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stmbl/tools/gentable.c
2018-03-16 01:59:36 +01:00

261 lines
9.7 KiB
C

#include <stdio.h>
#include <string.h>
#include <math.h>
#include <inttypes.h>
#include "../inc/sserial.h"
#include "../shared/defines.h"
memory_t memory;
uint8_t *heap_ptr;
uint32_t timeout;
pd_table_t pd_table;
uint16_t add_pd(char *name_string, char *unit_string, uint8_t data_size_in_bits, uint8_t data_type, uint8_t data_dir, float param_min, float param_max) {
process_data_descriptor_t pdr;
pdr.record_type = RECORD_TYPE_PROCESS_DATA_RECORD;
pdr.data_size = data_size_in_bits;
pdr.data_type = data_type;
pdr.data_direction = data_dir;
pdr.param_min = param_min;
pdr.param_max = param_max;
pdr.data_addr = MEMPTR(*heap_ptr);
heap_ptr += NUM_BYTES(data_size_in_bits);
// this aligns the heap pointer to 32bit. Not doing this causes the floats in the pd to be misaligned, which crashes the arm.
if((uint32_t)heap_ptr % 4) {
heap_ptr += 4 - (uint32_t)heap_ptr % 4;
}
memcpy(heap_ptr, &pdr, sizeof(process_data_descriptor_t));
// note that we don't store the names in the struct anymore. The fixed-length struct is copied into memory, and then the nmaes go in directly behind it, so they'll read out properly
uint16_t pd_ptr = MEMPTR(*heap_ptr); // save off the ptr to return, before we modify the heap ptr
heap_ptr = (uint8_t *)&(((process_data_descriptor_t *)heap_ptr)->names);
// copy the strings in after the pd
strcpy((char *)heap_ptr, unit_string);
heap_ptr += strlen(unit_string) + 1;
strcpy((char *)heap_ptr, name_string);
heap_ptr += strlen(name_string) + 1;
// moved this up to before the pd record
/*
// this aligns the heap pointer to 32bit. Not doing this causes the floats in the pd to be misaligned, which crashes the arm.
if((uint32_t)heap_ptr % 4){
heap_ptr += 4 - (uint32_t)heap_ptr % 4;
}
*/
return pd_ptr;
}
uint16_t add_mode(char *name_string, uint8_t index, uint8_t type) {
mode_descriptor_t mdr;
mdr.record_type = RECORD_TYPE_MODE_DATA_RECORD;
mdr.index = index;
mdr.type = type; //hw = 0, sw = 1
mdr.unused = 0x00;
memcpy(heap_ptr, &mdr, sizeof(mode_descriptor_t));
uint16_t md_ptr = MEMPTR(*heap_ptr);
heap_ptr = (uint8_t *)&(((mode_descriptor_t *)heap_ptr)->names);
strcpy((char *)heap_ptr, name_string);
heap_ptr += strlen(name_string) + 1;
return md_ptr;
}
void metadata(pd_metadata_t *pdm, process_data_descriptor_t *ptr) {
pdm->ptr = ptr;
pdm->range = ptr->data_type == DATA_TYPE_SIGNED ? MAX(ABS(ptr->param_min), ABS(ptr->param_max)) * 2 : ptr->param_max;
pdm->bitmax = (1 << ptr->data_size) - 1;
}
void print_pd(process_data_descriptor_t *pd) {
int strl = strlen(&pd->names);
char *unit = &pd->names;
char *name = &pd->names + strl + 1;
switch(pd->data_type) {
case DATA_TYPE_PAD:
printf("uint32_t padding : %u;\n", pd->data_size);
break;
case DATA_TYPE_BITS:
for(int i = 0; i < pd->data_size; i++) {
printf("uint32_t %s_%i : 1;\n", name, i);
}
break;
case DATA_TYPE_UNSIGNED:
if(pd->data_size == 8) {
printf("uint8_t %s;\n", name);
} else {
printf("warning: unsupported int size!\n");
}
break;
case DATA_TYPE_SIGNED:
if(pd->data_size == 8) {
printf("int8_t %s;\n", name);
} else {
printf("warning: unsupported int size!\n");
}
break;
case DATA_TYPE_FLOAT:
//TODO: check size
if(pd->data_size != 32) {
printf("warning: unsupported float size!");
}
printf("float %s;\n", name);
break;
case DATA_TYPE_BOOLEAN:
printf("uint32_t %s : %u;\n", name, pd->data_size);
break;
case DATA_TYPE_NONVOL_UNSIGNED:
case DATA_TYPE_NONVOL_SIGNED:
case DATA_TYPE_STREAM:
case DATA_TYPE_ENCODER:
case DATA_TYPE_ENCODER_H:
case DATA_TYPE_ENCODER_L:
default:
printf("unsupported data type: 0x%02X\n", pd->data_type);
}
}
int main() {
heap_ptr = memory.heap;
uint16_t input_bits = 8; // this starts at 8 bits = 1 byte for the fault byte
uint16_t output_bits = 0;
// these are temp toc arrays that the macros will write pointers into. the tocs get copied to main memory after everything else is written in
uint16_t ptoc[32];
uint16_t gtoc[32];
uint16_t *ptocp = ptoc;
uint16_t *gtocp = gtoc;
process_data_descriptor_t *last_pd;
ADD_PROCESS_VAR(("pos_cmd", "rad", 32, DATA_TYPE_FLOAT, DATA_DIRECTION_OUTPUT, -INFINITY, INFINITY));
metadata(&(pd_table.pos_cmd), last_pd);
ADD_PROCESS_VAR(("vel_cmd", "rad", 32, DATA_TYPE_FLOAT, DATA_DIRECTION_OUTPUT, -INFINITY, INFINITY));
metadata(&(pd_table.vel_cmd), last_pd);
ADD_PROCESS_VAR(("out", "none", 4, DATA_TYPE_BITS, DATA_DIRECTION_OUTPUT, 0, 1));
metadata(&(pd_table.output_pins), last_pd);
ADD_PROCESS_VAR(("enable", "none", 1, DATA_TYPE_BOOLEAN, DATA_DIRECTION_OUTPUT, 0, 1));
metadata(&(pd_table.enable), last_pd);
ADD_PROCESS_VAR(("pos_fb", "rad", 32, DATA_TYPE_FLOAT, DATA_DIRECTION_INPUT, -INFINITY, INFINITY));
metadata(&(pd_table.pos_fb), last_pd);
ADD_PROCESS_VAR(("vel_fb", "rad", 32, DATA_TYPE_FLOAT, DATA_DIRECTION_INPUT, -INFINITY, INFINITY));
metadata(&(pd_table.vel_fb), last_pd);
ADD_PROCESS_VAR(("current", "A", 8, DATA_TYPE_SIGNED, DATA_DIRECTION_INPUT, -30, 30));
metadata(&(pd_table.current), last_pd);
ADD_PROCESS_VAR(("in", "none", 4, DATA_TYPE_BITS, DATA_DIRECTION_INPUT, -100, 100));
metadata(&(pd_table.input_pins), last_pd);
ADD_PROCESS_VAR(("fault", "none", 1, DATA_TYPE_BOOLEAN, DATA_DIRECTION_INPUT, 0, 1));
metadata(&(pd_table.fault), last_pd);
ADD_PROCESS_VAR(("index_enable", "none", 1, DATA_TYPE_BOOLEAN, DATA_DIRECTION_BI_DIRECTIONAL, 0, 1));
metadata(&(pd_table.index_enable), last_pd);
ADD_GLOBAL_VAR(("scale", "none", 32, DATA_TYPE_FLOAT, DATA_DIRECTION_OUTPUT, -INFINITY, INFINITY));
ADD_MODE(("Position mode", 0, 1));
// automatically create padding pds based on the mod remainder of input/output bits
if(input_bits % 8)
ADD_PROCESS_VAR(("padding", "", 8 - (input_bits % 8), DATA_TYPE_PAD, DATA_DIRECTION_INPUT, 0, 0));
if(output_bits % 8)
ADD_PROCESS_VAR(("padding", "", 8 - (output_bits % 8), DATA_TYPE_PAD, DATA_DIRECTION_OUTPUT, 0, 0));
// now that all the toc entries have been added, write out the tocs to memory and set up the toc pointers
//calculate bytes from bits
memory.discovery.input = input_bits >> 3;
memory.discovery.output = output_bits >> 3;
memory.discovery.ptocp = MEMPTR(*heap_ptr);
for(uint8_t i = 0; i < ptocp - ptoc; i++) {
*heap_ptr++ = ptoc[i] & 0x00FF;
*heap_ptr++ = (ptoc[i] & 0xFF00) >> 8;
}
// this is the ptoc end marker
*heap_ptr++ = 0x00;
*heap_ptr++ = 0x00;
memory.discovery.gtocp = MEMPTR(*heap_ptr);
for(uint8_t i = 0; i < gtocp - gtoc; i++) {
*heap_ptr++ = gtoc[i] & 0x00FF;
*heap_ptr++ = (gtoc[i] & 0xFF00) >> 8;
}
// this is the gtoc end marker
*heap_ptr++ = 0x00;
*heap_ptr++ = 0x00;
// printf("gtoc:%u\n",memory.discovery.gtocp);
// printf("ptoc:%u\n",memory.discovery.ptocp);
// printf("%i\n",sizeof(memory_t));
//printf("%u\n",MEMPTR(*heap_ptr));
int nl = 0;
printf("uint8_t sserial_slave[] = {\n");
for(int i = 0; i < MEMPTR(*heap_ptr); i++) {
//printf("%u %c\n",memory.bytes[i],memory.bytes[i]);
printf("0x%02X,", memory.bytes[i]);
nl++;
if(nl > 7) {
nl = 0;
printf("// %i..%i\n", i - 7, i);
}
}
printf("\n};\n\n");
printf("const discovery_rpc_t discovery = {\n");
printf(" .ptocp = 0x%04X,\n", memory.discovery.ptocp);
printf(" .gtocp = 0x%04X,\n", memory.discovery.gtocp);
printf(" .input = %u,\n", memory.discovery.input);
printf(" .output = %u,\n", memory.discovery.output);
printf("};\n\n");
printf("typedef struct {\n");
ptocp = (uint16_t *)(memory.bytes + memory.discovery.ptocp);
gtocp = (uint16_t *)(memory.bytes + memory.discovery.gtocp);
while(*ptocp != 0x0000) {
process_data_descriptor_t *pd = (process_data_descriptor_t *)(memory.bytes + *ptocp++);
//printf("0x%02X\n",pd->data_direction);
if((pd->data_direction == DATA_DIRECTION_OUTPUT || pd->data_direction == DATA_DIRECTION_BI_DIRECTIONAL) && pd->record_type == RECORD_TYPE_PROCESS_DATA_RECORD) {
print_pd(pd);
}
// printf("pd has data at %x with value %x\n", pd->data_addr, MEMU16(pd->data_addr));
}
printf("} sserial_out_process_data_t; //size:%u bytes\n", memory.discovery.output);
printf("_Static_assert(sizeof(sserial_out_process_data_t) == %u, \"sserial_out_process_data_t size error!\");\n", memory.discovery.output);
printf("\n");
printf("typedef struct {\n");
ptocp = (uint16_t *)(memory.bytes + memory.discovery.ptocp);
while(*ptocp != 0x0000) {
process_data_descriptor_t *pd = (process_data_descriptor_t *)(memory.bytes + *ptocp++);
//printf("0x%02X\n",pd->data_direction);
if((pd->data_direction == DATA_DIRECTION_INPUT || pd->data_direction == DATA_DIRECTION_BI_DIRECTIONAL) && pd->record_type == RECORD_TYPE_PROCESS_DATA_RECORD) {
print_pd(pd);
}
// printf("pd has data at %x with value %x\n", pd->data_addr, MEMU16(pd->data_addr));
}
printf("} sserial_in_process_data_t; //size:%u bytes\n", memory.discovery.input - 1);
printf("_Static_assert(sizeof(sserial_in_process_data_t) == %u, \"sserial_in_process_data_t size error!\");\n", memory.discovery.input - 1);
gtocp = (uint16_t *)(memory.bytes + memory.discovery.gtocp);
while(*gtocp != 0x0000) {
process_data_descriptor_t *pd = (process_data_descriptor_t *)(memory.bytes + *gtocp++);
if(pd->record_type == RECORD_TYPE_PROCESS_DATA_RECORD) {
int strl = strlen(&pd->names);
char *unit = &pd->names;
char *name = &pd->names + strl + 1;
printf("//global name:%s addr:0x%x size:%i dir:0x%x\n", name, pd->data_addr, pd->data_size, pd->data_direction);
printf("#define %s_address %i\n", name, pd->data_addr);
}
}
}