ifneq ($(findstring MKL26Z64, $(MCU)),) # Cortex version MCU = cortex-m0plus # ARM version, CORTEX-M0/M1 are 6, CORTEX-M3/M4/M7 are 7 ARMV = 6 ## chip/board settings # - the next two should match the directories in # /os/hal/ports/$(MCU_FAMILY)/$(MCU_SERIES) MCU_FAMILY = KINETIS MCU_SERIES = KL2x # Linker script to use # - it should exist either in /os/common/ports/ARMCMx/compilers/GCC/ld/ # or /ld/ # - NOTE: a custom ld script is needed for EEPROM on Teensy LC MCU_LDSCRIPT ?= MKL26Z64 # Startup code to use # - it should exist in /os/common/ports/ARMCMx/compilers/GCC/mk/ MCU_STARTUP ?= kl2x # Board: it should exist either in /os/hal/boards/, # /boards/, or drivers/boards/ BOARD ?= PJRC_TEENSY_LC endif ifneq ($(findstring MK20DX128, $(MCU)),) # Cortex version MCU = cortex-m4 # ARM version, CORTEX-M0/M1 are 6, CORTEX-M3/M4/M7 are 7 ARMV = 7 ## chip/board settings # - the next two should match the directories in # /os/hal/ports/$(MCU_FAMILY)/$(MCU_SERIES) MCU_FAMILY = KINETIS MCU_SERIES = K20x # Linker script to use # - it should exist either in /os/common/ports/ARMCMx/compilers/GCC/ld/ # or /ld/ MCU_LDSCRIPT ?= MK20DX128 # Startup code to use # - it should exist in /os/common/ports/ARMCMx/compilers/GCC/mk/ MCU_STARTUP ?= k20x5 # Board: it should exist either in /os/hal/boards/, # /boards/, or drivers/boards/ BOARD ?= PJRC_TEENSY_3 endif ifneq ($(findstring MK20DX256, $(MCU)),) # Cortex version MCU = cortex-m4 # ARM version, CORTEX-M0/M1 are 6, CORTEX-M3/M4/M7 are 7 ARMV = 7 ## chip/board settings # - the next two should match the directories in # /os/hal/ports/$(MCU_FAMILY)/$(MCU_SERIES) MCU_FAMILY = KINETIS MCU_SERIES = K20x # Linker script to use # - it should exist either in /os/common/ports/ARMCMx/compilers/GCC/ld/ # or /ld/ MCU_LDSCRIPT ?= MK20DX256 # Startup code to use # - it should exist in /os/common/ports/ARMCMx/compilers/GCC/mk/ MCU_STARTUP ?= k20x7 # Board: it should exist either in /os/hal/boards/, # /boards/, or drivers/boards/ BOARD ?= PJRC_TEENSY_3_1 endif ifneq ($(findstring STM32F303, $(MCU)),) # Cortex version MCU = cortex-m4 # ARM version, CORTEX-M0/M1 are 6, CORTEX-M3/M4/M7 are 7 ARMV = 7 ## chip/board settings # - the next two should match the directories in # /os/hal/ports/$(MCU_FAMILY)/$(MCU_SERIES) MCU_FAMILY = STM32 MCU_SERIES = STM32F3xx # Linker script to use # - it should exist either in /os/common/ports/ARMCMx/compilers/GCC/ld/ # or /ld/ MCU_LDSCRIPT ?= STM32F303xC # Startup code to use # - it should exist in /os/common/startup/ARMCMx/compilers/GCC/mk/ MCU_STARTUP ?= stm32f3xx # Board: it should exist either in /os/hal/boards/, # /boards/, or drivers/boards/ BOARD ?= GENERIC_STM32_F303XC USE_FPU ?= yes # Options to pass to dfu-util when flashing DFU_ARGS ?= -d 0483:df11 -a 0 -s 0x08000000:leave DFU_SUFFIX_ARGS ?= -v 0483 -p df11 endif ifneq ($(findstring STM32F072, $(MCU)),) # Cortex version MCU = cortex-m0 # ARM version, CORTEX-M0/M1 are 6, CORTEX-M3/M4/M7 are 7 ARMV = 6 ## chip/board settings # - the next two should match the directories in # /os/hal/ports/$(MCU_FAMILY)/$(MCU_SERIES) MCU_FAMILY = STM32 MCU_SERIES = STM32F0xx # Linker script to use # - it should exist either in /os/common/ports/ARMCMx/compilers/GCC/ld/ # or /ld/ MCU_LDSCRIPT ?= STM32F072xB # Startup code to use # - it should exist in /os/common/startup/ARMCMx/compilers/GCC/mk/ MCU_STARTUP ?= stm32f0xx # Board: it should exist either in /os/hal/boards/, # /boards/, or drivers/boards/ BOARD ?= GENERIC_STM32_F072XB USE_FPU ?= no # Options to pass to dfu-util when flashing DFU_ARGS ?= -d 0483:df11 -a 0 -s 0x08000000:leave DFU_SUFFIX_ARGS ?= -v 0483 -p df11 endif ifneq ($(findstring STM32F042, $(MCU)),) # Cortex version MCU = cortex-m0 # ARM version, CORTEX-M0/M1 are 6, CORTEX-M3/M4/M7 are 7 ARMV = 6 ## chip/board settings # - the next two should match the directories in # /os/hal/ports/$(MCU_FAMILY)/$(MCU_SERIES) MCU_FAMILY = STM32 MCU_SERIES = STM32F0xx # Linker script to use # - it should exist either in /os/common/ports/ARMCMx/compilers/GCC/ld/ # or /ld/ MCU_LDSCRIPT ?= STM32F042x6 # Startup code to use # - it should exist in /os/common/startup/ARMCMx/compilers/GCC/mk/ MCU_STARTUP ?= stm32f0xx # Board: it should exist either in /os/hal/boards/, # /boards/, or drivers/boards/ BOARD ?= GENERIC_STM32_F042X6 USE_FPU ?= no # Options to pass to dfu-util when flashing DFU_ARGS ?= -d 0483:df11 -a 0 -s 0x08000000:leave DFU_SUFFIX_ARGS ?= -v 0483 -p df11 endif ifneq ($(findstring STM32F103, $(MCU)),) # Cortex version MCU = cortex-m3 # ARM version, CORTEX-M0/M1 are 6, CORTEX-M3/M4/M7 are 7 ARMV = 7 ## chip/board settings # - the next two should match the directories in # /os/hal/ports/$(MCU_FAMILY)/$(MCU_SERIES) MCU_FAMILY = STM32 MCU_SERIES = STM32F1xx # Linker script to use # - it should exist either in /os/common/ports/ARMCMx/compilers/GCC/ld/ # or /ld/ MCU_LDSCRIPT ?= STM32F103x8 # Startup code to use # - it should exist in /os/common/startup/ARMCMx/compilers/GCC/mk/ MCU_STARTUP ?= stm32f1xx # Board: it should exist either in /os/hal/boards/, # /boards/, or drivers/boards/ BOARD ?= GENERIC_STM32_F103 USE_FPU ?= no # Options to pass to dfu-util when flashing DFU_ARGS ?= -d 0483:df11 -a 0 -s 0x08000000:leave DFU_SUFFIX_ARGS ?= -v 0483 -p df11 endif ifneq (,$(filter $(MCU),atmega16u2 atmega32u2 atmega16u4 atmega32u4 at90usb646 at90usb1286)) PROTOCOL = LUFA # Processor frequency. # This will define a symbol, F_CPU, in all source code files equal to the # processor frequency in Hz. You can then use this symbol in your source code to # calculate timings. Do NOT tack on a 'UL' at the end, this will be done # automatically to create a 32-bit value in your source code. # # This will be an integer division of F_USB below, as it is sourced by # F_USB after it has run through any CPU prescalers. Note that this value # does not *change* the processor frequency - it should merely be updated to # reflect the processor speed set externally so that the code can use accurate # software delays. F_CPU ?= 16000000 # LUFA specific # # Target architecture (see library "Board Types" documentation). ARCH = AVR8 # Input clock frequency. # This will define a symbol, F_USB, in all source code files equal to the # input clock frequency (before any prescaling is performed) in Hz. This value may # differ from F_CPU if prescaling is used on the latter, and is required as the # raw input clock is fed directly to the PLL sections of the AVR for high speed # clock generation for the USB and other AVR subsections. Do NOT tack on a 'UL' # at the end, this will be done automatically to create a 32-bit value in your # source code. # # If no clock division is performed on the input clock inside the AVR (via the # CPU clock adjust registers or the clock division fuses), this will be equal to F_CPU. F_USB ?= $(F_CPU) # Interrupt driven control endpoint task ifeq (,$(filter $(NO_INTERRUPT_CONTROL_ENDPOINT),yes)) OPT_DEFS += -DINTERRUPT_CONTROL_ENDPOINT endif endif ifneq (,$(filter $(MCU),atmega32a)) # MCU name for avrdude AVRDUDE_MCU = m32 PROTOCOL = VUSB # Processor frequency. # This will define a symbol, F_CPU, in all source code files equal to the # processor frequency in Hz. You can then use this symbol in your source code to # calculate timings. Do NOT tack on a 'UL' at the end, this will be done # automatically to create a 32-bit value in your source code. F_CPU ?= 12000000 # unsupported features for now NO_UART ?= yes NO_SUSPEND_POWER_DOWN ?= yes endif ifneq (,$(filter $(MCU),atmega328p)) # MCU name for avrdude AVRDUDE_MCU = m328p PROTOCOL = VUSB # Processor frequency. # This will define a symbol, F_CPU, in all source code files equal to the # processor frequency in Hz. You can then use this symbol in your source code to # calculate timings. Do NOT tack on a 'UL' at the end, this will be done # automatically to create a 32-bit value in your source code. F_CPU ?= 16000000 # unsupported features for now NO_UART ?= yes NO_SUSPEND_POWER_DOWN ?= yes endif