With the T4 transaction code settings being dependent on which clock is choosen to be used in SPI. All of the work had to be done at run time. As such the statically defined ones may not work as you have no idea which clock may be actually used... So moved the work to comput CCR into the SPI.beginTransaction code, which is only called if something like the clock speed is different than the previous call to beginTransaction We can still convert the bit Order and Data Mode parameters into the TCR register value as part of the SPISettings constructor code as these do not depend on external run time settings.

pirms 5 gadiem · 67b17ba831
--- a/SPI.h
+++ b/SPI.h
@@ -1033,60 +1033,35 @@ private:

 //#include "debug/printf.h"

 // TODO......
 //#undef SPI_HAS_TRANSFER_ASYNC

 class SPISettings {
 public:
 	SPISettings(uint32_t clock, uint8_t bitOrder, uint8_t dataMode) {
 		if (__builtin_constant_p(clock)) {
 			init_AlwaysInline(clock, bitOrder, dataMode);
 		} else {
 			init_MightInline(clock, bitOrder, dataMode);
 		}
 	SPISettings(uint32_t clockIn, uint8_t bitOrderIn, uint8_t dataModeIn) : _clock(clockIn) {
 		init_AlwaysInline(bitOrderIn, dataModeIn);
 	}
 	SPISettings() {
 		init_AlwaysInline(4000000, MSBFIRST, SPI_MODE0);

 	SPISettings() : _clock(4000000) {
 		init_AlwaysInline(MSBFIRST, SPI_MODE0);
 	}
 private:
 	void init_MightInline(uint32_t clock, uint8_t bitOrder, uint8_t dataMode) {
 		init_AlwaysInline(clock, bitOrder, dataMode);
 	}
 	void init_AlwaysInline(uint32_t clock, uint8_t bitOrder, uint8_t dataMode)
 	void init_AlwaysInline(uint8_t bitOrder, uint8_t dataMode)
 	  __attribute__((__always_inline__)) {
 		// TODO: Need to check timings as related to chip selects?
 				
 		const uint32_t clk_sel[4] = {664615384,  // PLL3 PFD1
 					     720000000,  // PLL3 PFD0
 					     528000000,  // PLL2
 					     396000000}; // PLL2 PFD2				
 		uint32_t cbcmr = CCM_CBCMR;
 		uint32_t clkhz = clk_sel[(cbcmr >> 4) & 0x03] / (((cbcmr >> 26 ) & 0x07 ) + 1);  // LPSPI peripheral clock
 		
 		uint32_t d, div;		
 		if (clock == 0) clock =1;
 		d= clkhz/clock;
 		if (d && clkhz/d > clock) d++;
 		if (d > 257) d= 257;  // max div
 		if (d > 2) {
 			div = d-2;
 		} else {
 			div =0;
 		}
 		ccr = LPSPI_CCR_SCKDIV(div) | LPSPI_CCR_DBT(div/2);
 		tcr = LPSPI_TCR_FRAMESZ(7);    // TCR has polarity and bit order too
 			tcr = LPSPI_TCR_FRAMESZ(7);    // TCR has polarity and bit order too

 		// handle LSB setup 
 		if (bitOrder == LSBFIRST) tcr |= LPSPI_TCR_LSBF;
 			// handle LSB setup 
 			if (bitOrder == LSBFIRST) tcr |= LPSPI_TCR_LSBF;

 		// Handle Data Mode
 		if (dataMode & 0x08) tcr |= LPSPI_TCR_CPOL;
 			// Handle Data Mode
 			if (dataMode & 0x08) tcr |= LPSPI_TCR_CPOL;

 		// Note: On T3.2 when we set CPHA it also updated the timing.  It moved the 
 		// PCS to SCK Delay Prescaler into the After SCK Delay Prescaler	
 		if (dataMode & 0x04) tcr |= LPSPI_TCR_CPHA; 
 			// Note: On T3.2 when we set CPHA it also updated the timing.  It moved the 
 			// PCS to SCK Delay Prescaler into the After SCK Delay Prescaler	
 			if (dataMode & 0x04) tcr |= LPSPI_TCR_CPHA; 
 	}
 	uint32_t ccr; // clock config, pg 2660 (RT1050 ref, rev 2)

 	inline uint32_t clock() {return _clock;}

 	uint32_t _clock;
 	uint32_t tcr; // transmit command, pg 2664 (RT1050 ref, rev 2)
 	friend class SPIClass;
 };
@@ -1203,13 +1178,39 @@ public:
 		#endif

 		//printf("trans\n");
 		if (settings.clock() != _clock) {
 			static const uint32_t clk_sel[4] = {664615384,  // PLL3 PFD1
 						     720000000,  // PLL3 PFD0
 						     528000000,  // PLL2
 						     396000000}; // PLL2 PFD2				

 		    // First save away the new settings..
 		    _clock = settings.clock();

 			uint32_t cbcmr = CCM_CBCMR;
 			uint32_t clkhz = clk_sel[(cbcmr >> 4) & 0x03] / (((cbcmr >> 26 ) & 0x07 ) + 1);  // LPSPI peripheral clock
 			
 			uint32_t d, div;		
 			d = _clock ? clkhz/_clock : clkhz;

 			if (d && clkhz/d > _clock) d++;
 			if (d > 257) d= 257;  // max div
 			if (d > 2) {
 				div = d-2;
 			} else {
 				div =0;
 			}
 	
 			_ccr = LPSPI_CCR_SCKDIV(div) | LPSPI_CCR_DBT(div/2);

 		} 
 		//Serial.printf("SPI.beginTransaction CCR:%x TCR:%x\n", _ccr, settings.tcr);
 		port().CR = 0;
 		port().CFGR1 = LPSPI_CFGR1_MASTER | LPSPI_CFGR1_SAMPLE;
 		port().CCR = settings.ccr;
 		port().CCR = _ccr;
 		port().TCR = settings.tcr;
 		//port().CCR = LPSPI_CCR_SCKDIV(4);
 		//port().TCR = LPSPI_TCR_FRAMESZ(7);
 		port().CR = LPSPI_CR_MEN;

 	}

 	// Write to the SPI bus (MOSI pin) and also receive (MISO pin)
@@ -1264,6 +1265,7 @@ public:
 			if (interruptMasksUsed & 0x08) NVIC_ISER3 = interruptSave[3];
 			if (interruptMasksUsed & 0x10) NVIC_ISER4 = interruptSave[4];
 		}
 		//Serial.printf("SPI.endTransaction CCR:%x TCR:%x\n", port().CCR, port().TCR);
 	}

 	// Disable the SPI bus
@@ -1327,10 +1329,13 @@ private:
 	const SPI_Hardware_t & hardware() { return *(const SPI_Hardware_t *)hardware_addr; }
 	uintptr_t port_addr;
 	uintptr_t hardware_addr;

 	uint32_t _clock = 0;
 	uint32_t _ccr = 0;

 	//KINETISK_SPI_t & port() { return *(KINETISK_SPI_t *)port_addr; }
 //	IMXRT_LPSPI_t * const port;
 //	const SPI_Hardware_t * const hardware;

 	void updateCTAR(uint32_t ctar);
 	uint8_t miso_pin_index = 0;
 	uint8_t mosi_pin_index = 0;