#include #include #include #include #include "runmem.h" #include "mem_man.h" #ifdef ENABLE_LOGGING #define LOG(...) printf(__VA_ARGS__) #define BLOG(...) printf(__VA_ARGS__) #elif ENABLE_BASIC_LOGGING #define LOG(...) #define BLOG(...) printf(__VA_ARGS__) #else #define LOG(...) #define BLOG(...) #endif /* Globals declared extern in runmem.h */ uint8_t *data_memory = NULL; uint32_t data_memory_len = 0; uint8_t *executable_memory = NULL; uint32_t executable_memory_len = 0; entry_point_t entr_point = NULL; int data_offs = 0; void patch(uint8_t *patch_addr, uint32_t patch_mask, int32_t value) { uint32_t *val_ptr = (uint32_t*)patch_addr; uint32_t original = *val_ptr; uint32_t shift_factor = patch_mask & -patch_mask; uint32_t new_value = (original & ~patch_mask) | (((uint32_t)value * shift_factor) & patch_mask); *val_ptr = new_value; } void patch_hi21(uint8_t *patch_addr, int32_t page_offset) { uint32_t instr = *(uint32_t *)patch_addr; // Split page_offset into immhi (upper 19 bits) and immlo (lower 2 bits) uint32_t immlo = page_offset & 0x3; // bits[1:0] uint32_t immhi = (page_offset >> 2) & 0x7FFFF; // bits[20:2] // Clear previous imm fields: immhi (bits[23:5]) and immlo (bits[30:29]) instr &= ~((0x7FFFFu << 5) | (0x3 << 29)); // Set new immhi and immlo instr |= (immhi << 5) | (immlo << 29); *(uint32_t *)patch_addr = instr; } void free_memory() { deallocate_memory(executable_memory, executable_memory_len); deallocate_memory(data_memory, data_memory_len); executable_memory_len = 0; data_memory_len = 0; } int update_data_offs() { if (data_memory && executable_memory && (data_memory - executable_memory > 0x7FFFFFFF || executable_memory - data_memory > 0x7FFFFFFF)) { perror("Error: code and data memory to far apart"); return 0; } if (data_memory && executable_memory && (data_memory - executable_memory > 0x7FFFFFFF || executable_memory - data_memory > 0x7FFFFFFF)) { perror("Error: code and data memory to far apart"); return 0; } data_offs = (int)(data_memory - executable_memory); return 1; } int floor_div(int a, int b) { return a / b - ((a % b != 0) && ((a < 0) != (b < 0))); } int parse_commands(uint8_t *bytes) { int32_t value; uint32_t command; uint32_t patch_mask; int32_t patch_scale; uint32_t offs; uint32_t size; int end_flag = 0; uint32_t rel_entr_point = 0; while(!end_flag) { command = *(uint32_t*)bytes; bytes += 4; switch(command) { case ALLOCATE_DATA: size = *(uint32_t*)bytes; bytes += 4; data_memory = allocate_data_memory(size); data_memory_len = size; LOG("ALLOCATE_DATA size=%i mem_addr=%p\n", size, (void*)data_memory); if (!update_data_offs()) end_flag = -4; break; case COPY_DATA: offs = *(uint32_t*)bytes; bytes += 4; size = *(uint32_t*)bytes; bytes += 4; LOG("COPY_DATA offs=%i size=%i\n", offs, size); memcpy(data_memory + offs, bytes, size); bytes += size; break; case ALLOCATE_CODE: size = *(uint32_t*)bytes; bytes += 4; executable_memory = allocate_executable_memory(size); executable_memory_len = size; LOG("ALLOCATE_CODE size=%i mem_addr=%p\n", size, (void*)executable_memory); //LOG("# d %i c %i off %i\n", data_memory, executable_memory, data_offs); if (!update_data_offs()) end_flag = -4; break; case COPY_CODE: offs = *(uint32_t*)bytes; bytes += 4; size = *(uint32_t*)bytes; bytes += 4; LOG("COPY_CODE offs=%i size=%i\n", offs, size); memcpy(executable_memory + offs, bytes, size); bytes += size; break; case PATCH_FUNC: offs = *(uint32_t*)bytes; bytes += 4; patch_mask = *(uint32_t*)bytes; bytes += 4; patch_scale = *(int32_t*)bytes; bytes += 4; value = *(int32_t*)bytes; bytes += 4; LOG("PATCH_FUNC patch_offs=%i patch_mask=%#08x scale=%i value=%i\n", offs, patch_mask, patch_scale, value); patch(executable_memory + offs, patch_mask, value / patch_scale); break; case PATCH_OBJECT: offs = *(uint32_t*)bytes; bytes += 4; patch_mask = *(uint32_t*)bytes; bytes += 4; patch_scale = *(int32_t*)bytes; bytes += 4; value = *(int32_t*)bytes; bytes += 4; LOG("PATCH_OBJECT patch_offs=%i patch_mask=%#08x scale=%i value=%i\n", offs, patch_mask, patch_scale, value); patch(executable_memory + offs, patch_mask, value / patch_scale + data_offs / patch_scale); break; case PATCH_OBJECT_ABS: offs = *(uint32_t*)bytes; bytes += 4; patch_mask = *(uint32_t*)bytes; bytes += 4; patch_scale = *(int32_t*)bytes; bytes += 4; value = *(int32_t*)bytes; bytes += 4; LOG("PATCH_OBJECT_ABS patch_offs=%i patch_mask=%#08x scale=%i value=%i\n", offs, patch_mask, patch_scale, value); patch(executable_memory + offs, patch_mask, value / patch_scale); break; case PATCH_OBJECT_HI21: offs = *(uint32_t*)bytes; bytes += 4; patch_mask = *(uint32_t*)bytes; bytes += 4; patch_scale = *(int32_t*)bytes; bytes += 4; value = *(int32_t*)bytes; bytes += 4; LOG("PATCH_OBJECT_HI21 patch_offs=%i patch_mask=%#08x scale=%i value=%i res_value=%i\n", offs, patch_mask, patch_scale, value, floor_div(data_offs + value, patch_scale) - (int32_t)offs / patch_scale); patch_hi21(executable_memory + offs, floor_div(data_offs + value, patch_scale) - (int32_t)offs / patch_scale); break; case ENTRY_POINT: LOG("ENTRY_POINT rel_entr_point=%i\n", rel_entr_point); rel_entr_point = *(uint32_t*)bytes; bytes += 4; entr_point = (entry_point_t)(executable_memory + rel_entr_point); mark_mem_executable(executable_memory, executable_memory_len); break; case RUN_PROG: LOG("RUN_PROG\n"); int ret = entr_point(); BLOG("Return value: %i\n", ret); break; case READ_DATA: offs = *(uint32_t*)bytes; bytes += 4; size = *(uint32_t*)bytes; bytes += 4; BLOG("READ_DATA offs=%i size=%i data=", offs, size); for (uint32_t i = 0; i < size; i++) { printf("%02X ", data_memory[offs + i]); } printf("\n"); break; case FREE_MEMORY: LOG("FREE_MENORY\n"); free_memory(); break; case DUMP_CODE: LOG("DUMP_CODE\n"); end_flag = 2; break; case END_COM: LOG("END_COM\n"); end_flag = 1; break; default: LOG("Unknown command\n"); end_flag = -1; break; } } return end_flag; }