); // works with the timer - it should be inited already
// do not enbale counter initially - no need
// LL_TIM_EnableCounter(priv->TIMx);
return E_SUCCESS;
}
/** Tear down the unit */
void UDAC_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// de-init peripherals
if (unit->status == E_SUCCESS ) {
LL_DAC_DeInit(DAC);
LL_TIM_DeInit(priv->TIMx);
hw_periph_clock_disable(DAC1);
hw_periph_clock_disable(priv->TIMx);
irqd_detach(priv->TIMx, UDAC_HandleIT);
}
// Release all resources, deinit pins
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_DAC_INTERNAL_H
#define GEX_F072_DAC_INTERNAL_H
#ifndef DAC_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
enum UDAC_Noise {
NOISE_NONE = 0b00, // 0
NOISE_WHITE = 0b01, // 1
NOISE_TRIANGLE = 0b10, // 2
};
enum UDAC_Waveform {
UDAC_WAVE_DC,
UDAC_WAVE_SINE,
UDAC_WAVE_TRIANGLE,
UDAC_WAVE_SAWTOOTH_UP,
UDAC_WAVE_SAWTOOTH_DOWN,
UDAC_WAVE_RECTANGLE,
};
struct udac_channel_cfg {
bool enable;
bool buffered;
enum UDAC_Noise noise_type;
uint8_t noise_level; // 0-11
};
// 0 - 1 MHz, 2-500k, 4-250k, 8-125k
#define UDAC_TIM_FREQ_DIVIDER 8
#define UDAC_INDEX_WIDTH 13 // corresponds to 8192 places
#define UDAC_INDEX_SHIFT (32 - UDAC_INDEX_WIDTH)
#define UDAC_MAX_INDEX ((1 << UDAC_INDEX_WIDTH) - 1)
#define UDAC_VALUE_COUNT (1 << UDAC_INDEX_WIDTH)
extern const uint8_t LUT_sine_8192_quad_packed[];
struct udac_channel_live {
enum UDAC_Noise noise_type;
uint8_t noise_level; // 0-11
enum UDAC_Waveform waveform;
uint16_t rectangle_ontime; // for rectangle wave, 0-8191
uint16_t rectangle_high;
uint16_t rectangle_low;
uint16_t dc_level; // for DC wave
uint32_t counter;
uint32_t increment;
// last set phase if the frequencies are the same
// - can be used for live frequency changes without reset (meaningful only with matching increment values)
uint16_t phase;
uint16_t last_index;
uint16_t last_value;
};
/** Private data structure */
struct priv {
// settings
struct {
struct udac_channel_cfg ch[2];
} cfg;
// internal state
struct udac_channel_live ch[2];
TIM_TypeDef *TIMx; // timer used for the DDS function
};
/** Allocate data structure and set defaults */
error_t UDAC_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void UDAC_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void UDAC_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UDAC_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void UDAC_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t UDAC_init(Unit *unit);
/** Tear down the unit */
void UDAC_deInit(Unit *unit);
void UDAC_Reconfigure(Unit *unit);
void UDAC_HandleIT(void *arg);
error_t UDAC_SetFreq(Unit *unit, int channel, float freq);
void UDAC_ToggleTimerIfNeeded(Unit *unit);
#endif //GEX_F072_DAC_INTERNAL_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define DAC_INTERNAL
#include "_dac_internal.h"
/** Load from a binary buffer stored in Flash */
void UDAC_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->cfg.ch[0].enable = pp_bool(pp);
priv->cfg.ch[0].buffered = pp_bool(pp);
priv->cfg.ch[0].noise_type = (enum UDAC_Noise) pp_u8(pp);
priv->cfg.ch[0].noise_level = pp_u8(pp);
priv->cfg.ch[1].enable = pp_bool(pp);
priv->cfg.ch[1].buffered = pp_bool(pp);
priv->cfg.ch[1].noise_type = (enum UDAC_Noise) pp_u8(pp);
priv->cfg.ch[1].noise_level = pp_u8(pp);
}
/** Write to a binary buffer for storing in Flash */
void UDAC_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
pb_bool(pb, priv->cfg.ch[0].enable);
pb_bool(pb, priv->cfg.ch[0].buffered);
pb_u8(pb, priv->cfg.ch[0].noise_type);
pb_u8(pb, priv->cfg.ch[0].noise_level);
pb_bool(pb, priv->cfg.ch[1].enable);
pb_bool(pb, priv->cfg.ch[1].buffered);
pb_u8(pb, priv->cfg.ch[1].noise_type);
pb_u8(pb, priv->cfg.ch[1].noise_level);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UDAC_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
// Ch1
if (streq(key, "ch1_enable")) {
priv->cfg.ch[0].enable = cfg_bool_parse(value, &suc);
}
else if (streq(key, "ch1_buff")) {
priv->cfg.ch[0].buffered = cfg_bool_parse(value, &suc);
}
else if (streq(key, "ch1_noise")) {
priv->cfg.ch[0].noise_type =
(enum UDAC_Noise) cfg_enum3_parse(value,
"NONE", NOISE_NONE,
"WHITE", NOISE_WHITE,
"TRIANGLE", NOISE_TRIANGLE, &suc);
}
else if (streq(key, "ch1_noise-level")) {
uint8_t x = cfg_u8_parse(value, &suc);
if (x == 0) x = 1;
if (x > 12) x = 12;
priv->cfg.ch[0].noise_level = (uint8_t) (x - 1);
}
// Ch2
else if (streq(key, "ch2_enable")) {
priv->cfg.ch[1].enable = cfg_bool_parse(value, &suc);
}
else if (streq(key, "ch2_buff")) {
priv->cfg.ch[1].buffered = cfg_bool_parse(value, &suc);
}
else if (streq(key, "ch2_noise")) {
priv->cfg.ch[1].noise_type =
(enum UDAC_Noise) cfg_enum3_parse(value,
"NONE", NOISE_NONE,
"WHITE", NOISE_WHITE,
"TRIANGLE", NOISE_TRIANGLE, &suc);
}
else if (streq(key, "ch2_noise-level")) {
uint8_t x = cfg_u8_parse(value, &suc);
if (x == 0) x = 1;
if (x > 12) x = 12;
priv->cfg.ch[1].noise_level = (uint8_t) (x - 1);
}
// end
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void UDAC_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Enabled channels (1:A4, 2:A5)");
iw_entry_s(iw, "ch1_enable", str_yn(priv->cfg.ch[0].enable));
iw_entry_s(iw, "ch2_enable", str_yn(priv->cfg.ch[1].enable));
iw_comment(iw, "Enable output buffer");
iw_entry_s(iw, "ch1_buff", str_yn(priv->cfg.ch[0].buffered));
iw_entry_s(iw, "ch2_buff", str_yn(priv->cfg.ch[1].buffered));
iw_comment(iw, "Superimposed noise type (NONE,WHITE,TRIANGLE) and nbr. of bits (1-12)");
iw_entry_s(iw, "ch1_noise", cfg_enum3_encode(priv->cfg.ch[0].noise_type,
NOISE_NONE, "NONE",
NOISE_WHITE, "WHITE",
NOISE_TRIANGLE, "TRIANGLE"));
iw_entry_d(iw, "ch1_noise-level", priv->cfg.ch[0].noise_level + 1);
iw_entry_s(iw, "ch2_noise", cfg_enum3_encode(priv->cfg.ch[1].noise_type,
NOISE_NONE, "NONE",
NOISE_WHITE, "WHITE",
NOISE_TRIANGLE, "TRIANGLE"));
iw_entry_d(iw, "ch2_noise-level", priv->cfg.ch[1].noise_level + 1);
}

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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_dac.h"
#define DAC_INTERNAL
#include "_dac_internal.h"
// ------------------------------------------------------------------------
// Works OK up to about 20 kHz, could work faster with a faster interrupt
// (may be possible with some optimizations / adjusting priorities...)
enum DacCmd_ {
CMD_WAVE_DC = 0,
CMD_WAVE_SINE = 1,
CMD_WAVE_TRIANGLE = 2,
CMD_WAVE_SAWTOOTH_UP = 3,
CMD_WAVE_SAWTOOTH_DOWN = 4,
CMD_WAVE_RECTANGLE = 5,
CMD_SYNC = 10,
CMD_SET_FREQUENCY = 20,
CMD_SET_PHASE = 21,
CMD_SET_DITHER = 22,
};
/** Handle a request message */
static error_t UDAC_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
struct priv *priv = unit->data;
// Exceptions that aren't per-channel
switch (command) {
case CMD_SYNC:
dbg("Sync");
priv->ch[0].counter = priv->ch[0].phase << UDAC_INDEX_SHIFT;
priv->ch[1].counter = priv->ch[1].phase << UDAC_INDEX_SHIFT;
return E_SUCCESS;
}
uint8_t channels = pp_u8(pp);
bool want_reinit = false;
bool want_tog_timer = false;
// TODO move this stuff to the api file
for (int i = 0; i < 2; i++) {
if (channels & (1<<i)) {
switch (command) {
case CMD_SET_FREQUENCY:;
float freq = pp_float(pp);
TRY(UDAC_SetFreq(unit, i, freq));
break;
case CMD_WAVE_DC:
priv->ch[i].dc_level = pp_u16(pp);
priv->ch[i].waveform = UDAC_WAVE_DC;
want_tog_timer = true;
break;
case CMD_WAVE_SINE:
priv->ch[i].waveform = UDAC_WAVE_SINE;
want_tog_timer = true;
break;
case CMD_WAVE_TRIANGLE:
priv->ch[i].waveform = UDAC_WAVE_TRIANGLE;
want_tog_timer = true;
break;
case CMD_WAVE_SAWTOOTH_UP:
priv->ch[i].waveform = UDAC_WAVE_SAWTOOTH_UP;
want_tog_timer = true;
break;
case CMD_WAVE_SAWTOOTH_DOWN:
priv->ch[i].waveform = UDAC_WAVE_SAWTOOTH_DOWN;
want_tog_timer = true;
break;
case CMD_WAVE_RECTANGLE:;
uint16_t ontime = pp_u16(pp);
uint16_t high = pp_u16(pp);
uint16_t low = pp_u16(pp);
// use 0xFFFF to skip setting the value
if (high < 4096) priv->ch[i].rectangle_high = high;
if (low < 4096) priv->ch[i].rectangle_low = low;
if (ontime <= UDAC_VALUE_COUNT) priv->ch[i].rectangle_ontime = ontime;
// dbg("Set rect hi %d, low %d", (int)priv->ch[i].rectangle_high, (int)priv->ch[i].rectangle_low);
priv->ch[i].waveform = UDAC_WAVE_RECTANGLE;
want_tog_timer = true;
break;
case CMD_SET_PHASE:;
uint16_t ph = pp_u16(pp);
uint32_t newphase = ph << UDAC_INDEX_SHIFT;
uint32_t oldphase = priv->ch[i].phase << UDAC_INDEX_SHIFT;
int32_t diff = newphase - oldphase;
priv->ch[i].counter += diff;
priv->ch[i].phase = ph;
break;
case CMD_SET_DITHER:;
uint8_t noisetype = pp_u8(pp); // 0-none, 1-random, 2-triangle
uint8_t noisebits = pp_u8(pp);
// type 0xFF = not set
if (noisetype <= 2) {
priv->ch[i].noise_type = (enum UDAC_Noise) noisetype;
}
// bits 0xFF = not set
if (noisebits >= 1 && noisebits <= 12) {
priv->ch[i].noise_level = (uint8_t) (noisebits - 1);
}
// dbg("Ch %d: Dither type %d, level %d", i,
// (int)priv->ch[i].noise_type,
// (int)priv->ch[i].noise_level);
want_reinit = true;
break;
default:
return E_UNKNOWN_COMMAND;
}
}
}
if (want_reinit) {
UDAC_Reconfigure(unit);
}
if (want_tog_timer) {
UDAC_ToggleTimerIfNeeded(unit);
}
return E_SUCCESS;
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_DAC = {
.name = "DAC",
.description = "Two-channel analog output with waveforms",
// Settings
.preInit = UDAC_preInit,
.cfgLoadBinary = UDAC_loadBinary,
.cfgWriteBinary = UDAC_writeBinary,
.cfgLoadIni = UDAC_loadIni,
.cfgWriteIni = UDAC_writeIni,
// Init
.init = UDAC_init,
.deInit = UDAC_deInit,
// Function
.handleRequest = UDAC_handleRequest,
};

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//
// Created by MightyPork on 2017/11/25.
//
// Digital input unit; single or multiple pin read access on one port (A-F)
//
#ifndef U_DAC_H
#define U_DAC_H
#include "unit.h"
extern const UnitDriver UNIT_DAC;
// UU_ prototypes
#endif //U_DAC_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_din.h"
#define DIN_INTERNAL
#include "_din_internal.h"
/** Read request */
error_t UU_DIn_Read(Unit *unit, uint16_t *packed)
{
CHECK_TYPE(unit, &UNIT_DIN);
struct priv *priv = unit->data;
*packed = pinmask_pack((uint16_t) priv->port->IDR, priv->pins);
return E_SUCCESS;
}
/** Arm pins */
error_t UU_DIn_Arm(Unit *unit, uint16_t arm_single_packed, uint16_t arm_auto_packed)
{
CHECK_TYPE(unit, &UNIT_DIN);
struct priv *priv = unit->data;
uint16_t arm_single = pinmask_spread(arm_single_packed, priv->pins);
uint16_t arm_auto = pinmask_spread(arm_auto_packed, priv->pins);
// abort if user tries to arm pin that doesn't have a trigger configured
if (0 != ((arm_single | arm_auto) & ~(priv->trig_fall | priv->trig_rise))) {
return E_BAD_VALUE;
}
// arm and reset hold-offs
// we use critical section to avoid irq between the two steps
vPortEnterCritical();
{
priv->arm_auto |= arm_single;
priv->arm_single |= arm_auto;
const uint16_t combined = arm_single | arm_auto;
for (int i = 0; i < 16; i++) {
if (combined & (1 << i)) {
priv->holdoff_countdowns[i] = 0;
}
}
}
vPortExitCritical();
return E_SUCCESS;
}
/** DisArm pins */
error_t UU_DIn_DisArm(Unit *unit, uint16_t disarm_packed)
{
CHECK_TYPE(unit, &UNIT_DIN);
struct priv *priv = unit->data;
uint16_t disarm = pinmask_spread(disarm_packed, priv->pins);
// abort if user tries to disarm pin that doesn't have a trigger configured
if (0 != ((disarm) & ~(priv->trig_fall | priv->trig_rise))) {
return E_BAD_VALUE;
}
priv->arm_auto &= ~disarm;
priv->arm_single &= ~disarm;
return E_SUCCESS;
}

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define DIN_INTERNAL
#include "_din_internal.h"
/**
* Send a trigger event to master (called on the message queue thread).
*
* unit - unit
* timestamp - timestamp
* data1 - packed, triggering pin
* data2 - snapshot
*/
static void DIn_SendTriggerReportToMaster(Job *job)
{
PayloadBuilder pb = pb_start(unit_tmp512, UNIT_TMP_LEN, NULL);
pb_u16(&pb, (uint16_t) job->data1); // packed, 1 on the triggering pin
pb_u16(&pb, (uint16_t) job->data2); // packed, snapshot
assert_param(pb.ok);
EventReport event = {
.unit = job->unit,
.timestamp = job->timestamp,
.data = pb.start,
.length = (uint16_t) pb_length(&pb),
};
EventReport_Send(&event);
}
/**
* EXTI callback for pin change interrupts
*
* @param arg - the unit is passed here
*/
void DIn_handleExti(void *arg)
{
const uint64_t ts = PTIM_GetMicrotime();
Unit *unit = arg;
struct priv *priv = unit->data;
const uint16_t snapshot = (uint16_t) priv->port->IDR;
uint16_t trigger_map = 0;
uint16_t mask = 1;
const uint16_t armed_pins = priv->arm_single | priv->arm_auto;
for (int i = 0; i < 16; i++, mask <<= 1) {
if (!LL_EXTI_ReadFlag_0_31(LL_EXTI_LINES[i])) continue;
LL_EXTI_ClearFlag_0_31(LL_EXTI_LINES[i]);
// Armed and ready
if ((armed_pins & mask) && (priv->holdoff_countdowns[i] == 0)) {
// Mark as captured
trigger_map |= (1 << i);
// Start hold-off (no-op if zero hold-off)
priv->holdoff_countdowns[i] = priv->trig_holdoff;
}
}
// Disarm all possibly used single triggers
priv->arm_single &= ~trigger_map;
if (trigger_map != 0) {
Job j = {
.unit = unit,
.timestamp = ts,
.data1 = pinmask_pack(trigger_map, priv->pins),
.data2 = pinmask_pack(snapshot, priv->pins),
.cb = DIn_SendTriggerReportToMaster
};
scheduleJob(&j);
}
}

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define DIN_INTERNAL
#include "_din_internal.h"
/** Allocate data structure and set defaults */
error_t DIn_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
// some defaults
priv->port_name = 'A';
priv->pins = 0x0001;
priv->pulldown = 0x0000;
priv->pullup = 0x0000;
priv->trig_rise = 0x0000;
priv->trig_fall = 0x0000;
priv->trig_holdoff = 100;
priv->def_auto = 0x0000;
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t DIn_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
priv->pulldown &= priv->pins;
priv->pullup &= priv->pins;
priv->trig_rise &= priv->pins;
priv->trig_fall &= priv->pins;
priv->def_auto &= (priv->trig_rise|priv->trig_fall);
// copy auto-arm defaults to the auto-arm register (the register may be manipulated by commands)
priv->arm_auto = priv->def_auto;
priv->arm_single = 0;
// clear countdowns
memset(priv->holdoff_countdowns, 0, sizeof(priv->holdoff_countdowns));
// --- Parse config ---
priv->port = hw_port2periph(priv->port_name, &suc);
if (!suc) return E_BAD_CONFIG;
// Claim all needed pins
TRY(rsc_claim_gpios(unit, priv->port_name, priv->pins));
uint16_t mask;
// claim the needed EXTIs
mask = 1;
for (int i = 0; i < 16; i++, mask <<= 1) {
if (priv->pins & mask) {
if ((priv->trig_rise|priv->trig_fall) & mask) {
TRY(rsc_claim(unit, R_EXTI0+i));
}
}
}
mask = 1;
for (int i = 0; i < 16; i++, mask <<= 1) {
if (priv->pins & mask) {
uint32_t ll_pin = hw_pin2ll((uint8_t) i, &suc);
// --- Init hardware ---
LL_GPIO_SetPinMode(priv->port, ll_pin, LL_GPIO_MODE_INPUT);
uint32_t pull = 0;
#if PLAT_NO_FLOATING_INPUTS
pull = LL_GPIO_PULL_UP;
#else
pull = LL_GPIO_PULL_NO;
#endif
if (priv->pulldown & mask) pull = LL_GPIO_PULL_DOWN;
if (priv->pullup & mask) pull = LL_GPIO_PULL_UP;
LL_GPIO_SetPinPull(priv->port, ll_pin, pull);
if ((priv->trig_rise|priv->trig_fall) & mask) {
LL_EXTI_EnableIT_0_31(LL_EXTI_LINES[i]);
if (priv->trig_rise & mask) {
LL_EXTI_EnableRisingTrig_0_31(LL_EXTI_LINES[i]);
}
if (priv->trig_fall & mask) {
LL_EXTI_EnableFallingTrig_0_31(LL_EXTI_LINES[i]);
}
LL_SYSCFG_SetEXTISource(LL_SYSCFG_EXTI_PORTS[priv->port_name-'A'], LL_SYSCFG_EXTI_LINES[i]);
irqd_attach(EXTIS[i], DIn_handleExti, unit);
}
}
}
// request ticks if we have triggers and any hold-offs configured
if ((priv->trig_rise|priv->trig_fall) && priv->trig_holdoff > 0) {
unit->tick_interval = 1;
}
return E_SUCCESS;
}
/** Tear down the unit */
void DIn_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// pins are de-inited during teardown
// Detach EXTI handlers and disable interrupts
const uint16_t triggs = priv->trig_rise | priv->trig_fall;
if (unit->status == E_SUCCESS && triggs) {
uint16_t mask = 1;
for (int i = 0; i < 16; i++, mask <<= 1) {
if (triggs & mask) {
LL_EXTI_DisableIT_0_31(LL_EXTI_LINES[i]);
irqd_detach(EXTIS[i], DIn_handleExti);
}
}
}
// Release all resources
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_DIN_INTERNAL_H
#define GEX_F072_DIN_INTERNAL_H
#ifndef DIN_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
/** Private data structure */
struct priv {
char port_name;
uint16_t pins; // pin mask
uint16_t pulldown; // pull-downs (default is pull-up)
uint16_t pullup; // pull-ups
uint16_t trig_rise; // pins generating events on rising edge
uint16_t trig_fall; // pins generating events on falling edge
uint16_t trig_holdoff; // ms
uint16_t def_auto; // initial auto triggers
uint16_t arm_auto; // pins armed for auto reporting
uint16_t arm_single; // pins armed for single event
uint16_t holdoff_countdowns[16]; // countdowns to arm for each pin in the bit map
GPIO_TypeDef *port;
};
/** Allocate data structure and set defaults */
error_t DIn_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void DIn_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void DIn_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t DIn_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void DIn_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t DIn_init(Unit *unit);
/** Tear down the unit */
void DIn_deInit(Unit *unit);
// ------------------------------------------------------------------------
/**
* EXTI callback for pin change interrupts
*
* @param arg - the unit is passed here
*/
void DIn_handleExti(void *arg);
#endif //GEX_F072_DIN_INTERNAL_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define DIN_INTERNAL
#include "_din_internal.h"
/** Load from a binary buffer stored in Flash */
void DIn_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->port_name = pp_char(pp);
priv->pins = pp_u16(pp);
priv->pulldown = pp_u16(pp);
priv->pullup = pp_u16(pp);
priv->trig_rise = pp_u16(pp);
priv->trig_fall = pp_u16(pp);
priv->trig_holdoff = pp_u16(pp);
priv->def_auto = pp_u16(pp);
}
/** Write to a binary buffer for storing in Flash */
void DIn_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
pb_char(pb, priv->port_name);
pb_u16(pb, priv->pins);
pb_u16(pb, priv->pulldown);
pb_u16(pb, priv->pullup);
pb_u16(pb, priv->trig_rise);
pb_u16(pb, priv->trig_fall);
pb_u16(pb, priv->trig_holdoff);
pb_u16(pb, priv->def_auto);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t DIn_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "port")) {
suc = cfg_port_parse(value, &priv->port_name);
}
else if (streq(key, "pins")) {
priv->pins = cfg_pinmask_parse(value, &suc);
}
else if (streq(key, "pull-up")) {
priv->pullup = cfg_pinmask_parse(value, &suc);
}
else if (streq(key, "pull-down")) {
priv->pulldown = cfg_pinmask_parse(value, &suc);
}
else if (streq(key, "trig-rise")) {
priv->trig_rise = cfg_pinmask_parse(value, &suc);
}
else if (streq(key, "trig-fall")) {
priv->trig_fall = cfg_pinmask_parse(value, &suc);
}
else if (streq(key, "auto-trigger")) {
priv->def_auto = cfg_pinmask_parse(value, &suc);
}
else if (streq(key, "hold-off")) {
priv->trig_holdoff = cfg_u16_parse(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void DIn_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Port name");
iw_entry(iw, "port", "%c", priv->port_name);
iw_comment(iw, "Pins (comma separated, supports ranges)");
iw_entry_s(iw, "pins", cfg_pinmask_encode(priv->pins, unit_tmp512, 0));
iw_comment(iw, "Pins with pull-up");
iw_entry_s(iw, "pull-up", cfg_pinmask_encode(priv->pullup, unit_tmp512, 0));
iw_comment(iw, "Pins with pull-down");
iw_entry_s(iw, "pull-down", cfg_pinmask_encode(priv->pulldown, unit_tmp512, 0));
iw_cmt_newline(iw);
iw_comment(iw, "Trigger pins activated by rising/falling edge");
iw_entry_s(iw, "trig-rise", cfg_pinmask_encode(priv->trig_rise, unit_tmp512, 0));
iw_entry_s(iw, "trig-fall", cfg_pinmask_encode(priv->trig_fall, unit_tmp512, 0));
iw_comment(iw, "Trigger pins auto-armed by default");
iw_entry_s(iw, "auto-trigger", cfg_pinmask_encode(priv->def_auto, unit_tmp512, 0));
iw_comment(iw, "Triggers hold-off time (ms)");
iw_entry_d(iw, "hold-off", priv->trig_holdoff);
#if PLAT_NO_FLOATING_INPUTS
iw_comment(iw, "NOTE: Pins use pull-up by default.\r\n");
#endif
}

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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_din.h"
#define DIN_INTERNAL
#include "_din_internal.h"
// ------------------------------------------------------------------------
enum PinCmd_ {
CMD_READ = 0,
CMD_ARM_SINGLE = 1,
CMD_ARM_AUTO = 2,
CMD_DISARM = 3,
};
/** Handle a request message */
static error_t DIn_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
uint16_t pins = 0;
switch (command) {
case CMD_READ:;
TRY(UU_DIn_Read(unit, &pins));
PayloadBuilder pb = pb_start((uint8_t*)unit_tmp512, UNIT_TMP_LEN, NULL);
pb_u16(&pb, pins); // packed input pins
com_respond_buf(frame_id, MSG_SUCCESS, (uint8_t *) unit_tmp512, pb_length(&pb));
return E_SUCCESS;
case CMD_ARM_SINGLE:;
pins = pp_u16(pp);
if (!pp->ok) return E_MALFORMED_COMMAND;
TRY(UU_DIn_Arm(unit, pins, 0));
return E_SUCCESS;
case CMD_ARM_AUTO:;
pins = pp_u16(pp);
if (!pp->ok) return E_MALFORMED_COMMAND;
TRY(UU_DIn_Arm(unit, 0, pins));
return E_SUCCESS;
case CMD_DISARM:;
pins = pp_u16(pp);
if (!pp->ok) return E_MALFORMED_COMMAND;
TRY(UU_DIn_DisArm(unit, pins));
return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
/**
* Decrement all the hold-off timers on tick
*
* @param unit
*/
static void DIn_updateTick(Unit *unit)
{
struct priv *priv = unit->data;
for (int i = 0; i < 16; i++) {
if (priv->holdoff_countdowns[i] > 0) {
priv->holdoff_countdowns[i]--;
}
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_DIN = {
.name = "DI",
.description = "Digital input with triggers",
// Settings
.preInit = DIn_preInit,
.cfgLoadBinary = DIn_loadBinary,
.cfgWriteBinary = DIn_writeBinary,
.cfgLoadIni = DIn_loadIni,
.cfgWriteIni = DIn_writeIni,
// Init
.init = DIn_init,
.deInit = DIn_deInit,
// Function
.handleRequest = DIn_handleRequest,
.updateTick = DIn_updateTick,
};

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//
// Created by MightyPork on 2017/11/25.
//
// Digital input unit; single or multiple pin read access on one port (A-F)
//
#ifndef U_DIN_H
#define U_DIN_H
#include "unit.h"
extern const UnitDriver UNIT_DIN;
/**
* Read pins
*
* @param unit - unit instance
* @param packed - output; the packed (right aligned) bits representing the pins, highest to lowest, are written here.
* @return success
*/
error_t UU_DIn_Read(Unit *unit, uint16_t *packed);
/**
* Arm pins for trigger generation
*
* @param unit - unit instance
* @param arm_single_packed - packed bit map of pins to arm for single trigger
* @param arm_auto_packed - packed bit map of pins to arm for auto trigger (repeated)
* @return success
*/
error_t UU_DIn_Arm(Unit *unit, uint16_t arm_single_packed, uint16_t arm_auto_packed);
/**
* Dis-arm pins to not generate events
*
* @param unit - unit instance
* @param disarm_packed - packed bit map of pins to dis-arm
* @return success
*/
error_t UU_DIn_DisArm(Unit *unit, uint16_t disarm_packed);
#endif //U_DIN_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_dout.h"
#define DOUT_INTERNAL
#include "_dout_internal.h"
static void clear_pulse_by_mask(struct priv *priv, uint16_t spread)
{
assert_param(priv);
for (int i = 0; i < 16; i++) {
if (spread & (1 << i)) {
priv->msec_pulse_cnt[i] = 0;
}
}
}
error_t UU_DOut_Write(Unit *unit, uint16_t packed)
{
CHECK_TYPE(unit, &UNIT_DOUT);
struct priv *priv = unit->data;
uint16_t mask = priv->pins;
uint16_t spread = pinmask_spread(packed, mask);
clear_pulse_by_mask(priv, spread);
uint16_t set = spread;
uint16_t reset = ((~spread) & mask);
priv->port->BSRR = set | (reset << 16);
return E_SUCCESS;
}
error_t UU_DOut_Set(Unit *unit, uint16_t packed)
{
CHECK_TYPE(unit, &UNIT_DOUT);
struct priv *priv = unit->data;
uint16_t mask = priv->pins;
uint16_t spread = pinmask_spread(packed, mask);
clear_pulse_by_mask(priv, spread);
priv->port->BSRR = spread;
return E_SUCCESS;
}
error_t UU_DOut_Clear(Unit *unit, uint16_t packed)
{
CHECK_TYPE(unit, &UNIT_DOUT);
struct priv *priv = unit->data;
uint16_t mask = priv->pins;
uint16_t spread = pinmask_spread(packed, mask);
clear_pulse_by_mask(priv, spread);
priv->port->BSRR = (spread << 16);
return E_SUCCESS;
}
error_t UU_DOut_Toggle(Unit *unit, uint16_t packed)
{
CHECK_TYPE(unit, &UNIT_DOUT);
struct priv *priv = unit->data;
uint16_t mask = priv->pins;
uint16_t spread = pinmask_spread(packed, mask);
clear_pulse_by_mask(priv, spread);
uint16_t flipped = (uint16_t) (~priv->port->ODR) & mask;
uint16_t set = flipped & spread;
uint16_t reset = ((~flipped) & mask) & spread;
priv->port->BSRR = set | (reset << 16);
return E_SUCCESS;
}
error_t UU_DOut_GetPinCount(Unit *unit, uint8_t *count)
{
CHECK_TYPE(unit, &UNIT_DOUT);
struct priv *priv = unit->data;
uint32_t packed = pinmask_pack(0xFFFF, priv->pins);
*count = (uint8_t) (32 - __CLZ(packed));
return E_SUCCESS;
}
error_t UU_DOut_Pulse(Unit *unit, uint16_t packed, bool polarity, bool is_usec, uint16_t count)
{
CHECK_TYPE(unit, &UNIT_DOUT);
struct priv *priv = unit->data;
assert_param(priv);
uint16_t mask = priv->pins;
uint16_t spread = pinmask_spread(packed, mask);
clear_pulse_by_mask(priv, spread);
vPortEnterCritical();
if (is_usec) {
// we're gonna do this right here as a delay loop.
if (count >= 1000) {
// too long, fall back to msec
count /= 1000;
is_usec = false;
}
else {
const uint32_t bsrr1 = spread << (polarity ? 0 : 16);
const uint32_t bsrr0 = spread << (polarity ? 16 : 0);
const uint32_t start = PTIM_MicroDelayAlign();
priv->port->BSRR = bsrr1;
PTIM_MicroDelayAligned(count, start);
priv->port->BSRR = bsrr0;
}
}
if (!is_usec) {
// Load the counters
for (int i = 0; i < 16; i++) {
if (spread & (1 << i)) {
priv->msec_pulse_cnt[i] = (uint16_t) (count + 1);
}
}
if (polarity) {
priv->msec_pulse_scheduled_1 |= spread;
} else {
priv->msec_pulse_scheduled_0 |= spread;
}
unit->_tick_cnt = 0;
unit->tick_interval = 1;
}
vPortExitCritical();
return E_SUCCESS;
}
void DOut_Tick(Unit *unit)
{
struct priv *priv = unit->data;
uint16_t odr = (uint16_t) priv->port->ODR;
int live_cnt = 0;
for (int i = 0; i < 16; i++) {
if (priv->msec_pulse_scheduled_1 & (1<<i)) {
odr |= (1<<i);
} else if (priv->msec_pulse_scheduled_0 & (1<<i)) {
odr &= ~(1<<i);
}
if (priv->msec_pulse_cnt[i] > 0) {
live_cnt++;
priv->msec_pulse_cnt[i]--;
if (priv->msec_pulse_cnt[i] == 0) {
odr ^= 1 << i;
}
}
}
priv->port->ODR = odr;
priv->msec_pulse_scheduled_1 = 0;
priv->msec_pulse_scheduled_0 = 0;
if (live_cnt == 0) {
unit->_tick_cnt = 0;
unit->tick_interval = 0;
}
}

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define DOUT_INTERNAL
#include "_dout_internal.h"
/** Allocate data structure and set defaults */
error_t DOut_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
// some defaults
priv->port_name = 'A';
priv->pins = 0x0001;
priv->open_drain = 0x0000;
priv->initial = 0x0000;
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t DOut_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
priv->initial &= priv->pins;
priv->open_drain &= priv->pins;
// --- Parse config ---
priv->port = hw_port2periph(priv->port_name, &suc);
if (!suc) return E_BAD_CONFIG;
// Claim all needed pins
TRY(rsc_claim_gpios(unit, priv->port_name, priv->pins));
for (int i = 0; i < 16; i++) {
if (priv->pins & (1 << i)) {
uint32_t ll_pin = hw_pin2ll((uint8_t) i, &suc);
// --- Init hardware ---
LL_GPIO_SetPinMode(priv->port, ll_pin, LL_GPIO_MODE_OUTPUT);
LL_GPIO_SetPinOutputType(priv->port, ll_pin,
(priv->open_drain & (1 << i)) ? LL_GPIO_OUTPUT_OPENDRAIN : LL_GPIO_OUTPUT_PUSHPULL);
LL_GPIO_SetPinSpeed(priv->port, ll_pin, LL_GPIO_SPEED_FREQ_HIGH);
}
}
// Set the initial state
priv->port->ODR &= ~priv->pins;
priv->port->ODR |= priv->initial;
return E_SUCCESS;
}
/** Tear down the unit */
void DOut_deInit(Unit *unit)
{
// pins are de-inited during teardown
// Release all resources
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_DOUT_INTERNAL_H
#define GEX_F072_DOUT_INTERNAL_H
#ifndef DOUT_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
/** Private data structure */
struct priv {
char port_name;
uint16_t pins; // pin mask
uint16_t initial; // initial pin states
uint16_t open_drain; // open drain pins
GPIO_TypeDef *port;
uint16_t msec_pulse_cnt[16];
uint16_t msec_pulse_scheduled_1;
uint16_t msec_pulse_scheduled_0;
};
/** Allocate data structure and set defaults */
error_t DOut_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void DOut_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void DOut_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t DOut_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void DOut_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t DOut_init(Unit *unit);
/** Tear down the unit */
void DOut_deInit(Unit *unit);
void DOut_Tick(Unit *unit);
#endif //GEX_F072_DOUT_INTERNAL_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define DOUT_INTERNAL
#include "_dout_internal.h"
/** Load from a binary buffer stored in Flash */
void DOut_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->port_name = pp_char(pp);
priv->pins = pp_u16(pp);
priv->initial = pp_u16(pp);
priv->open_drain = pp_u16(pp);
}
/** Write to a binary buffer for storing in Flash */
void DOut_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
pb_char(pb, priv->port_name);
pb_u16(pb, priv->pins);
pb_u16(pb, priv->initial);
pb_u16(pb, priv->open_drain);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t DOut_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "port")) {
suc = cfg_port_parse(value, &priv->port_name);
}
else if (streq(key, "pins")) {
priv->pins = cfg_pinmask_parse(value, &suc);
}
else if (streq(key, "initial")) {
priv->initial = cfg_pinmask_parse(value, &suc);
}
else if (streq(key, "open-drain")) {
priv->open_drain = cfg_pinmask_parse(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void DOut_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Port name");
iw_entry(iw, "port", "%c", priv->port_name);
iw_comment(iw, "Pins (comma separated, supports ranges)");
iw_entry_s(iw, "pins", cfg_pinmask_encode(priv->pins, unit_tmp512, 0));
iw_comment(iw, "Initially high pins");
iw_entry_s(iw, "initial", cfg_pinmask_encode(priv->initial, unit_tmp512, 0));
iw_comment(iw, "Open-drain pins");
iw_entry_s(iw, "open-drain", cfg_pinmask_encode(priv->open_drain, unit_tmp512, 0));
}

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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_dout.h"
#define DOUT_INTERNAL
#include "_dout_internal.h"
enum PinCmd_ {
CMD_WRITE = 0,
CMD_SET = 1,
CMD_CLEAR = 2,
CMD_TOGGLE = 3,
CMD_PULSE = 4,
};
/** Handle a request message */
static error_t DOut_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
uint16_t packed = pp_u16(pp);
switch (command) {
case CMD_WRITE:
return UU_DOut_Write(unit, packed);
case CMD_SET:
return UU_DOut_Set(unit, packed);
case CMD_CLEAR:
return UU_DOut_Clear(unit, packed);
case CMD_TOGGLE:
return UU_DOut_Toggle(unit, packed);
case CMD_PULSE:;
bool polarity = pp_bool(pp);
bool is_usec = pp_bool(pp);
uint16_t count = pp_u16(pp);
return UU_DOut_Pulse(unit, packed, polarity, is_usec, count);
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_DOUT = {
.name = "DO",
.description = "Digital output",
// Settings
.preInit = DOut_preInit,
.cfgLoadBinary = DOut_loadBinary,
.cfgWriteBinary = DOut_writeBinary,
.cfgLoadIni = DOut_loadIni,
.cfgWriteIni = DOut_writeIni,
// Init
.init = DOut_init,
.deInit = DOut_deInit,
// Function
.handleRequest = DOut_handleRequest,
.updateTick = DOut_Tick,
};

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//
// Created by MightyPork on 2017/11/25.
//
// Digital output unit; single or multiple pin write access on one port (A-F)
//
#ifndef U_DOUT_H
#define U_DOUT_H
#include "unit.h"
extern const UnitDriver UNIT_DOUT;
/**
* Write pins (e.g. writing 0b10 if configured pins are PA5 and PA0 sets PA5=1,PA0=0)
*
* @param unit
* @param packed - packed pin states (aligned to right)
* @return success
*/
error_t UU_DOut_Write(Unit *unit, uint16_t packed);
/**
* Set pins (clear none)
*
* @param unit
* @param packed - packed pins, 1 if pin should be set
* @return success
*/
error_t UU_DOut_Set(Unit *unit, uint16_t packed);
/**
* Clear multiple pins
*
* @param unit
* @param packed - packed pins, 1 if pin should be cleared
* @return
*/
error_t UU_DOut_Clear(Unit *unit, uint16_t packed);
/**
* Toggle pins
*
* @param unit
* @param packed - packed pins, 1 if pin should be toggled
* @return
*/
error_t UU_DOut_Toggle(Unit *unit, uint16_t packed);
/**
* Get number of configured pins
*
* @param unit
* @param count output, written with 0-16
* @return success
*/
error_t UU_DOut_GetPinCount(Unit *unit, uint8_t *count);
/**
* Send a pulse
*
* @param unit
* @param packed - pins to pulse
* @param polarity - pulse active level
* @param is_usec - use usec precision (for < 1 ms)
* @param count - number of units (msec or usec)
* @return success
*/
error_t UU_DOut_Pulse(Unit *unit, uint16_t packed, bool polarity, bool is_usec, uint16_t count);
#endif //U_DOUT_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_fcap.h"
#define FCAP_INTERNAL
#include "_fcap_internal.h"

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//
// Created by MightyPork on 2018/02/20.
//
#include "platform.h"
#define FCAP_INTERNAL
#include "_fcap_internal.h"
static void UFCAP_StopMeasurement(Unit *unit);
static void UFCAP_ConfigureForIndirectCapture(Unit *unit);
static void UFCAP_ConfigureForDirectCapture(Unit *unit, uint16_t msec);
static void UFCAP_ConfigureForFreeCapture(Unit *unit);
uint32_t UFCAP_GetFreeCounterValue(Unit *unit)
{
struct priv * const priv = unit->data;
TIM_TypeDef * const TIMx = priv->TIMx;
return TIMx->CNT;
}
uint32_t UFCAP_FreeCounterClear(Unit *unit)
{
struct priv * const priv = unit->data;
TIM_TypeDef * const TIMx = priv->TIMx;
// this isn't perfect, we can miss one clock
// but it's probably the best we can do here ...
vPortEnterCritical();
uint32_t val = TIMx->CNT;
TIMx->CNT = 0;
vPortExitCritical();
return val;
}
static void UFCAP_IndirectBurstReportJob(Job *job)
{
Unit *unit = job->unit;
struct priv * const priv = unit->data;
uint8_t buf[20];
PayloadBuilder pb = pb_start(buf, 20, NULL);
pb_u16(&pb, PLAT_AHB_MHZ);
pb_u16(&pb, priv->ind_burst.n_count);
pb_u64(&pb, priv->ind_burst.period_acu);
pb_u64(&pb, priv->ind_burst.ontime_acu);
assert_param(pb.ok);
com_respond_pb(priv->request_id, MSG_SUCCESS, &pb);
// timer is already stopped, now in OPMODE_BUSY
priv->opmode = OPMODE_IDLE;
}
static void UFCAP_SinglePulseReportJob(Job *job)
{
Unit *unit = job->unit;
struct priv * const priv = unit->data;
uint8_t buf[6];
PayloadBuilder pb = pb_start(buf, 6, NULL);
pb_u16(&pb, PLAT_AHB_MHZ);
pb_u32(&pb, job->data1);
assert_param(pb.ok);
com_respond_pb(priv->request_id, MSG_SUCCESS, &pb);
// timer is already stopped, now in OPMODE_BUSY
priv->opmode = OPMODE_IDLE;
}
/**
* Count is passed in data1
* @param job
*/
static void UFCAP_DirectBurstReportJob(Job *job)
{
Unit *unit = job->unit;
struct priv * const priv = unit->data;
uint8_t buf[8];
PayloadBuilder pb = pb_start(buf, 8, NULL);
pb_u8(&pb, priv->direct_presc);
pb_u16(&pb, priv->dir_burst.msec);
pb_u32(&pb, job->data1);
assert_param(pb.ok);
com_respond_pb(priv->request_id, MSG_SUCCESS, &pb);
// timer is already stopped, now in OPMODE_BUSY
priv->opmode = OPMODE_IDLE;
}
void UFCAP_TIMxHandler(void *arg)
{
Unit *unit = arg;
assert_param(unit);
struct priv * const priv = unit->data;
assert_param(priv);
TIM_TypeDef * const TIMx = priv->TIMx;
if (priv->opmode == OPMODE_INDIRECT_CONT) {
if (LL_TIM_IsActiveFlag_CC1(TIMx)) {
if (priv->n_skip > 0) {
priv->n_skip--;
} else {
priv->ind_cont.last_period = LL_TIM_IC_GetCaptureCH1(TIMx);
priv->ind_cont.last_ontime = priv->ind_cont.ontime;
}
LL_TIM_ClearFlag_CC1(TIMx);
LL_TIM_ClearFlag_CC1OVR(TIMx);
}
if (LL_TIM_IsActiveFlag_CC2(TIMx)) {
priv->ind_cont.ontime = LL_TIM_IC_GetCaptureCH2(TIMx);
LL_TIM_ClearFlag_CC2(TIMx);
LL_TIM_ClearFlag_CC2OVR(TIMx);
}
}
else if (priv->opmode == OPMODE_SINGLE_PULSE) {
if (LL_TIM_IsActiveFlag_CC2(TIMx)) {
// single pulse - does not wait for the second edge
uint32_t len = LL_TIM_IC_GetCaptureCH2(TIMx);
priv->opmode = OPMODE_BUSY;
UFCAP_StopMeasurement(unit);
Job j = {
.cb = UFCAP_SinglePulseReportJob,
.unit = unit,
.data1 = len,
};
scheduleJob(&j);
}
}
else if (priv->opmode == OPMODE_INDIRECT_BURST) {
if (LL_TIM_IsActiveFlag_CC1(TIMx)) {
const uint32_t period = LL_TIM_IC_GetCaptureCH1(TIMx);
const uint32_t ontime = priv->ind_burst.ontime;
if (priv->n_skip > 0) {
priv->n_skip--;
} else {
priv->ind_burst.ontime_acu += ontime;
priv->ind_burst.period_acu += period;
if (++priv->ind_burst.n_count == priv->ind_burst.n_target) {
priv->opmode = OPMODE_BUSY;
UFCAP_StopMeasurement(unit);
Job j = {
.cb = UFCAP_IndirectBurstReportJob,
.unit = unit,
};
scheduleJob(&j);
}
}
LL_TIM_ClearFlag_CC1(TIMx);
LL_TIM_ClearFlag_CC1OVR(TIMx);
}
if (LL_TIM_IsActiveFlag_CC2(TIMx)) {
priv->ind_burst.ontime = LL_TIM_IC_GetCaptureCH2(TIMx);
LL_TIM_ClearFlag_CC2(TIMx);
LL_TIM_ClearFlag_CC2OVR(TIMx);
}
}
else if (priv->opmode == OPMODE_IDLE) {
// clear everything - in idle it would cycle in the handler forever
TIMx->SR = 0;
}
else {
trap("Unhandled fcap TIMx irq");
}
}
void UFCAP_TIMyHandler(void *arg)
{
Unit *unit = arg;
assert_param(unit);
struct priv *const priv = unit->data;
assert_param(priv);
TIM_TypeDef * const TIMx = priv->TIMx;
TIM_TypeDef * const TIMy = priv->TIMy;
uint32_t cnt = TIMx->CNT; // TIMx should be stopped now
// dbg("> TIMy Handler, TIMx cntr is %d", cnt);
priv->dir_cont.last_count = cnt;
if (priv->opmode == OPMODE_DIRECT_CONT) {
LL_TIM_DisableCounter(TIMx);
LL_TIM_DisableCounter(TIMy);
LL_TIM_SetCounter(TIMx, 0);
LL_TIM_SetCounter(TIMy, 0);
LL_TIM_EnableCounter(TIMy); // next loop
LL_TIM_EnableCounter(TIMx);
}
else if (priv->opmode == OPMODE_DIRECT_BURST) {
priv->opmode = OPMODE_BUSY;
UFCAP_StopMeasurement(unit);
Job j = {
.cb = UFCAP_DirectBurstReportJob,
.unit = unit,
.data1 = cnt,
};
scheduleJob(&j);
}
else if (priv->opmode == OPMODE_IDLE) {
// clear everything - in idle it would cycle in the handler forever
TIMy->SR = 0;
}
else {
trap("Unhandled fcap TIMy irq");
}
LL_TIM_ClearFlag_UPDATE(TIMy);
}
static void UFCAP_ClearTimerConfig(Unit *unit)
{
struct priv * const priv = unit->data;
TIM_TypeDef * const TIMx = priv->TIMx;
// CLEAR CURRENT STATE, STOP
UFCAP_StopMeasurement(unit);
// CONFIGURE TIMER BASIC PARAMS
LL_TIM_SetPrescaler(TIMx, 0);
LL_TIM_SetAutoReload(TIMx, 0xFFFFFFFF);
LL_TIM_EnableARRPreload(TIMx);
LL_TIM_GenerateEvent_UPDATE(TIMx);
}
/**
* Reset all timer registers
*
* @param unit
*/
static void UFCAP_StopMeasurement(Unit *unit)
{
struct priv * const priv = unit->data;
LL_TIM_DeInit(priv->TIMx); // clear all flags and settings
LL_TIM_DeInit(priv->TIMy); // clear all flags and settings
}
/**
* Switch the FCAP module opmode
*
* @param unit
* @param opmode
*/
void UFCAP_SwitchMode(Unit *unit, enum fcap_opmode opmode)
{
struct priv * const priv = unit->data;
if (opmode == priv->opmode) return;
priv->opmode = opmode;
switch (opmode) {
case OPMODE_IDLE:
// XXX maybe we should report the abort to the PC-side listener
UFCAP_StopMeasurement(unit);
break;
case OPMODE_INDIRECT_CONT:
priv->ind_cont.last_ontime = 0;
priv->ind_cont.last_period = 0;
priv->ind_cont.ontime = 0;
priv->n_skip = 1; // discard the first cycle (will be incomplete)
UFCAP_ConfigureForIndirectCapture(unit); // is also stopped and restarted
break;
case OPMODE_INDIRECT_BURST:
priv->ind_burst.ontime = 0;
priv->ind_burst.n_count = 0;
priv->ind_burst.period_acu = 0;
priv->ind_burst.ontime_acu = 0;
priv->n_skip = 1; // discard the first cycle (will be incomplete)
UFCAP_ConfigureForIndirectCapture(unit); // is also stopped and restarted
break;
case OPMODE_SINGLE_PULSE:
priv->n_skip = 0;
UFCAP_ConfigureForIndirectCapture(unit); // is also stopped and restarted
break;
case OPMODE_DIRECT_CONT:
// msec is set by caller
priv->dir_cont.last_count = 0;
priv->n_skip = 1; // discard the first cycle (will be incomplete)
UFCAP_ConfigureForDirectCapture(unit, priv->direct_msec);
break;
case OPMODE_DIRECT_BURST:
// msec is set by caller
priv->n_skip = 0; // no skip here (if there was any)
UFCAP_ConfigureForDirectCapture(unit, (uint16_t) priv->dir_burst.msec);
break;
case OPMODE_FREE_COUNTER:
UFCAP_ConfigureForFreeCapture(unit);
break;
default:
trap("Unhandled opmode %d", (int)opmode);
}
}
/**
* Configure peripherals for an indirect capture (PWM measurement) - continuous or burst
* @param unit
*/
static void UFCAP_ConfigureForIndirectCapture(Unit *unit)
{
struct priv * const priv = unit->data;
TIM_TypeDef * const TIMx = priv->TIMx;
const uint32_t ll_ch_a = priv->ll_ch_a;
const uint32_t ll_ch_b = priv->ll_ch_b;
UFCAP_ClearTimerConfig(unit);
// Enable channels and select mapping to TIx signals
// A - will be used to measure period
// B - will be used to measure the duty cycle
// _________ ______
// _______| |________________|
// A B A
// irq irq,cap irq
// reset
// B irq may be used if we want to measure a pulse width
// Normally TI1 = CH1, TI2 = CH2.
// It's possible to select the other channel, which we use to connect both TIx to the shame CHx.
LL_TIM_IC_SetActiveInput(TIMx, ll_ch_a, priv->a_direct ? LL_TIM_ACTIVEINPUT_DIRECTTI : LL_TIM_ACTIVEINPUT_INDIRECTTI);
LL_TIM_IC_SetActiveInput(TIMx, ll_ch_b, priv->a_direct ? LL_TIM_ACTIVEINPUT_INDIRECTTI : LL_TIM_ACTIVEINPUT_DIRECTTI);
LL_TIM_IC_SetPolarity(TIMx, ll_ch_a, priv->active_level ? LL_TIM_IC_POLARITY_RISING : LL_TIM_IC_POLARITY_FALLING);
LL_TIM_IC_SetPolarity(TIMx, ll_ch_b, priv->active_level ? LL_TIM_IC_POLARITY_FALLING : LL_TIM_IC_POLARITY_RISING);
if (priv->dfilter > 15) priv->dfilter = 15;
uint32_t filter = LL_TIM_IC_FILTERS[priv->dfilter];
LL_TIM_IC_SetFilter(TIMx, ll_ch_a, filter);
LL_TIM_IC_SetFilter(TIMx, ll_ch_b, filter);
LL_TIM_CC_EnableChannel(TIMx, ll_ch_a | ll_ch_b);
LL_TIM_SetSlaveMode(TIMx, LL_TIM_SLAVEMODE_RESET);
LL_TIM_SetTriggerInput(TIMx, LL_TIM_TS_TI1FP1); // Use Filtered Input 1 (TI1)
LL_TIM_EnableMasterSlaveMode(TIMx);
LL_TIM_ClearFlag_CC1(TIMx);
LL_TIM_ClearFlag_CC1OVR(TIMx);
LL_TIM_ClearFlag_CC2(TIMx);
LL_TIM_ClearFlag_CC2OVR(TIMx);
LL_TIM_EnableIT_CC1(TIMx);
LL_TIM_EnableIT_CC2(TIMx);
LL_TIM_EnableCounter(TIMx);
}
/**
* Configure peripherals for an indirect capture (PWM measurement) - continuous or burst
* @param unit
*/
static void UFCAP_ConfigureForDirectCapture(Unit *unit, uint16_t msec)
{
struct priv * const priv = unit->data;
// dbg("Configuring Direct capture...");
UFCAP_ClearTimerConfig(unit);
{
TIM_TypeDef *const TIMy = priv->TIMy;
assert_param(PLAT_AHB_MHZ<=65);
uint16_t presc = PLAT_AHB_MHZ*1000;
uint32_t count = msec+1; // it's one tick longer because we generate OCREF on the exact msec count - it must be at least 1 tick long
LL_TIM_SetPrescaler(TIMy, (uint32_t) (presc - 1));
LL_TIM_SetAutoReload(TIMy, count - 1);
LL_TIM_EnableARRPreload(TIMy);
LL_TIM_GenerateEvent_UPDATE(TIMy);
LL_TIM_SetOnePulseMode(TIMy, LL_TIM_ONEPULSEMODE_SINGLE);
LL_TIM_OC_EnableFast(TIMy, LL_TIM_CHANNEL_CH1);
// dbg("TIMy presc %d, count %d", (int) presc, (int) count);
LL_TIM_SetTriggerOutput(TIMy, LL_TIM_TRGO_OC1REF);
LL_TIM_OC_SetMode(TIMy, LL_TIM_CHANNEL_CH1, LL_TIM_OCMODE_PWM1); // 1 until CC, then 0
LL_TIM_OC_SetCompareCH1(TIMy, count-1);
LL_TIM_CC_EnableChannel(TIMy, LL_TIM_CHANNEL_CH1); // enable the output channel that produces a trigger
LL_TIM_ClearFlag_UPDATE(TIMy);
LL_TIM_EnableIT_UPDATE(TIMy);
}
{
// TIMx - the slave
TIM_TypeDef *const TIMx = priv->TIMx;
LL_TIM_SetSlaveMode(TIMx, LL_TIM_SLAVEMODE_GATED);
LL_TIM_SetTriggerInput(TIMx, LL_TIM_TS_ITR3); // ITR3 is TIM14 which we use as TIMy
LL_TIM_EnableMasterSlaveMode(TIMx);
uint32_t presc = LL_TIM_ETR_PRESCALER_DIV1;
switch (priv->direct_presc) {
case 1: presc = LL_TIM_ETR_PRESCALER_DIV1; break;
case 2: presc = LL_TIM_ETR_PRESCALER_DIV2; break;
case 4: presc = LL_TIM_ETR_PRESCALER_DIV4; break;
case 8: presc = LL_TIM_ETR_PRESCALER_DIV8; break;
default:
priv->direct_presc = 1; // will be sent with the response
}
if (priv->dfilter > 15) priv->dfilter = 15;
uint32_t filter = LL_TIM_ETR_FILTERS[priv->dfilter];
LL_TIM_ConfigETR(TIMx,
priv->active_level ? LL_TIM_ETR_POLARITY_NONINVERTED : LL_TIM_ETR_POLARITY_INVERTED,
presc,
filter);
LL_TIM_EnableExternalClock(TIMx); // TODO must check and deny this mode if the pin is not on CH1 = external trigger input
LL_TIM_SetCounter(TIMx, 0);
LL_TIM_EnableCounter(TIMx);
}
LL_TIM_EnableCounter(priv->TIMy); // XXX this will start the first pulse (maybe)
}
/**
* Freerunning capture (counting pulses - geiger)
* @param unit
*/
static void UFCAP_ConfigureForFreeCapture(Unit *unit)
{
struct priv * const priv = unit->data;
UFCAP_ClearTimerConfig(unit);
TIM_TypeDef *const TIMx = priv->TIMx;
LL_TIM_EnableExternalClock(TIMx);
LL_TIM_SetCounter(TIMx, 0);
LL_TIM_EnableCounter(TIMx);
}

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define FCAP_INTERNAL
#include "_fcap_internal.h"
/** Allocate data structure and set defaults */
error_t UFCAP_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
priv->conf.signal_pname = 'A';
priv->conf.signal_pnum = 0;
priv->conf.active_level = 1;
priv->conf.direct_presc = 1;
priv->conf.dfilter = 0;
priv->conf.direct_msec = 1000;
priv->conf.startmode = OPMODE_IDLE;
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t UFCAP_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
// ---- Resolve what to configure ----
TIM_TypeDef * const TIMx = TIM2;
Resource timRsc = R_TIM2;
TIM_TypeDef * const TIMy = TIM14;
Resource tim2Rsc = R_TIM14;
uint32_t ll_ch_a = 0;
uint32_t ll_ch_b = 0;
switch (priv->conf.signal_pname) {
case 'A':
switch (priv->conf.signal_pnum) {
case 5:
case 15:
case 0: ll_ch_a = LL_TIM_CHANNEL_CH1; break;
case 1: ll_ch_a = LL_TIM_CHANNEL_CH2; break;
default:
dbg("Bad signal pin!");
return E_BAD_CONFIG;
}
break;
case 'B':
switch (priv->conf.signal_pnum) {
case 3: ll_ch_a = LL_TIM_CHANNEL_CH2; break;
default:
dbg("Bad signal pin!");
return E_BAD_CONFIG;
}
break;
default:
dbg("Bad signal pin port!");
return E_BAD_CONFIG;
}
const uint32_t ll_timpin_af = LL_GPIO_AF_2;
bool a_direct = true;
switch (ll_ch_a) {
case LL_TIM_CHANNEL_CH1:
ll_ch_b = LL_TIM_CHANNEL_CH2;
break;
case LL_TIM_CHANNEL_CH2:
ll_ch_b = LL_TIM_CHANNEL_CH1;
a_direct = false;
break;
}
// ---- CLAIM ----
TRY(rsc_claim_pin(unit, priv->conf.signal_pname, priv->conf.signal_pnum));
TRY(rsc_claim(unit, timRsc));
TRY(rsc_claim(unit, tim2Rsc));
// ---- INIT ----
assert_param(ll_ch_a != ll_ch_b);
priv->TIMx = TIMx;
priv->TIMy = TIMy;
priv->ll_ch_a = ll_ch_a;
priv->ll_ch_b = ll_ch_b;
priv->a_direct = a_direct;
// Load defaults
priv->active_level = priv->conf.active_level;
priv->direct_presc = priv->conf.direct_presc;
priv->dfilter = priv->conf.dfilter;
priv->direct_msec = priv->conf.direct_msec;
priv->opmode = priv->conf.startmode;
TRY(hw_configure_gpio_af(priv->conf.signal_pname, priv->conf.signal_pnum, ll_timpin_af));
GPIO_TypeDef *gpio = hw_port2periph(priv->conf.signal_pname, &suc);
uint32_t ll_pin = hw_pin2ll(priv->conf.signal_pnum, &suc);
LL_GPIO_SetPinPull(gpio, ll_pin, LL_GPIO_PULL_DOWN); // XXX change to pull-up if the polarity is inverted
hw_periph_clock_enable(TIMx);
hw_periph_clock_enable(TIMy);
irqd_attach(TIMx, UFCAP_TIMxHandler, unit);
irqd_attach(TIMy, UFCAP_TIMyHandler, unit);
UFCAP_SwitchMode(unit, priv->opmode); // switch to the default opmode
return E_SUCCESS;
}
/** Tear down the unit */
void UFCAP_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// de-init peripherals
if (unit->status == E_SUCCESS ) {
UFCAP_SwitchMode(unit, OPMODE_IDLE);
TIM_TypeDef *TIMx = priv->TIMx;
TIM_TypeDef *TIMy = priv->TIMy;
LL_TIM_DeInit(TIMx);
LL_TIM_DeInit(TIMy);
irqd_detach(TIMx, UFCAP_TIMxHandler);
irqd_detach(TIMy, UFCAP_TIMyHandler);
hw_periph_clock_disable(TIMx);
hw_periph_clock_disable(TIMy);
}
// Release all resources, deinit pins
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_FCAP_INTERNAL_H
#define GEX_F072_FCAP_INTERNAL_H
#ifndef FCAP_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
enum fcap_opmode {
OPMODE_IDLE = 0,
OPMODE_BUSY = 1, // used after capture is done, before it's reported
OPMODE_INDIRECT_CONT = 2,
OPMODE_INDIRECT_BURST = 3, // averaging
OPMODE_DIRECT_CONT = 4,
OPMODE_DIRECT_BURST = 5,
OPMODE_FREE_COUNTER = 6,
OPMODE_SINGLE_PULSE = 7,
};
/** Private data structure */
struct priv {
// settings
struct {
char signal_pname; // the input pin - one of TIM2 channels
uint8_t signal_pnum;
bool active_level;
uint8_t direct_presc;
uint8_t dfilter;
uint16_t direct_msec;
enum fcap_opmode startmode;
} conf;
// internal state
TIM_TypeDef *TIMx;
TIM_TypeDef *TIMy; // used as a timebase source for TIMx in direct mode
uint32_t ll_ch_b;
uint32_t ll_ch_a;
bool a_direct;
enum fcap_opmode opmode;
TF_ID request_id;
uint8_t n_skip; //!< Periods to skip before starting the real capture
bool active_level; // in PWM mode, the first part that is measured. (if 1, HHHLLL, else LLLHHH). In direct mode, clock polarity
uint8_t direct_presc;
uint16_t direct_msec;
uint8_t dfilter;
union {
struct {
uint32_t ontime; // length of the captured positive pulse in the current interval
uint32_t last_period; //!< length of the captured interval between two rising edges
uint32_t last_ontime; //!< length of the last captured ontime
} ind_cont;
struct {
uint32_t ontime; // length of the captured positive pulse in the current interval
uint64_t period_acu; //!< length of the captured interval between two rising edges, sum
uint64_t ontime_acu; //!< length of the last captured ontime, sum
uint16_t n_count; //!< Periods captured
uint16_t n_target; //!< Periods captured - requested count
} ind_burst;
struct {
uint32_t last_count; //!< Pulse count in the last capture window
} dir_cont;
struct {
uint16_t msec; // capture window length (used in the report callback) - different from the cont time, which is a semi-persistent config
} dir_burst;
};
};
/** Allocate data structure and set defaults */
error_t UFCAP_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void UFCAP_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void UFCAP_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UFCAP_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void UFCAP_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t UFCAP_init(Unit *unit);
/** Tear down the unit */
void UFCAP_deInit(Unit *unit);
// ------------------------------------------------------------------------
void UFCAP_SwitchMode(Unit *unit, enum fcap_opmode opmode);
void UFCAP_TIMxHandler(void *arg);
void UFCAP_TIMyHandler(void *arg);
uint32_t UFCAP_GetFreeCounterValue(Unit *unit);
uint32_t UFCAP_FreeCounterClear(Unit *unit);
#endif //GEX_F072_FCAP_INTERNAL_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define FCAP_INTERNAL
#include "_fcap_internal.h"
/** Load from a binary buffer stored in Flash */
void UFCAP_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->conf.signal_pname = pp_char(pp);
priv->conf.signal_pnum = pp_u8(pp);
priv->conf.active_level = pp_bool(pp);
priv->conf.dfilter = pp_u8(pp);
priv->conf.direct_presc = pp_u8(pp);
priv->conf.direct_msec = pp_u16(pp);
priv->conf.startmode = (enum fcap_opmode) pp_u8(pp);
}
/** Write to a binary buffer for storing in Flash */
void UFCAP_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
pb_char(pb, priv->conf.signal_pname);
pb_u8(pb, priv->conf.signal_pnum);
pb_bool(pb, priv->conf.active_level);
pb_u8(pb, priv->conf.dfilter);
pb_u8(pb, priv->conf.direct_presc);
pb_u16(pb, priv->conf.direct_msec);
pb_u8(pb, priv->conf.startmode);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UFCAP_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "pin")) {
suc = cfg_portpin_parse(value, &priv->conf.signal_pname, &priv->conf.signal_pnum);
}
else if (streq(key, "active-level")) {
priv->conf.active_level = cfg_bool_parse(value, &suc);
}
else if (streq(key, "input-filter")) {
priv->conf.dfilter = cfg_u8_parse(value, &suc);
}
else if (streq(key, "direct-presc")) {
priv->conf.direct_presc = cfg_u8_parse(value, &suc);
}
else if (streq(key, "direct-time")) {
priv->conf.direct_msec = cfg_u16_parse(value, &suc);
}
else if (streq(key, "initial-mode")) {
priv->conf.startmode = (enum fcap_opmode) cfg_enum4_parse(value,
"N", OPMODE_IDLE,
"I", OPMODE_INDIRECT_CONT,
"D", OPMODE_DIRECT_CONT,
"F", OPMODE_FREE_COUNTER,
&suc);
}
else{
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void UFCAP_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Signal input pin - one of:");
iw_comment(iw, " Full support: A0, A5, A15");
iw_comment(iw, " Indirect only: A1, B3");
iw_entry(iw, "pin", "%c%d", priv->conf.signal_pname, priv->conf.signal_pnum);
iw_cmt_newline(iw);
iw_comment(iw, "Active level or edge (0-low,falling; 1-high,rising)");
iw_entry_d(iw, "active-level", priv->conf.active_level);
iw_comment(iw, "Input filtering (0-15)");
iw_entry_d(iw, "input-filter", priv->conf.dfilter);
iw_comment(iw, "Pulse counter pre-divider (1,2,4,8)");
iw_entry_d(iw, "direct-presc", priv->conf.direct_presc);
iw_comment(iw, "Pulse counting interval (ms)");
iw_entry_d(iw, "direct-time", priv->conf.direct_msec);
iw_cmt_newline(iw);
iw_comment(iw, "Mode on startup: N-none, I-indirect, D-direct, F-free count");
iw_entry_s(iw, "initial-mode", cfg_enum4_encode(priv->conf.startmode,
OPMODE_IDLE, "N",
OPMODE_INDIRECT_CONT, "I",
OPMODE_DIRECT_CONT, "D",
OPMODE_FREE_COUNTER, "F"));
}

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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_fcap.h"
#define FCAP_INTERNAL
#include "_fcap_internal.h"
// ------------------------------------------------------------------------
enum FcapCmd_ {
CMD_STOP = 0,
// Measuring a waveform
CMD_INDIRECT_CONT_START = 1, // keep measuring, read on demand
CMD_INDIRECT_BURST_START = 2, // wait and reply
// Counting pulses
CMD_DIRECT_CONT_START = 3, // keep measuring, read on demand
CMD_DIRECT_BURST_START = 4, // wait and reply
CMD_FREECOUNT_START = 5, // keep counting pulses until stopped, read on reply
CMD_MEASURE_SINGLE_PULSE = 6, // measure the first incoming pulse of the right polarity. NOTE: can glitch if the signal starts in the active level
CMD_FREECOUNT_CLEAR = 7, // clear the free counter, return last value
// Results readout for continuous modes
CMD_INDIRECT_CONT_READ = 10,
CMD_DIRECT_CONT_READ = 11,
CMD_FREECOUNT_READ = 12,
// configs
CMD_SET_POLARITY = 20,
CMD_SET_DIR_PRESC = 21,
CMD_SET_INPUT_FILTER = 22,
CMD_SET_DIR_MSEC = 23,
// go back to the configured settings
CMD_RESTORE_DEFAULTS = 30,
};
/** Handle a request message */
static error_t UFCAP_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
uint8_t presc;
uint16_t msec;
struct priv *priv = unit->data;
PayloadBuilder pb = pb_start(unit_tmp512, UNIT_TMP_LEN, NULL);
const char* msg_denied_on_pin = "Not available on the selected pin!";
switch (command) {
/**
* Stop any ongoing measurement and return to base state.
*/
case CMD_STOP:
UFCAP_SwitchMode(unit, OPMODE_IDLE);
return E_SUCCESS;
// ----------------------- CONFIG --------------------------
/**
* Set the active polarity, or triggering edge (for direct)
*
* pld: pol:u8 (0,1)
*/
case CMD_SET_POLARITY:
{
priv->active_level = pp_bool(pp);
}
return E_SUCCESS;
/**
* Set the direct measurement prescaller 1,2,4,8
*
* pld: presc:u8
*/
case CMD_SET_DIR_PRESC:
{
presc = pp_u8(pp);
if (presc != 1 && presc != 2 && presc != 4 && presc != 8) return E_BAD_VALUE;
priv->direct_presc = presc;
}
return E_SUCCESS;
/**
* Set the input filter for all modes
*
* pld: filter:u8 (0-15)
*/
case CMD_SET_INPUT_FILTER:
{
uint8_t input_filter = pp_u8(pp);
if (input_filter >= 16) return E_BAD_VALUE;
priv->dfilter = input_filter;
}
return E_SUCCESS;
/**
* Set the direct sampling time.
*
* pld: msec:u16
*/
case CMD_SET_DIR_MSEC:
{
msec = pp_u16(pp);
priv->direct_msec = msec;
}
return E_SUCCESS;
/**
* Reset all SET* settings to their default values, stop any ongoing measure.
*/
case CMD_RESTORE_DEFAULTS:
UFCAP_SwitchMode(unit, OPMODE_IDLE);
priv->active_level = priv->conf.active_level;
priv->direct_presc = priv->conf.direct_presc;
priv->direct_msec = priv->conf.direct_msec;
priv->dfilter = priv->conf.dfilter;
return E_SUCCESS;
// ------------------ COMMANDS ------------------------
/**
* Start indirect continuous measurement.
*/
case CMD_INDIRECT_CONT_START:
if (priv->opmode == OPMODE_INDIRECT_CONT) return E_SUCCESS; // no-op
if (priv->opmode != OPMODE_IDLE) return E_BUSY;
UFCAP_SwitchMode(unit, OPMODE_INDIRECT_CONT);
return E_SUCCESS;
/**
* Start a continuous direct measurement (counting pulses in fixed time intervals)
*
* - meas_time_ms 0 = no change
* - prescaller 0 = no change
*
* pld: meas_time_ms:u16, prescaller:u8
* - prescaller is 1,2,4,8; 0 = no change
*/
case CMD_DIRECT_CONT_START:
if (!priv->a_direct) {
// This works only if we use the ETR pin. TIM2 shares CH1 with ETR.
// If CH2 is selected as input, ETR is not available.
com_respond_str(MSG_ERROR, frame_id, msg_denied_on_pin);
return E_FAILURE;
}
if (priv->opmode == OPMODE_DIRECT_CONT) return E_SUCCESS; // no-op
if (priv->opmode != OPMODE_IDLE) return E_BUSY;
msec = pp_u16(pp);
presc = pp_u8(pp);
if (msec != 0) priv->direct_msec = msec;
if (presc != 0) priv->direct_presc = presc;
UFCAP_SwitchMode(unit, OPMODE_DIRECT_CONT);
return E_SUCCESS;
/**
* Start a burst of direct measurements with averaging.
* The measurement is performed on N consecutive pulses.
*
* pld: count:u16
*
* resp: core_mhz:u16, count:u16, period_sum:u64, ontime_sum:u64
*/
case CMD_INDIRECT_BURST_START:
if (priv->opmode != OPMODE_IDLE) return E_BAD_MODE;
priv->ind_burst.n_target = pp_u16(pp);
priv->request_id = frame_id;
UFCAP_SwitchMode(unit, OPMODE_INDIRECT_BURST);
return E_SUCCESS;
/**
* Start a single direct measurement of the given length (pulses in time period)
* If 'prescaller' is not 0, it is changed via the param field.
*
* pld: meas_time_ms:u16, prescaller:u8
* - prescaller is 1,2,4,8; 0 = no change
*
* resp: prescaller:u8, meas_time_ms:u16, pulse_count:u32
*/
case CMD_DIRECT_BURST_START:
if (priv->opmode != OPMODE_IDLE) return E_BAD_MODE;
priv->dir_burst.msec = pp_u16(pp);
presc = pp_u8(pp);
if (presc != 0) priv->direct_presc = presc;
priv->request_id = frame_id;
UFCAP_SwitchMode(unit, OPMODE_DIRECT_BURST);
return E_SUCCESS;
/**
* Measure a single pulse length of the given polarity.
* Measures time from a rising to a falling edge (or falling to rising, if polarity is 0)
*
* resp: core_mhz:u16, ontime:u32
*/
case CMD_MEASURE_SINGLE_PULSE:
if (priv->opmode != OPMODE_IDLE) return E_BAD_MODE;
priv->request_id = frame_id;
UFCAP_SwitchMode(unit, OPMODE_SINGLE_PULSE);
return E_SUCCESS;
/**
* Start a free-running pulse counter.
*
* pld: prescaller:u8
* - prescaller is 1,2,4,8; 0 = no change
*/
case CMD_FREECOUNT_START:
if (priv->opmode != OPMODE_IDLE) return E_BAD_MODE;
presc = pp_u8(pp);
if (presc != 0) priv->direct_presc = presc;
UFCAP_SwitchMode(unit, OPMODE_FREE_COUNTER);
return E_SUCCESS;
/**
* Reset the free-running pulse counter.
*
* resp: last_val:u32
*/
case CMD_FREECOUNT_CLEAR:
if (priv->opmode != OPMODE_FREE_COUNTER) {
return E_BAD_MODE;
}
pb_u32(&pb, UFCAP_FreeCounterClear(unit));
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
// ------------------ READING ---------------------
/**
* Read the most recent pulse measurement during continuous indirect measure.
*
* resp: core_mhz:u16, period:u32, ontime:u32
*/
case CMD_INDIRECT_CONT_READ:
if (priv->opmode != OPMODE_INDIRECT_CONT) {
return E_BAD_MODE;
}
if (priv->ind_cont.last_period == 0) {
return E_BUSY;
}
pb_u16(&pb, PLAT_AHB_MHZ);
pb_u32(&pb, priv->ind_cont.last_period);
pb_u32(&pb, priv->ind_cont.last_ontime);
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
/**
* Read the most recent result of a continuous direct measurement.
*
* resp: prescaller:u8, meas_time_ms:u16, pulse_count:u32
*/
case CMD_DIRECT_CONT_READ:
if (!priv->a_direct) { // see above
com_respond_str(MSG_ERROR, frame_id, msg_denied_on_pin);
return E_FAILURE;
}
if (priv->opmode != OPMODE_DIRECT_CONT) return E_BAD_MODE;
if (priv->dir_cont.last_count == 0) return E_BUSY;
pb_u8(&pb, priv->direct_presc);
pb_u16(&pb, priv->direct_msec);
pb_u32(&pb, priv->dir_cont.last_count);
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
/**
* Read the current value of the free-running pulse counter.
*
* The timing may have a significant jitter, this function is practically useful only for
* slow pulse sources (like a geiger counter, item counting etc)
*
* resp: count:u32
*/
case CMD_FREECOUNT_READ:
if (priv->opmode != OPMODE_FREE_COUNTER) {
return E_BAD_MODE;
}
pb_u32(&pb, UFCAP_GetFreeCounterValue(unit));
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Frequency capture */
const UnitDriver UNIT_FCAP = {
.name = "FCAP",
.description = "Frequency and pulse measurement",
// Settings
.preInit = UFCAP_preInit,
.cfgLoadBinary = UFCAP_loadBinary,
.cfgWriteBinary = UFCAP_writeBinary,
.cfgLoadIni = UFCAP_loadIni,
.cfgWriteIni = UFCAP_writeIni,
// Init
.init = UFCAP_init,
.deInit = UFCAP_deInit,
// Function
.handleRequest = UFCAP_handleRequest,
};

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//
// Created by MightyPork on 2017/11/25.
//
// Digital input unit; single or multiple pin read access on one port (A-F)
//
#ifndef U_FCAP_H
#define U_FCAP_H
#include "unit.h"
extern const UnitDriver UNIT_FCAP;
// UU_ prototypes
#endif //U_FCAP_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_i2c.h"
#define I2C_INTERNAL
#include "_i2c_internal.h"
static void i2c_reset(struct priv *priv)
{
LL_I2C_Disable(priv->periph);
HAL_Delay(1);
LL_I2C_Enable(priv->periph);
}
static error_t i2c_wait_until_flag(struct priv *priv, uint32_t flag, bool stop_state)
{
uint32_t t_start = HAL_GetTick();
while (((priv->periph->ISR & flag)!=0) != stop_state) {
if (HAL_GetTick() - t_start > 10) {
i2c_reset(priv);
return E_HW_TIMEOUT;
}
}
return E_SUCCESS;
}
error_t UU_I2C_Write(Unit *unit, uint16_t addr, const uint8_t *bytes, uint32_t bcount)
{
CHECK_TYPE(unit, &UNIT_I2C);
struct priv *priv = unit->data;
uint8_t addrsize = (uint8_t) (((addr & 0x8000) == 0) ? 7 : 10);
addr &= 0x3FF;
uint32_t ll_addrsize = (addrsize == 7) ? LL_I2C_ADDRSLAVE_7BIT : LL_I2C_ADDRSLAVE_10BIT;
if (addrsize == 7) addr <<= 1; // 7-bit address must be shifted to left for LL to use it correctly
TRY(i2c_wait_until_flag(priv, I2C_ISR_BUSY, 0));
bool first = true;
while (bcount > 0) {
uint32_t len = bcount;
uint32_t chunk_remain = (uint8_t) ((len > 255) ? 255 : len); // if more than 255, first chunk is 255
LL_I2C_HandleTransfer(priv->periph, addr, ll_addrsize, chunk_remain,
(len > 255) ? LL_I2C_MODE_RELOAD : LL_I2C_MODE_AUTOEND, // Autoend if this is the last chunk
first ? LL_I2C_GENERATE_START_WRITE : LL_I2C_GENERATE_NOSTARTSTOP); // no start/stop condition if we're continuing
first = false;
bcount -= chunk_remain;
for (; chunk_remain > 0; chunk_remain--) {
TRY(i2c_wait_until_flag(priv, I2C_ISR_TXIS, 1));
uint8_t byte = *bytes++;
LL_I2C_TransmitData8(priv->periph, byte);
}
}
TRY(i2c_wait_until_flag(priv, I2C_ISR_STOPF, 1));
LL_I2C_ClearFlag_STOP(priv->periph);
return E_SUCCESS;
}
error_t UU_I2C_Read(Unit *unit, uint16_t addr, uint8_t *dest, uint32_t bcount)
{
CHECK_TYPE(unit, &UNIT_I2C);
struct priv *priv = unit->data;
uint8_t addrsize = (uint8_t) (((addr & 0x8000) == 0) ? 7 : 10);
addr &= 0x3FF;
uint32_t ll_addrsize = (addrsize == 7) ? LL_I2C_ADDRSLAVE_7BIT : LL_I2C_ADDRSLAVE_10BIT;
if (addrsize == 7) addr <<= 1; // 7-bit address must be shifted to left for LL to use it correctly
TRY(i2c_wait_until_flag(priv, I2C_ISR_BUSY, 0));
bool first = true;
while (bcount > 0) {
if (!first) {
TRY(i2c_wait_until_flag(priv, I2C_ISR_TCR, 1));
}
uint8_t chunk_remain = (uint8_t) ((bcount > 255) ? 255 : bcount); // if more than 255, first chunk is 255
LL_I2C_HandleTransfer(priv->periph, addr, ll_addrsize, chunk_remain,
(bcount > 255) ? LL_I2C_MODE_RELOAD : LL_I2C_MODE_AUTOEND, // Autoend if this is the last chunk
first ? LL_I2C_GENERATE_START_READ : LL_I2C_GENERATE_NOSTARTSTOP); // no start/stop condition if we're continuing
first = false;
bcount -= chunk_remain;
for (; chunk_remain > 0; chunk_remain--) {
TRY(i2c_wait_until_flag(priv, I2C_ISR_RXNE, 1));
uint8_t byte = LL_I2C_ReceiveData8(priv->periph);
*dest++ = byte;
}
}
TRY(i2c_wait_until_flag(priv, I2C_ISR_STOPF, 1));
LL_I2C_ClearFlag_STOP(priv->periph);
return E_SUCCESS;
}
error_t UU_I2C_ReadReg(Unit *unit, uint16_t addr, uint8_t regnum, uint8_t *dest, uint32_t width)
{
TRY(UU_I2C_Write(unit, addr, &regnum, 1));
TRY(UU_I2C_Read(unit, addr, dest, width));
return E_SUCCESS;
}
error_t UU_I2C_WriteReg(Unit *unit, uint16_t addr, uint8_t regnum, const uint8_t *bytes, uint32_t width)
{
CHECK_TYPE(unit, &UNIT_I2C);
// we have to insert the address first - needs a buffer (XXX realistically the buffer needs 1-4 bytes + addr)
PayloadBuilder pb = pb_start((uint8_t*)unit_tmp512, UNIT_TMP_LEN, NULL);
pb_u8(&pb, regnum);
pb_buf(&pb, bytes, width);
TRY(UU_I2C_Write(unit, addr, (uint8_t *) unit_tmp512, pb_length(&pb)));
return E_SUCCESS;
}

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define I2C_INTERNAL
#include "_i2c_internal.h"
/** Allocate data structure and set defaults */
error_t UI2C_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
// some defaults
priv->periph_num = 1;
priv->speed = 1;
priv->anf = true;
priv->dnf = 0;
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t UI2C_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
if (!(priv->periph_num >= 1 && priv->periph_num <= 2)) {
dbg("!! Bad I2C periph"); // TODO report
return E_BAD_CONFIG;
}
if (!(priv->speed >= 1 && priv->speed <= 3)) {
dbg("!! Bad I2C speed");
return E_BAD_CONFIG;
}
if (priv->dnf > 15) {
dbg("!! Bad I2C DNF bw");
return E_BAD_CONFIG;
}
// assign and claim the peripheral
if (priv->periph_num == 1) {
TRY(rsc_claim(unit, R_I2C1));
priv->periph = I2C1;
} else {
TRY(rsc_claim(unit, R_I2C2));
priv->periph = I2C2;
}
// This is written for F072, other platforms will need adjustments
char portname;
uint8_t pin_scl;
uint8_t pin_sda;
uint32_t af_i2c;
uint32_t timing; // magic constant from CubeMX
#if STM32F072xB
// scl - 6 or 8 for I2C1, 10 for I2C2
// sda - 7 or 9 for I2C1, 11 for I2C2
if (priv->periph_num == 1) {
// I2C1
if (priv->remap == 0) {
af_i2c = LL_GPIO_AF_1;
portname = 'B';
pin_scl = 6;
pin_sda = 7;
} else if (priv->remap == 1) {
af_i2c = LL_GPIO_AF_1;
portname = 'B';
pin_scl = 8;
pin_sda = 9;
} else {
return E_BAD_CONFIG;
}
} else {
// I2C2
if (priv->remap == 0) {
af_i2c = LL_GPIO_AF_1;
portname = 'B';
pin_scl = 10;
pin_sda = 11;
} else if (priv->remap == 1) {
af_i2c = LL_GPIO_AF_5;
portname = 'B';
pin_scl = 13;
pin_sda = 14;
} else {
return E_BAD_CONFIG;
}
}
if (priv->speed == 1)
timing = 0x00301D2B; // Standard
else if (priv->speed == 2)
timing = 0x0000020B; // Fast
else
timing = 0x00000001; // Fast+
#elif GEX_PLAT_F103_BLUEPILL
#error "NO IMPL"
#elif GEX_PLAT_F303_DISCOVERY
#error "NO IMPL"
#elif GEX_PLAT_F407_DISCOVERY
#error "NO IMPL"
#else
#error "BAD PLATFORM!"
#endif
// first, we have to claim the pins
TRY(rsc_claim_pin(unit, portname, pin_sda));
TRY(rsc_claim_pin(unit, portname, pin_scl));
TRY(hw_configure_gpio_af(portname, pin_sda, af_i2c));
TRY(hw_configure_gpio_af(portname, pin_scl, af_i2c));
hw_periph_clock_enable(priv->periph);
/* Disable the selected I2Cx Peripheral */
LL_I2C_Disable(priv->periph);
LL_I2C_ConfigFilters(priv->periph,
(priv->anf ? LL_I2C_ANALOGFILTER_ENABLE : LL_I2C_ANALOGFILTER_DISABLE),
priv->dnf);
LL_I2C_SetTiming(priv->periph, timing);
//LL_I2C_DisableClockStretching(priv->periph);
LL_I2C_Enable(priv->periph);
LL_I2C_DisableOwnAddress1(priv->periph); // OA not used
LL_I2C_SetMode(priv->periph, LL_I2C_MODE_I2C); // not using SMBus
return E_SUCCESS;
}
/** Tear down the unit */
void UI2C_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// de-init the pins & peripheral only if inited correctly
if (unit->status == E_SUCCESS) {
assert_param(priv->periph);
LL_I2C_DeInit(priv->periph);
hw_periph_clock_disable(priv->periph);
}
// Release all resources
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_I2C_INTERNAL_H
#define GEX_F072_I2C_INTERNAL_H
#ifndef I2C_INTERNAL
#error bad include!
#endif
/** Private data structure */
struct priv {
uint8_t periph_num; //!< 1 or 2
uint8_t remap; //!< I2C remap option
bool anf; //!< Enable analog noise filter
uint8_t dnf; //!< Enable digital noise filter (1-15 ... max spike width)
uint8_t speed; //!< 0 - Standard, 1 - Fast, 2 - Fast+
I2C_TypeDef *periph;
};
/** Load from a binary buffer stored in Flash */
void UI2C_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void UI2C_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UI2C_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void UI2C_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Allocate data structure and set defaults */
error_t UI2C_preInit(Unit *unit);
/** Finalize unit set-up */
error_t UI2C_init(Unit *unit);
/** Tear down the unit */
void UI2C_deInit(Unit *unit);
// ------------------------------------------------------------------------
#endif //GEX_F072_I2C_INTERNAL_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define I2C_INTERNAL
#include "_i2c_internal.h"
/** Load from a binary buffer stored in Flash */
void UI2C_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->periph_num = pp_u8(pp);
priv->anf = pp_bool(pp);
priv->dnf = pp_u8(pp);
priv->speed = pp_u8(pp);
priv->remap = pp_u8(pp);
}
/** Write to a binary buffer for storing in Flash */
void UI2C_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
pb_u8(pb, priv->periph_num);
pb_bool(pb, priv->anf);
pb_u8(pb, priv->dnf);
pb_u8(pb, priv->speed);
pb_u8(pb, priv->remap);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UI2C_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "device")) {
priv->periph_num = cfg_u8_parse(value, &suc);
}
else if (streq(key, "remap")) {
priv->remap = cfg_u8_parse(value, &suc);
}
else if (streq(key, "analog-filter")) {
priv->anf = cfg_bool_parse(value, &suc);
}
else if (streq(key, "digital-filter")) {
priv->dnf = cfg_u8_parse(value, &suc);
}
else if (streq(key, "speed")) {
priv->speed = cfg_u8_parse(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void UI2C_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Peripheral number (I2Cx)");
iw_entry_d(iw, "device", priv->periph_num);
iw_comment(iw, "Pin mappings (SCL,SDA)");
#if STM32F072xB
iw_comment(iw, " I2C1: (0) B6,B7 (1) B8,B9");
iw_comment(iw, " I2C2: (0) B10,B11 (1) B13,B14");
#elif GEX_PLAT_F103_BLUEPILL
#error "NO IMPL"
#elif GEX_PLAT_F303_DISCOVERY
#error "NO IMPL"
#elif GEX_PLAT_F407_DISCOVERY
#error "NO IMPL"
#else
#error "BAD PLATFORM!"
#endif
iw_entry_d(iw, "remap", priv->remap);
iw_cmt_newline(iw);
iw_comment(iw, "Speed: 1-Standard, 2-Fast, 3-Fast+");
iw_entry_d(iw, "speed", priv->speed);
iw_comment(iw, "Analog noise filter enable (Y,N)");
iw_entry_s(iw, "analog-filter", str_yn(priv->anf));
iw_comment(iw, "Digital noise filter bandwidth (0-15)");
iw_entry_d(iw, "digital-filter", priv->dnf);
}

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//
// Created by MightyPork on 2018/01/02.
//
#include "comm/messages.h"
#include "unit_base.h"
#include "utils/avrlibc.h"
#include "unit_i2c.h"
// I2C master
#define I2C_INTERNAL
#include "_i2c_internal.h"
enum PinCmd_ {
CMD_WRITE = 0,
CMD_READ = 1,
CMD_WRITE_REG = 2,
CMD_READ_REG = 3,
};
/** Handle a request message */
static error_t UI2C_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
uint16_t addr;
uint32_t len;
uint8_t regnum;
uint32_t size;
// NOTE: 10-bit addresses must have the highest bit set to 1 for indication (0x8000 | addr)
switch (command) {
/** Write byte(s) - addr:u16, byte(s) */
case CMD_WRITE:
addr = pp_u16(pp);
const uint8_t *bb = pp_tail(pp, &len);
return UU_I2C_Write(unit, addr, bb, len);
/** Read byte(s) - addr:u16, len:u16 */
case CMD_READ:
addr = pp_u16(pp);
len = pp_u16(pp);
TRY(UU_I2C_Read(unit, addr, (uint8_t *) unit_tmp512, len));
com_respond_buf(frame_id, MSG_SUCCESS, (uint8_t *) unit_tmp512, len);
return E_SUCCESS;
/** Read register(s) - addr:u16, reg:u8, size:u16 */
case CMD_READ_REG:;
addr = pp_u16(pp);
regnum = pp_u8(pp); // register number
size = pp_u16(pp); // total number of bytes to read (allows use of auto-increment)
TRY(UU_I2C_ReadReg(unit, addr, regnum, (uint8_t *) unit_tmp512, size));
com_respond_buf(frame_id, MSG_SUCCESS, (uint8_t *) unit_tmp512, size);
return E_SUCCESS;
/** Write a register - addr:u16, reg:u8, byte(s) */
case CMD_WRITE_REG:
addr = pp_u16(pp);
regnum = pp_u8(pp); // register number
const uint8_t *tail = pp_tail(pp, &size);
return UU_I2C_WriteReg(unit, addr, regnum, tail, size);
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_I2C = {
.name = "I2C",
.description = "I2C master",
// Settings
.preInit = UI2C_preInit,
.cfgLoadBinary = UI2C_loadBinary,
.cfgWriteBinary = UI2C_writeBinary,
.cfgLoadIni = UI2C_loadIni,
.cfgWriteIni = UI2C_writeIni,
// Init
.init = UI2C_init,
.deInit = UI2C_deInit,
// Function
.handleRequest = UI2C_handleRequest,
};

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//
// Created by MightyPork on 2018/01/02.
//
// I2C master unit
//
#ifndef GEX_F072_UNIT_I2C_H
#define GEX_F072_UNIT_I2C_H
#include "unit.h"
extern const UnitDriver UNIT_I2C;
// Unit-to-Unit API
/**
* Raw write to I2C
*
* @param unit - I2C unit
* @param addr - device address (set highest bit if address is 10-bit)
* @param bytes - bytes to write
* @param bcount - byte count
* @return success
*/
error_t UU_I2C_Write(Unit *unit, uint16_t addr, const uint8_t *bytes, uint32_t bcount);
/**
* Raw read from I2C
*
* @param unit - I2C unit
* @param addr - device address (set highest bit if address is 10-bit)
* @param dest - buffer for read bytes
* @param bcount - byte count
* @return success
*/
error_t UU_I2C_Read(Unit *unit, uint16_t addr, uint8_t *dest, uint32_t bcount);
/**
* Read one or more registers from a I2C register-based device with auto-increment.
*
* @param unit - I2C unit
* @param addr - device address (set highest bit if address is 10-bit)
* @param regnum - first register number
* @param dest - destination buffer
* @param width - register width (or multiple consecutive registers total size)
* @return success
*/
error_t UU_I2C_ReadReg(Unit *unit, uint16_t addr, uint8_t regnum, uint8_t *dest, uint32_t width);
/**
* Write a register value
*
* @param unit - I2C unit
* @param addr - device address (set highest bit if address is 10-bit)
* @param regnum - register number
* @param bytes - register bytes (use &byte) if just one
* @param width - register width (number of bytes)
* @return success
*/
error_t UU_I2C_WriteReg(Unit *unit, uint16_t addr, uint8_t regnum, const uint8_t *bytes, uint32_t width);
/**
* Write a 8-bit register value
*
* @param unit - I2C unit
* @param addr - device address (set highest bit if address is 10-bit)
* @param regnum - register number
* @param value - byte to write to the register
* @return success
*/
static inline error_t UU_I2C_WriteReg8(Unit *unit, uint16_t addr, uint8_t regnum, uint8_t value)
{
return UU_I2C_WriteReg(unit, addr, regnum, &value, 1);
}
#endif //GEX_F072_UNIT_I2C_H

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GexUnits/neopixel/_npx_api.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_neopixel.h"
#define NPX_INTERNAL
#include "_npx_internal.h"
#include "ws2812.h"
/* Clear the strip */
error_t UU_Npx_Clear(Unit *unit)
{
CHECK_TYPE(unit, &UNIT_NEOPIXEL);
struct priv *priv = unit->data;
ws2812_clear(priv->port, priv->ll_pin, priv->cfg.pixels);
return E_SUCCESS;
}
/* Load packed */
error_t UU_Npx_Load(Unit *unit, const uint8_t *packed_rgb, uint32_t nbytes)
{
CHECK_TYPE(unit, &UNIT_NEOPIXEL);
struct priv *priv = unit->data;
if (nbytes != 3*priv->cfg.pixels) return E_BAD_COUNT;
ws2812_load_raw(priv->port, priv->ll_pin, packed_rgb, priv->cfg.pixels);
return E_SUCCESS;
}
/* Load U32, LE or BE */
error_t UU_Npx_Load32(Unit *unit, const uint8_t *bytes, uint32_t nbytes, bool order_bgr, bool zero_before)
{
CHECK_TYPE(unit, &UNIT_NEOPIXEL);
struct priv *priv = unit->data;
if (nbytes != 4*priv->cfg.pixels) return E_BAD_COUNT;
ws2812_load_sparse(priv->port, priv->ll_pin, bytes, priv->cfg.pixels, order_bgr, zero_before);
return E_SUCCESS;
}
/* Get the pixel count */
error_t UU_Npx_GetCount(Unit *unit, uint16_t *count)
{
CHECK_TYPE(unit, &UNIT_NEOPIXEL);
struct priv *priv = unit->data;
*count = priv->cfg.pixels;
return E_SUCCESS;
}

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GexUnits/neopixel/_npx_init.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define NPX_INTERNAL
#include "_npx_internal.h"
#include "ws2812.h"
/** Allocate data structure and set defaults */
error_t Npx_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
// some defaults
priv->cfg.pin = R_PA0;
priv->cfg.pixels = 1;
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t Npx_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
// --- Parse config ---
suc = hw_pinrsc2ll(priv->cfg.pin, &priv->port, &priv->ll_pin);
if (!suc) return E_BAD_CONFIG;
TRY(rsc_claim(unit, priv->cfg.pin));
// --- Init hardware ---
LL_GPIO_SetPinMode(priv->port, priv->ll_pin, LL_GPIO_MODE_OUTPUT);
LL_GPIO_SetPinOutputType(priv->port, priv->ll_pin, LL_GPIO_OUTPUT_PUSHPULL);
LL_GPIO_SetPinSpeed(priv->port, priv->ll_pin, LL_GPIO_SPEED_FREQ_HIGH);
// clear strip
ws2812_clear(priv->port, priv->ll_pin, priv->cfg.pixels);
return E_SUCCESS;
}
/** Tear down the unit */
void Npx_deInit(Unit *unit)
{
// pins are de-inited during teardown
// Release all resources
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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GexUnits/neopixel/_npx_internal.h
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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_NPX_INTERNAL_H
#define GEX_F072_NPX_INTERNAL_H
#ifndef NPX_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
/** Private data structure */
struct priv {
struct {
Resource pin;
uint16_t pixels;
} cfg;
uint32_t ll_pin;
GPIO_TypeDef *port;
};
// ------------------------------------------------------------------------
/** Allocate data structure and set defaults */
error_t Npx_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void Npx_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void Npx_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t Npx_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void Npx_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t Npx_init(Unit *unit);
/** Tear down the unit */
void Npx_deInit(Unit *unit);
#endif //GEX_F072_NPX_INTERNAL_H

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GexUnits/neopixel/_npx_settings.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define NPX_INTERNAL
#include "_npx_internal.h"
/** Load from a binary buffer stored in Flash */
void Npx_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
priv->cfg.pin = (Resource) pp_u8(pp);
priv->cfg.pixels = pp_u16(pp);
}
/** Write to a binary buffer for storing in Flash */
void Npx_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, priv->cfg.pin);
pb_u16(pb, priv->cfg.pixels);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t Npx_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "pin")) {
priv->cfg.pin = cfg_pinrsc_parse(value, &suc);
}
else if (streq(key, "pixels")) {
priv->cfg.pixels = cfg_u16_parse(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void Npx_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Data pin");
iw_entry_s(iw, "pin", cfg_pinrsc_encode(priv->cfg.pin));
iw_comment(iw, "Number of pixels");
iw_entry_d(iw, "pixels", priv->cfg.pixels);
}

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GexUnits/neopixel/unit_neopixel.c
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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_neopixel.h"
#define NPX_INTERNAL
#include "_npx_internal.h"
enum PinCmd_ {
CMD_CLEAR = 0,
CMD_LOAD = 1,
CMD_LOAD_ZRGB = 4, // 0,0 - trail zero, bgr
CMD_LOAD_ZBGR = 5, // 0,1
CMD_LOAD_RGBZ = 6, // 1,0
CMD_LOAD_BGRZ = 7, // 1,1
CMD_GET_LEN = 10,
};
/** Handle a request message */
static error_t Npx_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
uint32_t len;
const uint8_t *bytes;
switch (command) {
/** Clear the entire strip */
case CMD_CLEAR:
return UU_Npx_Clear(unit);
/** Load packed RGB colors (length must match the strip size) */
case CMD_LOAD:;
bytes = pp_tail(pp, &len);
return UU_Npx_Load(unit, bytes, len);
/** Load sparse (uint32_t) colors */
case CMD_LOAD_ZRGB:
case CMD_LOAD_ZBGR:
case CMD_LOAD_RGBZ:
case CMD_LOAD_BGRZ:
bytes = pp_tail(pp, &len);
bool trail_zero = (bool) (command & 0b10);
bool order_bgr = (bool) (command & 0b01);
return UU_Npx_Load32(unit, bytes, len, order_bgr, !trail_zero);
/** Get the Neopixel strip length */
case CMD_GET_LEN:;
uint16_t count;
TRY(UU_Npx_GetCount(unit, &count));
com_respond_u16(frame_id, count);
return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_NEOPIXEL = {
.name = "NPX",
.description = "Neopixel RGB LED strip",
// Settings
.preInit = Npx_preInit,
.cfgLoadBinary = Npx_loadBinary,
.cfgWriteBinary = Npx_writeBinary,
.cfgLoadIni = Npx_loadIni,
.cfgWriteIni = Npx_writeIni,
// Init
.init = Npx_init,
.deInit = Npx_deInit,
// Function
.handleRequest = Npx_handleRequest,
};

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GexUnits/neopixel/unit_neopixel.h
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//
// Created by MightyPork on 2017/11/25.
//
// NeoPixel RGB LED strip bit-banged output.
// The nanosecond timing is derived from the AHB clock speed.
//
#ifndef U_NEOPIXEL_H
#define U_NEOPIXEL_H
#include "unit.h"
extern const UnitDriver UNIT_NEOPIXEL;
/**
* Clear the Neopixel strip
*
* @param unit
* @return success
*/
error_t UU_Npx_Clear(Unit *unit);
/**
* Load the strip with packed bytes R,G,B.
*
* @param unit
* @param packed_rgb - bytes to load
* @param nbytes - number of bytes, must be count*3
* @return success
*/
error_t UU_Npx_Load(Unit *unit, const uint8_t *packed_rgb, uint32_t nbytes);
/**
* Load from 32-bit numbers
* @param unit
* @param bytes
* @param nbytes
* @param order_bgr
* @param zero_before
* @return success
*/
error_t UU_Npx_Load32(Unit *unit, const uint8_t *bytes, uint32_t nbytes, bool order_bgr, bool zero_before);
/**
* Get number of pixels on the strip
*
* @param unit
* @param count - destination for the count value
* @return success
*/
error_t UU_Npx_GetCount(Unit *unit, uint16_t *count);
#endif //U_NEOPIXEL_H

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GexUnits/neopixel/ws2812.c
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#include "platform.h"
#include "ws2812.h"
#define FREQ_STEP (PLAT_AHB_MHZ/20.0f)
#define NPX_DELAY_SHORT (uint32_t)(FREQ_STEP*1.5f)
#define NPX_DELAY_LONG (uint32_t)(FREQ_STEP*3.5f)
#define NPX_DELAY_SHOW (uint32_t)(FREQ_STEP*50)
static inline __attribute__((always_inline))
void ws2812_byte(GPIO_TypeDef *port, uint32_t ll_pin, uint8_t b)
{
for (register volatile uint8_t i = 0; i < 8; i++) {
LL_GPIO_SetOutputPin(port, ll_pin);
// duty cycle determines bit value
if (b & 0x80) {
__asm_loop(NPX_DELAY_LONG);
LL_GPIO_ResetOutputPin(port, ll_pin);
__asm_loop(NPX_DELAY_SHORT);
} else {
__asm_loop(NPX_DELAY_SHORT);
LL_GPIO_ResetOutputPin(port, ll_pin);
__asm_loop(NPX_DELAY_LONG);
}
b <<= 1; // shift to next bit
}
}
/** Set many RGBs from packed stream */
void ws2812_load_raw(GPIO_TypeDef *port, uint32_t ll_pin, const uint8_t *rgbs, uint32_t count)
{
vPortEnterCritical();
uint8_t b, g, r;
for (uint32_t i = 0; i < count; i++) {
r = *rgbs++;
g = *rgbs++;
b = *rgbs++;
ws2812_byte(port, ll_pin, g);
ws2812_byte(port, ll_pin, r);
ws2812_byte(port, ll_pin, b);
}
vPortExitCritical();
__asm_loop(NPX_DELAY_SHOW);
}
/** Set many RGBs from uint32 stream */
void ws2812_load_sparse(GPIO_TypeDef *port, uint32_t ll_pin, const uint8_t *rgbs, uint32_t count,
bool order_bgr, bool zero_before)
{
vPortEnterCritical();
uint8_t b, g, r;
for (uint32_t i = 0; i < count; i++) {
if (zero_before) rgbs++; // skip
if (order_bgr) {
b = *rgbs++;
g = *rgbs++;
r = *rgbs++;
} else {
r = *rgbs++;
g = *rgbs++;
b = *rgbs++;
}
if (!zero_before) rgbs++; // skip
ws2812_byte(port, ll_pin, g);
ws2812_byte(port, ll_pin, r);
ws2812_byte(port, ll_pin, b);
}
vPortExitCritical();
__asm_loop(NPX_DELAY_SHOW);
}
/** Set many RGBs */
void ws2812_clear(GPIO_TypeDef *port, uint32_t ll_pin, uint32_t count)
{
vPortEnterCritical();
for (uint32_t i = 0; i < count*3; i++) {
ws2812_byte(port, ll_pin, 0);
}
vPortExitCritical();
__asm_loop(NPX_DELAY_SHOW);
}

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GexUnits/neopixel/ws2812.h
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#ifndef WS2812_H
#define WS2812_H
#include "platform.h"
/**
* Load RGBs from a packed byte stream
*
* @param port
* @param ll_pin
* @param rgbs - packed R,G,B, R,G,B, ... array
* @param count - number of pixels (triplets)
*/
void ws2812_load_raw(GPIO_TypeDef *port, uint32_t ll_pin, const uint8_t *rgbs, uint32_t count);
/**
* Load all pixels with BLACK (0,0,0)
*
* @param port
* @param ll_pin
* @param count - number of pixels
*/
void ws2812_clear(GPIO_TypeDef *port, uint32_t ll_pin, uint32_t count);
/**
* Load from a stream of 32-bit numbers (4th or 1st byte skipped)
* @param port
* @param ll_pin
* @param rgbs - payload
* @param count - number of pixels
* @param order_bgr - B,G,R colors, false - R,G,B
* @param zero_before - insert padding byte before colors, false - after
*/
void ws2812_load_sparse(GPIO_TypeDef *port, uint32_t ll_pin, const uint8_t *rgbs, uint32_t count,
bool order_bgr, bool zero_before);
#endif //WS2812_H

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GexUnits/pwmdim/_pwmdim_api.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_pwmdim.h"
#define PWMDIM_INTERNAL
#include "_pwmdim_internal.h"
error_t UPWMDIM_SetFreq(Unit *unit, uint32_t freq)
{
struct priv *priv = unit->data;
uint16_t presc;
uint32_t count;
float real_freq;
if (!hw_solve_timer(PLAT_APB1_HZ, freq, true, &presc, &count, &real_freq)) {
dbg("Failed to resolve timer params.");
return E_BAD_VALUE;
}
LL_TIM_SetPrescaler(priv->TIMx, (uint32_t) (presc - 1));
LL_TIM_SetAutoReload(priv->TIMx, count - 1);
// we must re-calculate duty cycles because they are absolute related to the ARR which we just changed
UPWMDIM_SetDuty(unit, 0, priv->duty1);
UPWMDIM_SetDuty(unit, 1, priv->duty2);
UPWMDIM_SetDuty(unit, 2, priv->duty3);
UPWMDIM_SetDuty(unit, 3, priv->duty4);
// LL_TIM_GenerateEvent_UPDATE(priv->TIMx); // - this appears to cause jumpiness
priv->freq = freq;
return E_SUCCESS;
}
error_t UPWMDIM_SetDuty(Unit *unit, uint8_t ch, uint16_t duty1000)
{
struct priv *priv = unit->data;
uint32_t cnt = (LL_TIM_GetAutoReload(priv->TIMx) + 1)*duty1000 / 1000;
if (ch == 0) {
priv->duty1 = duty1000;
LL_TIM_OC_SetCompareCH1(priv->TIMx, cnt);
}
else if (ch == 1) {
priv->duty2 = duty1000;
LL_TIM_OC_SetCompareCH2(priv->TIMx, cnt);
}
else if (ch == 2) {
priv->duty3 = duty1000;
LL_TIM_OC_SetCompareCH3(priv->TIMx, cnt);
}
else if (ch == 3) {
priv->duty4 = duty1000;
LL_TIM_OC_SetCompareCH4(priv->TIMx, cnt);
} else {
return E_BAD_VALUE;
}
return E_SUCCESS;
}

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define PWMDIM_INTERNAL
#include "_pwmdim_internal.h"
/** Allocate data structure and set defaults */
error_t UPWMDIM_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
priv->cfg.freq = 1000;
priv->cfg.ch1_choice = 1;
priv->cfg.ch2_choice = 0;
priv->cfg.ch3_choice = 0;
priv->cfg.ch4_choice = 0;
priv->duty1 = 500;
priv->duty2 = 500;
priv->duty3 = 500;
priv->duty4 = 500;
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t UPWMDIM_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
TRY(rsc_claim(unit, R_TIM3));
priv->TIMx = TIM3;
hw_periph_clock_enable(priv->TIMx);
// copy the default frequency
priv->freq = priv->cfg.freq;
const Resource ch1_pins[] = { R_PA6, R_PB4, R_PC6 };
const uint32_t ch1_af[] = { LL_GPIO_AF_1, LL_GPIO_AF_1, LL_GPIO_AF_0 };
const Resource ch2_pins[] = { R_PA7, R_PB5, R_PC7 };
const uint32_t ch2_af[] = { LL_GPIO_AF_1, LL_GPIO_AF_1, LL_GPIO_AF_0 };
const Resource ch3_pins[] = { R_PB0, R_PC8 };
const uint32_t ch3_af[] = { LL_GPIO_AF_1, LL_GPIO_AF_0 };
const Resource ch4_pins[] = { R_PB1, R_PC9 };
const uint32_t ch4_af[] = { LL_GPIO_AF_1, LL_GPIO_AF_0 };
Resource r[4] = {};
uint32_t af[4] = {};
// --- resolve pins and AFs ---
if (priv->cfg.ch1_choice > 0) {
if (priv->cfg.ch1_choice > 3) return E_BAD_CONFIG;
r[0] = ch1_pins[priv->cfg.ch1_choice - 1];
af[0] = ch1_af[priv->cfg.ch1_choice - 1];
TRY(rsc_claim(unit, r[0]));
}
if (priv->cfg.ch2_choice > 0) {
if (priv->cfg.ch2_choice > 3) return E_BAD_CONFIG;
r[1] = ch2_pins[priv->cfg.ch2_choice - 1];
af[1] = ch2_af[priv->cfg.ch2_choice - 1];
TRY(rsc_claim(unit, r[1]));
}
if (priv->cfg.ch3_choice > 0) {
if (priv->cfg.ch3_choice > 2) return E_BAD_CONFIG;
r[2] = ch3_pins[priv->cfg.ch3_choice - 1];
af[2] = ch3_af[priv->cfg.ch3_choice - 1];
TRY(rsc_claim(unit, r[2]));
}
if (priv->cfg.ch4_choice > 0) {
if (priv->cfg.ch4_choice > 2) return E_BAD_CONFIG;
r[3] = ch4_pins[priv->cfg.ch4_choice - 1];
af[3] = ch4_af[priv->cfg.ch4_choice - 1];
TRY(rsc_claim(unit, r[3]));
}
// --- configure AF + timer ---
LL_TIM_DeInit(priv->TIMx); // force a reset
uint16_t presc;
uint32_t count;
float real_freq;
if (!hw_solve_timer(PLAT_APB1_HZ, priv->freq, true, &presc, &count, &real_freq)) {
dbg("Failed to resolve timer params.");
return E_BAD_VALUE;
}
LL_TIM_SetPrescaler(priv->TIMx, (uint32_t) (presc - 1));
LL_TIM_SetAutoReload(priv->TIMx, count - 1);
LL_TIM_EnableARRPreload(priv->TIMx);
dbg("Presc %d, cnt %d", (int)presc, (int)count);
// TODO this can probably be turned into a loop over an array of structs
if (priv->cfg.ch1_choice > 0) {
TRY(hw_configure_gpiorsc_af(r[0], af[0]));
LL_TIM_OC_EnablePreload(priv->TIMx, LL_TIM_CHANNEL_CH1);
LL_TIM_OC_SetMode(priv->TIMx, LL_TIM_CHANNEL_CH1, LL_TIM_OCMODE_PWM1);
LL_TIM_OC_SetCompareCH1(priv->TIMx, count/2);
LL_TIM_CC_EnablePreload(priv->TIMx);
LL_TIM_CC_EnableChannel(priv->TIMx, LL_TIM_CHANNEL_CH1);
}
if (priv->cfg.ch2_choice > 0) {
TRY(hw_configure_gpiorsc_af(r[1], af[1]));
LL_TIM_OC_EnablePreload(priv->TIMx, LL_TIM_CHANNEL_CH2);
LL_TIM_OC_SetMode(priv->TIMx, LL_TIM_CHANNEL_CH2, LL_TIM_OCMODE_PWM1);
LL_TIM_OC_SetCompareCH2(priv->TIMx, count/2);
LL_TIM_CC_EnableChannel(priv->TIMx, LL_TIM_CHANNEL_CH2);
}
if (priv->cfg.ch3_choice > 0) {
TRY(hw_configure_gpiorsc_af(r[2], af[2]));
LL_TIM_OC_EnablePreload(priv->TIMx, LL_TIM_CHANNEL_CH3);
LL_TIM_OC_SetMode(priv->TIMx, LL_TIM_CHANNEL_CH3, LL_TIM_OCMODE_PWM1);
LL_TIM_OC_SetCompareCH3(priv->TIMx, count/2);
LL_TIM_CC_EnableChannel(priv->TIMx, LL_TIM_CHANNEL_CH3);
}
if (priv->cfg.ch4_choice > 0) {
TRY(hw_configure_gpiorsc_af(r[3], af[3]));
LL_TIM_OC_EnablePreload(priv->TIMx, LL_TIM_CHANNEL_CH4);
LL_TIM_OC_SetMode(priv->TIMx, LL_TIM_CHANNEL_CH4, LL_TIM_OCMODE_PWM1);
LL_TIM_OC_SetCompareCH4(priv->TIMx, count/2);
LL_TIM_CC_EnableChannel(priv->TIMx, LL_TIM_CHANNEL_CH4);
}
LL_TIM_GenerateEvent_UPDATE(priv->TIMx);
LL_TIM_EnableAllOutputs(priv->TIMx);
// postpone this for later - when user uses the start command.
// prevents beeping right after restart if used for audio.
// LL_TIM_EnableCounter(priv->TIMx);
return E_SUCCESS;
}
/** Tear down the unit */
void UPWMDIM_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// de-init peripherals
if (unit->status == E_SUCCESS ) {
LL_TIM_DeInit(priv->TIMx);
}
// Release all resources, deinit pins
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_PWMDIM_INTERNAL_H
#define GEX_F072_PWMDIM_INTERNAL_H
#ifndef PWMDIM_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
/** Private data structure */
struct priv {
// settings
struct {
uint32_t freq;
uint8_t ch1_choice;
uint8_t ch2_choice;
uint8_t ch3_choice;
uint8_t ch4_choice;
} cfg;
// internal state
uint32_t freq;
uint16_t duty1;
uint16_t duty2;
uint16_t duty3;
uint16_t duty4;
TIM_TypeDef *TIMx;
};
/** Allocate data structure and set defaults */
error_t UPWMDIM_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void UPWMDIM_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void UPWMDIM_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UPWMDIM_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void UPWMDIM_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t UPWMDIM_init(Unit *unit);
/** Tear down the unit */
void UPWMDIM_deInit(Unit *unit);
error_t UPWMDIM_SetFreq(Unit *unit, uint32_t freq);
error_t UPWMDIM_SetDuty(Unit *unit, uint8_t ch, uint16_t duty1000);
#endif //GEX_F072_PWMDIM_INTERNAL_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define PWMDIM_INTERNAL
#include "_pwmdim_internal.h"
/** Load from a binary buffer stored in Flash */
void UPWMDIM_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->cfg.freq = pp_u32(pp);
priv->cfg.ch1_choice = pp_u8(pp);
priv->cfg.ch2_choice = pp_u8(pp);
priv->cfg.ch3_choice = pp_u8(pp);
priv->cfg.ch4_choice = pp_u8(pp);
}
/** Write to a binary buffer for storing in Flash */
void UPWMDIM_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
pb_u32(pb, priv->cfg.freq);
pb_u8(pb, priv->cfg.ch1_choice);
pb_u8(pb, priv->cfg.ch2_choice);
pb_u8(pb, priv->cfg.ch3_choice);
pb_u8(pb, priv->cfg.ch4_choice);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UPWMDIM_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "frequency")) {
priv->cfg.freq = cfg_u32_parse(value, &suc);
}
else if (streq(key, "ch1_pin")) {
priv->cfg.ch1_choice = cfg_u8_parse(value, &suc);
}
else if (streq(key, "ch2_pin")) {
priv->cfg.ch2_choice = cfg_u8_parse(value, &suc);
}
else if (streq(key, "ch3_pin")) {
priv->cfg.ch3_choice = cfg_u8_parse(value, &suc);
}
else if (streq(key, "ch4_pin")) {
priv->cfg.ch4_choice = cfg_u8_parse(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void UPWMDIM_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Default pulse frequency (Hz)");
iw_entry_d(iw, "frequency", priv->cfg.freq);
iw_comment(iw, "Pin mapping - 0=disabled");
iw_comment(iw, "Channel1 - 1:PA6, 2:PB4, 3:PC6");
iw_entry_d(iw, "ch1_pin", priv->cfg.ch1_choice);
iw_comment(iw, "Channel2 - 1:PA7, 2:PB5, 3:PC7");
iw_entry_d(iw, "ch2_pin", priv->cfg.ch2_choice);
iw_comment(iw, "Channel3 - 1:PB0, 2:PC8");
iw_entry_d(iw, "ch3_pin", priv->cfg.ch3_choice);
iw_comment(iw, "Channel4 - 1:PB1, 2:PC9");
iw_entry_d(iw, "ch4_pin", priv->cfg.ch4_choice);
}

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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_pwmdim.h"
#define PWMDIM_INTERNAL
#include "_pwmdim_internal.h"
// ------------------------------------------------------------------------
enum PwmSimpleCmd_ {
CMD_SET_FREQUENCY = 0,
CMD_SET_DUTY = 1,
CMD_STOP = 2,
CMD_START = 3,
};
/** Handle a request message */
static error_t UPWMDIM_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
struct priv *priv = unit->data;
switch (command) {
case CMD_SET_FREQUENCY:
TRY(UPWMDIM_SetFreq(unit, pp_u32(pp)));
return E_SUCCESS;
case CMD_SET_DUTY:
for (; pp_length(pp) > 0;) {
uint8_t ch = pp_u8(pp);
uint16_t duty = pp_u16(pp);
TRY(UPWMDIM_SetDuty(unit, ch, duty));
}
return E_SUCCESS;
case CMD_STOP:
LL_TIM_DisableCounter(priv->TIMx);
LL_TIM_SetCounter(priv->TIMx, 0);
return E_SUCCESS;
case CMD_START:
LL_TIM_EnableCounter(priv->TIMx);
return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Simple PWM dimming output */
const UnitDriver UNIT_PWMDIM = {
.name = "PWMDIM",
.description = "Simple PWM output",
// Settings
.preInit = UPWMDIM_preInit,
.cfgLoadBinary = UPWMDIM_loadBinary,
.cfgWriteBinary = UPWMDIM_writeBinary,
.cfgLoadIni = UPWMDIM_loadIni,
.cfgWriteIni = UPWMDIM_writeIni,
// Init
.init = UPWMDIM_init,
.deInit = UPWMDIM_deInit,
// Function
.handleRequest = UPWMDIM_handleRequest,
};

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//
// Created by MightyPork on 2017/11/25.
//
// Digital input unit; single or multiple pin read access on one port (A-F)
//
#ifndef U_PWMDIM_H
#define U_PWMDIM_H
#include "unit.h"
extern const UnitDriver UNIT_PWMDIM;
// UU_ prototypes
#endif //U_PWMDIM_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_sipo.h"
#define SIPO_INTERNAL
#include "_sipo_internal.h"
static void send_pulse(bool pol, GPIO_TypeDef *port, uint32_t ll)
{
if (pol) {
LL_GPIO_SetOutputPin(port, ll);
}
else {
LL_GPIO_ResetOutputPin(port, ll);
}
__asm_loop(2);
if (pol) {
LL_GPIO_ResetOutputPin(port, ll);
}
else {
LL_GPIO_SetOutputPin(port, ll);
}
}
#pragma GCC push_options
#pragma GCC optimize ("O2")
error_t UU_SIPO_Write(Unit *unit, const uint8_t *buffer, uint16_t buflen, uint16_t terminal_data)
{
CHECK_TYPE(unit, &UNIT_SIPO);
struct priv *priv = unit->data;
if (buflen % priv->data_width != 0) {
dbg("Buflen %d vs width %d", (int)buflen, (int)priv->data_width);
return E_BAD_COUNT; // must be a multiple of the channel count
}
// buffer contains data for the individual data pins, back to back as AAA BBB CCC (whole bytes)
const uint8_t data_width = priv->data_width;
const uint16_t bytelen = buflen / data_width;
const uint16_t mask = priv->cfg.data_pins;
uint8_t offsets[16];
for (int i=0; i<16; i++) offsets[i] = (uint8_t) (bytelen * i);
for (int32_t bn = bytelen - 1; bn >= 0; bn--) {
// send the byte
for (int32_t i = 0; i < 8; i++) {
uint16_t packed = 0;
for (int32_t j = data_width - 1; j >= 0; j--) {
packed |= (buffer[bn + offsets[j]] >> i) & 1;
if (j > 0) packed <<= 1;
}
uint16_t spread = pinmask_spread(packed, mask);
priv->data_port->BSRR = spread | (((~spread) & mask) << 16);
// Shift clock pulse
send_pulse(priv->cfg.shift_pol, priv->shift_port, priv->shift_ll);
}
}
// load the final data - this may be used by some other circuitry or
// simply to rest the lines at a defined known level
uint16_t spread = pinmask_spread(terminal_data, mask);
priv->data_port->BSRR = spread | (((~spread) & mask) << 16);
send_pulse(priv->cfg.store_pol, priv->store_port, priv->store_ll);
return E_SUCCESS;
}
#pragma GCC pop_options
error_t UU_SIPO_DirectData(Unit *unit, uint16_t data_packed)
{
CHECK_TYPE(unit, &UNIT_SIPO);
struct priv *priv = unit->data;
uint16_t spread = pinmask_spread(data_packed, priv->cfg.data_pins);
priv->data_port->BSRR = spread | (((~spread) & priv->cfg.data_pins) << 16);
return E_SUCCESS;
}
error_t UU_SIPO_DirectClear(Unit *unit)
{
CHECK_TYPE(unit, &UNIT_SIPO);
struct priv *priv = unit->data;
send_pulse(priv->cfg.clear_pol, priv->clear_port, priv->clear_ll);
return E_SUCCESS;
}
error_t UU_SIPO_DirectShift(Unit *unit)
{
CHECK_TYPE(unit, &UNIT_SIPO);
struct priv *priv = unit->data;
send_pulse(priv->cfg.shift_pol, priv->shift_port, priv->shift_ll);
return E_SUCCESS;
}
error_t UU_SIPO_DirectStore(Unit *unit)
{
CHECK_TYPE(unit, &UNIT_SIPO);
struct priv *priv = unit->data;
send_pulse(priv->cfg.store_pol, priv->store_port, priv->store_ll);
return E_SUCCESS;
}

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define SIPO_INTERNAL
#include "_sipo_internal.h"
/** Allocate data structure and set defaults */
error_t USIPO_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
priv->cfg.pin_store = R_PA0;
priv->cfg.store_pol = true;
priv->cfg.pin_shift = R_PA1;
priv->cfg.shift_pol = true;
priv->cfg.pin_clear = R_PA2;
priv->cfg.clear_pol = false;
priv->cfg.data_pname = 'A';
priv->cfg.data_pins = (1<<3);
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t USIPO_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
// --- Parse config ---
suc &= hw_pinrsc2ll(priv->cfg.pin_store, &priv->store_port, &priv->store_ll);
suc &= hw_pinrsc2ll(priv->cfg.pin_shift, &priv->shift_port, &priv->shift_ll);
suc &= hw_pinrsc2ll(priv->cfg.pin_clear, &priv->clear_port, &priv->clear_ll);
if (!suc) return E_BAD_CONFIG;
TRY(rsc_claim(unit, priv->cfg.pin_store));
TRY(rsc_claim(unit, priv->cfg.pin_shift));
TRY(rsc_claim(unit, priv->cfg.pin_clear));
// Claim all needed pins
TRY(rsc_claim_gpios(unit, priv->cfg.data_pname, priv->cfg.data_pins));
priv->data_port = hw_port2periph(priv->cfg.data_pname, &suc);
// --- Init hardware ---
priv->data_width = 0;
for (int i = 0; i < 16; i++) {
if (priv->cfg.data_pins & (1 << i)) {
uint32_t ll_pin = hw_pin2ll((uint8_t) i, &suc);
LL_GPIO_SetPinMode(priv->data_port, ll_pin, LL_GPIO_MODE_OUTPUT);
LL_GPIO_SetPinOutputType(priv->data_port, ll_pin, LL_GPIO_OUTPUT_PUSHPULL);
LL_GPIO_SetPinSpeed(priv->data_port, ll_pin, LL_GPIO_SPEED_FREQ_HIGH);
priv->data_width++;
}
}
// Set the initial state - zeros
priv->data_port->ODR &= ~priv->cfg.data_pins;
// STORE
LL_GPIO_SetPinMode(priv->store_port, priv->store_ll, LL_GPIO_MODE_OUTPUT);
LL_GPIO_SetPinOutputType(priv->store_port, priv->store_ll, LL_GPIO_OUTPUT_PUSHPULL);
LL_GPIO_SetPinSpeed(priv->store_port, priv->store_ll, LL_GPIO_SPEED_FREQ_HIGH);
if (priv->cfg.store_pol)
LL_GPIO_ResetOutputPin(priv->store_port, priv->store_ll);
else
LL_GPIO_SetOutputPin(priv->store_port, priv->store_ll);
// SHIFT
LL_GPIO_SetPinMode(priv->shift_port, priv->shift_ll, LL_GPIO_MODE_OUTPUT);
LL_GPIO_SetPinOutputType(priv->shift_port, priv->shift_ll, LL_GPIO_OUTPUT_PUSHPULL);
LL_GPIO_SetPinSpeed(priv->shift_port, priv->shift_ll, LL_GPIO_SPEED_FREQ_HIGH);
if (priv->cfg.shift_pol)
LL_GPIO_ResetOutputPin(priv->shift_port, priv->shift_ll);
else
LL_GPIO_SetOutputPin(priv->shift_port, priv->shift_ll);
// CLEAR
LL_GPIO_SetPinMode(priv->clear_port, priv->clear_ll, LL_GPIO_MODE_OUTPUT);
LL_GPIO_SetPinOutputType(priv->clear_port, priv->clear_ll, LL_GPIO_OUTPUT_PUSHPULL);
LL_GPIO_SetPinSpeed(priv->clear_port, priv->clear_ll, LL_GPIO_SPEED_FREQ_HIGH);
if (priv->cfg.clear_pol)
LL_GPIO_ResetOutputPin(priv->clear_port, priv->clear_ll);
else
LL_GPIO_SetOutputPin(priv->clear_port, priv->clear_ll);
// initial clear
UU_SIPO_DirectClear(unit);
return E_SUCCESS;
}
/** Tear down the unit */
void USIPO_deInit(Unit *unit)
{
// Release all resources, deinit pins
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_SIPO_INTERNAL_H
#define GEX_F072_SIPO_INTERNAL_H
#ifndef SIPO_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
/** Private data structure */
struct priv {
struct {
// settings
Resource pin_store;
bool store_pol; //!< Store pulse active edge
Resource pin_shift;
bool shift_pol; //!< Shift clock active edge
Resource pin_clear;
bool clear_pol; //!< Clear signal active level
char data_pname;
uint16_t data_pins;
} cfg;
// live fields
uint32_t store_ll;
uint32_t shift_ll;
uint32_t clear_ll;
GPIO_TypeDef *store_port;
GPIO_TypeDef *shift_port;
GPIO_TypeDef *clear_port;
GPIO_TypeDef *data_port;
uint8_t data_width;
};
/** Allocate data structure and set defaults */
error_t USIPO_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void USIPO_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void USIPO_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t USIPO_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void USIPO_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t USIPO_init(Unit *unit);
/** Tear down the unit */
void USIPO_deInit(Unit *unit);
// ------------------------------------------------------------------------
/**
* Write a buffer to the pins.
* Buffer contains data for the individual channels, sequentially (AAAAAA BBBBBB CCCCCC ...)
* The bytes are sent LSB first, from the last byte (e.g. 1,2,3 - 3 is sent first, LSB-first).
*
* The chunks order is from the lowest to the highest bit
*
* @param unit
* @param buffer - buffer of data to send
* @param buflen - number of bytes in the buffer
* @param terminal_data - data to set before sending the store pulse (final data lines state, will not appear in the SIPOs)
* @return success
*/
error_t UU_SIPO_Write(Unit *unit, const uint8_t *buffer, uint16_t buflen, uint16_t terminal_data);
/**
* Direct access to the output data pins (may be useful for debugging, or circuits that use them
* for something else when not loading a new value).
*
* @param unit
* @param data_packed - packed data to set on the output (right-aligned, highest to lowest pin)
* @return success
*/
error_t UU_SIPO_DirectData(Unit *unit, uint16_t data_packed);
/**
* Send a clear pulse.
*
* @param unit
* @return success
*/
error_t UU_SIPO_DirectClear(Unit *unit);
/**
* Send a shift pulse.
*
* @param unit
* @return success
*/
error_t UU_SIPO_DirectShift(Unit *unit);
/**
* Send a store pulse.
*
* @param unit
* @return success
*/
error_t UU_SIPO_DirectStore(Unit *unit);
#endif //GEX_F072_SIPO_INTERNAL_H

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GexUnits/sipo/_sipo_settings.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define SIPO_INTERNAL
#include "_sipo_internal.h"
/** Load from a binary buffer stored in Flash */
void USIPO_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->cfg.pin_store = (Resource) pp_u8(pp);
priv->cfg.store_pol = pp_bool(pp);
priv->cfg.pin_shift = (Resource) pp_u8(pp);
priv->cfg.shift_pol = pp_bool(pp);
priv->cfg.pin_clear = (Resource) pp_u8(pp);
priv->cfg.clear_pol = pp_bool(pp);
priv->cfg.data_pname = pp_char(pp);
priv->cfg.data_pins = pp_u16(pp);
}
/** Write to a binary buffer for storing in Flash */
void USIPO_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
pb_u8(pb, priv->cfg.pin_store);
pb_bool(pb, priv->cfg.store_pol);
pb_u8(pb, priv->cfg.pin_shift);
pb_bool(pb, priv->cfg.shift_pol);
pb_u8(pb, priv->cfg.pin_clear);
pb_bool(pb, priv->cfg.clear_pol);
pb_char(pb, priv->cfg.data_pname);
pb_u16(pb, priv->cfg.data_pins);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t USIPO_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "store-pin")) {
priv->cfg.pin_store = cfg_pinrsc_parse(value, &suc);
}
else if (streq(key, "shift-pin")) {
priv->cfg.pin_shift = cfg_pinrsc_parse(value, &suc);
}
else if (streq(key, "clear-pin")) {
priv->cfg.pin_clear = cfg_pinrsc_parse(value, &suc);
}
else if (streq(key, "store-pol")) {
priv->cfg.store_pol = cfg_bool_parse(value, &suc);
}
else if (streq(key, "shift-pol")) {
priv->cfg.shift_pol = cfg_bool_parse(value, &suc);
}
else if (streq(key, "clear-pol")) {
priv->cfg.clear_pol = cfg_bool_parse(value, &suc);
}
else if (streq(key, "data-port")) {
suc = cfg_port_parse(value, &priv->cfg.data_pname);
}
else if (streq(key, "data-pins")) {
priv->cfg.data_pins = cfg_pinmask_parse(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void USIPO_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Shift pin & its active edge (1-rising,0-falling)");
iw_entry_s(iw, "shift-pin", cfg_pinrsc_encode(priv->cfg.pin_shift));
iw_entry_d(iw, "shift-pol", priv->cfg.shift_pol);
iw_comment(iw, "Store pin & its active edge");
iw_entry_s(iw, "store-pin", cfg_pinrsc_encode(priv->cfg.pin_store));
iw_entry_d(iw, "store-pol", priv->cfg.store_pol);
iw_comment(iw, "Clear pin & its active level");
iw_entry_s(iw, "clear-pin", cfg_pinrsc_encode(priv->cfg.pin_clear));
iw_entry_d(iw, "clear-pol", priv->cfg.clear_pol);
iw_comment(iw, "Data port and pins");
iw_entry(iw, "data-port", "%c", priv->cfg.data_pname);
iw_entry_s(iw, "data-pins", cfg_pinmask_encode(priv->cfg.data_pins, unit_tmp512, true));
}

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GexUnits/sipo/unit_sipo.c
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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_sipo.h"
#define SIPO_INTERNAL
#include "_sipo_internal.h"
// ------------------------------------------------------------------------
enum SipoCmd_ {
CMD_WRITE = 0,
CMD_DIRECT_DATA = 1,
CMD_DIRECT_SHIFT = 2,
CMD_DIRECT_CLEAR = 3,
CMD_DIRECT_STORE = 4,
};
/** Handle a request message */
static error_t USIPO_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
switch (command) {
case CMD_WRITE:
{
uint32_t len;
uint16_t terminal_packed = pp_u16(pp);
const uint8_t *tail = pp_tail(pp, &len);
TRY(UU_SIPO_Write(unit, (uint8_t *) tail, (uint16_t) len, terminal_packed));
}
return E_SUCCESS;
case CMD_DIRECT_DATA:
TRY(UU_SIPO_DirectData(unit, pp_u16(pp)));
return E_SUCCESS;
case CMD_DIRECT_CLEAR:
TRY(UU_SIPO_DirectClear(unit));
return E_SUCCESS;
case CMD_DIRECT_SHIFT:
TRY(UU_SIPO_DirectShift(unit));
return E_SUCCESS;
case CMD_DIRECT_STORE:
TRY(UU_SIPO_DirectStore(unit));
return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_SIPO = {
.name = "SIPO",
.description = "Shift register driver (595, 4094)",
// Settings
.preInit = USIPO_preInit,
.cfgLoadBinary = USIPO_loadBinary,
.cfgWriteBinary = USIPO_writeBinary,
.cfgLoadIni = USIPO_loadIni,
.cfgWriteIni = USIPO_writeIni,
// Init
.init = USIPO_init,
.deInit = USIPO_deInit,
// Function
.handleRequest = USIPO_handleRequest,
};

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GexUnits/sipo/unit_sipo.h
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//
// Created by MightyPork on 2017/11/25.
//
// Digital input unit; single or multiple pin read access on one port (A-F)
//
#ifndef U_SIPO_H
#define U_SIPO_H
#include "unit.h"
extern const UnitDriver UNIT_SIPO;
// UU_ prototypes
#endif //U_SIPO_H

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GexUnits/spi/_spi_api.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_spi.h"
#define SPI_INTERNAL
#include "_spi_internal.h"
static error_t spi_wait_until_flag(struct priv *priv, uint32_t flag, bool stop_state)
{
uint32_t t_start = HAL_GetTick();
while (((priv->periph->SR & flag) != 0) != stop_state) {
if (HAL_GetTick() - t_start > 10) {
return E_HW_TIMEOUT;
}
}
return E_SUCCESS;
}
/**
* Perform a low level SPI transfer
*
* @param priv - private object of the SPI unit
* @param request - request buffer
* @param response - response buffer
* @param req_len - request len
* @param resp_skip - response skip bytes
* @param resp_len - response len
* @return success
*/
static error_t xfer_do(struct priv *priv, const uint8_t *request,
uint8_t *response,
uint32_t req_len,
uint32_t resp_skip,
uint32_t resp_len)
{
// TODO this is slow, use DMA
if (response == NULL) resp_len = 0;
// avoid skip causing stretch beyond tx window if nothing is to be read back
if (resp_len == 0) resp_skip = 0;
// in tx only mode, return zeros
if (priv->tx_only && resp_len>0) {
memset(response, 0, resp_len);
}
uint8_t tb;
uint32_t end = MAX(req_len, resp_len + resp_skip);
for (uint32_t i = 0; i < end; i++) {
if (i < req_len) tb = *request++;
else tb = 0;
TRY(spi_wait_until_flag(priv, SPI_SR_TXE, true));
LL_SPI_TransmitData8(priv->periph, tb);
if (!priv->tx_only) {
TRY(spi_wait_until_flag(priv, SPI_SR_RXNE, true));
uint8_t rb = LL_SPI_ReceiveData8(priv->periph);
if (resp_skip > 0) resp_skip--;
else if (resp_len > 0) {
resp_len--;
*response++ = rb;
}
}
}
return E_SUCCESS;
}
error_t UU_SPI_Multicast(Unit *unit, uint16_t slaves,
const uint8_t *request, uint32_t req_len)
{
struct priv *priv= unit->data;
uint16_t mask = pinmask_spread(slaves, priv->ssn_pins);
priv->ssn_port->BRR = mask;
{
TRY(xfer_do(priv, request, NULL, req_len, 0, 0));
}
priv->ssn_port->BSRR = mask;
return E_SUCCESS;
}
error_t UU_SPI_Write(Unit *unit, uint8_t slave_num,
const uint8_t *request, uint8_t *response,
uint32_t req_len, uint32_t resp_skip, uint32_t resp_len)
{
struct priv *priv= unit->data;
uint16_t mask = pinmask_spread((uint16_t) (1 << slave_num), priv->ssn_pins);
priv->ssn_port->BRR = mask;
{
TRY(xfer_do(priv, request, response, req_len, resp_skip, resp_len));
}
priv->ssn_port->BSRR = mask;
return E_SUCCESS;
}

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GexUnits/spi/_spi_init.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define SPI_INTERNAL
#include "_spi_internal.h"
/** Allocate data structure and set defaults */
error_t USPI_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
// some defaults
priv->periph_num = 1;
priv->prescaller = 64;
priv->remap = 0;
priv->cpol = 0;
priv->cpha = 0;
priv->tx_only = false;
priv->lsb_first = false;
priv->ssn_port_name = 'A';
priv->ssn_pins = 0x0001;
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t USPI_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
if (!(priv->periph_num >= 1 && priv->periph_num <= 2)) {
dbg("!! Bad SPI periph");
// XXX some chips have also SPI3
return E_BAD_CONFIG;
}
// assign and claim the peripheral
if (priv->periph_num == 1) {
TRY(rsc_claim(unit, R_SPI1));
priv->periph = SPI1;
}
else if (priv->periph_num == 2) {
TRY(rsc_claim(unit, R_SPI2));
priv->periph = SPI2;
}
// This is written for F072, other platforms will need adjustments
// Configure SPI own pins (AF)
char spi_portname;
uint8_t pin_miso;
uint8_t pin_mosi;
uint8_t pin_sck;
uint32_t af_spi;
// TODO
#if STM32F072xB
// SPI1 - many options
// sck, miso, mosi, af
if (priv->periph_num == 1) {
// SPI1
if (priv->remap == 0) {
spi_portname = 'A';
af_spi = LL_GPIO_AF_0;
pin_sck = 5;
pin_miso = 6;
pin_mosi = 7;
}
else if (priv->remap == 1) {
spi_portname = 'B';
af_spi = LL_GPIO_AF_0;
pin_sck = 3;
pin_miso = 4;
pin_mosi = 5;
}
// else if (priv->remap == 2) {
// // large packages only
// spi_portname = 'E';
// af_spi = LL_GPIO_AF_1;
// pin_sck = 13;
// pin_miso = 14;
// pin_mosi = 15;
// }
else {
return E_BAD_CONFIG;
}
}
else {
// SPI2
if (priv->remap == 0) {
spi_portname = 'B';
af_spi = LL_GPIO_AF_0;
pin_sck = 13;
pin_miso = 14;
pin_mosi = 15;
}
// else if (priv->remap == 1) {
// // NOTE: there's also an incomplete remap in PB and PC
// spi_portname = 'D';
// af_spi = LL_GPIO_AF_0;
// pin_sck = 1;
// pin_miso = 3;
// pin_mosi = 4;
// }
else {
return E_BAD_CONFIG;
}
}
#elif GEX_PLAT_F103_BLUEPILL
#error "NO IMPL"
#elif GEX_PLAT_F303_DISCOVERY
#error "NO IMPL"
#elif GEX_PLAT_F407_DISCOVERY
#error "NO IMPL"
#else
#error "BAD PLATFORM!"
#endif
// first, we have to claim the pins
TRY(rsc_claim_pin(unit, spi_portname, pin_mosi));
TRY(rsc_claim_pin(unit, spi_portname, pin_miso));
TRY(rsc_claim_pin(unit, spi_portname, pin_sck));
TRY(hw_configure_gpio_af(spi_portname, pin_mosi, af_spi));
TRY(hw_configure_gpio_af(spi_portname, pin_miso, af_spi));
TRY(hw_configure_gpio_af(spi_portname, pin_sck, af_spi));
// configure SSN GPIOs
{
// Claim all needed pins
TRY(rsc_claim_gpios(unit, priv->ssn_port_name, priv->ssn_pins));
TRY(hw_configure_sparse_pins(priv->ssn_port_name, priv->ssn_pins, &priv->ssn_port,
LL_GPIO_MODE_OUTPUT, LL_GPIO_OUTPUT_PUSHPULL));
// Set the initial state - all high
priv->ssn_port->BSRR = priv->ssn_pins;
}
hw_periph_clock_enable(priv->periph);
// Configure SPI - must be configured under reset
LL_SPI_Disable(priv->periph);
{
uint32_t presc = priv->prescaller;
uint32_t lz = __CLZ(presc);
if (lz < 23) lz = 23;
if (lz > 30) lz = 30;
presc = (32 - lz - 2);
LL_SPI_SetBaudRatePrescaler(priv->periph, (presc<<SPI_CR1_BR_Pos)&SPI_CR1_BR_Msk);
LL_SPI_SetClockPolarity(priv->periph, priv->cpol ? LL_SPI_POLARITY_HIGH : LL_SPI_POLARITY_LOW);
LL_SPI_SetClockPhase(priv->periph, priv->cpha ? LL_SPI_PHASE_1EDGE : LL_SPI_PHASE_2EDGE);
LL_SPI_SetTransferDirection(priv->periph, priv->tx_only ? LL_SPI_HALF_DUPLEX_TX : LL_SPI_FULL_DUPLEX);
LL_SPI_SetTransferBitOrder(priv->periph, priv->lsb_first ? LL_SPI_LSB_FIRST : LL_SPI_MSB_FIRST);
LL_SPI_SetNSSMode(priv->periph, LL_SPI_NSS_SOFT);
LL_SPI_SetDataWidth(priv->periph, LL_SPI_DATAWIDTH_8BIT);
LL_SPI_SetRxFIFOThreshold(priv->periph, LL_SPI_RX_FIFO_TH_QUARTER); // trigger RXNE on 1 byte
LL_SPI_SetMode(priv->periph, LL_SPI_MODE_MASTER);
}
LL_SPI_Enable(priv->periph);
return E_SUCCESS;
}
/** Tear down the unit */
void USPI_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// de-init the pins & peripheral only if inited correctly
if (unit->status == E_SUCCESS) {
assert_param(priv->periph);
LL_SPI_DeInit(priv->periph);
hw_periph_clock_disable(priv->periph);
}
// Release all resources
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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GexUnits/spi/_spi_internal.h
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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_SPI_INTERNAL_H
#define GEX_F072_SPI_INTERNAL_H
#ifndef SPI_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
/** Private data structure */
struct priv {
uint8_t periph_num; //!< 1 or 2
uint8_t remap; //!< SPI remap option
uint16_t prescaller; //!< Clock prescaller, stored as the dividing factor
bool cpol; //!< CPOL setting
bool cpha; //!< CPHA setting
bool tx_only; //!< If true, Enable only the MOSI line
bool lsb_first; //!< Option to send LSB first
char ssn_port_name; //!< SSN port
uint16_t ssn_pins; //!< SSN pin mask
SPI_TypeDef *periph;
GPIO_TypeDef *ssn_port;
};
// ------------------------------------------------------------------------
/** Load from a binary buffer stored in Flash */
void USPI_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void USPI_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t USPI_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void USPI_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Allocate data structure and set defaults */
error_t USPI_preInit(Unit *unit);
/** Finalize unit set-up */
error_t USPI_init(Unit *unit);
/** Tear down the unit */
void USPI_deInit(Unit *unit);
#endif //GEX_F072_SPI_INTERNAL_H

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GexUnits/spi/_spi_settings.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define SPI_INTERNAL
#include "_spi_internal.h"
/** Load from a binary buffer stored in Flash */
void USPI_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->periph_num = pp_u8(pp);
priv->prescaller = pp_u16(pp);
priv->remap = pp_u8(pp);
priv->cpol = pp_bool(pp);
priv->cpha = pp_bool(pp);
priv->tx_only = pp_bool(pp);
priv->lsb_first = pp_bool(pp);
priv->ssn_port_name = pp_char(pp);
priv->ssn_pins = pp_u16(pp);
}
/** Write to a binary buffer for storing in Flash */
void USPI_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
pb_u8(pb, priv->periph_num);
pb_u16(pb, priv->prescaller);
pb_u8(pb, priv->remap);
pb_bool(pb, priv->cpol);
pb_bool(pb, priv->cpha);
pb_bool(pb, priv->tx_only);
pb_bool(pb, priv->lsb_first);
pb_char(pb, priv->ssn_port_name);
pb_u16(pb, priv->ssn_pins);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t USPI_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "device")) {
priv->periph_num = cfg_u8_parse(value, &suc);
}
else if (streq(key, "remap")) {
priv->remap = cfg_u8_parse(value, &suc);
}
else if (streq(key, "prescaller")) {
priv->prescaller = cfg_u16_parse(value, &suc);
}
else if (streq(key, "cpol")) {
priv->cpol = cfg_bool_parse(value, &suc);
}
else if (streq(key, "cpha")) {
priv->cpha = cfg_bool_parse(value, &suc);
}
else if (streq(key, "tx-only")) {
priv->tx_only = cfg_bool_parse(value, &suc);
}
else if (streq(key, "first-bit")) {
priv->lsb_first = (bool) cfg_enum2_parse(value, "MSB", 0, "LSB", 1, &suc);
}
else if (streq(key, "port")) {
suc = cfg_port_parse(value, &priv->ssn_port_name);
}
else if (streq(key, "pins")) {
priv->ssn_pins = cfg_pinmask_parse(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void USPI_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Peripheral number (SPIx)");
iw_entry_d(iw, "device", priv->periph_num);
// TODO show a legend for peripherals and remaps
iw_comment(iw, "Pin mappings (SCK,MISO,MOSI)");
#if STM32F072xB
iw_comment(iw, " SPI1: (0) A5,A6,A7 (1) B3,B4,B5"); // (2) E13,E14,E15
iw_comment(iw, " SPI2: (0) B13,B14,B15"); // (1) D1,D3,D4
#elif GEX_PLAT_F103_BLUEPILL
#error "NO IMPL"
#elif GEX_PLAT_F303_DISCOVERY
#error "NO IMPL"
#elif GEX_PLAT_F407_DISCOVERY
#error "NO IMPL"
#else
#error "BAD PLATFORM!"
#endif
iw_entry_d(iw, "remap", priv->remap);
iw_cmt_newline(iw);
iw_comment(iw, "Prescaller: 2,4,8,...,256");
iw_entry_d(iw, "prescaller", priv->prescaller);
iw_comment(iw, "Clock polarity: 0,1 (clock idle level)");
iw_entry_d(iw, "cpol", priv->cpol);
iw_comment(iw, "Clock phase: 0,1 (active edge, 0-first, 1-second)");
iw_entry_d(iw, "cpha", priv->cpha);
iw_comment(iw, "Transmit only, disable MISO");
iw_entry_s(iw, "tx-only", str_yn(priv->tx_only));
iw_comment(iw, "Bit order (LSB or MSB first)");
iw_entry_s(iw, "first-bit", cfg_enum2_encode((uint32_t) priv->lsb_first, 0, "MSB", 1, "LSB"));
iw_cmt_newline(iw);
iw_comment(iw, "SS port name");
iw_entry(iw, "port", "%c", priv->ssn_port_name);
iw_comment(iw, "SS pins (comma separated, supports ranges)");
iw_entry_s(iw, "pins", cfg_pinmask_encode(priv->ssn_pins, unit_tmp512, 0));
}

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GexUnits/spi/unit_spi.c
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//
// Created by MightyPork on 2018/01/02.
//
// SPI master with unicast and multicats support, up to 16 slave select lines
//
#include "comm/messages.h"
#include "unit_base.h"
#include "utils/avrlibc.h"
#include "unit_spi.h"
#define SPI_INTERNAL
#include "_spi_internal.h"
// SPI master
enum PinCmd_ {
CMD_QUERY = 0,
CMD_MULTICAST = 1,
};
/** Handle a request message */
static error_t USPI_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
uint8_t slave;
uint16_t slaves;
uint16_t req_len;
uint16_t resp_skip;
uint16_t resp_len;
const uint8_t *bb;
uint32_t len;
switch (command) {
/** Write and read byte(s) - slave_num:u8, req_len:u16, resp_skip:u16, resp_len:u16, byte(s) */
case CMD_QUERY:
slave = pp_u8(pp);
resp_skip = pp_u16(pp);
resp_len = pp_u16(pp);
bb = pp_tail(pp, &len);
TRY(UU_SPI_Write(unit, slave,
bb, (uint8_t *) unit_tmp512,
len, resp_skip, resp_len));
// no response if we aren't reading
if (resp_len > 0) {
com_respond_buf(frame_id, MSG_SUCCESS, (uint8_t *) unit_tmp512, resp_len);
}
return E_SUCCESS;
/** Write byte(s) to multiple slaves - slaves:u16, req_len:u16, byte(s) */
case CMD_MULTICAST:
slaves = pp_u16(pp);
bb = pp_tail(pp, &len);
TRY(UU_SPI_Multicast(unit, slaves, bb, len));
return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_SPI = {
.name = "SPI",
.description = "SPI master",
// Settings
.preInit = USPI_preInit,
.cfgLoadBinary = USPI_loadBinary,
.cfgWriteBinary = USPI_writeBinary,
.cfgLoadIni = USPI_loadIni,
.cfgWriteIni = USPI_writeIni,
// Init
.init = USPI_init,
.deInit = USPI_deInit,
// Function
.handleRequest = USPI_handleRequest,
};

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GexUnits/spi/unit_spi.h
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//
// Created by MightyPork on 2018/01/02.
//
#ifndef GEX_F072_UNIT_SPI_H
#define GEX_F072_UNIT_SPI_H
#include "unit.h"
extern const UnitDriver UNIT_SPI;
// Unit-to-Unit API
/**
* Raw read/write via SPI.
* It's possible to simultaneously write and read, or skip bytes in either direction.
*
* Example scenarios:
*
* req 2, skip 2, read 3
* |<-- req_len --->|
* [ write ][ write ] . . . . . . . .
* . . . . . . . . . [ read ][ read ][ read ]
* |<-- resp_skip ->|<------ resp_len ----->|
*
* req 2, skip 0, read 2
* |<-- req_len --->|
* [ write ][ write ]
* [ read ][ read ]
* |<-- resp_len -->|
*
* @param unit - SPI unit
* @param slave_num - slave number (SS pin index, counted from least significant bit)
* @param request - request bytes buffer
* @param response - response bytes buffer
* @param req_len - number of bytes in the request. Will be right-padded with zeros.
* @param resp_skip - response bytes to discard before starting to capture them
* @param resp_len - number of bytes to capture, after discarding resp_skip received bytes
* @return success
*/
error_t UU_SPI_Write(Unit *unit, uint8_t slave_num,
const uint8_t *request,
uint8_t *response,
uint32_t req_len,
uint32_t resp_skip,
uint32_t resp_len);
/**
* Write to multiple slaves at once.
* This is similar to UU_SPI_Write, but performs no read and works only if the device
* is configured as tx-only.
*
* @param unit - SPI unit
* @param slaves - bitmap of slaves to write (packed bits representing the SSN pins)
* @param request - request bytes buffer
* @param req_len - length of the request buffer
* @return success
*/
error_t UU_SPI_Multicast(Unit *unit, uint16_t slaves,
const uint8_t *request,
uint32_t req_len);
#endif //GEX_F072_UNIT_SPI_H

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This is a template unit, used for reference when creating new units.
It is not registered into the unit registry, and cannot be instantiated.

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GexUnits/template/_tpl_api.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_tpl.h"
#define TPL_INTERNAL
#include "_tpl_internal.h"

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define TPL_INTERNAL
#include "_tpl_internal.h"
/** Allocate data structure and set defaults */
error_t UTPL_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
//
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t UTPL_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
//
return E_SUCCESS;
}
/** Tear down the unit */
void UTPL_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// de-init peripherals
if (unit->status == E_SUCCESS ) {
//
}
// Release all resources, deinit pins
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_TPL_INTERNAL_H
#define GEX_F072_TPL_INTERNAL_H
#ifndef TPL_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
/** Private data structure */
struct priv {
// settings
// internal state
};
/** Allocate data structure and set defaults */
error_t UTPL_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void UTPL_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void UTPL_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UTPL_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void UTPL_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t UTPL_init(Unit *unit);
/** Tear down the unit */
void UTPL_deInit(Unit *unit);
#endif //GEX_F072_TPL_INTERNAL_H

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define TPL_INTERNAL
#include "_tpl_internal.h"
/** Load from a binary buffer stored in Flash */
void UTPL_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
//
}
/** Write to a binary buffer for storing in Flash */
void UTPL_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 0); // version
//
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UTPL_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (false) {
//
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void UTPL_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
//
}

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#!/bin/bash
echo "Enter unit type identifier (empty to cancel):"
read x
if [ -e $x ]; then
exit;
fi
xl="${x,,}"
xu="${x^^}"
for f in *.h; do mv -- "$f" "${f//tpl/$xl}"; done
for f in *.c; do mv -- "$f" "${f//tpl/$xl}"; done
sed "s/tpl/$xl/" -i *.h
sed "s/TPL/$xu/" -i *.h
sed "s/tpl/$xl/" -i *.c
sed "s/TPL/$xu/" -i *.c
echo "Unit $xu set up completed. Removing installer.."
rm '!README.TXT'
rm $0

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GexUnits/template/unit_tpl.c
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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_tpl.h"
#define TPL_INTERNAL
#include "_tpl_internal.h"
// ------------------------------------------------------------------------
enum TplCmd_ {
//
};
/** Handle a request message */
static error_t UTPL_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command,
PayloadParser *pp)
{
switch (command) {
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/**
* Handle update-tick (if configured in init)
*
* @param unit
*/
static void UTPL_updateTick(Unit *unit)
{
//
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_TPL = {
.name = "TPL",
.description = "Template unit",
// Settings
.preInit = UTPL_preInit,
.cfgLoadBinary = UTPL_loadBinary,
.cfgWriteBinary = UTPL_writeBinary,
.cfgLoadIni = UTPL_loadIni,
.cfgWriteIni = UTPL_writeIni,
// Init
.init = UTPL_init,
.deInit = UTPL_deInit,
// Function
.handleRequest = UTPL_handleRequest,
.updateTick = UTPL_updateTick,
};

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//
// Created by MightyPork on 2017/11/25.
//
// Digital input unit; single or multiple pin read access on one port (A-F)
//
#ifndef U_TPL_H
#define U_TPL_H
#include "unit.h"
extern const UnitDriver UNIT_TPL;
// UU_ prototypes
#endif //U_TPL_H

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GexUnits/touch/_touch_api.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_touch.h"
#define TOUCH_INTERNAL
#include "_touch_internal.h"

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//
// Created by MightyPork on 2018/02/25.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_touch.h"
#define TOUCH_INTERNAL
#include "_touch_internal.h"
// discharge time in ms
#define DIS_TIME 1
static void startNextPhase(Unit *unit);
static void UTOUCH_EventReportJob(Job *job)
{
Unit *unit = job->unit;
struct priv *priv = unit->data;
uint8_t buf[8];
PayloadBuilder pb = pb_start(buf, 8, NULL);
pb_u32(&pb, pinmask_pack_32(~job->data1, priv->all_channels_mask)); // inverted and packed - all pins (pressed state)
pb_u32(&pb, pinmask_pack_32(job->data2, priv->all_channels_mask)); // trigger generating pins
assert_param(pb.ok);
EventReport er = {
.unit = unit,
.type = 0x00,
.length = 8,
.data = buf,
.timestamp = job->timestamp,
};
EventReport_Send(&er);
}
static void UTOUCH_CheckForBinaryEvents(Unit *const unit)
{
struct priv *priv = unit->data;
const uint32_t time_ms = PTIM_GetTime();
if (priv->last_done_ms == 0) {
// avoid bug with trigger on first capture
priv->last_done_ms = time_ms;
}
const uint64_t ts = PTIM_GetMicrotime();
uint32_t eventpins = 0;
const uint16_t ms_elapsed = (uint16_t) (time_ms - priv->last_done_ms);
for (uint16_t i = 0; i < 32; i++) {
const uint32_t poke = (uint32_t) (1 << i);
if (0 == (priv->all_channels_mask & poke)) continue;
if (priv->binary_thr[i] == 0) continue; // skip disabled channels
const bool isactive = (bool) (priv->binary_active_bits & poke);
const bool can_go_up = !isactive && (priv->readouts[i] > (priv->binary_thr[i] + priv->binary_hysteresis));
const bool can_go_down = isactive && (priv->readouts[i] < priv->binary_thr[i]);
if (can_go_up) {
priv->bin_trig_cnt[i] += ms_elapsed;
if (priv->bin_trig_cnt[i] >= priv->binary_debounce_ms) {
priv->binary_active_bits |= poke;
priv->bin_trig_cnt[i] = 0; // reset for the other direction of the switch
eventpins |= poke;
}
}
else if (priv->bin_trig_cnt[i] > 0) {
priv->bin_trig_cnt[i] = 0;
}
if (can_go_down) {
priv->bin_trig_cnt[i] -= ms_elapsed;
if (priv->bin_trig_cnt[i] <= -priv->binary_debounce_ms) {
priv->binary_active_bits &= ~poke;
priv->bin_trig_cnt[i] = 0; // reset for the other direction of the switch
eventpins |= poke;
}
}
else if (priv->bin_trig_cnt[i] < 0) {
priv->bin_trig_cnt[i] = 0;
}
}
if (eventpins != 0) {
Job j = {
.timestamp = ts,
.data1 = priv->binary_active_bits,
.data2 = eventpins,
.unit = unit,
.cb = UTOUCH_EventReportJob,
};
scheduleJob(&j);
}
priv->last_done_ms = time_ms;
}
void UTOUCH_HandleIrq(void *arg)
{
Unit *unit = arg;
struct priv *priv = unit->data;
if (TSC->ISR & TSC_ISR_MCEF) {
priv->status = UTSC_STATUS_FAIL;
dbg_touch("TSC Failure.");
TSC->ICR = TSC_ICR_EOAIC | TSC_ICR_MCEIC;
}
if (TSC->ISR & TSC_ISR_EOAF) {
TSC->ICR = TSC_ICR_EOAIC;
// assert_param((TSC->IOGCSR>>16) == priv->groups_phase[priv->next_phase]);
// Store captured data
const uint32_t chmask = TSC->IOCCR;
for (int i = 0; i < 32; i++) {
if (chmask & (1<<i)) {
priv->readouts[i] = (uint16_t) (TSC->IOGXCR[i >> 2] & 0x3FFF);
}
}
priv->next_phase++;
if (!priv->cfg.interlaced) {
// check if we've run out of existing or populated groups
if (priv->next_phase == 3 || priv->groups_phase[priv->next_phase] == 0) {
priv->next_phase = 0;
priv->status = UTSC_STATUS_READY;
UTOUCH_CheckForBinaryEvents(unit);
}
}
TSC->CR &= ~TSC_CR_IODEF; // pull low - discharge
}
priv->ongoing = false;
priv->discharge_delay = DIS_TIME;
}
#if TSC_DEBUG
static volatile uint32_t xcnt=0;
#endif
void UTOUCH_updateTick(Unit *unit)
{
#if TSC_DEBUG
xcnt++;
#endif
struct priv *priv = unit->data;
if (priv->ongoing) {
return;
}
if (priv->discharge_delay > 0) {
priv->discharge_delay--;
} else {
startNextPhase(unit);
}
#if TSC_DEBUG
if(xcnt >= 250) {
xcnt=0;
PRINTF("> ");
for (int i = 0; i < 32; i++) {
if (priv->all_channels_mask & (1<<i)) {
PRINTF("%d ", (int)priv->readouts[i]);
}
}
PRINTF("\r\n");
}
#endif
}
static void startNextPhase(Unit *unit)
{
struct priv *priv = unit->data;
if (priv->all_channels_mask == 0) return;
if (priv->cfg.interlaced) {
// Find the next non-zero bit, wrap around if needed
while ((priv->all_channels_mask & (1<<priv->next_phase))==0) {
priv->next_phase++;
if (priv->next_phase == 32) {
priv->next_phase = 0;
priv->status = UTSC_STATUS_READY;
UTOUCH_CheckForBinaryEvents(unit);
}
}
TSC->IOGCSR = (uint32_t) (1 << (priv->next_phase >> 2)); // phase divided by 4
TSC->IOCCR = (uint32_t) (1 << priv->next_phase);
// interlaced - float neighbouring electrodes
TSC->CR |= TSC_CR_IODEF;
} else {
TSC->IOGCSR = priv->groups_phase[priv->next_phase];
TSC->IOCCR = priv->channels_phase[priv->next_phase];
// separate - keep neighbouring electrodes at GND
}
TSC->ICR = TSC_ICR_EOAIC | TSC_ICR_MCEIC;
// Go!
priv->ongoing = true;
TSC->CR |= TSC_CR_START;
}

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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define TOUCH_INTERNAL
#include "_touch_internal.h"
/** Allocate data structure and set defaults */
error_t UTOUCH_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
priv->cfg.charge_time = 2;
priv->cfg.drain_time = 2;
priv->cfg.spread_deviation = 0;
priv->cfg.ss_presc = 1;
priv->cfg.pg_presc = 32;
priv->cfg.sense_timeout = 7;
memset(priv->cfg.group_scaps, 0, 8);
memset(priv->cfg.group_channels, 0, 8);
priv->cfg.binary_hysteresis = 10;
priv->cfg.binary_debounce_ms = 20;
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t UTOUCH_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
unit->tick_interval = 1; // sample every 1 ms
// copy from conf
priv->binary_debounce_ms = priv->cfg.binary_debounce_ms;
priv->binary_hysteresis = priv->cfg.binary_hysteresis;
TRY(rsc_claim(unit, R_TSC));
// simple bound checks, just clamp without error
if (priv->cfg.charge_time > 16) priv->cfg.charge_time = 16;
if (priv->cfg.charge_time < 1) priv->cfg.charge_time = 1;
if (priv->cfg.drain_time > 16) priv->cfg.drain_time = 16;
if (priv->cfg.drain_time < 1) priv->cfg.drain_time = 1;
if (priv->cfg.spread_deviation > 128) priv->cfg.drain_time = 128;
if (priv->cfg.ss_presc > 2) priv->cfg.ss_presc = 2;
if (priv->cfg.ss_presc < 1) priv->cfg.ss_presc = 1;
if (priv->cfg.sense_timeout > 7) priv->cfg.sense_timeout = 7;
if (priv->cfg.sense_timeout < 1) priv->cfg.sense_timeout = 1;
uint8_t tmppgpresc = priv->cfg.pg_presc;
if (tmppgpresc == 0) return E_BAD_CONFIG;
uint8_t pgpresc_reg = 0;
while ((tmppgpresc & 1) == 0 && tmppgpresc != 0) {
pgpresc_reg++;
tmppgpresc >>= 1;
}
if (tmppgpresc != 1 || pgpresc_reg > 7) {
dbg("Bad pgpresc");
return E_BAD_CONFIG; // TODO better reporting
}
if ((pgpresc_reg==0 && priv->cfg.drain_time<=2) || (pgpresc_reg==1 && priv->cfg.drain_time==0)) {
dbg("Illegal PGPSC vs CTPL");
return E_BAD_CONFIG;
}
// enable clock
hw_periph_clock_enable(TSC);
// reset
__HAL_RCC_TSC_FORCE_RESET();
__HAL_RCC_TSC_RELEASE_RESET();
priv->all_channels_mask = 0;
for (int gi = 0; gi < 8; gi++) {
const uint8_t cap = priv->cfg.group_scaps[gi];
const uint8_t ch = priv->cfg.group_channels[gi];
if (cap == 0) {
if (ch != 0) {
dbg_touch("TSC group %d has no cap!", (int) (gi + 1));
return E_BAD_CONFIG;
}
continue;
}
if (ch == 0) continue; // if no channels, don't bother setting up anything
if (cap != 2 && cap != 4 && cap != 8 && cap != 16) {
dbg_touch("TSC group %d has more than 1 cap!", (int) (gi + 1));
return E_BAD_CONFIG;
}
if (cap & ch) {
dbg_touch("TSC pin can't be both channel and cap! (gpr %d)", (int) (gi + 1));
return E_BAD_CONFIG;
}
// This is a loop through the pins in a group gi
int phasenum = 0;
for (int pi = 0; pi < 4; pi++) {
// pin numbers are 1-based in the config
const bool iscap = 0 != (cap & (2 << pi));
const bool isch = 0 != (ch & (2 << pi));
if (!iscap && !isch) continue;
Resource r = utouch_group_rscs[gi][pi];
TRY(rsc_claim(unit, r));
GPIO_TypeDef *port;
uint32_t ll;
assert_param(hw_pinrsc2ll(r, &port, &ll));
LL_GPIO_SetPinOutputType(port, ll, isch ? LL_GPIO_OUTPUT_PUSHPULL : LL_GPIO_OUTPUT_OPENDRAIN);
// 7 and 8 (1-based) use AF1, else AF3
TRY(hw_configure_gpiorsc_af(r, gi >= 6 ? LL_GPIO_AF_1 : LL_GPIO_AF_3));
uint32_t bit = (uint32_t) (1 << (gi * 4 + pi));
if (iscap) {
dbg_touch("TSC cap @ %s", rsc_get_name(r));
// Sampling cap
TSC->IOSCR |= bit;
// Disable pin hysteresis (causes noise)
TSC->IOHCR ^= bit;
}
else {
dbg_touch("TSC ch @ %s", rsc_get_name(r));
if (priv->cfg.interlaced) {
// interlaced - only update the mask beforehand
priv->all_channels_mask |= bit;
} else {
// channels are configured individually when read.
// we prepare bitmaps to use for the read groups (all can be read in at most 3 steps)
priv->channels_phase[phasenum] |= bit; // this is used for the channel selection register
priv->groups_phase[phasenum] |= 1 << gi; // this will be used for the group enable register, if all 0, this and any following phases are unused.
phasenum++;
}
}
}
}
// common TSC config
TSC->CR =
((priv->cfg.charge_time - 1) << TSC_CR_CTPH_Pos) |
((priv->cfg.drain_time - 1) << TSC_CR_CTPL_Pos) |
((priv->cfg.ss_presc - 1) << TSC_CR_SSPSC_Pos) |
(pgpresc_reg << TSC_CR_PGPSC_Pos) |
((priv->cfg.sense_timeout - 1) << TSC_CR_MCV_Pos) |
TSC_CR_TSCE;
if (priv->cfg.spread_deviation > 0) {
TSC->CR |= ((priv->cfg.spread_deviation - 1) << TSC_CR_SSD_Pos) | TSC_CR_SSE;
}
dbg_touch("CR = %08x, ht is %d, lt is %d", (int)TSC->CR,
(int)priv->cfg.charge_time,
(int)priv->cfg.drain_time);
// iofloat is used for discharging
// Enable the interrupts
TSC->IER = TSC_IER_EOAIE | TSC_IER_MCEIE;
irqd_attach(TSC, UTOUCH_HandleIrq, unit);
if (!priv->cfg.interlaced) {
dbg_touch("TSC phases:");
for (int i = 0; i < 3; i++) {
priv->all_channels_mask |= priv->channels_phase[i];
dbg_touch(" %d: ch %08"PRIx32", g %02"PRIx32,
i + 1,
priv->channels_phase[i],
(uint32_t) priv->groups_phase[i]);
}
}
priv->status = UTSC_STATUS_BUSY; // first loop ...
priv->next_phase = 0;
// starts in the tick callback
return E_SUCCESS;
}
/** Tear down the unit */
void UTOUCH_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// de-init peripherals
if (unit->status == E_SUCCESS) {
hw_periph_clock_disable(TSC);
// clear all registers to their default values
__HAL_RCC_TSC_FORCE_RESET();
__HAL_RCC_TSC_RELEASE_RESET();
irqd_detach(TSC, UTOUCH_HandleIrq);
}
// Release all resources, deinit pins
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
}

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//
// Created by MightyPork on 2018/02/03.
//
#ifndef GEX_F072_TOUCH_INTERNAL_H
#define GEX_F072_TOUCH_INTERNAL_H
#ifndef TOUCH_INTERNAL
#error bad include!
#endif
#include "unit_base.h"
#define TSC_DEBUG 0
#if TSC_DEBUG
#define dbg_touch(f,...) dbg(f,##__VA_ARGS__)
#else
#define dbg_touch(f,...) do{}while(0)
#endif
enum utsc_status {
UTSC_STATUS_BUSY = 0,
UTSC_STATUS_READY = 1,
UTSC_STATUS_FAIL = 2
};
/** Private data structure */
struct priv {
// settings
struct {
uint8_t charge_time; // 1-16 -> 0..15
uint8_t drain_time; // 1-16 -> 0..15
uint8_t spread_deviation; // 1-128, 0=off ... 0-127, 0 sets 0 to SSE
uint8_t ss_presc; // 1-2 -> 0..1
uint8_t pg_presc; // 1,2,4,8,16,32,64,128 -> 0..7 when writing to the periph
uint8_t sense_timeout; // 1-7 -> 0..6 hex when writing to the periph
// the schmitts must be disabled on all used channels, restored to 0xFFFF on deinit
uint8_t group_scaps[8];
uint8_t group_channels[8];
bool interlaced;
uint16_t binary_debounce_ms;
uint16_t binary_hysteresis;
} cfg;
uint8_t next_phase;
uint8_t discharge_delay;
uint32_t channels_phase[3];
uint8_t groups_phase[3];
uint16_t readouts[32];
int16_t bin_trig_cnt[32];
uint16_t binary_debounce_ms;
uint16_t binary_hysteresis;
uint16_t binary_thr[32];
uint32_t binary_active_bits;
uint32_t all_channels_mask;
uint32_t last_done_ms;
bool ongoing;
enum utsc_status status;
} __attribute__((packed));
extern const char *utouch_group_labels[8];
extern const Resource utouch_group_rscs[8][4];
/** Allocate data structure and set defaults */
error_t UTOUCH_preInit(Unit *unit);
/** Load from a binary buffer stored in Flash */
void UTOUCH_loadBinary(Unit *unit, PayloadParser *pp);
/** Write to a binary buffer for storing in Flash */
void UTOUCH_writeBinary(Unit *unit, PayloadBuilder *pb);
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UTOUCH_loadIni(Unit *unit, const char *key, const char *value);
/** Generate INI file section for the unit */
void UTOUCH_writeIni(Unit *unit, IniWriter *iw);
// ------------------------------------------------------------------------
/** Finalize unit set-up */
error_t UTOUCH_init(Unit *unit);
/** Tear down the unit */
void UTOUCH_deInit(Unit *unit);
void UTOUCH_updateTick(Unit *unit);
void UTOUCH_HandleIrq(void *arg);
#endif //GEX_F072_TOUCH_INTERNAL_H

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GexUnits/touch/_touch_settings.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#define TOUCH_INTERNAL
#include "_touch_internal.h"
const char *utouch_group_labels[8] = {
"1:A0, 2:A1, 3:A2, 4:A3",
"1:A4, 2:A5, 3:A6, 4:A7",
"1:C5, 2:B0, 3:B1, 4:B2",
"1:A9, 2:A10, 3:A11, 4:A12",
"1:B3, 2:B4, 3:B6, 4:B7",
"1:B11, 2:B12, 3:B13, 4:B14",
"1:E2, 2:E3, 3:E4, 4:E5",
"1:D12, 2:D13, 3:D14, 4:D15",
};
const Resource utouch_group_rscs[8][4] = {
{R_PA0, R_PA1, R_PA2, R_PA3},
{R_PA4, R_PA5, R_PA6, R_PA7},
{R_PC5, R_PB0, R_PB1, R_PB2},
{R_PA9, R_PA10, R_PA11, R_PA12},
{R_PB3, R_PB4, R_PB6, R_PB7},
{R_PB11, R_PB12, R_PB13, R_PB14},
{R_PE2, R_PE3, R_PE4, R_PE5},
{R_PD12, R_PD13, R_PD14, R_PD15},
};
/** Load from a binary buffer stored in Flash */
void UTOUCH_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->cfg.charge_time = pp_u8(pp);
priv->cfg.drain_time = pp_u8(pp);
priv->cfg.spread_deviation = pp_u8(pp);
priv->cfg.ss_presc = pp_u8(pp);
priv->cfg.pg_presc = pp_u8(pp);
priv->cfg.sense_timeout = pp_u8(pp);
pp_buf(pp, priv->cfg.group_scaps, 8);
pp_buf(pp, priv->cfg.group_channels, 8);
if (version >= 1) {
priv->cfg.interlaced = pp_bool(pp);
}
if (version >= 2) {
priv->cfg.binary_debounce_ms = pp_u16(pp);
priv->cfg.binary_hysteresis = pp_u16(pp);
}
}
/** Write to a binary buffer for storing in Flash */
void UTOUCH_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 2); // version
pb_u8(pb, priv->cfg.charge_time);
pb_u8(pb, priv->cfg.drain_time);
pb_u8(pb, priv->cfg.spread_deviation);
pb_u8(pb, priv->cfg.ss_presc);
pb_u8(pb, priv->cfg.pg_presc);
pb_u8(pb, priv->cfg.sense_timeout);
pb_buf(pb, priv->cfg.group_scaps, 8);
pb_buf(pb, priv->cfg.group_channels, 8);
pb_bool(pb, priv->cfg.interlaced);
pb_u16(pb, priv->cfg.binary_debounce_ms);
pb_u16(pb, priv->cfg.binary_hysteresis);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
error_t UTOUCH_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "charge-time")) {
priv->cfg.charge_time = cfg_u8_parse(value, &suc);
}
else if (streq(key, "drain-time")) {
priv->cfg.drain_time = cfg_u8_parse(value, &suc);
}
else if (streq(key, "ss-deviation")) {
priv->cfg.spread_deviation = cfg_u8_parse(value, &suc);
}
else if (streq(key, "ss-clock-prediv")) {
priv->cfg.ss_presc = cfg_u8_parse(value, &suc);
}
else if (streq(key, "pg-clock-prediv")) {
priv->cfg.pg_presc = cfg_u8_parse(value, &suc);
}
else if (streq(key, "sense-timeout")) {
priv->cfg.sense_timeout = cfg_u8_parse(value, &suc);
}
else if (streq(key, "interlaced-pads")) {
priv->cfg.interlaced = cfg_bool_parse(value, &suc);
}
else if (streq(key, "btn-debounce")) {
priv->cfg.binary_debounce_ms = cfg_u16_parse(value, &suc);
}
else if (streq(key, "btn-hysteresis")) {
priv->cfg.binary_hysteresis = cfg_u16_parse(value, &suc);
}
else {
volatile char namebuf[10]; // must be volatile or gcc optimizes out the second compare and fucks it up
for (int i = 0; i < 6; i++) { // skip 7,8
SPRINTF(namebuf, "g%d_cap", i+1);
if (streq(key, namebuf)) {
priv->cfg.group_scaps[i] = (uint8_t) cfg_pinmask_parse(value, &suc);
goto matched;
}
SPRINTF(namebuf, "g%d_ch", i+1);
if (streq(key, namebuf)) {
priv->cfg.group_channels[i] = (uint8_t) cfg_pinmask_parse(value, &suc);
goto matched;
}
}
return E_BAD_KEY;
}
matched:
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
void UTOUCH_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "This unit utilizes the touch sensing controller.");
iw_comment(iw, "See the reference manual for details about its function.");
iw_cmt_newline(iw);
iw_comment(iw, "Pulse generator clock prescaller (1,2,4,...,128)");
iw_entry_d(iw, "pg-clock-prediv", priv->cfg.pg_presc);
iw_comment(iw, "Sense pad charging time (1-16)");
iw_entry_d(iw, "charge-time", priv->cfg.charge_time);
iw_comment(iw, "Charge transfer time (1-16)");
iw_entry_d(iw, "drain-time", priv->cfg.drain_time);
iw_comment(iw, "Measurement timeout (1-7)");
iw_entry_d(iw, "sense-timeout", priv->cfg.sense_timeout);
iw_cmt_newline(iw);
iw_comment(iw, "Spread spectrum max deviation (0-128,0=off)");
iw_entry_d(iw, "ss-deviation", priv->cfg.spread_deviation);
iw_comment(iw, "Spreading clock prescaller (1,2)");
iw_entry_d(iw, "ss-clock-prediv", priv->cfg.ss_presc);
iw_cmt_newline(iw);
iw_comment(iw, "Optimize for interlaced pads (individual sampling with others floating)");
iw_entry_s(iw, "interlaced-pads", str_yn(priv->cfg.interlaced));
iw_cmt_newline(iw);
iw_comment(iw, "Button mode debounce (ms) and release hysteresis (lsb)");
iw_entry_d(iw, "btn-debounce", priv->cfg.binary_debounce_ms);
iw_entry_d(iw, "btn-hysteresis", priv->cfg.binary_hysteresis);
iw_cmt_newline(iw);
iw_comment(iw, "Each used group must have 1 sampling capacitor and 1-3 channels.");
iw_comment(iw, "Channels are numbered 1,2,3,4");
iw_cmt_newline(iw);
char namebuf[10];
for (int i = 0; i < 6; i++) { // skip 7,8
iw_commentf(iw, "Group%d - %s", i+1, utouch_group_labels[i]);
SPRINTF(namebuf, "g%d_cap", i+1);
iw_entry_s(iw, namebuf, cfg_pinmask_encode(priv->cfg.group_scaps[i], unit_tmp512, true));
SPRINTF(namebuf, "g%d_ch", i+1);
iw_entry_s(iw, namebuf, cfg_pinmask_encode(priv->cfg.group_channels[i], unit_tmp512, true));
}
}

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GexUnits/touch/unit_touch.c
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//
// Created by MightyPork on 2017/11/25.
//
#include "unit_base.h"
#include "unit_touch.h"
#define TOUCH_INTERNAL
#include "_touch_internal.h"
// ------------------------------------------------------------------------
enum TouchCmd_ {
CMD_READ=0,
CMD_SET_BIN_THR=1,
CMD_DISABLE_ALL_REPORTS=2,
CMD_SET_DEBOUNCE_TIME=3,
CMD_SET_HYSTERESIS=4,
CMD_GET_CH_COUNT=10,
};
/** Handle a request message */
static error_t UTOUCH_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
struct priv* priv = unit->data;
PayloadBuilder pb = pb_start(unit_tmp512, UNIT_TMP_LEN, NULL);
switch (command) {
/**
* read the current touch pad values (smaller = higher capacity)
*
* resp: a list of u16 (order: group and pin, ascending)
*/
case CMD_READ:
if (priv->status == UTSC_STATUS_BUSY) return E_BUSY;
if (priv->status == UTSC_STATUS_FAIL) return E_HW_TIMEOUT;
for (int i = 0; i < 32; i++) {
if (priv->all_channels_mask & (1<<i)) {
pb_u16(&pb, priv->readouts[i]);
}
}
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
/**
* Set thresholds for the button mode.
*
* pld: a list of u16 for the enabled channels (order: group and pin, ascending)
*/
case CMD_SET_BIN_THR:
for (int i = 0; i < 32; i++) {
if (priv->all_channels_mask & (1<<i)) {
priv->bin_trig_cnt[i] = 0;
priv->binary_thr[i] = pp_u16(pp);
if (priv->readouts[i] >= (priv->binary_thr[i] + priv->binary_hysteresis)) {
priv->binary_active_bits |= 1<<i;
}
}
}
return E_SUCCESS;
/**
* Set the debounce time in ms (replaces the default value from settings)
*
* pld: ms:u16
*/
case CMD_SET_DEBOUNCE_TIME:
priv->binary_debounce_ms = pp_u16(pp);
return E_SUCCESS;
/**
* Set hysteresis (replaces the default value from settings)
*
* Hysteresis is added to the threshold value for the switch-off level
* (switch-off happens when the measured value is exceeded - capacity of the pad drops)
*
* pld: hyst:u16
*/
case CMD_SET_HYSTERESIS:
priv->binary_hysteresis = pp_u16(pp);
return E_SUCCESS;
/**
* Disable button mode reports. This effectively sets all thresholds to 0, disabling checking.
*/
case CMD_DISABLE_ALL_REPORTS:
for (int i = 0; i < 32; i++) {
if (priv->all_channels_mask & (1<<i)) {
priv->binary_thr[i] = 0;
priv->bin_trig_cnt[i] = 0;
}
}
priv->binary_active_bits = 0;
return E_SUCCESS;
/**
* Get the number of configured touch pad channels
*
* resp: count:u8
*/
case CMD_GET_CH_COUNT:;
uint8_t nb = 0;
for (int i = 0; i < 32; i++) {
if (priv->all_channels_mask & (1<<i)) {
nb++;
}
}
pb_u8(&pb, nb);
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_TOUCH = {
.name = "TOUCH",
.description = "Capacitive touch sensing",
// Settings
.preInit = UTOUCH_preInit,
.cfgLoadBinary = UTOUCH_loadBinary,
.cfgWriteBinary = UTOUCH_writeBinary,
.cfgLoadIni = UTOUCH_loadIni,
.cfgWriteIni = UTOUCH_writeIni,
// Init
.init = UTOUCH_init,
.deInit = UTOUCH_deInit,
// Function
.handleRequest = UTOUCH_handleRequest,
.updateTick = UTOUCH_updateTick,
};

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GexUnits/touch/unit_touch.h
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//
// Created by MightyPork on 2017/11/25.
//
// Digital input unit; single or multiple pin read access on one port (A-F)
//
#ifndef U_TOUCH_H
#define U_TOUCH_H
#include "unit.h"
extern const UnitDriver UNIT_TOUCH;
// UU_ prototypes
#endif //U_TOUCH_H

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GexUnits/units_manifest.h
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// This is a GEX units manifest file
// For a unit to be included in the firmware, its uppercase name
// must be included in the GEX_UNITS list in build.mk, and it must have
// an entry here.
#ifdef ENABLE_UNIT_1WIRE
#include "1wire/unit_1wire.h"
#endif
#ifdef ENABLE_UNIT_ADC
#include "adc/unit_adc.h"
#endif
#ifdef ENABLE_UNIT_DAC
#include "dac/unit_dac.h"
#endif
#ifdef ENABLE_UNIT_DIN
#include "din/unit_din.h"
#endif
#ifdef ENABLE_UNIT_DOUT
#include "dout/unit_dout.h"
#endif
#ifdef ENABLE_UNIT_FCAP
#include "fcap/unit_fcap.h"
#endif
#ifdef ENABLE_UNIT_I2C
#include "i2c/unit_i2c.h"
#endif
#ifdef ENABLE_UNIT_NEOPIXEL
#include "neopixel/unit_neopixel.h"
#endif
#ifdef ENABLE_UNIT_PWMDIM
#include "pwmdim/unit_pwmdim.h"
#endif
#ifdef ENABLE_UNIT_SIPO
#include "sipo/unit_sipo.h"
#endif
#ifdef ENABLE_UNIT_SPI
#include "spi/unit_spi.h"
#endif
#ifdef ENABLE_UNIT_TOUCH
#include "touch/unit_touch.h"
#endif
#ifdef ENABLE_UNIT_USART
#include "usart/unit_usart.h"
#endif

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GexUnits/usart/_usart_api.c
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//
// Created by MightyPork on 2018/02/03.
//
#include "platform.h"
#include "unit_base.h"
#include "unit_usart.h"
#define UUSART_INTERNAL
#include "_usart_internal.h"
error_t UU_USART_Write(Unit *unit, const uint8_t *buffer, uint32_t len)
{
CHECK_TYPE(unit, &UNIT_USART);
struct priv *priv = unit->data;
uint32_t t_start = HAL_GetTick();
while (len > 0) {
// this should be long enough even for the slowest bitrates and 512 bytes
if (HAL_GetTick() - t_start > 5000) {
return E_HW_TIMEOUT;
}
uint16_t chunk = UUSART_DMA_TxQueue(priv, buffer, (uint16_t) len);
buffer += chunk;
len -= chunk;
// We give up control if there's another thread waiting and this isn't the last cycle
if (len > 0) {
osThreadYield();
}
}
return E_SUCCESS;
}
error_t UU_USART_WriteSync(Unit *unit, const uint8_t *buffer, uint32_t len)
{
CHECK_TYPE(unit, &UNIT_USART);
struct priv *priv = unit->data;
TRY(UU_USART_Write(unit, buffer, len));
// Now wait for the last DMA to complete
uint32_t t_start = HAL_GetTick();
while (priv->tx_dma_busy) {
if (HAL_GetTick() - t_start > 1000) {
return E_HW_TIMEOUT;
}
}
return E_SUCCESS;
}

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GexUnits/usart/_usart_dmas.c
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//
// Created by MightyPork on 2018/01/14.
//
#include "platform.h"
#include "irq_dispatcher.h"
#include "unit_base.h"
#define UUSART_INTERNAL
#include "_usart_internal.h"
static void UUSART_DMA_RxHandler(void *arg);
static void UUSART_DMA_TxHandler(void *arg);
#if UUSART_DEBUG
#define dbg_uusart(fmt, ...) dbg(fmt, ##__VA_ARGS__)
#else
#define dbg_uusart(fmt, ...)
#endif
error_t UUSART_ClaimDMAs(Unit *unit)
{
error_t rv;
assert_param(unit);
struct priv *priv = unit->data;
assert_param(priv);
priv->dma = DMA1;
switch (priv->periph_num) {
/* USART1 */
case 1:
// TX
rv = rsc_claim(unit, R_DMA1_2);
if (rv == E_SUCCESS) {
LL_SYSCFG_SetRemapDMA_USART(LL_SYSCFG_USART1TX_RMP_DMA1CH2);
priv->dma_tx = DMA1_Channel2;
priv->dma_tx_chnum = 2;
} else {
// try the remap
TRY(rsc_claim(unit, R_DMA1_4));
LL_SYSCFG_SetRemapDMA_USART(LL_SYSCFG_USART1TX_RMP_DMA1CH4);
priv->dma_tx = DMA1_Channel4;
priv->dma_tx_chnum = 4;
}
// RX
rv = rsc_claim(unit, R_DMA1_3);
if (rv == E_SUCCESS) {
LL_SYSCFG_SetRemapDMA_USART(LL_SYSCFG_USART1RX_RMP_DMA1CH3);
priv->dma_rx = DMA1_Channel3;
priv->dma_rx_chnum = 3;
} else {
// try the remap
TRY(rsc_claim(unit, R_DMA1_5));
LL_SYSCFG_SetRemapDMA_USART(LL_SYSCFG_USART1RX_RMP_DMA1CH5);
priv->dma_rx = DMA1_Channel5;
priv->dma_rx_chnum = 5;
}
break;
/* USART2 */
case 2:
// RX,TX
rv = rsc_claim_range(unit, R_DMA1_4, R_DMA1_5);
if (rv == E_SUCCESS) {
LL_SYSCFG_SetRemapDMA_USART(LL_SYSCFG_USART2_RMP_DMA1CH54);
priv->dma_tx = DMA1_Channel4;
priv->dma_rx = DMA1_Channel5;
priv->dma_tx_chnum = 4;
priv->dma_rx_chnum = 5;
} else {
// try the remap
TRY(rsc_claim_range(unit, R_DMA1_6, R_DMA1_7));
LL_SYSCFG_SetRemapDMA_USART(LL_SYSCFG_USART2_RMP_DMA1CH67);
priv->dma_tx = DMA1_Channel7;
priv->dma_rx = DMA1_Channel6;
priv->dma_tx_chnum = 7;
priv->dma_rx_chnum = 6;
}
break;
/* USART3 */
case 3:
// RX,TX
rv = rsc_claim_range(unit, R_DMA1_6, R_DMA1_7);
if (rv == E_SUCCESS) {
LL_SYSCFG_SetRemapDMA_USART(LL_SYSCFG_USART3_RMP_DMA1CH67);
priv->dma_tx = DMA1_Channel7;
priv->dma_rx = DMA1_Channel6;
priv->dma_tx_chnum = 7;
priv->dma_rx_chnum = 6;
} else {
// try the remap
TRY(rsc_claim_range(unit, R_DMA1_2, R_DMA1_3));
LL_SYSCFG_SetRemapDMA_USART(LL_SYSCFG_USART3_RMP_DMA1CH32);
priv->dma_tx = DMA1_Channel2;
priv->dma_rx = DMA1_Channel3;
priv->dma_tx_chnum = 2;
priv->dma_rx_chnum = 3;
}
break;
/* USART4 */
case 4:
// RX,TX
TRY(rsc_claim_range(unit, R_DMA1_6, R_DMA1_7));
priv->dma_tx = DMA1_Channel7;
priv->dma_rx = DMA1_Channel6;
priv->dma_tx_chnum = 7;
priv->dma_rx_chnum = 6;
break;
default:
trap("Missing DMA mapping for USART%d", (int)priv->periph_num);
}
dbg_uusart("USART %d - selected DMA ch Tx(%d), Rx(%d)", priv->periph_num, priv->dma_tx_chnum, priv->dma_rx_chnum);
return E_SUCCESS;
}
error_t UUSART_SetupDMAs(Unit *unit)
{
assert_param(unit);
struct priv *priv = unit->data;
assert_param(priv);
priv->rx_buffer = malloc_ck(UUSART_RXBUF_LEN);
if (NULL == priv->rx_buffer) return E_OUT_OF_MEM;
priv->tx_buffer = malloc_ck(UUSART_TXBUF_LEN);
if (NULL == priv->tx_buffer) return E_OUT_OF_MEM;
// Those must be aligned to a word boundary for the DMAs to work.
// Any well-behaved malloc impl should do this correctly.
assert_param(((uint32_t)priv->rx_buffer & 3) == 0);
assert_param(((uint32_t)priv->tx_buffer & 3) == 0);
priv->rx_buf_readpos = 0;
LL_DMA_InitTypeDef init;
// Transmit buffer
{
LL_DMA_StructInit(&init);
init.Direction = LL_DMA_DIRECTION_MEMORY_TO_PERIPH;
init.Mode = LL_DMA_MODE_NORMAL;
init.PeriphOrM2MSrcAddress = (uint32_t) &priv->periph->TDR;
init.PeriphOrM2MSrcDataSize = LL_DMA_PDATAALIGN_BYTE;
init.PeriphOrM2MSrcIncMode = LL_DMA_PERIPH_NOINCREMENT;
init.MemoryOrM2MDstAddress = (uint32_t) priv->tx_buffer;
init.MemoryOrM2MDstDataSize = LL_DMA_MDATAALIGN_BYTE;
init.MemoryOrM2MDstIncMode = LL_DMA_MEMORY_INCREMENT;
assert_param(SUCCESS == LL_DMA_Init(priv->dma, priv->dma_tx_chnum, &init));
irqd_attach(priv->dma_tx, UUSART_DMA_TxHandler, unit);
// Interrupt on transfer complete
LL_DMA_EnableIT_TC(priv->dma, priv->dma_tx_chnum);
}
// Receive buffer
{
LL_DMA_StructInit(&init);
init.Direction = LL_DMA_DIRECTION_PERIPH_TO_MEMORY;
init.Mode = LL_DMA_MODE_CIRCULAR;
init.NbData = UUSART_RXBUF_LEN;
init.PeriphOrM2MSrcAddress = (uint32_t) &priv->periph->RDR;
init.PeriphOrM2MSrcDataSize = LL_DMA_PDATAALIGN_BYTE;
init.PeriphOrM2MSrcIncMode = LL_DMA_PERIPH_NOINCREMENT;
init.MemoryOrM2MDstAddress = (uint32_t) priv->rx_buffer;
init.MemoryOrM2MDstDataSize = LL_DMA_MDATAALIGN_BYTE;
init.MemoryOrM2MDstIncMode = LL_DMA_MEMORY_INCREMENT;
assert_param(SUCCESS == LL_DMA_Init(priv->dma, priv->dma_rx_chnum, &init));
irqd_attach(priv->dma_rx, UUSART_DMA_RxHandler, unit);
// Interrupt on transfer 1/2 and complete
// We will capture the first and second half and send it while the other half is being filled.
LL_DMA_EnableIT_HT(priv->dma, priv->dma_rx_chnum);
LL_DMA_EnableIT_TC(priv->dma, priv->dma_rx_chnum);
}
LL_DMA_EnableChannel(priv->dma, priv->dma_rx_chnum);
LL_DMA_EnableChannel(priv->dma, priv->dma_tx_chnum);
return E_SUCCESS;
}
/**
* Handler for the Rx DMA half or full interrupt
* @param arg - unit instance
*/
static void UUSART_DMA_RxHandler(void *arg)
{
Unit *unit = arg;
assert_param(unit);
struct priv *priv = unit->data;
assert_param(priv);
const uint32_t isrsnapshot = priv->dma->ISR;
if (LL_DMA_IsActiveFlag_G(isrsnapshot, priv->dma_rx_chnum)) {
bool tc = LL_DMA_IsActiveFlag_TC(isrsnapshot, priv->dma_rx_chnum);
bool ht = LL_DMA_IsActiveFlag_HT(isrsnapshot, priv->dma_rx_chnum);
// Here we have to either copy it somewhere else, or notify another thread (queue?)
// that the data is ready for reading
if (ht) {
uint16_t end = (uint16_t) UUSART_RXBUF_LEN / 2;
UUSART_DMA_HandleRxFromIRQ(unit, end);
LL_DMA_ClearFlag_HT(priv->dma, priv->dma_rx_chnum);
}
if (tc) {
uint16_t end = (uint16_t) UUSART_RXBUF_LEN;
UUSART_DMA_HandleRxFromIRQ(unit, end);
LL_DMA_ClearFlag_TC(priv->dma, priv->dma_rx_chnum);
}
if (LL_DMA_IsActiveFlag_TE(isrsnapshot, priv->dma_rx_chnum)) {
// this shouldn't happen
dbg("USART DMA TE!");
LL_DMA_ClearFlag_TE(priv->dma, priv->dma_rx_chnum);
}
}
}
/**
* Start sending a chunk of data.
* This must be called when the DMA is completed.
*
* @param priv
*/
static void UUSART_DMA_TxStart(struct priv *priv)
{
priv->tx_dma_busy = true;
assert_param(priv->dma_tx->CNDTR == 0);
dbg_uusart("DMA_TxStart (nr %d, nw %d)", (int)priv->tx_buf_nr, (int)priv->tx_buf_nw);
uint16_t nr = priv->tx_buf_nr;
uint16_t nw = priv->tx_buf_nw;
if (nr == nw) {
dbg_uusart("remain=0,do nothing");
return;
} // do nothing if we're done
uint8_t chunk = priv->tx_buffer[nr++];
//nr += (uint16_t) (4 - (nr & 0b11));
if (chunk == 0) {
// wrap-around
chunk = priv->tx_buffer[0];
nr = 1;
assert_param(nr < nw);
}
// nr was advanced by the lpad preamble
priv->tx_buf_nr = nr;
priv->tx_buf_chunk = chunk; // will be further moved by 'chunk' bytes when dma completes
dbg_uusart("# TX: chunk start %d, len %d", (int)nr, (int)chunk);
//#if UUSART_DEBUG
// PUTS(">"); PUTSN((char *) (priv->tx_buffer + nr), chunk); PUTS("<");
// PUTNL();
//#endif
LL_DMA_DisableChannel(priv->dma, priv->dma_tx_chnum);
{
LL_DMA_ClearFlags(priv->dma, priv->dma_tx_chnum);
LL_DMA_SetMemoryAddress(priv->dma, priv->dma_tx_chnum, (uint32_t) (priv->tx_buffer + nr));
LL_DMA_SetDataLength(priv->dma, priv->dma_tx_chnum, chunk);
LL_USART_ClearFlag_TC(priv->periph);
}
LL_DMA_EnableChannel(priv->dma, priv->dma_tx_chnum);
}
COMPILER_ASSERT(UUSART_TXBUF_LEN <= 256); // more would break the "len tag" algorithm
/**
* Put data on the queue. Only a part may be sent due to a buffer size limit.
*
* @param priv
* @param buffer - buffer to send
* @param len - buffer size
* @return number of bytes that were really written (from the beginning)
*/
uint16_t UUSART_DMA_TxQueue(struct priv *priv, const uint8_t *buffer, uint16_t len)
{
const uint16_t nr = priv->tx_buf_nr;
uint16_t nw = priv->tx_buf_nw;
// shortcut for checking a completely full buffer
if (nw == nr-1 || (nr==0&&nw==UUSART_TXBUF_LEN-1)) {
dbg_uusart("Buffer full, cant queue");
return 0;
}
dbg_uusart("\r\nQueue..");
uint16_t used = 0;
if (nr == nw) {
used = 0;
} else if (nw > nr) { // simple linear
used = (uint16_t) (nw - nr);
} else if (nw < nr) { // wrapped
used = (uint16_t) ((UUSART_TXBUF_LEN - nr) + nw);
}
dbg_uusart("Trying to send buffer of len %d", (int)len);
uint16_t avail = (const uint16_t) (UUSART_TXBUF_LEN - 1 - used);
dbg_uusart("nr %d, nw %d, used %d, avail %d", (int)nr, (int)nw, (int)used, (int)avail);
// hack to avoid too large chunks (we use 1 byte to store chunk size)
if (avail > 255) avail = 255;
uint8_t written = 0;
// this avoids attempting to write if we don't have space
if (avail <= 5) {
dbg_uusart("No space (only %d)", (int) avail);
return written;
}
int cnt = 0;
while (avail > 0 && written < len) {
assert_param(cnt < 2); // if more than two, we have a bug and it's repeating infinitely
cnt++;
// Padding with chunk information (1 byte: length) - for each chunk
const uint8_t lpad = 1;
// Chunk can go max to the end of the buffer
uint8_t chunk = (uint8_t) MIN((len-written) + lpad, UUSART_TXBUF_LEN - nw);
if (chunk > avail) chunk = (uint8_t) avail;
dbg_uusart("nw %d, raw available chunk %d", (int) nw, (int)chunk);
if (chunk < lpad + 1) {
// write 0 to indicate a wrap-around
dbg_uusart("Wrap-around marker at offset %d", (int) nw);
priv->tx_buffer[nw] = 0;
nw = 0;
}
else {
// enough space for a preamble + some data
dbg_uusart("Preamble of %d bytes at offset %d", (int) lpad, (int) nw);
priv->tx_buffer[nw] = (uint8_t) (chunk - lpad);
nw += lpad;
uint8_t datachunk = (uint8_t) (chunk - lpad);
dbg_uusart("Datachunk len %d at offset %d", (int) datachunk, (int) nw);
//#if UUSART_DEBUG
// PUTS("mcpy src >"); PUTSN((char *) (buffer), datachunk); PUTS("<\r\n");
//#endif
memcpy((uint8_t *) (priv->tx_buffer + nw), buffer, datachunk);
//#if UUSART_DEBUG
// PUTS("mcpy dst >"); PUTSN((char *) (priv->tx_buffer + nw), datachunk); PUTS("<\r\n");
//#endif
buffer += datachunk;
nw += datachunk;
written += datachunk;
if (nw == UUSART_TXBUF_LEN) nw = 0;
}
avail -= chunk;
dbg_uusart(". end of loop, avail is %d", (int)avail);
}
{
dbg_uusart("Write done -> nr %d, nw %d", (int) nr, (int) nw);
// FIXME a potential race condition can happen here (but it's unlikely)
priv->tx_buf_nw = nw;
if (!priv->tx_dma_busy) {
dbg_uusart("Write done, requesting DMA.");
UUSART_DMA_TxStart(priv);
}
else {
dbg_uusart("DMA in progress, not requesting");
}
}
return written;
}
/**
* Handler for the Tx DMA - completion interrupt
* @param arg - unit instance
*/
static void UUSART_DMA_TxHandler(void *arg)
{
Unit *unit = arg;
assert_param(unit);
struct priv *priv = unit->data;
assert_param(priv);
uint32_t isrsnapshot = priv->dma->ISR;
if (LL_DMA_IsActiveFlag_TC(isrsnapshot, priv->dma_tx_chnum)) {
// chunk Tx is finished
dbg_uusart("~ DMA tx done, nr %d, nw %d, chunk %d", (int)priv->tx_buf_nr, (int)priv->tx_buf_nw, (int)priv->tx_buf_chunk);
priv->tx_buf_nr += priv->tx_buf_chunk;
if (UUSART_TXBUF_LEN == priv->tx_buf_nr) priv->tx_buf_nr = 0;
priv->tx_buf_chunk = 0;
LL_DMA_ClearFlag_TC(priv->dma, priv->dma_tx_chnum);
// Wait for TC
while (!LL_USART_IsActiveFlag_TC(priv->periph)); // TODO timeout
// start the next chunk
if (priv->tx_buf_nr != priv->tx_buf_nw) {
dbg_uusart(" Asking for more, if any");
UUSART_DMA_TxStart(priv);
} else {
priv->tx_dma_busy = false;
}
}
}
void UUSART_DeInitDMAs(Unit *unit)
{
assert_param(unit);
struct priv *priv = unit->data;
assert_param(priv);
irqd_detach(priv->dma_tx, UUSART_DMA_TxHandler);
irqd_detach(priv->dma_rx, UUSART_DMA_RxHandler);
LL_DMA_DeInit(priv->dma, priv->dma_rx_chnum);
LL_DMA_DeInit(priv->dma, priv->dma_tx_chnum);
free_ck(priv->rx_buffer);
free_ck(priv->tx_buffer);
}

344
GexUnits/usart/_usart_init.c
Unescape View File

@ -1,344 +0,0 @@
//
// Created by MightyPork on 2018/01/14.
//
#include "platform.h"
#include "unit_base.h"
#define UUSART_INTERNAL
#include "_usart_internal.h"
extern error_t UUSART_ClaimDMAs(Unit *unit);
extern error_t UUSART_SetupDMAs(Unit *unit);
extern void UUSART_DeInitDMAs(Unit *unit);
/** Allocate data structure and set defaults */
error_t UUSART_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
// some defaults
priv->periph_num = 1;
priv->remap = 0;
priv->baudrate = 115200;
priv->parity = 0; //!< 0-none, 1-odd, 2-even
priv->stopbits = 1; //!< 0-half, 1-one, 2-1.5, 3-two
priv->direction = UUSART_DIRECTION_RXTX; // RXTX
priv->hw_flow_control = false;
priv->clock_output = false;
priv->cpol = 0;
priv->cpha = 0;
priv->lsb_first = true; // LSB first is default for UART
priv->width = 8;
priv->data_inv = false;
priv->rx_inv = false;
priv->tx_inv = false;
priv->de_output = false;
priv->de_polarity = 1; // active high
// this should equal to a half-byte length when oversampling by 16 is used (default)
priv->de_assert_time = 8;
priv->de_clear_time = 8;
return E_SUCCESS;
}
/** Claim the peripheral and assign priv->periph */
static inline error_t UUSART_claimPeriph(Unit *unit)
{
struct priv *priv = unit->data;
if (!(priv->periph_num >= 1 && priv->periph_num <= 5)) {
dbg("!! Bad USART periph");
return E_BAD_CONFIG;
}
// assign and claim the peripheral
if (priv->periph_num == 1) {
TRY(rsc_claim(unit, R_USART1));
priv->periph = USART1;
}
else if (priv->periph_num == 2) {
TRY(rsc_claim(unit, R_USART2));
priv->periph = USART2;
}
else if (priv->periph_num == 3) {
TRY(rsc_claim(unit, R_USART3));
priv->periph = USART3;
}
#if defined(USART4)
else if (priv->periph_num == 4) {
TRY(rsc_claim(unit, R_USART4));
priv->periph = USART4;
}
#endif
#if defined(USART5)
else if (priv->periph_num == 5) {
TRY(rsc_claim(unit, R_USART5));
priv->periph = USART5;
}
#endif
else return E_BAD_CONFIG;
TRY(UUSART_ClaimDMAs(unit));
return E_SUCCESS;
}
/** Claim and configure GPIOs used */
static inline error_t UUSART_configPins(Unit *unit)
{
struct priv *priv = unit->data;
// This is written for F072, other platforms will need adjustments
// Configure UART pins (AF)
#define want_ck_pin(priv) ((priv)->clock_output)
#define want_tx_pin(priv) (bool)((priv)->direction & 2)
#define want_rx_pin(priv) (bool)((priv)->direction & 1)
#define want_cts_pin(priv) ((priv)->hw_flow_control==2 || (priv)->hw_flow_control==3)
#define want_rts_pin(priv) ((priv)->de_output || (priv)->hw_flow_control==1 || (priv)->hw_flow_control==3)
/* List of required pins based on the user config */
bool pins_wanted[5] = {
want_ck_pin(priv),
want_tx_pin(priv),
want_rx_pin(priv),
want_cts_pin(priv),
want_rts_pin(priv)
};
#if STM32F072xB
const struct PinAF *mappings = NULL;
// TODO adjust this, possibly remove / split to individual pin config for ..
// the final board
const struct PinAF mapping_1_0[5] = {
{'A', 8, LL_GPIO_AF_1}, // CK
{'A', 9, LL_GPIO_AF_1}, // TX
{'A', 10, LL_GPIO_AF_1}, // RX
{'A', 11, LL_GPIO_AF_1}, // CTS - collides with USB
{'A', 12, LL_GPIO_AF_1}, // RTS - collides with USB
};
const struct PinAF mapping_1_1[5] = {
{'A', 8, LL_GPIO_AF_1}, // CK*
{'B', 6, LL_GPIO_AF_1}, // TX
{'B', 7, LL_GPIO_AF_1}, // RX
{'A', 11, LL_GPIO_AF_1}, // CTS* - collides with USB
{'A', 12, LL_GPIO_AF_1}, // RTS* - collides with USB
};
const struct PinAF mapping_2_0[5] = {
{'A', 4, LL_GPIO_AF_1}, // CK
{'A', 2, LL_GPIO_AF_1}, // TX
{'A', 3, LL_GPIO_AF_1}, // RX
{'A', 0, LL_GPIO_AF_1}, // CTS
{'A', 1, LL_GPIO_AF_1}, // RTS
};
const struct PinAF mapping_2_1[5] = {
{'A', 4, LL_GPIO_AF_1}, // CK*
{'A', 14, LL_GPIO_AF_1}, // TX
{'A', 15, LL_GPIO_AF_1}, // RX
{'A', 0, LL_GPIO_AF_1}, // CTS*
{'A', 1, LL_GPIO_AF_1}, // RTS*
};
const struct PinAF mapping_3_0[5] = {
{'B', 12, LL_GPIO_AF_4}, // CK
{'B', 10, LL_GPIO_AF_4}, // TX
{'B', 11, LL_GPIO_AF_4}, // RX
{'B', 13, LL_GPIO_AF_4}, // CTS
{'B', 14, LL_GPIO_AF_4}, // RTS
};
const struct PinAF mapping_4_0[5] = {
{'C', 12, LL_GPIO_AF_0}, // CK
{'A', 0, LL_GPIO_AF_4}, // TX
{'A', 1, LL_GPIO_AF_4}, // RX
{'B', 7, LL_GPIO_AF_4}, // CTS
{'A', 15, LL_GPIO_AF_4}, // RTS
};
const struct PinAF mapping_4_1[5] = {
{'C', 12, LL_GPIO_AF_0}, // CK*
{'C', 10, LL_GPIO_AF_0}, // TX
{'C', 11, LL_GPIO_AF_0}, // RX
{'B', 7, LL_GPIO_AF_4}, // CTS*
{'A', 15, LL_GPIO_AF_4}, // RTS*
};
if (priv->periph_num == 1) {
// USART1
if (priv->remap == 0) mappings = &mapping_1_0[0];
else if (priv->remap == 1) mappings = &mapping_1_1[0];
else return E_BAD_CONFIG;
}
else if (priv->periph_num == 2) {
// USART2
if (priv->remap == 0) mappings = &mapping_2_0[0];
else if (priv->remap == 1) mappings = &mapping_2_1[0];
else return E_BAD_CONFIG;
}
else if (priv->periph_num == 3) {
// USART3
if (priv->remap == 0) mappings = &mapping_3_0[0];
else return E_BAD_CONFIG;
}
else if (priv->periph_num == 4) {
// USART3
if (priv->remap == 0) mappings = &mapping_4_0[0];
else if (priv->remap == 1) mappings = &mapping_4_1[0];
else return E_BAD_CONFIG;
}
else return E_BAD_CONFIG;
// Apply mappings based on the 'wanted' table
for (int i = 0; i < 5; i++) {
if (pins_wanted[i]) {
if (mappings[i].port == 0) return E_BAD_CONFIG;
TRY(rsc_claim_pin(unit, mappings[i].port, mappings[i].pin));
TRY(hw_configure_gpio_af(mappings[i].port, mappings[i].pin, mappings[i].af));
}
}
#elif GEX_PLAT_F103_BLUEPILL
#error "NO IMPL"
#elif GEX_PLAT_F303_DISCOVERY
#error "NO IMPL"
#elif GEX_PLAT_F407_DISCOVERY
#error "NO IMPL"
#else
#error "BAD PLATFORM!"
#endif
return E_SUCCESS;
}
/** Finalize unit set-up */
error_t UUSART_init(Unit *unit)
{
struct priv *priv = unit->data;
TRY(UUSART_claimPeriph(unit));
TRY(UUSART_configPins(unit));
// --- Configure the peripheral ---
// Enable clock for the peripheral used
hw_periph_clock_enable(priv->periph);
LL_USART_Disable(priv->periph);
{
LL_USART_DeInit(priv->periph);
LL_USART_SetBaudRate(priv->periph, PLAT_APB1_HZ, LL_USART_OVERSAMPLING_16, priv->baudrate);
LL_USART_SetParity(priv->periph,
priv->parity == 0 ? LL_USART_PARITY_NONE :
priv->parity == 1 ? LL_USART_PARITY_ODD
: LL_USART_PARITY_EVEN);
LL_USART_SetStopBitsLength(priv->periph,
priv->stopbits == 0 ? LL_USART_STOPBITS_0_5 :
priv->stopbits == 1 ? LL_USART_STOPBITS_1 :
priv->stopbits == 2 ? LL_USART_STOPBITS_1_5
: LL_USART_STOPBITS_2);
LL_USART_SetTransferDirection(priv->periph,
(priv->direction == UUSART_DIRECTION_RX) ? LL_USART_DIRECTION_RX :
(priv->direction == UUSART_DIRECTION_TX) ? LL_USART_DIRECTION_TX
: LL_USART_DIRECTION_TX_RX);
LL_USART_SetHWFlowCtrl(priv->periph,
priv->hw_flow_control == 0 ? LL_USART_HWCONTROL_NONE :
priv->hw_flow_control == 1 ? LL_USART_HWCONTROL_RTS :
priv->hw_flow_control == 2 ? LL_USART_HWCONTROL_CTS
: LL_USART_HWCONTROL_RTS_CTS);
LL_USART_ConfigClock(priv->periph,
priv->cpha ? LL_USART_PHASE_2EDGE : LL_USART_PHASE_1EDGE,
priv->cpol ? LL_USART_POLARITY_HIGH : LL_USART_POLARITY_LOW,
true); // clock on last bit - TODO configurable?
if (priv->clock_output)
LL_USART_EnableSCLKOutput(priv->periph);
else
LL_USART_DisableSCLKOutput(priv->periph);
LL_USART_SetTransferBitOrder(priv->periph,
priv->lsb_first ? LL_USART_BITORDER_LSBFIRST
: LL_USART_BITORDER_MSBFIRST);
LL_USART_SetDataWidth(priv->periph,
priv->width == 7 ? LL_USART_DATAWIDTH_7B :
priv->width == 8 ? LL_USART_DATAWIDTH_8B
: LL_USART_DATAWIDTH_9B);
LL_USART_SetBinaryDataLogic(priv->periph,
priv->data_inv ? LL_USART_BINARY_LOGIC_NEGATIVE
: LL_USART_BINARY_LOGIC_POSITIVE);
LL_USART_SetRXPinLevel(priv->periph, priv->rx_inv ? LL_USART_RXPIN_LEVEL_INVERTED
: LL_USART_RXPIN_LEVEL_STANDARD);
LL_USART_SetTXPinLevel(priv->periph, priv->tx_inv ? LL_USART_TXPIN_LEVEL_INVERTED
: LL_USART_TXPIN_LEVEL_STANDARD);
if (priv->de_output)
LL_USART_EnableDEMode(priv->periph);
else
LL_USART_DisableDEMode(priv->periph);
LL_USART_SetDESignalPolarity(priv->periph,
priv->de_polarity ? LL_USART_DE_POLARITY_HIGH
: LL_USART_DE_POLARITY_LOW);
LL_USART_SetDEAssertionTime(priv->periph, priv->de_assert_time);
LL_USART_SetDEDeassertionTime(priv->periph, priv->de_clear_time);
// Prepare for DMA
LL_USART_ClearFlag_TC(priv->periph);
LL_USART_EnableDMAReq_RX(priv->periph);
LL_USART_EnableDMAReq_TX(priv->periph);
}
LL_USART_Enable(priv->periph);
// modifies some usart registers that can't be modified when enabled
TRY(UUSART_SetupDMAs(unit));
// timeout based on the baudrate
unit->tick_interval = (uint16_t) ((50 * 1000) / priv->baudrate); // receive timeout (ms)
if (unit->tick_interval < 5) unit->tick_interval = 5;
return E_SUCCESS;
}
/** Tear down the unit */
void UUSART_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// de-init the pins & peripheral only if inited correctly
if (unit->status == E_SUCCESS) {
assert_param(priv->periph);
LL_USART_DeInit(priv->periph);
// Disable clock
hw_periph_clock_disable(priv->periph);
UUSART_DeInitDMAs(unit);
}
// Release all resources
rsc_teardown(unit);
// Free memory
free_ck(unit->data);
unit->data = NULL;
}

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