I would advise against any new design based on ARM7 - it is a legacy ARM architecture. You should check the the vendor's part status and planned obsolescence for any part you intend to design in. No vendor is releasing new designs based on ARM7.
I would also suggest that for DSP algorithms, the DSP features of the Cortex-M4 are more important than its floating point. The ARM Cortex-M CMSIS includes a DSP library that takes advantage of this. Either way fixed-point DSP algorithms will be far more efficient than using floating point.
Cortex-M is a far more efficient design that ARM7 achieving 1.2 DMIPS per MHz compared to less than 1.0 DMIPS per MHz. That coupled with DSP instructions, floating-point, and separate buses for on-chip flags, RAM and peripherals make most code significantly faster on Cortex-M.
The Cortex-M architecture defines the SYSCLK and interrupt controller, wheras on ARM7 these are defined by the chip vendor and vary between vendors making porting of code between them more difficult.
STM32F4xx parts run at upto 180MHz; Most ARM7 parts are 60MHz or less.
Performing a comparison using floating point is almost pointless. Floating point hardware will easily outperform software floating point necessary on ARM7 by a factor of 5 to 10 at least. Unless your application can cope with that drop in performance, it is unsuited to ARM7. However, most applications do not need floating point. Integer or fixed point algorithms can run around 5 times faster than software floating point, so compete with hardware floating point. Remember also that the Cortex-M4 FPU is single precision only.
It would be more reasonable to be comparing Cortex-M3 with Cortex-M4 to test the sensitivity of your application to lack of hardware FP and DSP support.
SDIO performance will be limited by the SDIO interface and the SD card itself (which vary widely in performance even at the same "speed rating") - the load imposed on the processor itself will be very low, or it will spend most of its time waiting for data if your application busy-waits rather than doing something useful while waiting on the SD card. The use of DMA transfers can make the CPU load more-or-less negligible.
The following diagram illustrates how ARM7 is positioned compared with Cortex-M4. The latter is both higher performance and greater capability. At the same clock frequency, Cortex-M4 sites between ARM9 and ARM11 on the performance scale.
I do not think that you need to perform any benchmark tests comparing ARM7 and Cortex M4 since the broad performance figures are already available. What you could perhaps do is measure the CPU load of your existing application on its current platform. If it is low (perhaps < 20%) and it spends most of its time idle, then ARM7 might be feasible. Of course if your application is not running on an RTOS or scheduler with an idle task, then measuring true CPU load might be difficult.